Sd30mtsw01ci Manual Sw Sd300 Eng Revc w

VARIABLE SPEED DRIVE

Variable Speed Drive

Programming and Software Manual

Variable Speed Drive

Programming and Software Manual SD300_2.20

Edition: March 2017

SD30MTSW01CI Rev. C

SD300 SERIES

POWER ELECTRONICS

ABOUT AB OUT THIS MANUAL MANUA L PURPOSE

This manual contains important instructions for the installation and maintenance of Power Electronics SD300 variable speed drives.

INTENDED USERS

This manual is intended for qualified customers who will install, operate and maintain Power Electronics SD300 variable speed drives. Only trained electricians approved by the installation company may install and commi ssion th e drives. The instructio ns assume that the installer is familiar with electrical installation rules and regulations.

REFERENCE MANUALS

The following reference guides are available for the SD300 variable speed drives: • •

SD300 Programming and Software Manual. SD300 Hardware and Installation Manual.

POWER ELECTRONICS CONTACT INFORMATION

Power Electronics, S.A. C/ Leonardo da Vinci, 24 – 26 46980 – PATERNA SPAIN Tel. 902 40 20 70 (Spain) • Tel. (+34) 96 136 65 57 • Fax (+34) 96 131 82 01

Email: [email protected] Website: www.power-electronics.com

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ABOUT

SD300 SERIES

POWER ELECTRONICS

SAFETY SYMBOLS Always follow safety instructions to prevent accidents and potential hazards from occurring. In this manual, safety messages are classified as follows:

WARNING

CAUTION

Identifies potentially hazardous situations where dangerous voltage may be present which if not avoided could result in minor personal injury, serious injury or death Be extremely careful and follow the instructions to avoid the risk of electrical shocks. Identifies potentially hazardous situations which if not avoided could result in product damage or minor or moderate personal injury. Read the message and follow the instructions carefully.

NOTICE

Identifies important measures to take in order to prevent damage equipment and warranty lost, as well as encouraging good use and environmental practices.

Other symbols used in this manual for CAUTION messages are the following:

Hot surface. Be careful and follow the instructions to avoid burns and personal injuries. Risk of fire. Be careful and follow the instructions to prevent causing an unintentional fire.

SAFETY SYMBOLS

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Revisions

Date

Revision

Description

17 / 02 / 2017 28 / 02 / 2017

A B

31 / 03 / 2017

C

First edition. Changes in configuration and visualization parameters. Misprints corrections. Modbus address map. Misprintis corrections.

The equipment and technical documentation are periodically updated. Power Electronics reserves the right to modify all or part of the contents of this manual without previous notice. To consult the most updated information of this product, you may access through our website www.power-electronics.com where the latest version of this manual can be downloaded.

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REVISIONS

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SD300 SERIES

TABLE OF CONTENTS Abou Ab ou t thi t hi s m anual anu al ............................................................... ................................................................. ....... 2 SAFETY INSTRUCTIONS ............................................................... ............................................................. 6 1.

DISPLAY AND CONTROL UNITS .............................................................. ........................................ 9 1.1. Seven Segment Display ............................................................ .................................................. 9 1.2. LCD Display ......................................................................................................................... ........................................................ ...................................................................... ..... 11

2.

STATUS MESSA GES ............................................................ ........................................................... 14 2.1. List of Status Messages ................................................................................. ................ ............................................................................................ ........................... 14

3.

WARNING & FAULT MESSAGES ................................................................................................... 15 3.1. List of Warning Messages ......................................................... ................................................ 15 3.2. List of Fault Messages & Troubleshooting ................................................................ ................................................................................. ................. 16 3.2.1. List of fault messages ....................................................................................................... 17 3.2.2. Fault troubleshooting .................................................................. ...................................... 19

4.

VISUALIZA TION AND STATUS STA TUS PARAMETERS PARAM ETERS ............................................................. ................ 22 4.1. Parameters SV.1 – Motor Visualization .......................................................... ..................................................................................... ........................... 22 4.2. Parameters SV.2 – Drive Visualization ...................................................................................... 23 4.3. Parameters SV.3 – External Visualization ................................................................ ................................................................................. ................. 23 4.4. Parameters SV.4 – Internal Visualization .................................................................................. 23 4.5. Parameters SV.5 – PID Visualization ........................................................................................ 23 4.6. Parameters SV.6 – Registers ......................................................................... ........................... 23

5.

DESCRIPTION OF PROGRAMMING PARAMETERS ..................................................................... 24 5.1. Group 0: Operation ......................................................... .................................................................................................................... ........................................................... 25 5.2. Group 1 – G1: Drive  dr.......................................................... .......................................................................................................... ................................................ 25 5.3. Group 2 – G2: Basic Functions  bA............................................................. ........................................................................................ ........................... 29 5.4. Group 3 – G3: Expanded Functions  Ad ................................................................................ .......................................... ...................................... 34 5.5. Group 4 – G4: Control Functions  Cn.......................................................... ..................................................................................... ........................... 39 5.6. Group 5 – G5: Inputs  In ................................................................................................ ................................. ....................................................................... ........ 43 5.7. Group 6 – G6: Outputs  OU ................................................................................................... .................................................. ................................................. 48 5.8. Group 7 – G7: Communication Bus  CM................................................................ ................................................................................ ................ 52 5.9. Group 8 – G8: PID  AP .......................................................................................................... ............................................... ........................................................... 54 5.10. Group 9 – G9: Protections  Pr .......................................................... ................................................................................................ ...................................... 57 5.11. Group 10 – G10: Second Motor  M2 ........................................................... ...................................................................................... ........................... 62 5.12. Group 11 – G11: PLC Sequence  US .................................................................................... ......................................................... ........................... 64 5.13. Group 12 – G12: PLC Function  UF ............................................................ ....................................................................................... ........................... 65 5.14. Group 13 – G13: Fault History ............................................................. ................................................................................................... ...................................... 68

6.

MODBUS COMMUNICATION .......................................................... ................................................ 70 6.1. Introduction.......................................................... ........................................................................................................................... ...................................................................... ..... 70 6.2. Supported Modbus Function Codes .......................................................................................... 71 6.2.1. Modbus Function Code Nº 3: Registers Reading ............................................................. ............................................. ................ 71 6.2.2. Modbus Function Code Nº 16: Registers W riting......................................................... .............................................................. ..... 72 6.3. Addressing Modes ............................................................................................................. ........ 72 6.3.1. Broadcast Addressing Mode ....................................................... ............................................................................................. ...................................... 72 6.4. Summary of Modbus Addresses ............................................................................... .............. ................................................................................. ................ 73 6.4.1. Common Area................................................................................................................... Area........................................................ ........................................................... 73 6.4.2. Monitoring Parameters ..................................................................................................... .................................................... ................................................. 74 6.4.3. Control Parameters........................................................... ........................................................................................................... ................................................ 77 6.4.4. Memory Control Area....................................................... ........................................................................................................ ................................................. 77 6.4.5. Programming Parameters........................................................... ................................................................................................. ...................................... 78 6.4.6. Visualization Parameters ............................................................ ...................................... 93

7.

CONFIGURATION REGISTER ................................................................................................. ........ 94

TABLE OF CONTENTS

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SAFETY INSTRUCTIONS IMPORTANT! Read carefully this manual to maximize the performance of the product and to ensure its safe use. In order to use appropriately the drive, please, follow all instructions described in the installation manual referred to transport, installation, electrical connection and commissioning of the equipment. Power Electronics accepts no responsibility or liability for partial or total damages resulting from inappropriate equipment use. Please, pay careful attention to the following recommendations:

WARNING Do not run the dri ve with the front c over removed. Otherwise, you may get an electric shock. The drive does not remove the voltage from its input terminals. Before working on the drive, isolate the whole drive from the suppl y. If you do not remove the power supply, you may get an electric shock. Do not remove the cover except except for periodic i nspections or wi ring, even if the input power is not applied. Otherwise, you may get an electric shock. Before opening the covers for wir ing and periodic inspections, ensure DC voltage has been been full y discharged. Check Check with a multimeter the followi ng measures: Measure between the output power busbars U, V, W and the cabinet and check that the • voltage is around 0V. • Measure Measure t hat the DC link termin als P2(+), P2(+), N(-) N(-) and and c hassis volt age are below 30VDC. 30VDC. Otherwise, you may get an electric shock. Operate Operate the drive wi th dr y hands. Otherwise, you may get an electric shock. Do not use cables with damaged damaged insul ation. Otherwise, you may get an electric shock. Do not subj ect the cables to abrasions, excessive stress, heavy heavy loads or pinching . Otherwise, you may get an electric shock. Do not make any any insul ation or volt age withstand tests on the motor wh ile the drive is connected.

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SAFETY INSTRUCTIONS

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POWER ELECTRONICS

CAUTION Install the drive on a non-flammable surface. Do not place flammable material nearby. Otherwise, a fire could occur. Disconnect the input power if the dr ive is damaged. Otherwise, it could result in a secondary accident or fire. Do not allow lint, paper, wood chips , dust, metallic metallic c hips or o ther foreign matter into t he drive. Otherwise, a fire or accident could occur. The drive becomes hot during operation. Wait until it cools down before performing any actions. Touching hot parts may result in skin burns. Do not apply power to a damaged drive or to a drive with parts missin g, even even if the installation is complete. Otherwise, you may get an electric shock.

NOTICE RECEPTION ▪

SD300 drives are carefully carefully tested and perfectly packed before delivering.

▪ In

the event of transport damage, please ensure to notify the transport agency and POWER ELECTRONICS: ELECTRONICS: 902 40 20 70 (International +34 96 136 65 57), or your nearest agent, within 24hrs from receiving the goods.

UNPACKING ▪

Make sure model and serial number of the variable speed drive are the the same on the box, delivery note and unit.

▪

Each variable speed drive is delivered with Hardware Hardware and Software Software technical manuals.

RECYCLING ▪

Packing of the equipment should be recycled. For this, it is necessary necessary to separate the different included materials (plastic, paper, cardboard...) and deposit them on proper banks.

▪

Waste products of electric and and electronic devices should be selectively collected for their correct environmental management.

ELECTROMAGNETIC COMPATIBILITY (EMC) ▪

The drive is intended to be used in industrial environments (Second Environment). It achieves compliance with C3 category defined in IEC/EN 61800-3 standard when the installation recommendation within this manual are followed.

▪

Select communication and control system according to the drive EMC EMC environment. Otherwise, systems could suffer from interferences due to a low EMS level.

SAFETY INSTRUCTIONS

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POWER ELECTRONICS

SAFETY

Before operating the drive, read this manual thoroughly to gain an understanding of th e unit. If any doubt exists, please contact POWER ELECTRONICS, (902 40 20 70 / +34 96 136 65 57) or your nearest agent. ▪

Wear safety glasses when operating the drive with with power applied or the front cover is removed.

▪

Handle and transport the drive following the recommendations within this manual.

▪

Install the drive according to the instructions within this manual and local regulations. regulations.

▪

Do not place place heavy objects on the drive.

▪

Ensure that the drive is mounted vertically and keeping the minimum clearance distances.

▪

Do not drop the drive or subject it to impact.

▪

The SD300 drives contain static sensitive printed circuits boards. Use Use static safety procedures when handling these boards.

▪

Avoid installing the drive in conditions that that differ from those described described in the Environmental Ratings Ratings section.

CONNECTION PRECAUTIONS ▪

To ensure a correct operation of the drive, it is recommended to use a SCREENED CABLE for the control wiring.

▪

The motor cable should comply with the requirements requirements within this manual. Due to increased leakage capacitance between conductors, external ground fault protection threshold value should be adjusted ad hoc.

▪

Do not disconnect motor cables if the input power power supply remains connected.

▪

The internal circuits of the SD300 Series will be damaged if the incoming power is connected and applied to the output terminals (U, V, W).

▪

Do not use power factor correction capacitors banks, surge suppressors, or RFI filters filters on the output side of the drive. Doing so may damage these components.

▪

Before wiring terminals, make sure that the drive keypad display is turned off and the front cover is off as well. The drive may hold a high voltage electric charge long after the power supply has been turned off.

TRIAL RUN ▪

Verify all parameters before operating operating the drive. Alteration of parameters may be req required uired depending on application and load.

▪

Always apply voltage and current signals to each terminal that are within the levels indicated indicated in this manual. Otherwise, damage to the drive may occur.

EARTH CONNECTION ▪

Ground the drive and adjoining cabinets cabinets to ensure a safe operation and to to reduce electromagnetic emission.

▪

Connect the input PE terminal only to the dedicated PE terminal of the drive. Do not use the case, nor chassis screws for grounding.

▪

Ground the drive chassis through the labelled terminals. Use appropriate conductors to comply with local regulations. The ground conductor should be connected first and removed last.

▪ Motor

ground cable must be connected to the PE output terminal of the drive and not to the

installation’s ground. We recommend that the section of the ground conductor (PE) is equal or

greater than the active conductor (U, V, W).

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SAFETY INSTRUCTIONS

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1. DISPLAY AND CONTROL UNITS 1.1. Seven Segment Display The SD300 variable drives, up to 30kW, have a built-in seven segment display which provides intuitive data presentation, an easy navigation through the control parameters and allows storing thousands of user-customized configurations.

Figure 1.1 Integrated display unit

It has four indicator leds that supply information about the drive operational status, plus eight control keys. They are described in the table below: KEY / LED

NAME

FUNCTION

RUN key

Run command.

STOP/RESET key

UP key

DOWN key

STOP: Stop command during operation. RESET: Reset command when a fault occurs. Used both to scroll up through the parameters of a group and to increase a parameter value. Used both to scroll down through the parameters of a group and to decrease a parameter value.

Left key

Used to jump to other parameter groups or move the cursor to the left.

Right key

Used to jump to other parameter groups or move the cursor to the right.

Enter key

Used to set a parameter value or to save the changed parameter value.

Escape key

Used to cancel the changes or to switch from Remote/Local if this option was previously configured.

FWD LED

Forward Run

Illuminated during forward run. LEDS flicker when a fault occurs.

REV LED

Reverse Run

Illuminated during reverse run.

RUN LED

Run

SET LED

Setting

Seven-segment display

Current value

Illuminated during operation / Flickering during acceleration/decelerat acceleration/deceleration. ion. Illuminated during parameter setting / Flickering when the ESC key is operating as a multi-key. Indicates operating conditions and parameter data.

DISPLAY UNIT AND CONTROL KEYPAD

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The following table shows the different characters of the seven-s egment display:

To learn how to switch between groups and parameters, follow the next examples:

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Step Step

Instruction

1

Move to the desired group using the [◀] & [▶] keys.

2

Move up and down through the parameters using the [▲] and [▼] keys.

3

Press the [ENT] key to save the changes.

Keypad Keypad display


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Binary numbers are shown in the integrated display as segment lines. “1” is displayed i n the top part of the display and “0” in the bottom part. For example, “010” is represented as:

1.2. LCD Display As an option, there is a remote LCD display for remote installation. The removable display integrates three LEDs indicating the drive operating status, an LCD display screen with 4 lines of 16 characters and control keypad for parameter setting and commissioning.

Figure 1.2 Removable display

LED Status Indicators

Leds show at any time, and in a comprehensive way for the user, information about output voltage or if a fault has taken place. LED

COLOR

FUNCTION

ON RUN FAULT

Yellow Green Red

Switched on indicates the equipment is powered. Switched on indicates the motor receives voltage from the SD500. Flashing indicates the equipment is in fault.

Figure 1.3 Display status indicators


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Alphanumeric LCD Display Screen The removable display integrates a four-line LCD screen with sixteen characters per line (16x4). Each line has different functions. Status Status Line: Upper line. Shows the drive status (RUN, STP, etc…) as well as the motor output current and speed. It is not configurable by the user. Display Line 1: Second screen line. Allows the user to select the different variables within the display menu. It is configurable b y the user. Display Line 2: Third screen line. Allows the user to select the different variables within the display menu. Programming Line: Lower line The user can view and set the different parameters. Figure 1.4 Display lines detail

Control Keypad The keypad items have different function depending on their individual or combined use: Enter into a parameter group to access the subgroups. In case a group does not have subgroups, the access would be straight to the group parameters. parameters . To modify numeric parameters: &

Pressed simultaneously, the value increases

&

Pressed simultaneously, the value decreases

To modify enumerated parameters: By pressing this key, the extended description is shown. & &

Press these two keys simultaneously to switch between possible values in ascending order. Press these two keys simultaneously to switch between possible values in descending order.

Scroll through the parameter groups. Within a parameter group, it is possible to browse the different parameters in ascending order. It also allows setting (increase) the value of configurable parameters. Same function as the previous key, but downwards. It also allows setting (decrease) the value of configurable parameters. By pressing for a 2 second period p eriod (approximately), the cursor changes within the different lines configurable by the user. It also allows to exit from a menu location to a previous one. By pressing this key, the drive starts if it is configured in local control mode (check equipment configuration). This button will only operate when the equipment is configured in local control mode. Pressing this key stops the drive if it is running. In case the equipment is at fault, pressing this button will reset the drive whenever the fault conditions have disappeared. This button will only work when the equipment is configured in local control. Not used.

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POWER ELECTRONICS The figure below shows a programming example, following the previous explication.

Figure 1.5 Parameter navigation example


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2. STATUS MESSAGES The upper line of the display corresponds to the status line. In this line, the equipment status, motor mean current consumption (A), and motor speed (Hz) are displayed. This line is always visible in the display screen and cannot be modified by the user.

Figure 2.1 Description of the Status Line

Note: The user can access to the displayed information in the status line through Modbus communication. Refer to section “Modbus Communication”.

2.1. List of Status Messages

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Screen

Name

Descript ion

FLT

Fault trip

The drive is in fault state

DCB

DC Brake

The SD300 has injected DC current to stop the motor.

STP

Stopping

The drive is decreasing the output frequency due to a stop order.

DCL

Decelerating

The drive is decreasing the output frequency. The motor is decreasing its speed, it is decelerating.

ACL

Accelerating Accelerating

RUN

Running

RDY

Ready

STATUS MESSAGES

The drive is increasing the output frequency. The motor is increasing its speed, it is accelerating. The drive is operating at reference speed. The motor will keep the introduced speed. Operating in nominal rate. The drive is ready for commissioning. commissioni ng.

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3. WARNING & FAULT MESSAGES 3.1. List of Warning Messages The following table summarizes the possible warning messages that may be displayed and their description. messages are only show n in the integrated display. Please notice that these messages Screen

Name

OLU

Over Load

ULU

Under Load

IOLU

INV Over Load

LCU

Lost Command

FANU

Fan Warning

EFAN

Fan Exchange

ECAP

CAP Exchange

DBU

DB Warn %ED

TRTR

Retry Tr Tune

Descript ion Displayed when the motor is overloaded. Operates when ‘Pr.17’ Pr.17’ is set to 1. To operate, select 5. Set the digital output terminal or relay ‘OU.31’ OU.31’or or ‘OU.33’ OU.33’ to 5 ‘OVERLOAD’ ‘OVERLOAD’ to receive overload warning output signals. Displayed when the motor is underloaded. Operates when ‘Pr.25’ Pr.25’ is set to 1. Set the digital output terminal or relay ‘OU.31’ OU.31’or or ‘OU.33’ OU.33’ to 7 ‘UNDERLOAD’ to receive underload warning output signals. Displayed when the overload time equivalent to 60% of the drive overheat protection level is accumulated. Set the digital output terminal or relay ‘OU.31’ OU.31’or or ‘OU.33’ OU.33’ to to 6 ‘IOL’ IOL’ to receive drive overload warning output signals. Lost command warning alarm occurs even with ‘Pr.12’ Pr.12’ set to 0. The warning alarm occurs based on the condition set at ‘Pr.13’ Pr.13’ to ‘Pr.15’ Pr.15’. Set the digital output terminal or relay ‘OU.31’ OU.31’or or ‘OU.33’ OU.33’ to to 13 ‘LOSTCOMMAND’ to receive lost command warning output signals. If the communication settings and status are not suitable for P2P, a Lost Command alarm occurs. Displayed when an error is detected from the cooling fan while ‘Pr.79’ Pr.79’ is set to 1. Set the digital output terminal or relay ‘OU.31’ OU.31’or or ‘OU.33’ OU.33’ to 8 ‘FAN WARNING’ to WARNING’ to receive fan warning output signals. An alarm occurs when the v alue set at ‘Pr .86’ is .86’ is less than the value set at ‘Pr .87’. .87’. To receive fan exchange output signals, set the digital output terminal or relay ‘OU.31’ OU.31’ or or ‘OU.33’ OU.33’ to to 38 ‘FAN EXCHANGE’ An alarm occurs when the v alue set at ‘Pr .63’ is .63’ is less than the value set at ‘Pr .62’ .62’ (the value set at ‘Pr .61’ .61’ must be 2 (Pre Diag)). To receive CAP exchange signals, set the digital output terminal or relay ‘OU.31’ OU.31’ or or ‘OU.33’ OU.33’ to 36 ‘CAP ‘CAP Exchange’ ’ Exchange . Displayed when the DB resistor usage rate exceeds the set value. Set the detection level at ‘Pr.66’ Pr.66’ Tr tune error warning alarm is activated when ‘dr.9’ dr.9’ is set to 4. The warning alarm occurs when the motor’s rotor time constant (Tr) is either too low or too high.

WARNING & FAULT MESSAGES

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3.2. List of Fault Messages & Troubleshooting Whenever a fault is produced, the SD300 will stop the motor. The lower line (programming line) of the removable display will show the fault description, while the upper line will show the fault code and the values of current and speed at the instant the fault occurred. Press the

key to view fault details.

Figure 2.2 Fault visualization – Programming Line

Without resetting the fault, it is possible to navigate and access the visualization lines parameters to find out more information about the fault. See section “Visualization and Status Parameters” for details about

these parameters.

On the other hand, the FAULT led will remain enabled and the fault message displayed until the breakdown b reakdown is repaired and the equipment reset. In the integrated display, faults are stored in parameters Pr.90 to Pr.96. Section 3.2.1 shows a list of all possible faults. Probable causes and troubleshooting for each fault are listed in section 3.2.2.

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3.2.1. List of fault messages Removable display DESCRIPTION Integrated Integrated di splay F0 No Fault The equipment is operative. No fault is present. F1 OverLoad The drive trips when the output current reaches the value set in parameter ‘G9.21’ G9.21’ (Pr.21), exceeding the time limit set in parameter ‘G9.22’ G9.22’ (Pr.22). The protection is operative if the parameter ‘G9.20’ G9.20’ (Pr.20) has been set with a value different to 0 ‘NONE’.

F2 UnderLoad

The motor is working with insufficient load. The drive trips when its current is within the values set in parameter ‘G9.29’ G9.29’ (Pr.29) and ‘G9.30’ G9.30’ (Pr.30) exceeding the time limit set in parameter ‘G9.28’ G9.28’. The protection will be enabled if the parameter ‘G9.27’ G9.27’ (Pr.27) has been set with a value different to 0 ‘NONE’.

F3 Inv OverLoad

The drive cuts the output supply when the output current exceeds the value set in the corresponding parameters (150% for 1 minute, 200% for 4 seconds of the drive rated current). The 200% for 4 seconds can vary depending on the drives capacity.

F4 E-Thermal

The internal thermo-electronic protection determines the motor overheating. If the motor is overheated, the drive stops its output. The protection is enabled setting the parameter ‘G9.40’ G9.40’ (Pr.40) to a value different than 0 ‘NONE’.

F5 Ground Fault

The drive trips when an earth leakage and its current exceed the internal value configured in the drive. The overload protection function will protect the drive from any ground fault caused by a small leakage resistance.

F6 Output Ph Loss

F7 Input Ph Loss

F8 OverSpeed F10 NTC

One of the three output phases is open. The protection will be enabled if the parameter ‘G9.5’ G9.5’ (Pr.5) is set as 1 ‘OUTPUT’ or 3 ‘ALL’. One of the three input phases is open. The protection will be enabled if the parameter ‘G9.5’ G9.5’ (Pr.5) is set as 2 ‘INPUT’ or 3 ‘ALL’. The motor speed has reached the speed limit set in ‘G1.20’ G1.20’ (dr20). The drive uses a NTC thermal sensor to detect temperature increases within the supply system. When this message is displayed, display ed, the thermal sensor cable may have been cut. (The drive will continue running).

F11 OverCurrent The drive trips when the output current exceeds the 200% of the rated current value.

F12 OverVoltage

The drive trips if the DC voltage within bus exceeds the value established. This value has been established in the internal configuration during the deceleration process or when the motor regenerative energy return to the drive is excessive for the capacitors which compose the DC bus. This fault can also be caused due to a transitory overvoltage within the supply system.

F13 External Trip

This function can be used whenever the user needs to cut the output by the use of an external trip signal. (‘G5.65’-‘G5.71’, The open /closed contact use will depend on the configuration within the digital inputs (‘G5.65’In.65-In.71) configured as 4 ‘EXTERNAL TRIP’. TRIP ’. The drive cuts the motor output protecting it from fro m the controlled situation within the terminal.

F14 Short ARM The drive trips when a short-circuit occurs in the IGBT or in the output power.

F15 OverHeat

F20 FAN TRIP

The drive trips if overheated caused by a damaged cooling fan or by the presence of any strange substance within the cooling system. An anomaly anomaly detecting detecting within the cooling cooling fan. The The protection protection will be be enabled if parameter parameter ‘G9.79’ G9.79’ (Pr.79) is set as 0 ‘TRIP’. ‘TRIP’.

F22 Param_Wr_Err A problem problem has been been detected detected during the writing writing of a parameter parameter by by keypad.


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Removable display DESCRIPTION Integrated Integrated di splay F23 Pipe Fill Flt

An error has been detected which makes the PID feedback be always under the established value. Possible pipe breakdown.

F25 External Brake Drive trips when the braking unit reaches a dangerous temperature.

F26 No Motor

The drive has not detected a connected motor at its output when the Start order has been given. The protection is enabled setting the parameter ‘G9.31’ G9.31’ (Pr.31) to a value different to 0 ‘NONE’. ‘NONE’ .

F27 Slot 1 Fail The optional board located in the slot1 has been extracted or there is no possible communication.

F30 STO Automatic Automatic internal protection protection of several of the the IGBT semiconductors semiconductors has acted acted or the safe stop contact of the drive (connected to an external circuit by the user) has been activated (for example, emergency stop).

F33 BX

F34 LV

F35 Lost Command

F36 KeyPadLostCMD

One of the digital inputs (‘G5.65’(‘G5.65’-‘G5.71’, In.65-In.71) In.65 -In.71) has been enabled configured as 1 ‘DIS START’, forcing the drive to cut the output supply and making it stop due to inertia. The drive trips when the voltage within the DC bus is under the detection level. Therefore, the torque generated can be insufficient or the motor can be overheated if the input voltage decreases. The drive trips due to a loss of speed set point established by the use of the control or communication terminals. Drive trips if display is not connected.

F49 ADC Error Analog Input error. error.

F50 EEPROM The (EEPROM) memory is defective.

F51 Watchdog-1 Err Micro-controller internal fault.

F52 Watchdog-2 Err Micro-controller internal fault.

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3.2.2. Fault troubleshooting troubleshooting Screen Screen F1: Over Load

F2 UnderLoad

F3 Inv OverLoad

F4 E-Thermal

F5 Ground Fault

F6 Output Ph Loss

F7 Input Ph Loss

Descripti Descripti on or possible cause Elevated motor consumption caused by an excessive load. Load defined in parameter ‘G9.21’ G9.21’ (Pr.21) is too low A connection connection problem between the motor motor and and the load is present. The load defined in parameters ‘G9.29’ G9.29’ (Pr.29) and ‘G9.30’ G9.30’ (Pr.30) is too low. The load within the drive is greater than the rated value of the drive.

Increase the defined value in parameter ‘G9.21’ G9.21’ (Pr.21). Check the connection between motor and load is correctly set. Increase the value defined in parameters ‘G9.29’ G9.29’ (Pr.29) and ‘G9.30’ G9.30’ (Pr.30).

The start torque setting is too high.

Reduce the start torque value.

Motor overheated.

Reduce load and / or operating cycle

Load exceeds the drive capacity.

Use a more powerful drive.

Electro-thermal protection level (ETH) too low.

Set the ETH level properly.

Invalid selection of the drive rated power.

Select a correct drive power.

Invalid V/f pattern setting.

Select a correct V/f pattern.

Ground leakage produced in the drive output.

Check the drive output wiring.

The motor insulation is damaged due to heat.

Change the motor.

Problem present in the drive output electric connection.

Check the output electric connections.

Poor output electric distribution.

Check that the output electric distribution is correct.

Problem present in the drive input electric connection. Bad input electric distribution. The drive DC capacitor must be replaced.

F8 OverSpeed F10 NTC

Speed reference is higher or equal that the speed limit. Motor speed is out of control The room temperature is over the allowed range. Problem present in the drive internal temperature sensor. Acceleration Acceleration / deceleration deceleration time too short compared to the load inertia. The load exceeds the drive rated power.

F11 OverCurrent

Actions Increase the motor and drive capacity.

Increase the motor and drive capacity.

Check the input electric connections. Check that the input electric distribution is correct. Replace the drive DC capacitor. Contact the Technical Service. Check the reference source and the motor load. Verify speed limits. Keep the installation location at temperature within the specified limits.

room

Contact the Technical Service. Increase the acceleration /deceleration time.

Ground fault or short circuit produced.

Increase the drive rated power. Ensure the correct programming spin start conditions. Set the load inertia and the parameters which enable the speed search properly. Note: Adequate spin start conditions fulfilment depends on each installation. Check the output wiring.

The mechanic brake enters too quickly. The power circuit components overheated due to a cooling fan malfunction.

Check the mechanic brake. Check the cooling fan. Verify it is correctly powered and not blocked by dirt.

The drive attempts to start the motor while spinning.

Caution: Starting the drive without correcting anomalies may damage the IGBTs.


19

SD300 SERIES

POWER ELECTRONICS

Screen Screen

Descripti Descripti on or possible cause

Actions

F12 OverVoltage

The deceleration time is too short compared to the load inertia.

Increase the deceleration time.

Excessive energy regeneration in the drive. Line with High Voltage.

Use an optional brake resistor (dynamic brake units). Check the supply line voltage.

F13 External Trip

F14 Short ARM

External fault produced.

Delete the circuit fault connected by the input fault terminal configured.

Short circuit upper and lower IGBT.

Check IGBT.

Short circuit at the drive output. Acceleration Acceleration / deceleration deceleration time is too short compared with the inertia of the load (GD 2)

Check the wiring of the drive output circuit.

Cooling fan damaged or foreign matter present.

F15 OverHeat

Fault within the cooling system. Excessive room temperature. Motor overheat produced (PTC / NTC external signal) produced.

Increase acceleration / deceleration time. Replace the cooling fans and / or remove the foreign matter. Check the foreign matter presence. Keep the room temperature under 50ºC or verify the drive capacity according to temperature. Check the motor cooling. Reduce the load and / or operating cycle.

F20 Fan Trip Cooling fan damaged or foreign matter present.

Replace the cooling fans and or remove the foreign matter.

A problem occurred while editing a parameter parameter with the numeric keyboard.

Check if the keyboard is properly inserted.

Possible pipe breakdown inhibits pressure to reach the minimum level.

Check installation pipe status.

PID feedback sensor is not showing the correct values.

Check the PID feedback pressure sensor is measuring properly. In case it is damaged, replace it.

The braking unit has reached a dangerous temperature.

Check the braking unit.

F22 Param Wr Err

F23 Pipe Fill Flt

F25 External Brake

F26 No Motor

F27 Slot 1 Fail

No motor connected to the drive output or defective wiring. The value set in parameter ‘G9.31’ (Pr.31) is too high. The port 1 optional board is not connected properly. Defective optional board.

Check the motor is correctly connected to the drive output.

Check the board is inserted in the expansion board slot. Replace the optional board for a new one.

Defective optional board.

Replace the optional board.

The internal automatic protection of several IGBTS or the drive safe stop contact have been activated (connected by the user to an external circuit). E.g.: Emergency stop.

Check if the circuit is properly wired. Check wiring and ensure that neither of both circuits is open.

One of the digital inputs configured as 1 ‘DIS START’ has been enabled.

Disable the digital input configured as 1 ‘DIS START’. START’.

Reduce the parameter ‘G9.31’ (Pr.31) value.

F30 STO

F33 BX

20


SD300 SERIES

POWER ELECTRONICS Screen Screen

F34 LV

Descripti Descripti on or possible cause

Actions

Low voltage in the line Load exceeds the line rated power (welding machine, motor with high start current connected to the commercial line) Defective magnetothermic switch in the drive supply circuit.

Check the line voltage.

F35 Lost Command

F36 KeypadLostCMD F49 ADC Error

Increase the line rated power. Change the magnetothermic switch.

Speed reference lost introduced through the communications or keypad inputs.

Check the drive communications or the inputs are within the defined ranges to provide the speed references.

Display connection is not correct.

Check the connection.

Analog input error error produced. produced.

Contact the Technical Technical Service. Service.

EEP Error (memory fault).

Disconnect and reconnect the power supply. If fail, contact the Power Electronics Technical Service.

Watchdog Error (CPU fault).


Watchdog Error (CPU fault).


F50 EEPROM

F51 Watchdog-1 Err

F52 Watchdog-2 Err


21

SD300 SERIES

POWER ELECTRONICS

4. VISUALIZATION AND STATUS PARAMETERS These parameters constantly indicate the input signal status and dynamic parameter status of the SD300. Visualization lines are the second and the third lines. The user can select the parameter to be displayed in each line from the different visualization options. To select a display parameter, move the cursor to the second or third line. To do this, press the ESC / key for approximately two seconds; the cursor moves from one line to the next. Once l ocated on the second or third line, navigate through parameter groups, enter using the key. and select the desired parameter to be displayed. Once selected, these parameters are saved into memory and will be displayed on lines 2 and 3 whenever the drive is powered up. Thanks to these lines user can display desired parameters and obtain additional information easily.

Figure 4.1 Visualization Visualization Lines Description

4.1. Parameters SV.1 – Motor Visualization Screen Screen Mtr Iout=0.0 MTR O/P current Mtr Freq= 0.00Hz Motor Frequency Mtr Sp= 0rpm Motor Speed(rpm) Mtr FBSp=+0rpm MTR FBK Speed Mtr Vout=0V MTR O/P voltage Mtr Pow = 0.00kW MTR O/P power Mtr Torq = 0.0% MTR O/P torque

22

Units

Descripti Descripti on

A

Shows the current running through the motor, corresponding to the second field of the status line  OFF 0.0A +0.0Hz

Hz

Shows the motor frequency

rpm

Shows the motor speed in rpm

rpm

Shows the motor encoder speed. This value will be only shown if an encoder board has been installed in the drive.

V kW % Motor torque

Shows the motor voltage Shows the motor instantaneous power consumption Shows the torque applied to the motor.

VISUALIZATION AND STATUS PARAMETERS

SD300 SERIES

POWER ELECTRONICS

4.2. Parameters SV.2 – Drive Visualization Screen Screen Bus vol = 528V Bus voltage Temperature Temperature = 27ºC Temperature

Units VDC ºC

Descripti Descripti on Shows the DC voltage measured in the drive bus. Shows the internal temperature of the drive.

4.3. Parameters SV.3 – External Visualization Screen Screen ANLG IN V1 = +0.00V AI V1 Monitor ANLG IN V2 = +0.00V AI V2 Monitor ANLG IN I2 = +0.00mA AI I2 Monitor DigI= 0000000 Dig I/P Status ANL OUT1 = 0.0% Anl Out1 Monitor DOstatus= 0-00 Dig Output status

Units


V

Shows the voltage analog input 1 mean value.

V

Shows the voltage analog input 2 mean value.

mA

Shows the current analog input 2 mean value.

-

Shows the activation or rest status of the Digital Inputs, from left to right P7 to P1. The number of Digital Inputs varies depending on the equipment. IP20 drives integrate 7 Digital Inputs and IP66 drives integrate 5.

%

Shows the value of the Analog Output 1.

-

Shows the status of the digital outputs in the following order: SD-Relay2 Relay1.

4.4. Parameters SV.4 – Internal Visualization Screen Screen Inv.Power= Inv.Power Inv. S/W Inv.SW SW Disp= DP version

Units kW

Descripti Descripti on Shows the drive power in kW.

-

Shows the last software version installed in the drive Ex. 0xE6 = v2.30.

-

Shows the last software version installed in the display.

4.5. Parameters SV.5 – PID Visualization This display group appears when the parameter ‘G8.1 Apmod’ (Ap.1) has been set to the PID option. Screen Screen S=0.0% F=0.0% Set- Fdb PID PID Out=+0.00% PID Out

Units


%

Shows the PID set point value of the analog PID (left) and the sensor value that sends the feedback signal (right).

%

Shows the t PID Output.

4.6. Parameters SV.6 – Registers Screen Screen Operating Time. Total runtime Consumed Energy Consumed Energy

Units


-

Shows the total runtime in days and minutes.

-

Shows the total consumed energy, in MWh and kWh.

VISUALIZATION AND STATUS PARAMETERS

23

SD300 SERIES

POWER ELECTRONICS

5. DESCRIPTION OF PROGRAMMING PARAMETERS The different parameters of the SD300 are organized in groups (G1, G2, G3, …) and can be set both from the integrated display and from the removable display. In the integrated display, use the left Use the up

and down

and right

arrow keys to jump from a parameter group to another.

keys to navigate between the parameters of the selected group.

In the removable LCD display, configuration parameters are shown in the bottom lin e. Use the plus and minus keys to jump from a parameter group to another. Press the key to enter a group and, again, the plus and minus keys to navigate between the parameters of the selected group. Details about each parameter can be seen by pressing the key. Please refer to section 1, Display Unit and Control Keypad, for instructions on how to modify parameter values.

Figure 5.1 Programming Line detail.

See the following subsections for the complete parameter list for each group.

24

DESCRIPTION OF PROGRAMMING PARAMETERS

SD300 SERIES

POWER ELECTRONICS

5.1. Group 0: Operation This group is only available in the integrated display. It allows performing a basic set up of the drive with its main parameters. Parameter

Modbus Address

Function

Decimal

Hexadecimal

0h1F00

See G1.1

ACC - Acceleration time = 20.0s

47936 47937

0h1F01

See G1.3

dEC - Deceleration time = 30.0s

47938

0h1F02

See G1.4

drv - Command source = Remote

47939

0h1F03

See G1.6

Frq - Frequency reference source = LOCAL

47940

0h1F04

See G1.7

St1 - Multi-step speed frequency 1 = 10.00Hz

47941

0h1F05

See G2.50

St2 - Multi-step speed frequency 2 = 20.00Hz

47942

0h1F06

See G2.51

St2 -Multi-step speed frequency 3 = 30.0Hz

47943

0h1F07

See G2.52

Cur - Output current

47944

0h1F08

rPM -Motor revolutions per minute

47945

0h1F09

dCL -Inverter direct current voltage

47946

0h1F0A

vOL -Inverter output v oltage

47947

0h1F0B

LuT -Out of order signal

47948

0h1F0C

drC -Select rotation direction

47949

0h1F0D

Target frequency =0.00Hz

5.2. Group 1 – G1: Drive Removable Name / display Description Integrated Integrated di splay

dr Function

Set on RUN

Set the the motor speed value. Minimum value is set in ‘G1.19’ (dr.19) and the maximum value in ‘G1.20’ (dr.20).

YES

Set the torque value of the motor.

YES

Acceleration ramp 0.0 to 600.0s

Set the acceleration ramp 1, in seconds. This ramp will be set according to the requirements of each process.

YES

Deceleration ramp 0.0 to 600.0s

Set the deceleration ramp 1, in seconds. This ramp will be set according to the requirements of each process.

YES

G1.1 LCLSP=0.00Hz [1] Local speed

0.00 G1.2 LclTQ=0.0% dr.2 G1.3 ACC1=20.0s [1] ACC G1.4 DECEL1=30.0s [1] dEC

These values depend on drive characteristics.

Local torque

Range [G1.19] to [G1.20] (dr.10 to dr.20) -180.0 to 180.0%

Set the control mode to command the drive (Start/Stop, Reset...).

OPT. DESCRIPTION FUNCTION G1.6 CONTROLMODE1= REMOTE [1]

Control mode 1

0 to 5

0

LOCAL

1

REMOTE

2

REMOTE 2

3

MODBUS

4

COMMS

5

PLC

dru

Drive is controlled from the keypad. Commands are sent from the control terminals. Commands are sent from the control 2 terminals. The drive is controlled through the communications bus, integrated in the equipment. The drive control is carried out by the use of any of the optional communication boards. The common area can be linked with the user sequence output and can be used as command.

NO

[1] Only displayed in the removable LCD display.


25

SD300 SERIES

POWER ELECTRONICS

Removable Name / display Description Integrated Integrated di splay

Range

Function

Set on RUN

Select the source for the speed reference.

OPT. DESCRIPTION FUNCTION Reference will be given by keypad and will be set in ‘G1.1’ (dr.1) - Local Speed. Reference will be introduced through the 2 V1 voltage analog input 1. Reference will be introduced through the 4 V2 voltage analog input 2. Reference will be introduced through the 5 I2 current analog input 2. The reference will be introduced through 6 MODBUS Modbus. The reference will be introduced through the 8 COMMS communications. The common area can be linked with user 9 PLC sequence output and can be used as command. Reference will be introduced through the Pulse 12 PULSE input. Select the source for the torque reference. 0

G1.7 REF1 SP= LOCAL [1]

Speed reference 1

0 to 12

Frq

LOCAL

NO

OPT. DESCRIPTION FUNCTION Reference will be given by keypad and will be set in ‘G1.1’ (dr.1) ‘G1.1’ (dr.1) - Local Speed. Reference will be introduced through the 2 V1 voltage analog input 1. Reference will be introduced through the 4 V2 voltage analog input 2. Reference will be introduced through the 5 I2 current analog input 2. The reference will be introduced through 6 MODBUS Modbus. The reference will be introduced through 8 COMMS communications. The common area can be linked with user 9 PLC sequence output and can be used as command. Reference will be introduced through the Pulse 12 PULSE input. Define the drive control type. 0

G1.8 REF1 TQ= LOCAL

Torque reference1

0 to 12

dr.8

LOCAL

NO

OPT. DESCRIPTION FUNCTION

G1.9 Ctr.T=V/Hz

Control type

0 to 4

0

V/Hz

2

SlipCom

4

S-less1

dr.9

G1.10 Torq CTRL=N dr.10

26

Torque control

N Y

Not configurable by users.


A linear V/Hz pattern configures the drive to increase or decrease the output voltage at a fixed rate for different operation frequencies. This is particularly useful when a constant torque load is applied. Slip refers to the variation between frequency (synchronous speed) and motor rotation speed. As the load increases, there can be variations between the set frequency and motor rotation speed. Slip compensation is used for loads that require compensation of these speed variations. Sensorless vector control is an operation to carry out vector control without the rotation speed feedback from the motor but with an estimation of the motor rotation speed calculated by the drive. Sensorless vector control can generate greater torque at a lower current level than V/Hz control

NO

NO

SD300 SERIES

POWER ELECTRONICS Removable Name / display Description Integrated Integrated di splay G1.11 InchF=10.00Hz Inch Frequency

dr.11 G1.12 InchAcT=20.0s dr.12 G1.13 InchDeT=30.0s dr.13

G1.14 MTRPWR= (*)

dr.14

Range [G1.19] to [G1.20] (dr.19 to dr.20)

YES YES

NO

OPT. DESCRIPTION FUNCTION Manual Auto1 Auto2

dr.15

0

Manual

1

Auto1

2

Auto2

Starting voltage manual setting by the use of parameters “FWBoost” FWBoost” and “RVBoost” RVBoost ” (parameters ‘G1.16’ and ‘G1.17’, ‘G1.17’, (dr.16 and dr.17)). The drive automatically calculates the voltage to apply at the start using the motor parameters.

NO

Start torque in forward direction

0.0 to 15.0% Set the start torque in forward direction.

NO

Start torque in reverse direction.

0.0 to 15.0% Set the start torque in reverse direction.

NO

30.00 to 400.00Hz

Set the base frequency (drive output frequency when running at its rated voltage) according to the motor nameplate

NO

Start frequency

0.01 to 10.00Hz

Set the start frequency. A start frequency is a frequency at which the drive starts voltage output. The drive does not produce output voltage while the frequency reference is lower than the set frequency. However, if a deceleration stop is made while operating above the start frequency, output voltage will continue until the operation frequency reaches a full-stop (0Hz).

NO

Max speed limit

40.00 to 400.00 Hz

Hz/Rpm Display

Hz Rpm

Motor frequency

G1.19 STRFRQ=0.5Hz dr.19 G1.20 MxSpL=60.00Hz

G1.21 Hz/Rpm=Hz [1]

YES

INCH deceleration Set the time in which the drive decelerates from the maximum speed until 0.0 to 600.0s time stopping. 0.2 kW 0.4 kW 0.75 kW 1.1 kW 1.5 kW 2.2 kW 3.0 kW 3.7 kW Motor power Set the motor rated power according to its nameplate. 4.0 kW 5.5 kW 7.5 kW 11.0 kW 15.0 kW 18.5 kW 22.0 kW 30.0 kW Proportional to the initial voltage value applied to the motor in the start moment to overcome the resistive torque in heavy starts.

Torque boost

dr.20

Set the motor inch frequency.

INCH acceleration 0.0 to 600.0s Set the time in which the drive accelerates to reach the maximum speed. time

G1.15 TqBoost=Manual TqBoost=Manual

G1.16 FWBoost=2.0% dr.16 G1.17 RVBoost=2.0% dr.17 G1.18 MTRFRQ=60.00Hz dr.18

Set on RUN

Function

Set upper and lower frequency limits. All frequency selections are restricted to frequencies from within the upper and lower limits. This restriction also applies when you in input a frequency reference using the keypad. Change the units used to display the operational speed of the drive by setting to 0 (Hz) or 1 (Rpm). This function is only available in he removable display.

NO

YES

Select ranges displayed by the drive at power input.

OPT. DESCRIPTION OPT. DESCRIPTION

G1.80 SelRngEnt=Run SelRngEnt=Run Freq. Select range

dr.80

0 to 17

0 1 2 3 4 5 6 7 8

Run Freq. Accel. Time Decel. Time Cmd Source Ref. Source MultiStep 1 MultiStep 2 MultiStep 3 Oupt. Curr.

9 10 11 12 13 14 15 16 17

Motor RPM DC Voltage User Sel. 1 Out of Order Sel. Run Dir. Oupt. Curr. 2 Motor2 RPM DC Voltage2 User Sel. 2

YES


27

SD300 SERIES

POWER ELECTRONICS


Range

Function

Set on RUN

Select the monitor code.

G1.81 SelCod=Volt V

OPT. DESCRIPTION FUNCTION Select monitor code

0 to 2

dr.81

G1.89 DspChng=All

0

Volt V

1 2

Pow kW Tq kgf

Scalar control mode. Drive carries out the control applying a voltage / frequency ramp to the motor. Control by power. Control by torque.

YES

Displays all parameters that are different from the factory defaults. Use this feature to track changed parameters. Display changed parameters

All Chang


YES

0 All Display all parameters. 1 Chang Display changed parameters. The [ESC] key is a multi-functional key that can be configured to carry out a number of different functions.

dr.89 G1.90 ESC Func= Mov. In. Pos. ESC key function

0 to 2

dr.90

OPT. DESCRIPTION FUNCTION 0 1

Mov. In. Pos. JOG Key

2

Local/Rem

Move to the initial position. Perform a jog operation. Change from Local to remote control if the key has previously been configured as such.

NO

Set Eloader function

G1.91 Eloader=None Eloader=None [1]

OPT. DESCRIPTION FUNCTION Eloader function

0 to 3

0 1 3

None Download Upload

No actions are executed. Download upgrade file. Store drive current values.

NO

Set all parameters back to their factory value.

OPT. DESCRIPTION FUNCTION G1.93 INITIALIS=No

Parameter initialization

dr.93

No All dr bA Ad Cn In OU CM AP Pr M2 run

0

No

1

All

2 3 4 5 6 7 8 9 12 13 16

dr bA Ad Cn In OU CM AP Pr M2 run

All parameters keep their current value. Initializes all parameter groups (set to factory values). Initialize parameters from group dr. Initialize parameters from group bA. Initialize parameters from group Ad. Initialize parameters from group Cn. Initialize parameters from group In. Initialize parameters from group OU. Initialize parameters from group CM. Initialize parameters from group AP. Initialize parameters from group Pr. Initialize parameters from group M2. Initialize parameters from group Operation.

NO

Note: Options 2 to 16 are only available in the integrated display. G1.94 PswRg=0 dr.94 G1.95 PrmLock=0 dr.95 G1.97 SoftVer=0 dr.97 G1.98 IOSwVer=0 dr.98 G1.99 IOHwVer=0 dr.99

28

Register password

0 to 9999

Register password. Reserved for Power Electronics.

YES

Lock password

0 to 9999

Password to lock parameter settings.

YES

Software version

0 to 9999

Displays the software version. Ex: 0xE6 = v2.30.

YES

IO Software version

0 to 65535

Displays the IO software version.

YES

Hardware version

0 to 65535

Displays the hardware version.

YES


SD300 SERIES

POWER ELECTRONICS

5.3. Group 2 – G2: Basic Functions Removable Name / display Description Integrated Integrated di splay

bA

Range

Function

Set on RUN

Select the auxiliar speed reference source for the speed sum to the main reference, according to the following table:

OPT. OPT.

G2.1 REF2 SP=None

The reference will be introduced by using the keypad. Reference will be introduced through the 1 V1 voltage analog input 1. Reference will be introduced through the 3 V2 voltage analog input 2. Reference will be introduced through the 4 I2 current analog input 2. Reference will be introduced through the Pulse 6 Pulse input. Adjust the equation to calculate calculate the speed reference. In order to to do this, the present reference source, the a uxiliar reference (bA.1) and the gain fos this reference (bA.3) are used. 0

Alt Speed Ref

0 to 6

bA.1

DESCRIPTION

None

NO

Notice that options 4-7 could result in references with positive or negative sign (forward or reverse operation) even when unipolar analog inputs are used.

G2.2 AuxCalcType= M+(G*A) [2]

The following table shows the calculation for each option, where:

Aux calculation type

0 to 7

M: Main speed reference G: Auxiliary reference gain (‘G2.3’, bA.3) A: Auxiliary reference (‘G2.1’, bA.1)

NO

OPT. CALCULATION FUNCTION

bA.2 [2]

G2.3 AuxRfG=100.0% [2] Auxiliary reference gain bA.3 [2]

-200.0 to 200.0%

G2.4 CONTROLMODE2= REMOTE

7

M+(G*A)

  . . + (.3 (.3 ∗ .1 .1 ∗ .1 .1 )

Mx(G*A)

  . . ∗ (.3 (.3 ∗ . . 1)

M/(G*A)

  . . / (. (. 3 ∗ .1 )

M+[M*(G*A)]

 . + {  . .∗ ∗ (.3 (.3 ∗ . . 1)}

M+G*2(A-50%)

  . . + .3 .3 ∗ 2 ∗ (.1 (.1 − 50) 50) ∗ .1 .1

Mx[G*2(A-50%)

  . . ∗ (.3 (.3 ∗ 2 ∗ (.1 .1 − 50))

M/[G*2(A-50%)]

  . . /(. /(. 3 ∗ 2 ∗ (.1− 50))

M+M*G*2(A-50%)

  . . +   . . ∗ .3 ∗ 2 ∗ (.1 .1 − 50)

Adjust a gain to the auxiliary reference configured in parameter ‘G2.1’ (bA.1). Set the alternative control mode to command the drive (Start/Stop, Reset...).

YES


Control mode 2

bA.4

0 1 2 3 4 5 6

0 to 5

0

LOCAL

1

REMOTE

2

REMOTE 2

3

MODBUS

4

COMMS

Drive is controlled from the keypad. Commands are sent from the control terminals. Commands are sent from the control 2 terminals. The drive is controlled through the communications bus, integrated in the equipment. The drive control is carried out by the use of any of the optional communication boards.

NO

[2] These parameters will only be displayed if ‘G2.1’ (bA.1 in integrated display) is not set to 0 (NONE).


29

SD300 SERIES

POWER ELECTRONICS


Range

Function

Set on RUN

Select the alternative source for the speed and torque reference respectively.

G2.5 REF2 SP=LOCAL


Speed reference source 2

0

LOCAL

2

V1

4

V2

5

I2

6

MODBUS

8

COMMS

bA.5 0 to 9

G2.6 REF2 TQ= LOCAL Alternative torque reference

bA.6

Reference will be given by keypad and will be set in ‘G1.1’ (dr.1) ‘G1.1’ (dr.1) - Local Speed. Reference will be introduced through the voltage analog input 1. Reference will be introduced through the voltage analog input 2. Reference will be introduced through the current analog input 2. The reference will be introduced through Modbus. The reference will be introduced through communications.

YES

YES

Set the alternative acceleration ramp.

G2.7 V/FPn=Linear V/FPn=Linear

OPT. DESCRIPTION FUNCTION 0 V/F Pattern

Linear

0 to 3

bA.7

1

Square

2

V/F Us

3

Square2

Output voltage increases and decreases at constant rate proportional to voltage/frequency (V/F) relation. Used to achieve a constant torque load regardless the frequency. Output voltage increases quadratically with a proportion of 1.5. Define a customized V/F pattern. Output voltage increases quadratically with a proportion of 2.

NO

Enables the acceleration ramp settings:

G2.8 RmpT= MaxFreq

OPT. DESCRIPTION FUNCTION Acceleration ramp type

MaxFreq DeltaFreq

bA.8

MaxFreq

1

DeltaFreq

Allows accelerating or decelerating with the same ramp based on the maximum frequency, independently from the operating frequency. Allows defining the accelerating/decelerating accelerating/decelerating time which will reach the next speed reference when working at constant speed.

NO

Set the time scale for all time-related values. It is particularly useful when a more accurate Acc/Dec times are required because of load characteristics, or when the maximum time range needs to be extended.

G2.9 TimScl=0.1s Time scale

0.01s 0.1s 1s

bA.9

OPT. DESCRIPTION FUNCTION 0 1 2

0.01s 0.1s 1s

NO

Sets 0.01 second as the minimum unit Sets 0.1 second as the minimum unit. Sets 1 second as the minimum unit

Set the input frequency. If the frequency changes, so do all related settings (base frequency, maximum frequency…).

G2.10 I/P Freq=60Hz Input Frequency

60Hz 50Hz

bA.10 G2.11 POLE Numbr=4 (*) Pole Number bA.11 G2.12 RtSlp=40rpm (*) Rated Slip bA.12 G2.13 MTRCUR=3.6A (*) Motor Current bA.13

30

0

2 to 48 0 to 3000rpm


60Hz 50Hz

NO

Set drive frequency to 60Hz. Set drive frequency to 50Hz.

Set the number of poles in the motor according to its nameplate.

NO

When a heavy load produces a big slip during the start, configure this parameter to compensate the motor slip.

NO

1.0 to 200.0A Set the motor nominal current in accordance with the nameplate.


NO

SD300 SERIES

POWER ELECTRONICS Removable Name / display Description Integrated Integrated di splay G2.14 NOLODC=1.6A (*) No load Current

bA.14 G2.15 MTR VOLT=0V Motor Voltage bA.15 G2.16 EFFICIEN=72% (*) Efficiency bA.16

Range

Function

Set the measured current at rated frequency without load. If any difficulties 0.5 to 200.0A are found when measuring the current without load, this setting should be between 30% and 50% of the motor nameplate rated current.

NO

180 to 480V Set the motor rated voltage according to its nameplate.

NO

70 to 100% Set the motor efficiency according to its nameplate.

NO

Select load inertia based on motor inertia.

G2.17 InertiaRate=0

OPT. FUNCTION Inertia Rate

0 1 2-8

0 to 8

bA.17 G2.18 TrimPwr%=100% TrimPwr%=100% bA.18

Set on RUN

Output power adjustment

G2.19 ACi/Volt=380V AC Input voltage

bA.19

Less than 10 times motor inertia 10 times motor inertia More than 10 times motor inertia

Fine adjustment of the output power calculation, i ncreasing its value if it is lower than expected or reducing it to match the real value. Set the input voltage. Note: The default setting value and this parameter range will vary 170 to 240V depending on the drive supply voltage: 320 to 480V 220V 220 400V 380 Set autotuning type: 70 to 130%

NO

YES

YES

OPT. DESCRIPTION FUNCTION 0

None

1

All

G2.20 AutoTuning=None AutoTuning=None

Auto tuning

0 to 6

2

Allst

3

Rs+Lsig

6

Tr

bA.20

G2.21 Rs=0 (*) bA.21 (*) G2.22 LSigma=0mH (*) bA.22 (*) G2.23 Ls=0mH (*) bA.23 (*) G2.24 Tr=145ms [3] bA.24 [3] G2.25 Ls Scl=100% [3] bA.25 [3] G2.26 Tr Scl=100% [3] bA.26 [3] G2.31 LsR Scl=80% [3] bA.31 [3] G2.41 UsFq1=15.00Hz [4] bA.41 [4] G2.42 User V1=25% [4] bA.42 [4]

Auto-tunning is not active The motor parameters are measured with the motor rotating. The stator resistance (Rs), leak inductance (Lσ), stator inductance (Ls), nono load current and rotor time constant are all measured. The encoder state is also measured. The encoder related functions should be rightly set. If load is connected to the motor axis, the parameter might not be correctly measured so remove the load before measurement. Motor parameters are measured when the motor is stopped. Stator resistance (Rs), leak inductance (Lσ) and rotor time constant are measured at the same time. The parameter is measured with the motor stopped. The measured values are used for auto torque boost and sensorless vector control. Measures the rotor time constant (Tr) with the motor in the stopped position and Control Mode ‘G1.9’ (dr.9) ‘G1.9’ (dr.9) is set to IM Sensorless.

NO

Stator Resistor

*

Stator resistor fine setting.

NO

Leak Inductor

*

Leak inductor fine setting.

NO

Stator Inductor

*

Inductor stator fine setting.

NO

Rotor Time Const

25 to 5000ms Rotor time constant fine setting.

NO

Stator inductance scale.

50 to 150% Set stator inductance scale.

NO

Rotor time constant scale.

50 to 150% Set rotor time constant scale.

NO

Regeneration inductance scale

70 to 100% Set regeneration inductance scale.

NO

User Frequency 1 User Voltage 1

0.00 to Set user frequency 1. When the output frequency reaches this value, the [G1.20]/dr.20 drive will provide the voltage set in parameter ‘G2.42 User V1’ (bA.42). V1’ (bA.42). 0 to 100%

Set user voltage 1. The drive will provide the frequency set in parameter (bA.41) is reached. when the frequency configured in ‘G2.41 UsFq1’ (bA.41) is

NO NO

* These values depend on the motor setting. [3] These parameters will only be displayed if ‘G 1.9’ (dr.19 in integrated display) is set to 4 (S-less1). [4] These parameters will only be displayed if ‘G2.7’ (bA.7 in integrated display) is set to 2 (V/F Us).


31

SD300 SERIES

POWER ELECTRONICS

Removable Name / display Description Integrated Integrated di splay G2.43 UsFq2=30.00Hz [4] bA.43 [4] G2.44 User V2=50% [4] bA.44 [4] G2.45 UsFq3=45.00Hz [5] bA.45 [5] G2.46 User I2=75% [5] bA.46 [5] G2.47 UsFrq4=0.00Hz [4] bA.47 [4] G2.48 User V4=0% [4] bA.48 [4]

User Frequency 2 User Voltage 2 User Frequency 3 User Voltage 3 User Frequency 4 User Voltage 4

G2.50 MREF1=10.00% [5] Multi-Reference1

Range

Set on RUN

Function

0.00 to Set user frequency 2. When the output frequency reaches this value, the [G1.20]/dr.20 drive will provide the voltage set in parameter ‘G2.44 User V2’ (bA.44).

NO

Set user voltage 2. The drive will provide the frequency set in parameter (bA.43) is reached. when the frequency configured in ‘G2.43 UsFq2’ (bA.43) is

NO

0.00 to Set user frequency 3. When the output frequency reaches this value, the [G1.20]/dr.20 drive will pr ovide ovide the voltage set in parameter ‘G2.46 User I2’ (bA.46).

NO

Set user voltage 3. The drive will provide the frequency set in parameter when the frequency configured in ‘G2.45 UsFq3’ (bA.45) is (bA.45) is reached.

NO

0.00 to Set user frequency 4. When the output frequency reaches this value, the [G1.20]/dr.20 drive will provide the voltage set in parameter ‘G2.48 User V4’ (bA.48).

NO

0 to 100%

0 to 100%

0 to 100%

Set user voltage 4. The drive will provide the frequency set in parameter when the frequency configured in ‘G2.47 UsFq2’ (bA.47) is (bA.47) is reached. The user can set multiple speed references for the drive. This will be enabled by the use of the digital inputs configured as speed multireferences.

NO

YES

St1 G2.51 MREF2=20.00 % [5] Multi-Reference2

St2

The speed applied in each situation will depend on the digital inputs that control the multi-references, which are set as SPEED-L, SPEED-M and SPEED-H.

YES

For example, with the following options:

G2.52 MREF3=30.00% [5] Multi-Reference3

St3 G2.53 MREF4=40.00% [5] Multi-Reference4

bA.53 [5]

Multi-Reference5

bA.54 [5] [5]

Multi-Reference6

bA.55 [5] G2.56 MREF7=60.00% [5] Multi-Reference7

bA.56 [5]

YES

The adjustment is carried out by assigning a speed value for every 0.00 to parameter within this group, from ‘G2.50’ to ‘G2.56’ (bA.50 to bA.56). [G1.20]/dr.20

YES

The following table links the digital inputs configured as SPEED to the selected multi-reference:

G2.54 MREF5=50.00% [5]

G2.55 MREF6=60.00%

- ‘G5.65’ (ln.65) DI1 = ′Speed′Speed -H′ ′Speed -M′ - 'G5.66‘ (ln.65) DI2 = ′Speed′Speed -L′ L′ - 'G5.67‘ (ln.65) DI3 = ′Speed -

DIGITAL OUTPUT: SPEED H M L 0 0 0 X X X X

0 X X 0 0 X X

X 0 X 0 X 0 X

PID REFERENCE Multi-reference 1 Multi-reference 2 Multi-reference 3 Multi-reference 4 Multi-reference 5 Multi-reference 6 Multi-reference 7

PARAM. G2.50 (bA.50) G2.51 (bA.51) G2.52 (bA.52) G2.53 (bA.53) G2.54 (bA.54) G2.55 (bA.55) G2.56 (bA.56)

YES

YES

YES

Note: 0: Inactive and X: Active.

[5] These parameters will only be displayed if one of ‘G5.65’-‘G5.71’ (ln.65-ln71 in integrated display) is set to SpeedL/M/H.

32


SD300 SERIES

POWER ELECTRONICS Removable Name / display Description Integrated Integrated di splay G2.70 ACC2=20.0s bA.70 G2.71 DEC2=30.0s bA.71 G2.72 ACC3=20.0s bA.72 G2.73 DEC3=30.0s [6] bA.73 [6] G2.74 ACC4=20.0s [6] bA.74 [6] G2.75 DEC4=30.0s [6] bA.75 [6] G2.76 ACC5=20.0s [6] bA.76 [6] G2.77 DEC5=30.0s [6] bA.77 [6] G2.78 ACC6=20.0s [6] bA.78 [6] G2.79 DEC6=30.0s [6] bA.79 [6] G2.80 ACC7=20.0s [6] bA.80 [6] G2.81 DEC7=30.0s [6] bA.81 [6] G2.82 ACC8=20.0s [6] bA.82 [6] G2.83 DEC8=30.0s [6]

bA.83 [6]

Function

Set on RUN

The user can set different acceleration and deceleration ramps for the drive. In order to do this, parameters ‘G2.70-82' ‘G2.70-82' (bA70-82) must be configured and the corresponding codes entered in the group “Operation”. “Operation”.

YES

Range

Acceleration ramp 2 Deceleration ramp 2 Acceleration ramp 3 Deceleration ramp 3 Acceleration ramp 4 Deceleration ramp 4 Acceleration ramp 5

The established setting within the parameter is the time required to reach the maximum frequency value, starting from 0Hz (or to reduce the frequency according to the deceleration times). These ramps will be set according to the process necessities.

YES

The setting is carried out by assigning a speed value for each parameter of this group: bA.8 2): for acceleration times. - ‘G2.70’ to ‘G2.82’ (bA.70 to bA.82): - - ‘G2.71’ to ‘G2.83’ (bA.71 to bA.83): for deceleration times.

YES

Once multi function terminals have been configured (G5.65-71, In.65-71) as Speed-L/M/H (options 11, 12 and 49), acceleration and deceleration commands will control the drive operation based on the setting of ‘G2.70 83’ (bA.70-83). (bA.70 -83).

YES

YES

YES

YES

For example, with the following options: Deceleration ramp 5 Acceleration ramp 0.0 to 600.0s 6

YES

′Speed -L′ - ‘G5.65’ (ln.65) DI1 = ′Speed′Speed -M′ - 'G5.66‘ (ln.65) DI2 = ′Speed-

YES The drive will operate as shown in the figure:

Deceleration ramp 6

YES

Acceleration ramp 7

YES

Deceleration ramp 7

YES

Acceleration ramp 8

YES

Deceleration ramp 8

Accel / decel time 0 1 2 3

DI1

DI2 YES

✓ ✓ ✓

✓

[6] These parameters will only be displayed if one of ‘G5.65’-‘G5.71’ (ln.65-ln71 in integrated display) is set to Xcel-L/M/H.


33

SD300 SERIES

POWER ELECTRONICS

5.4. Group 3 – G3: Expanded Functions Removable Name / display Description Integrated Integrated di splay G3.1 AccPn=Linear Ad.1 G3.2 DecPn=Linear Ad.2 G3.3 AccSSrt=40% [7] Ad.3 [7] G3.4 AccSEnd=40% [7] Ad.4 [7] G3.5 DecSSrt=40% [8] Ad.5 [8] G3.6 DecSEnd=40% [8] Ad.6

[8]

Range

Ad Function

Set on RUN

Set the type of acceleration and deceleration depending on the application: Acceleration pattern

OPT. DESCRIPTION FUNCTION Linear S-curve

Deceleration pattern

0

1

S curve start acceleration slope

1 to 100%

S curve stop acceleration slope

1 to 100%

S curve start deceleration slope

1 to 100%

S curve stop deceleration slope

1 to 100%

Linear

S-curve

The output frequency is constant and increases/ decreases linearly. Used in applications which require a soft acceleration/ deceleration, such as lifting loads. The S curve index can be set from parameters ‘G3.3’ – ‘G3.6’ (Ad.3-Ad.6). ‘G3.6’ (Ad.3-Ad.6).

Set the curve whenever the acceleration/deceleration pattern is defined as S curve. It is used to set the S curve curvilinear relation when starting the acceleration. Set the curve’s ramp once the acceleration/deceleration pattern has been defined as S Curve. It is used to set the S Curve curvilinear relation when ending the acceleration. Set the curve whenever the acceleration/deceleration pattern is defined as S curve. It is used to set the S curve curvilinear relation when starting the deceleration. Set the curve’s ramp once the acceleration/deceleration pattern has been defined as S Curve. It is used to set the S Curve curvilinear relation when ending the deceleration. Define the motor start mode.

NO

NO

NO

NO

NO


G3.7 START=RAMP

The drive will start applying a frequency ramp to the motor. Allows accelerating after after having stopped the the motor by the use of the DC Brake. It can also be used after a normal brake whenever some torque is needed after opening the external 1 DCSTART brake. To configure this option, see parameters ‘G3.12 DCSt T’ and ‘G3.13 DC Curr’ (Ad.12 Curr’ (Ad.12 and Ad.13). Select the drive main stop mode. This value should be adequate for each application. 0

Motor start mode

RAMP DCSTART

Ad.7

RAMP

NO

OPT. DESCRIPTION FUNCTION G3.8 STOP=RAMP

Stop mode

0 to 4

Allow speed invertion

None FWDPrev REVPrev

Ad.8

G3.9 FWR/RV=None Ad.9 G3.10 Run Aft VlF=N Power-on Run

Ad.10

The drive will stop applying a frequency ramp to stop the motor. The drive will apply DC to stop the motor. To configure this option, see parameters from 1 DC BRAKE ‘G3.14 PreDC T’ (Ad.14) T’ (Ad.14) to ‘G3.17 DCBk F’ (Ad.17). The drive will cut the motor output supply, 2 SPIN stopping due to inertia. The drive will stop the motor as soon as possible by controlling the regenerative energy to avoid an overvoltage fault. This option may increase or decrease the deceleration time 4 POW BRKE according to the inertia of the load. Note: Do not use this option in applications where decelerations are frequent. It may cause overheating. Invert motor speed. This function helps to prevent the motor from rotating in inverse direction. 0

NO YES

RAMP

OPT. DESCRIPTION FUNCTION 0 None The motor can spin in both directions. 1 FWDPrev Motor cannot rotate clockwise. 2 RevPrev Motor cannot rotate anti clockwise. This parameter allows operating the drive if once powered up the start command is already present.

NO


NO

The drive will NOT operate if the start command is present on power up. To operate, a stop command should previously be sent.

1

YES

The drive starts after powering up.

[7] These parameters will only be displayed if ‘G 3.1’ (Ad.1 in integrated display) is set t o1 (S-curve). [8] These parameters will only be displayed if ‘G3.2’ (Ad.2) is set to 1 (S-curve).

34

NO


YES

SD300 SERIES

POWER ELECTRONICS Removable Name / display Description Integrated Integrated di splay G3.12 DCSt T=0.00s [9] Ad.12 [9] G3.13 DC Curr=50% Ad.13 G3.14 PreDCT=0.10s [10] Ad.14 [10] G3.15 DCBrkT=1.00s [10] Ad.15 [10] G3.16 DCBkCur=50% [10] Ad.16 [10] G3.17 DCBkF=5.00Hz [10] Ad.17 [10] G3.20 AcDF=5.00Hz [10] Ad.20

[10]

G3.21 AccDWT=0.0s Ad.21

G3.23 DecDWT=0.0s Ad.23 G3.24 UseFrqLimit=N Ad.24

Function

Set the time during which the equipment applies DC voltage before starting 0.00 to 60.00s to accelerate when the equipment is set in DC start mode. To enable the DC start, parameter ‘G3.7’ (Ad.7) ‘G3.7’ (Ad.7) must be set to ‘DCSTART’. Set the start current level when the equipment is set in DC START mode. Current injection 0 to 200% To enable DC start option, parameter ‘G3.7’ (Ad.7) (Ad.7) must be set to DC start ‘DCSTART’. Set the time before starting the DC Brake. Once the frequency is below the Pre DC brake time 0.00 to 60.00s value adjusted in parameter ‘G3.17 DCBkF’ (Ad.17) the drive will wait this time before starting the DC Brake operation. Time to DC start

DC brake time Current level DC brake Frequency start DC brake Acceleration dwell frequency Acceleration dwell time

G3.22 DeDF=5.00Hz Ad.22

Range

Deceleration dwell frequency Deceleration dwell time

Use frequency limit

0.00 to 60.00s Set the DC Brake operation time. 0 to 200%

Set the current level which will be applied to the motor in percentage of the motor rated current during DC Brake operation.

Set the frequency value at which the drive will enable the DC brake. The [G1.19]/dr.19 DC Brake operation will start once the frequency is below this value and the to 60.00 time set in parameter parameter ‘G3.14 PreDCT’ (Ad.14) PreDCT’ (Ad.14) has elapsed. [G1.19] to During the acceleration process, the drive will pause at this frequency, [G1.20] keeping it constant during the time set in parameter ‘G3.21 AccDWT’ (dr.19 to dr.20) (Ad.21). During the acceleration process, this parameter allows to define during how 0.0 to 60.0s long the drive will operate at the constant frequency set in in parameter ‘G3.20 AccDF’ (Ad.20). AccDF’ (Ad.20). [G1.19] to During the deceleration process, the drive will pause at this frequency [G1.20] value, remaining constant during the time period established in pa rameter (dr.19 to ‘G3.23 DecDWT’ (Ad.23). DecDWT’ (Ad.23). dr.20) During the deceleration process, this parameter allows to set how long will 0.0 to 60.0s the drive be operating at the constant frequency set in parameter parameter ‘G3.22 DecDF’ (Ad.22). DecDF’ (Ad.22). Enable or disable the frequency limit. NO YES


NO YES

Frequency limit disabled. Frequency limit enabled.

G3.25 FLtLo=0.50Hz [11] Frequency lower 0.00 to Set the lower frequency limit if parameter ‘G3. 24’ (Ad. 24’) 24’) is set as YES. limit [G3.26]/Ad.26 Ad.25 [11] G3.26 FLtHi=[G1.20]/dr.20 [G3.25] to Hz [11] Frequency higher Set the upper frequency frequency limit whenever parameter ‘G3. 24’ (Ad. 24) is set [G1.20] Ad.26 [11]

limit

(Ad.25/dr.20)

G3.27 Jump Freq=N Jump frequency activation

NO YES

Ad.27 G3.28 JmpL1=10.00Hz [12] Ad.28 [12] G3.29 JmpH1=15.00Hz [12] Ad.29 [12] G3.30 JmpL2=20.00Hz [12] Ad.30 [12] G3.31 JmpH2=25.00Hz [12] Ad.31 [12] G3.32 JmpL3=30.00Hz [12] Ad.32 [12] G3.33 JmpH3=35.00Hz [12] Ad.33 [12] G3.41 RlsCur=50.0% [13] Ad.41 [13]

as YES.

The user can enable or disable a band of jump frequencies to avoid resonance frequencies or other frequency types that the motor will avoid as references. The drive will pass these frequencies during the speed changes (acceleration and/or deceleration) but will not operate within these values.


Lower limit jump frequency 1 Upper limit jump frequency 1

NO YES

Set on RUN NO

NO

NO NO NO NO

NO

NO

NO

NO

NO

YES

NO

NO

Disable the frequency jump function. Enable the frequency jump function.

0.00 to Set the frequency jump 1 lower limit. [G3.29]/Ad.29 [G3.28] to [G1.20] Set the frequency jump 1 upper limit.

YES YES

(Ad.28 to dr.20)

Lower limit jump frequency 2

0.00 to Set the frequency jump 2 lower limit. [G3.31]/Ad.31

YES

Upper limit jump frequency 2

[G3.30] to [G1.20] Set the frequency jump 2 upper limit. (Ad.30 to dr.20)

YES


0.00 to Set the frequency jump 3 lower limit. [G3.33]/Ad.33

YES


[G3.32] to Set the frequency jump 3 upper limit. [G1.20]/dr.20

YES

Open brake current

0.0 to 180.0%

Set the output current at which the drive will open the relay configured as ‘BRCtrl’. See parameter ‘G6.31’ (OU.1). ‘G6.31’ (OU.1).

NO

[9] This parameter will only be displayed if ‘G3.7’ (Ad.7) is set to 1 (DCSTART). [10] These parameters will only be displayed if ‘G3.8’ (Ad.8) is set to 1 (DCBRAKE). [11] These parameters will only be displayed if ‘ G3.24’ (Ad.24) is set to 1 (YES). [12] These parameters will only be displayed if ‘ G3.27’ (Ad.27) is set to 1 (YES). [13] These parameters will only be displayed if either ‘G6.31’ or ‘G6.33’ (OU.31, OU.33 for integrated display) is set to BRCtrl.


35

SD300 SERIES

POWER ELECTRONICS

Removable Name / display Description Integrated Integrated di splay G3.42 RlsDly=1.00s [13] Ad.42

[13]

Range

Function

Once the motor current is greater than the one set in parameter ‘G3.41 RlsCurr’ (Ad.41) RlsCurr’ (Ad.41) and the frequency reached in the motor is the same as the Delay before brake 0.00 to 10.00s one set in parameter ‘G3.44 FwdFrq’ (Ad.44), FwdFrq’ (Ad.44), the drive will open the relay opening configured as ‘BRCtrl’ and will keep this speed during the time established in this parameter.

G3.44 FwdFq=1.00Hz [13] Brake opening 0.00 to Set the brake opening frequency of the relay configured as ‘BRCtrl’ while forward frequency [G1.20]/dr.20 the motor is accelerating in positive direction. Ad.44 [13] G3.45 RevFq=1.00Hz [13] Brake opening 0.00 to Set the brake opening frequency of the relay configured as ‘BRCtrl’ while [13] reverse frequency [G1.20]/dr.20 the motor is accelerating in negative direction. Ad.45 Once the motor has reached the frequency set in ‘G3.47 BEngFr’ (Ad.47), BEngFr’ (Ad.47), G3.46 BEngDly=1.00s [13] Delay before brake closing Ad.46 [13] G3.47 BEngF=2.00Hz [13] Brake closing frequncy Ad.47 [13]

0.00 to 10.00s the drive will close the braking relay and will keep this speed during the time established in this pa rameter. 0.00 to Set the frequency value at which the braking relay will stop operating, [G1.20]/dr.20 allowing the closed brake function.

Set on RUN

NO

NO NO NO NO

Set the minimum flux that the motor can employ to operate under low load conditions. With this optimized flux system, noises and power losses will be reduced due to the automatic flux level arrangement. The following table shows the different available configurations:

G3.50 FLX MIN=NONE

OPT. DESCRIPTION FUNCTION 0 Minimum flux mode

NONE

0 to 2 1

MANU

2

AUTO

Ad.50

G3.51 FluxLVEL=0% FluxLVEL=0% [14] Ad.51 [14]

Minimum flux level in manual mode

0 to 30%

No action is executed Selects the manual mode. If the output current is lower than the parameter ‘G2.14 N OLODC’ (bA.14) (no load motor current), output voltage will be reduced in the magnitude set in parameter ‘G3.51 FluxLVEL’ (Ad.51) FluxLVEL’ (Ad.51) Selects the automatic mode. The output voltage is set taking into account the motor r ated ated current set in ‘G2.13 MTRCUR’ and ‘G2.14 NOLODC’ (bA.13 NOLODC’ (bA.13 and bA.14).

Set the output voltage reducing magnitude if parameter ‘G3.50’ (Ad.50) ‘G3.50’ (Ad.50) is set to ‘MANU’. Set the frequency at which the drive will change the acceleration ramps, from the standard to those configured in ‘G2.70’ (bA.70) and ‘G2.71’ (bA.71).

NO

YES

G3.60 XclCF=0.00Hz

Acceleration dwell dwell 0.00 to frequency [G1.20]/dr.20

NO

Ad.60

Choose the fan operating mode.


G3.64 FAN=During Run Fan operating mode

0

DuringRun

0 to 2 1

Always ON

2

Temp Ctrl

Ad.64

G3.65 SaveMot Frq=N Ad.65

Save motorized potentiometer frequency

The drive fans will connect with the start command and disconnect three minutes after the drive stops. The fans are permanently working whenever the drive is powered. The fan will connect when the temperature in the heat sink reaches the preset control temperature.

Automatically save the speed reference defined by the motorized potentiometer. NO YES


NO YES

Speed reference is not saved. The speed reference is saved in the memory.

[14] These parame ters will only be displayed i f ‘G3.50’ (Ad.50 in integrated display) is different than ‘NONE’ .

36

YES


YES

SD300 SERIES

POWER ELECTRONICS Removable Name / display Description Integrated Integrated di splay

Range

Function

Set on RUN

The comparator source can be set according to the following table:


G3.66 SLCOM=None

0

Select comparator source

0 to 6

Ad.66

None

There is no source for the comparator Voltage analog input 1 will be used as source 1 V1 by the comparator. Voltage analog input 2 will be used as source 2 V2 by the comparator. Current analog input 2 will be used as source 3 I2 by the comparator. Pulse input will be used as source by the 6 Pulse comparator. Define the level to compare with the source selected in parameter ‘G3.66 SLCOM’ (Ad.66). SLCOM’ (Ad.66). In case this level is o ver passed, one of the digital outputs adjusted as ‘COMPARAT’ in ‘G6 ‘G6 Outputs’ Outputs’ will enable. See parameters ‘G6.31’ and ‘G6.32’ (OU.31 ‘G6.32’ (OU.31 a OU.33). Define the level to compare with the source selected in parameter ‘G3.66 SLCOM’. In case this level is over passed, one of the digital outputs adjusted as ‘COMPARAT’ in [G6 Outputs] will Outputs] will disable it. See parameters ‘G6.31’ and ‘G6.32’ (OU.31 ‘G6.32’ (OU.31 a OU.33). Configure safe operation mode. With it, the drive operates if it has permissions to do so.

NO

3

G3.67 ScON=90.00% Ad.67 G3.68 SC OF=10.00% Ad.68

Output activation level comparator mode

[G3.68] to 100.00

Output deactivation level comparator mode

-100.00 to [G3.67]

G3.70 RunEMod=Always RunEMod=Always Enable Ad.70

Safe operation selection

OPT. DESCRIPTION FUNCTION Always Enable The drive respondos to any start command 0 Always Enable without requiring further permisisons. DI Dependent The drive will only operate if the digital input 1 DI Dependent configured as ‘13 RUNEnable’ is active. Set the operation of the drive when the multi-function input terminal in safe operation mode is off.

NO

NO

NO


G3.71 RunDStp=Free RunDStp=Free Run [15]

Safe operation stop

Free-Run Q-Stop Q-Stop Res

0

Free-Run

1

Q-Stop

2

Q-Stop Res

Blocks the drive output when the multifunction terminal is off. If the digital input configured as ’13 RUNEnable’ is disabled when the drive is operating, the drive decelerates according to the ramp defined in parameter Ad.72. To establish again the start command, the input has to be enabled while the drive is stopped. If the digital input configured as ’13 RUNEnable’ is disabled when the drive is operating, the drive decelerates according to the ramp defined in parameter Ad.72. If once the permission digital input is reset the start command is present, the drive will start normally.

NO

The figure below illustrates the safe stop operation mode depending on the chosen option:

Ad.71 [15]

G3.72 QStpT=5.0s [15] Ad.72 [15] G3.74 RegAvdSel=N Ad.74

Q-Stop Time

0.0 to 600.0s

Enable regeneration prevention

N Y

Set the deceleration time when ‘G3.71’ (Ad.71 (Ad .71 in the integrated display) is set to 1 (Q-Stop) or 2 (Q-Stop Res). Enable regeneration prevention. When this situation occurs, the drive will increase the output frequency to prevent a fault due to overvoltage in the DC link. With this parameter, the drive helps the dynamic brake unit to avoid regeneration situations when the drive operates at normal speed.

YES

NO

[15] These parameters will only be displayed if ‘G3.70’ (Ad.70) is set to 1(DI DEPENDENT) .


37

SD300 SERIES

POWER ELECTRONICS


Range

Function

Set on RUN

Set the voltage level in the DC link voltage at which the algorithm will start increasing the speed.

G3.75 VlRegL=350V / 700V

NO

Regeneration prevention level

300 to 800V

Ad.75

NO

G3.76 CpFrL=1.00Hz 16 Ad.76 [16]

Compare frequency limit

G3.77 RegAvP=50.0% [16] P gain Ad.77 [16]

regeneration prevention

G3.78 RgAvI=50.0ms [16] I gain regeneration prevention Ad.78 [16]

0.00 to 10.00Hz

Note: The default value and parameter range will vary depending on the drive supply voltage: 220V300 to 400V 380V600 to 800V Set the alternative frequency width to be used by the algorithm when the voltage level set in parameter ‘G3.76’ (Ad.75) is overcome during regeneration prevention.

To prevent regeneration zone, set P gain/I gain in the DC link voltage 0.0 to 100.0% suppress PI controller.

NO

YES

Note: Press regeneration prevention does not operate during accelerations 0.0 to 3000.0ms

or decelerations; it only operates during constant speed motor operation. When regeneration prevention is activated, output frequency may change within the range set at ‘G3.76’(Ad.76).

YES

Fire mode forces the drive to ignore all minor faults and resets and restarts with major faults without considering the number of retry attempts. This action is performed until equipment destruction if necessary.

G3.80 FireModSel=None FireModSel=None [17]

The drive runs in Fire mode when this parameter is set to ‘ 1 (Fire Mode)’, and the multifunction terminal ‘G5.65‘G5.65 -71’ (In. 65-71) 65-71) configured for Fire mode is turned on. Fire mode selection

0 to 2


1

Ad.80 [17]

2

G3.81 FMdFr=60.00Hz FMdFr=60.00Hz [17] Fire mode frequency Ad.81 [17]

0.00 to 60.00Hz

G3.82 FModD=Forward FModD=Forward [17]

Ad.82

[17]

Fire mode is off Fire mode enabled. When the digital input configured as ‘Fire Mode’, the drive will start Fire Mode working in this mode, at the frequency configured in ‘G3.81’ (Ad.81) and the direction set in ‘G3.82’ (Ad.82). The drive simulates fire mode operation for a Fire Mode Test while. Then, it stops.

Set the frequency for drive operation in Fire mode. The Fire mode frequency takes priority over the Jog frequency, Multi-step frequencies, and frequency configured from keyboard.

NO

Set Fire mode direction according to the following table: Fire mode direction

Forward Reverse


Forward Reverse

[16] Displayed when ‘G3.74’ (Ad.74) is set to YES. [17] Displayed when ‘G3.80’(Ad.80) is set to YES.

38

NO

None


Forward direction. Reverse direction.

NO

SD300 SERIES

POWER ELECTRONICS

5.5. Group 4 – G4: Control Functions Removable display Integrated Integrated dis play

Name / Description

Range

Function

Set on RUN

Adjust motor operational noise by varying the commutation frequency in the motor output stage

G4.4 FREQ=2.0 / 3.0kHz Modulation frequency

-

If the frequency is set high, it reduces operational noise from the motor, and if it is set low, the operational noise from the motor increases.

YES

Default value and range for this parameter depend on the load rate:

Cn.4

Normal load: 2kHz (Max 5kHz). Heavy load: 3kHz (Max 15kHz). Change the modulation to reduce the heat loss and leakage current from the drive.

G4.5 PWM=Normal PWM Modulationmode

0 to 1

Cn.5 G4.9 PreExT=1.00s Cn.9

Cn

Pre-excitation time 0.00 to 60.00s 60.00s


Normal PWM

1

LowLeakage PWM

No changes to load rate. Reduces heat loss and leakage current compared to Normal PWM, but the motor noise increases.

Set the initial excitation time. Pre-excitation is used to start the operation after performing excitation up to the motor ’s rated flux.

NO

NO

Adjust the flux supplied during during the pre-excitation pre-excitation time setin set in ‘G4.9 ‘G4.9’ (Cn.9). The motor flux increases up to the rated flux with the time constant as shown in the following figure.

10 PreExF=100.0%

Pre-excitation flux

100.0 to 500.0%

NO

Cn.10 To reduce the time taken to reach the rated flux, a higher motor flux base value than the rated flux must be provided. When the magnetic flux reaches the rated flux, the provided motor flux base value i s reduced. After the motor stops, this parameter sets the time during which direct current from the drive is fed into the motor.

G4.11 PwofDl=0.00s

Power off delay

0.00 to 60.00s

NO

Cn.11

Allows configuring the sensorless sensorless control gain. gain.

G4.20 SL2GaViSel=N

OPT. DESCRIPTION FUNCTION Sensorless control gain 2

Cn.20 G4.21 ASR P1=500% (*) ASR proportional proportional gain 1 Cn.21

YES NO

0

YES

1

NO

Sensorless control gain configuration parameters will not be shown. Enables sensorless control gain configuration. Parameters ‘G4.21‘G4.21-32’ 32’ (Cn.21-32) will be displayed.

Set the proportional gain 1 of the speed controller (ASR). The higher the 0 to 5000% proportional gain, the faster the response will be. But if the gain is too high, the speed of the motor might oscillate.

G4.22 ASR I1=300ms (*) ASR integral time time 10 to 9999ms Set the integral gain 1 of the speed controller (ASR). (ASR). 1 Cn.22

YES

YES

YES


39

SD300 SERIES Removable display Integrated Integrated dis play G4.23 ASR P2=120.0% [18] (*) Cn.23 [18] G4.24 ASR I2=30.0% [18] (*) Cn.24 [18] G4.25 ASR I1=300ms [18] (*) Cn.25 [18] G4.26 P Flux=50% [18] (*) Cn.26 [18] G4.27 I Flux=50% [18] (*) Cn.27 [18] G4.28 SpEsP1=100 [18] (*) Cn.28 [18] G4.29 SpEsI1=500 [18] (*) Cn.29 [18] G4.30 SpEsI2=2000 [18] (*) Cn.30 [18] G4.31 ACR P2=500 [18] (*) Cn.31 [18] G4.32 ACR I2=500 [18] (*) Cn.32 [18] G4.48 ACR P1=1200 Cn.48 G4.49 ACR I1=120 Cn.49 G4.52 OuFVec=0ms Cn.52

POWER ELECTRONICS

Name / Description

Range

Function

Set on RUN

Independent controller proportional gain 2

1.0 to 1000.0%

Set the proportional gain 2 of a separate controller. The higher the proportional gain, the faster the response will be. But if the gain is too high, the speed of the motor might oscillate.

YES

Independent controller integral gain 2

1.0 to 1000.0%

Set the integral gain 2 of a separate controller.

YES

Integral time sensorless controller

10 to 999ms Sensorless speed controller integral gain 0.

YES

Flux estimator proportional gain

1 to 200%

Flux estimator integral gain

1 to 200%

YES

Speed estimator proportional gain 1

sensorless vector control: 0 to 32767 Adjusts speed estimator gain for sensorless

YES

Speed estimator integral gain 1

100 to 1000

Speed estimator integral gain 2

100 to 10000

YES Sensorless vector control requires the rotor flux estimator. Use these parameters to adjust flux estimator gain.

•

•

At low speed (10Hz or lower), increase the value of ‘G4.29’ ‘G4.29’ (Cn.29) by increments of 5. At mid speed (30 Hz or higher), higher), increase the value of ‘G4.28’ (Cn.28) ‘G4.28’ (Cn.28) by increments of 500. If the parameter setting is too extreme, over current trip may occur at low speed.

YES YES

Sensorless cont. proportional gain

gains of the sensorless sensorless current controller. 10 to 1000 Adjusts the P and I gains

Sensorless cont. integral gain

10 to 1000

Controller P gain

10 to 10000 Adjust current controller P gain.

YES

Controller I gain

10 to 10000 Adjust current controller I gain

YES

If the value of G4.10 (Cn.10) is high, an overcurrent trip at start can occur. In this case, reduce the value of ‘G4.31’ G4.31’ (Cn.31) by (Cn.31) by decrements of 10.

Output filter vector 0 to 2000ms Set the torque controller output filter

YES YES

NO

Select the source to introduce the torque limit reference.


LOCAL

2

V1

4

V2

5

I2

6

MODBUS

8

COMMS

9

PLC

12

PULSE

G4.53 TqLimRef=LOCAL TqLimRef=LOCAL

Torque limit reference

0 to 12

Cn.53

G4.54 TLpsFW=180.0% TLpsFW=180.0% [19]

Cn.54

[19]

Forward positive torque limit

0.0 to 200.0%

Reference will be given by keypad and will be set in ‘G1.1’ (dr.1) - Local Speed. Reference will be introduced through the voltage analog input 1. Reference will be introduced through the voltage analog input 2. Reference will be introduced through the current analog input 2. The reference will be introduced through Modbus. The reference will be introduced through the communications. The common area can be linked with user sequence output and can be used as command. Reference will be introduced through the Pulse input.

The user can set the forward motoring operation torque limit whenever the torque limit reference has been set as LOCAL

NO

YES

* These values depend on the motor setting. [18] Displayed when ‘G1.9’ (dr.9 in integrated display) is set to 4 (IM Sensorless) and ‘G4.20’ (Cn.20) is set to 1 (YES) [19] Displayed when ‘G1.9’ (dr.19) is set to 4 (IM Sensorless). This will change the initial value of ‘G3.74’ (Ad.74), Torque limit, to 150%.

40


SD300 SERIES

POWER ELECTRONICS Removable display Integrated Integrated dis play G4.55 TLngFW=180.0% TLngFW=180.0% [19]

Name / Description Forward negative torque limit

Cn.55 [19] G4.56 TLpsRV=180.0% [19] Reverse positive torque limit Cn.56 [19] G4.57 TLngRV=180.0% TLngRV=180.0% [19]

Cn.57 [19]

Reverse negative torque limit

Range

Function

Set on RUN

0.0 to 200.0%

The user can set the forward regeneration operation torque limit whenever the torque limit reference has been set as LOCAL

YES

0.0 to 200.0%

The user can set the reverse motoring operation torque limit whenever the torque limit reference has been set as LOCAL

YES

0.0 to 200.0%

The user can set the reverse regeneration operation torque limit whenever the torque limit reference has been set as LOCAL

YES

Select the source to introduce the speed limit reference.

OPT. DESCRIPTION FUNCTION G4.62 SpLiRf=LOCAL [19]

Speed limit reference

LOCAL

2

V1

4

V2

5

I2

6

MODBUS

7

COMMS

8

PLC

0 to 8

Cn.62 [19]

G4.63 SpL(+)=60.00Hz [19] Cn.63 [19] G4.64 SpL(-)=60.00Hz SpL(-)=60.00Hz [19] Cn.64 [19] G4.65 SpLGa=500% [19] Cn.65 [19]

0

Reference will be given by keypad and will be set in ‘G1.1’ (dr.1) - Local Speed. Reference will be introduced through the voltage analog input 1. Reference will be introduced through the voltage analog input 2. Reference will be introduced through the current analog input 2. The reference will be introduced through Modbus. The reference will be introduced through the communications. The common area can be linked with user sequence output and can be used as command.

NO

Forward speed limit

0.00 to 400.00Hz

The user can set the forward speed limit whenever the speed limit reference has been set as LOCAL.

YES

Reverse speed limit

0.00 to 400.00Hz

The user can set the reverse speed limit whenever the speed limit reference has been set as LOCAL.

YES

Speed limit gain

100 to 5000%

Set how much the speed reference has to decrease when motor speed exceeds the speed limit.

YES

Select a speed search mode.


G4.70 SSMode=Flying SSMode=Flying Start1 0

Speed search mode selection

Cn.70

Flying Start1

Flying Start1 Flying Start2

1

Flying Start2

Speed search is carried out as it controls the drive output current during idling below the ‘G4.72’ G4.72’ (Cn.72) parameter setting. If the direction of the idling motor and the direction of operation command at restart are the same, a stable speed search function can be performed at about 10 Hz or lower. However, if the direction of the idling motor and of operation command at restart are different, the speed search does not produce a satisfactory result because the direction of idling cannot be established. The speed search is carried out as it controls the ripple current which is generated by the counter electromotive force during no-load rotation. This mode establishes the direction of the idling motor (forward/reverse), thus the speed search function is stable regardless the direction of the idling motor and of operation command. However, since ripple current is used, the idle frequency is not accurately determined and re-acceleration may start from zero speed when the speed search is performed for the idling motor at low speed (about 10 - 15 Hz, though it depends on motor characteristics).

NO


41

SD300 SERIES Removable display Integrated Integrated dis play

POWER ELECTRONICS

Name / Description

Range

Function

Set on RUN

Set the search mode. Adjust each bit to 0 or 1 according to the table below:

G4.71 Srch Mod=0000 Search mode

00 to 15

Cn.71 G4.72 Srch I=150% [20] Cn.72 [20] G4.73 Kp Srch [21] Cn.73 [21] G4.74 Ki Srch [21] Cn.74 [21] G4.75 SrchDly=1.0s [21] Cn.75 [21] G4.76 SpEsGa=100% [21] Cn.76 [21]

OPT

DESCRIPTION

0001 0010 0100

Selection of speed search on acceleration. Speed seach on start after fault. Speed search after a power supply fault. Speed search when the drive is energized, if the start command is present.

1000

Speed search mode current Speed search mode prop. gain Speed search mode integral gain

NO

80 to 200%

Allows controlling the current during the speed search in percentage in relation with the motor rated current.

YES

0 to 9999

‘G4.73 Search Proporc’ (Cn.73) Proporc’ (Cn.73) allows setting the proportional gain for the speed search. ‘G4.74 Search integral’ (Cn.74) integral’ (Cn.74) sets the integral gain for the speed search.

YES

Note: Default value of these parameters depends on ‘G4.70’ G4.70’ (Cn.70): 0 to 9999

Flying Start1100 Flying Start2600

Speed search delay

0.0 to 60.0s

Allows locking the output during an established time before proceeding proceeding with the speed search.

Speed estimator gain

50 to 150% Speed search estimator gain.

YES

NO

YES

When the input power supply is disconnected, the drive DC link voltage decreases and a low voltage trip occurs blocking the output. A kinetic energy buffering operation uses regenerative energy generated by the motor during the blackout to maintain the DC link voltage. This extends the time for a low voltage trip to occur after a sudden power interruption.

G4.77 KEB Sel=No

This parameter allows selecting the kinetic energy buffering operation. If 1 or 2 is selected, it controls the drive output frequency and charges the DC link (drive DC part) with energy generated from the motor.

OPT. DESCRIPTION FUNCTION 0 KEB Select

No

0 to 2

1

KEB1

2

KEB2

Cn.77

G4.78 KEBStr=125.0% [22] Cn.78 [22] G4.79 KEBStp=130.0% [22] Cn.79 [22] G4.80 KEBPGn=10000 [22] Cn.80 [22]

Initial value for KEB operation

110.0 to 140.0%

Sets the start and stop points of the kinetic energy buffering operation. The set values must be based on the low voltage trip level as 100% and the stop level ‘G4.79’ G4.79’ (Cn.79) must (Cn.79) must be higher than the start level ‘G4.78’ G4.78’ (Cn.78).

NO

[G4.78] to 140.0

KEB proportional gain

1 to 20000

Maintain the voltage of the DC power section during the kinetic energy buffering operation. Change the setting value when a low voltage trip occurs right after a power failure.

YES

KEB integral gain

1 to 20000

Maintain the voltage of the DC power section during the kinetic energy buffering operation. Sets the gain value to maintain the frequency during the kinetic energy buffering operation until the drive stops.

YES

* These values depend on the motor setting. [20] Displayed when ‘G4.70’ (Cn.70) is set to 0 (YES). [21] Displayed when any of the ‘G4.71’ (Cn.71) bits are set to 1. [22] Displayed when ‘G4.77’ (Cn.77) is not set to 0 (NO).

42

NO

Value to stop KEB operation

G4.81 KEBIGn=500 [22] Cn.81 [22]

General deceleration is carried out until a low voltage trip occurs. When the input power is lost, it charges the DC link with regenerated energy. When the input power is restored, so does normal operation from energy buffering operation to the frequency reference operation. Operation frequency acceleration is set in ‘G4.89’ G4.89’ (Cn.89). When the input power is lost, it charges the DC link with regenerated energy. When the input power is restored, it changes from the energy buffering operation to the deceleration stop operation. The operation frequency (dr.4). deceleration time is set in ‘G1.4’ G1.4’ (dr.4).


NO

SD300 SERIES

POWER ELECTRONICS Removable display Integrated Integrated dis play G4.85 FlxPrGa1=370 [23] Cn.85 [23] G4.86 FlxPrGa2=0 [23] Cn.86 [23] G4.87 FlxPrGa3=100 FlxPrGa3=100 [23] Cn.87 [23] G4.88 FlxInGa1=50 [23] Cn.88 [23] G4.89 FlxInGa2=50 [23] Cn.89 [23] G4.90 FlxInGa3=50 [23] Cn.90 [23] G4.91 SLVoCmp1=20 (*) [23]

Name / Description

Range

100 to 700

Flux estimator proportional gain 1.

YES

Flux proportional gain 2

0 to 100


YES


0 to 500


YES

Flux integral gain 1

0 to 200

Flux estimator integral gain 1.

YES


0 to 200


YES


0 to 200


YES

SL voltage compensation 1

0 to 60

Adjust output voltage compensation compensation values for sensorless vector control. control. •

compensation 2

0 to 60

Cn.92 G4.93 SLVoCmp3=20 (*) SL voltage [23]

[23]

Set on RUN


Cn.91 [23] G4.92 SLVoCmp2=20 (*) SL voltage [23]

Function

• •

compensation 3

0 to 60

If the output frequency is higher than the base frequency during no-load operation at low speed, decrease the value of ‘G4.91’ G4.91’ (Cn.91) (Cn.91) by decrements of 5 (10Hz or lower). If the torque is insufficient, increase ‘G4.93’ G4.93’ (Cn.93) by (Cn.93) by increments of 5. If the motor hunts or overcurrent trip occurs in regenerative load at low speed (10 Hz or lower), increase the value of ‘G4.92-93’ G4.92-93’ (Cn.92-93) (Cn.92-93) by increments of 5 at the same time.

YES

YES

YES

Cn.93 [23] G4.94 FWFrS=100.0% FWFrS=100.0% [23] SL fluctuation frequency Cn.94 [23]

80.0 to 110.0%

If an over current trip occurs due to sudden load fluctuation at high speed (50 Hz or higher), increase/decrease the value of ‘G4.94’ Cn.94 by increments/decrements of 5% (set below 100%).

YES

G4.95 FcFrS=2.00Hz [23] Cn.95 [23]

0.00 to 8.00Hz

Set sensorless gain switching frequency.

YES

SL switching frequency

5.6. Group 5 – G5: Inputs Removable display Integrated Integrated dis play G5.1 MxFA=[G1.20] In.1 G5.2 MaxTrq=100.0% In.2 G5.5 AnlgIN1=0.00V In.5

Name / Description

In

Range

YES

Analog input max. 0.0 to 200.0% Reserved. torque

YES

V1 Monitor

0.00 to 12.00 Voltage analog input 1 (V1) visualization. This parameter allows setting the operation directions of the drive.

V1 polarity

In.6

0-10V -/+10V

V1 filter

FUNCTION

0-10V

Unipolar (forward operation) Bipolar (forward and reverse operation directions)

Low Pass Filter for V1. Allows setting the time response to a change 0 to 10000ms produced in the speed reference, to reduce the speed fluctuation due to unstable signs or noise. Thus, the response becomes slower.

NO

YES

V1 minimum voltage

0.00 to 10.00V

Define the minimum voltage for the analog input 1 according to the connected sensor characteristics

YES

V1 minimum reference

0.00 to 100.00%

Set the speed reference corresponding to the analog input 1 minimum negative range. Is corresponds to the minimum voltage level set in ‘G5.12 A1NMn’ (In.12). A1NMn’ (In.12). It is configured to introduce the speed reference through the AI. The value is a percentage of the frequency set in ‘G5.1 MxFA’ (In.1). MxFA’ (In.1).

YES

G5.9 A1MnR=0.00% In.9

OPTION 10V

G5.7 Ain1LP=10ms G5.8 A1MnV=0.00V In.8

Set on RUN

[G1.19] to Analog input max. Set drive operating frequency for the maximum voltage input of the analog [G1.20] freq input. (dr.19 to dr.20)

G5.6 An1PT=0-10V

In.7

Function

[23] Displayed when ‘G4.20’ (Cn.20) is set to 1 (YES).


43

SD300 SERIES Removable display

POWER ELECTRONICS

Range

Function

Set on RUN

V1 maximum voltage

0.00 to 10.00V

Define the maximum voltage for the analog input 1, according to the connected sensor characteristics.

YES

V1 maximum reference

0.00 to 100.00%

Set the speed reference corresponding to the analog input 1 minimum range. It corresponds to the minimum voltage level set in ‘G5.10 An1MxV’ (In.10). It is configured to introduce the speed reference through the V1 MxFA’ (In.1). analog input. input. The value is a percentage of ‘G5.1 MxFA’ (In.1).

YES

-10.00 to 0.00V

Define the negative minimum voltage for the analog input 1, according to the connected sensor characteristics.

YES

Set the speed reference corresponding to the analog input 1 minimum negative range. Is corresponds to the minimum voltage level set in ‘G5.12 -100.00 to A1NMn’ (In.12). A1NMn’ (In.12). It is configured to introduce the speed reference through 0.00% the analog input. The value is a percentage of the frequency adjusted in parameter ‘G5.1 MxFA’ (In.1). MxFA’ (In.1).

YES

G5.14 A1MxV=-10.00V [24] V1 maximum negative voltage In.14 [24]

-10.00 to 0.00V

Define the maximum negative voltage for the analog input 1 according to the connected sensor characteristics.

YES

G5.15 A1Mx=-10.00% [24]

Set the speed reference corresponding to the analog input 1 maximum -100.00 to negative range. It corresponds to the maximum voltage level set in ‘G5.13 0.00% A1MnR’ (In.13). A1MnR’ (In.13). It is configured to introduce the speed reference through an analog input. The value is a percentage of ‘G5.1 MxFA’ (In.1). MxFA’ (In.1).

YES

Integrated Integrated dis play G5.10 An1MxV=10.00V In.10 G5.11 A1MxR=100.00% In.11

Name / Description

G5.12 A1NMn=-10.00V [24] V1 minimum negative voltage In.12 [24] G5.13 A1MnR=-10.00% [24] In.13

[24]

In.15 [24] G5.16 V1 Invert=N In.16

V1 minimum negative reference

V1 maximum negative reference

N Y

Inverts the direction of rotation. Set this parameter to 1 (NO) if you need the motor to run in the opposite direction from the current rotation.

YES

Adjust V1 quantification

0.04 to 10.00%

Set the voltage analog input 1 quantification level. It is used when too much noise is present within the analog input signals. The quantification value is defined as the analog input 1 maximum percentage value. For example, if the input maximum value is 10V and the quantification level is 1%, the frequency will change in 0.05Hz (when the maximum frequency is 50Hz), in 0.1V intervals. As the input voltage increases or decreases, the output frequency will differ, removing the fluctuation effect within the analog input value.

YES

V2 Monitor

0.00 to 12.00V

Voltage analog input 2 monitor.

YES

V1 Inverting

G5.17 A1DeLl=0.04%

In.17 G5.35 AngIN2=0.00V [25] In.35 [25] G5.37 A2LPF=10ms [25] In.37 [25] G5.38 A2MnC=0.00V [25] In.38 [25]

V2 filter V2 minimum voltage

Set the time response against a change produced in the speed reference, 0 to 10000ms so that it can reduce the speed fluctuation due to unstable signs or noise. Thus, the response becomes slower. 0.00 to 10.00V

Define the minimum current for the analog input 2 according to the connected sensor characteristics.

0.00 to 100.00%

Set the speed reference corresponding to the analog input 2 minimum range. It corresponds to the minimum voltage level set in ‘G5.38 A2MnC’ (In.38). It is configured to introduce the speed reference through the analog input. The value is a percentage of the frequency adjusted in parameter ‘G5.1 MxFA’ (In.1). MxFA’ (In.1).

YES

0.00 to 10.00V

Define the maximum current for the analog input 2, according to the connected sensor characteristics.

YES

V2 maximum reference

0.00 to 100.00%

Set the speed reference corresponding to the analog input 2 maximum range. It corresponds to the maximum current level set in ‘G5.40 A2MxC’ (In.40). It is configured to introduce the speed reference through the analog input. The value is a percentage of the frequency adjusted in parameter ‘G5.1 MxFA’ (In.1). MxFA’ (In.1).

YES

V2 Inverting

YES NO

Same as ‘G5.16 V1 Invert’ Invert’ (In.16), but for the voltage analog input 2.

YES

Adjust I2 visualization

0.04 to 10.00%

Same as ‘G5.17 A1DeLl’ (In.17), but for the voltage analog input 2.

YES

I2 Monitor

0.00 to 24.00mA

Used to monitor current analog input 2.

NO

Configures the time for the operation frequency to reach 63% of target frequency based on the input current at the analog input 2.

YES

G5.39 A2MnR=0.00% [25] In.39 [25]

V2 minimum reference

G5.40 A2MxC=10.00V [25] V2 maximum current In.40 [25] G5.41 A2MxR=100.00% [25]

In.41

[25]

G5.46 V2 Invert=N [25] In.46 [25] G5.47 A2DeLl=0.04% [25] In.47 [25] G5.50 AnI2=0.00mA [26] In.50 [26] G5.52 AI2LF=10ms [26] In.52 [26]

I2 filter

0 to 10000ms

[24] Displayed if ‘G5.6’ (ln.6 in integrated display) is configured as bipolar ( 10V). [25] Displayed when V is selected s elected on the analog current/voltage input circuit selection switch (SW2). [26] Displayed when I is sselected elected on the analog current/voltage input circuit selection switch (SW2).

44

NO


SD300 SERIES

POWER ELECTRONICS Removable display Integrated Integrated dis play G5.53 A3MnC=4.00mA [26] In.53 [26] G5.54 A3MnR=0.00% [26] In.54 [26] G5.55 A2MxC=20.00mA [26]

In.55 [26] G5.56 A2MxR=100.00% [26]

Name / Description

Function

Set on RUN

I2 minimum current

0.00 to 20.00mA

Same as ‘G5.38 A2MnC ‘G5.38 A2MnC’’ (In.38), but for the current analog input 2.

YES

I2 minimum reference

0.00 to 100.00%

Same as ‘G5.13 A1MnR ‘G5.13 A1MnR’’ (In.13), but for the current analog input 2.

YES

I2 maximum current

0.00 to 24.00mA

Same as ‘G5.40 A2MxC ‘G5.40 A2MxC’’ (In.40), but for the current analog input 2.

YES

I2 maximum reference

0.00 to 100.00

Same as ‘G5.11 A1MxR ‘G5.11 A1MxR’’ (In.11), but for the current analog input 2.

YES

Same as ‘G5.16 V1 Invert’ Invert’ (In.16), but for the current analog input 2.

YES

Same as ‘G5.17 A1DeLl’ (In.17), but for the current analog input 2.

YES

In.56 G5.61 I2 Invert=N [26] I2 Inverting In.61 [26] G5.62 A2DeLl=0.04% [26] Adjust I2 visualization In.62 [26] [26]

Range

N Y 0.04 to 10.00%

Digital Inputs configuration for individual use.

OPT. DESCRIPTION FUNCTION G5.65 DI1=START(+)

Digital input 1

In.65

0

None

1

START(+)

2

START(-)

3

RESET

4

EXTTRIP

5

DISSTART

6

INCH1

7

SPEED-L

8

SPEED-M

9

SPEED-H

11

XCEL-L

12

XCEL-M

13

RUNEnable

Sets the digital input to safe operation mode. Configure digital inputs for a behaviour with pushbuttons. This input is set as NC and acts as stop to a start command.

14

3-WIRE

DI1 = 1 START(+) (NO) DI2 = 14 3 WIRE (NC) DI3 = 18 DOWN (NO) This way, the DI1 button orders to start and the DI2 orders to stop. The DI3 button decreases the speed. Enable the alternative control mode programmed in ‘G2.4 Alt Ctrl Mode′ (bA.4) Mode′ (bA.4) (NO).

G5.66 DI2=START(-)

Digital input 2

0 to 54

In.66

G5.67 DI3=RESET

Not programmed entry. Send the start command through an open contactor (NO). The operation of the Digital Input varies when ‘3 WIRE’ is selected. Send the reverse start command through an open contactor (NO). The operation of the Digital Input varies when ‘3 WIRE’ is selected.

NO

Send a ‘Reset’ command through digital inputs. ( NO) Trigger an external fault to stop the drive through digital inputs (NO). Is advisable to invert the digital input logic configured as Extreme Fault and set it as contact (NC). See parameter ‘G5.87’ (In.87). ‘G5.87’ (In.87). Stop the drive by removing the motor output power supply, forcing a stop by inertia. (NO) Enable the speed reference programmed in ‘G1.11 InchFq’ (dr.11). InchFq’ (dr.11). (NO) Bit 0 speed reference. Allows selecting the multiple preconfigured speed references. See ‘G2.50’ to ‘G2.56 ‘G2.56’’ (bA.50 to bA.56) (NO). Bit 1 speed reference. Allows selecting the multiple preconfigured speed speed references. See ‘G2.50’ to ‘G2.56 ‘G2.56’’ (bA.50 to bA.56) (NO). Bit 2 speed reference. Allows selecting the multiple preconfigured speed references. See ‘G2.50’ to ‘G2.56 ‘G2.56’’ (bA.50 to bA.56) (NO). Bit 0 for alternative acceleration ramps. Allows the selection of the multiple preconfigured acceleration/deceleration ramps. See ‘G2.70’ to ‘G2.83’ (bA.70 ‘G2.83’ (bA.70 to bA.83). Bit 1 for alternative acceleration ramps. Allows the selection of the multiple preconfigured acceleration/deceleration r amps. amps. See ‘G2.70’ to ‘G2.83’ (bA.70 ‘G2.83’ (bA.70 to bA.83).

NO

Example:

Digital input 3 15

CTR/REF2

NO

In.67 Note: Continues on the next page.


45


POWER ELECTRONICS

Name / Description

Range

Function

Set on RUN

Note: Comes from the previous page. OPT. DESCRIPTION FUNCTION This option switches motor power supply from the drive with direct network supply. To do this, digital output options 17 ‘Line in’ and 18 ‘Line Co’ are used. While the digital input is open, the digital output configured as 17 ‘Line in’ remains active. Once this digital input is closed, the relay ‘Line in’ is disabled, waits for 500ms and enables ‘Line Co’. When this digital input in disabled, disabled, ‘Line Co’ is disabled, waits for 500ms, enables ‘Line In’ and performs a speed search to sinchronize with the motor.

G5.68 DI4=RESET

Digital input 4 16

Exchange

17

UP

18

DOWN

20

POTCLEAR

21

AnalogHLD

22

I-Term Clear

NO

In.68

G5.69 DI5= SPEED-L

Digital input 5

In.69

23

PIDOPLoop

24

PGain2

25

XCELStop

26

2ndMotor

34

Pre-Excit

Assign the fu nction to increase the speed reference through a button (NO) to the digital input. reference limits are those set se t in ‘G1 Drive’ (dr). Set digital input to decrease the speed reference by the use of a button (NO). The reference limits will be those set on ‘G.1 Drive’. Reset to 0 the speed reference of the motorized potentiometer. This way, even if parameter ‘G3.65’ (Ad.65) is set to NO, when restarting the drive, the drive will operate at the reference set in ‘G1.1 Local Speed’ (dr.1). Set a speed reference from an analog input to the present activation time value. When this digital input is active, the drive will ignore any change produced in the analog input reference (NO). Reset the accumulated error by the integral PID function.

NO

Allow disabling the PID function. When it is disabled, the control PID will be resumed. Note: This option must be used when the PID reference is set by analogue input. If PID reference is set by display, use option ‘INCH1’. Set the proportional gain 2 for PID operation. Sets the digital input to stop acceleration or deceleration.

G5.70 DI6= SPEED-M

Digital input 6

38

TimerIN

In.70

Set the digital input as 2nd motor operation, which is used when a single drive switch operates two motors. Enable the motor pre-excitation activation, before start. The user can adjust this functionality in parameters ‘G3.7 START’, ‘G3.12 DCSt T’ and ‘G3.13 DC Curr’ (Ad.7, Ad.1 and Ad.13). Set the function for the temporized digital output. If option 28 “Timer -Ou” is selected in G6.31’ (OU.31) or ‘G6.36’ (OU.33), the digital output will wil l be enabled once the time set in ‘G6.56’ (OU.56) has elapsed. Once this digital input is disabled, the digital output will be disabled once the time set in ‘G6.57’ (OU.57) has elapsed.

Note: Continues on the next page.

46


NO

SD300 SERIES

POWER ELECTRONICS Removable display Integrated Integrated dis play

Name / Description

Range

Set on RUN

Function Note: Comes from the previous page. OPT. DESCRIPTION FUNCTION

G5.71 DI7= SPEED-H

Digital input 7

In.71

85 DIOnF=10ms In.85 86 DIOfF=3ms In.86

Digital input activation delay

40

disAuxRef.

46

INCH(+)

47

INCH(-)

This digital input sets the main reference + alternative reference functionality. When drive speed is controlled by the main reference source, if this input is enabled, the speed reference will be calculated according to parameter ‘G2.2’ (ba.2). Enable the direct starting fix speed reference to the one set in parameter ‘G1.11 InchFq’ (dr.11).

49

XCEL-H

50

PLC

51

FireMode

52

KEB1Sel

54

TI

Bit 2 for alternative acceleration ramps. Allows the selection of the multiple preconfigured acceleration/deceleration ramps. See ‘G2.70’ to ‘G2.83’ (bA.70 to 83). Enables the user to implement simple sequences using various function blocks. The drive runs in Fire mode when ‘G3.80’ (Ad.80) is set to 2 and the multifunction multifunction terminal (‘G5.65(‘G5.65 -71’, In 65-71) configured for Fire mode is turned on. For kinetic energy buffering operation, select the multifunction terminal, set it to ‘KEB1Sel’ and enable the digital input. In IP66 equipment, pulse input TI and Multi-function terminal P5 share the same therminal. In this case, set parameter ‘G5.69’ (In.69) to 54(TI).

NO

Set the delay time when activating the digital input. In case any variation occurs within a smaller time gap, the input will remain disabled.

YES

Digital input Set the delay time when disabling a digital input. In case any variations 0 to 10000ms deactivation delay occur within a smaller time gap, the input will remain enabled.

YES

0 to 10000ms

Allows defining the digital inputs as normally open contactors (YES). or normally closed (NC).

87 DCTy=0000000

BIT SETTING DESCRIPTION Digital input contact type

0000000 to 1111111

In.87

89 DiScan=1ms In.89

0 1

Contact normally open (YES) Contact normally closed (NC)

NO

The assignment order is P1, P2, P2, …, P7 starting from the bit placed farthest to the right. The number of Digital Inputs varies depending on the equipment (IP20 drives integrate 7 Digital Inputs and IP66 drives integrate 5). DI scan time

1 to 5000ms

Set the time to wait before refreshing the digital inputs configured as multireference.

NO

Shows the status of digital inputs:

90 StDI=0000000

BIT SETTING DESCRIPTION Digital inputs status

0000000 to 1111111

In.90 91 TIPls=0.00kHz In.91 92 TIFlt=10 In.92

0 Contact normally open (NO) 1 Contact normally closed (NC) The assignment order is P1, P2, …, P7 starting from the bit placed farthest to the right. The number of Digital Inputs varies depending on the equipment (IP20 drives integrate 7 Digital Inputs and IP66 drives integrate 5).

TI Monitor

0.00 to 50.00kHz

This parameter shows the pulse frequency in this input.

TI Filter

0 to 9999

This parameter allows setting the time in which the pulse input reaches 63% of its nominal frequency. It is useful when the pulse frequency is supplied in multiple steps.

TI minimum input frequency

0.00 to 32.00kHz

93 TIMn=0.00kHz In.93

PARAMETER DESCRIPTION G5.93/In93 G5.94/In94

94 TIMnR=0.00% In.94

TI minimum input frequency percentage

G5.95/In95 0.00 to 100.00%

YES

G5.96/In96

This parameter allows setting the frequency through TI. This parameter allows setting the frequency percentage through TI. This parameter allows setting the frequency through TI. This parameter allows setting the frequency percentage through TI.

minimum input

YES

minimum input maximum input maximum input

YES


47


POWER ELECTRONICS

Name / Description

Range

TI maximum input frequency

0.00 to 32.00kHz

YES

TI maximum input frequency percentage

0.00 to 100.00%

YES

Function

Set on RUN

95 TIMx=32.00kHz In.95 96 TIMxR=100.00%

In.96 97 TI Invert=N In.97 98 TIDeLl=0.04% In.98

TI Inverting TI noise reduction level

N Y

This parameter allows inverting the TI signal. Set this parameter to 1 (NO) if you need a reverse signal.

YES

0.04 to 10.00%

This parameter is used to reduce noise in the TI input signal. The quantification value is defined as the input maximum percentage value.

YES

Software status. Set each bit to 0 or 1 according to the following table:

99 IOSWST=00

BIT SETTING DESCRIPTION Input mode setting

00 to 11

In.99

5.7. Group 6 – G6: Outputs Removable display Integrated Integrated dis play

Name / Description

00 01 10 11

V2, NPN V2, PNP I2, NPN I2, PNP

NO

OU

Range

Function

Set on RUN

The analog output 1 is programmable according to the following table:


G6.1 AO1=Frequency

Analog output 1 mode selection

0 to 15

0

Frequency

1

O/pCurr

2

O/pVolt

3

DCLinkV

4

Torque

5

O/pPower

6

Idse

7

Iqse

8

TargetFq

Proportional signal to the motor speed. For the maximum frequency defined in ‘G10.20 MsSpL’ MsSpL’ (M2.20), analogue value will be 10V/20mA. Proportional signal to the motor current. 10V/20mA are generated when the drive rated current is at 200%. Proportional signal to the motor voltage. For the voltage value defined in ‘G2.15 MTR VOLT’ VOLT’ (bA.15), analogue value will be 10V/20mA. Proportional signal to the bus DC voltage. The analogue output is 10V/20mA when the DC voltage is 410Vdc for 220Vac drives and 820Vdc for 400Vac drives. Proportional signal to the generated torque. Outputs 10V/20mA at 250% of motor rated torque. Proportional signal to the output power. 10V/20mA are generated operating 200% of the nominal power. Maximum current at 200% of no load current. Maximum current at 250% of rated torque current. Proportional signal to the target frequency set in the drive.

Note: continues on the next page.

48


YES

SD300 SERIES


Name / Description

Range

Function

Set on RUN

Note: comes from the previous page OPT. DESCRIPTION FUNCTION

OU.1

G6.2 AO1Ga=100.0% OU.2

Analog output 1 gain

-1000.0 to 1000.0%

9

RampFreq

10

SpeedFdb

12

PIDRefVal

13

PIDFdbVal

14

PIDO/p

15

Constant

These parameters allow adjusting the gain and offset level of the analogue output 1. If a current signal is desired, the set value will be 20%. For example, when the analogue output is configured as ‘Frequency’, the equation that governs the operation is:

1 =

G6.3 AO1Ofs=0.0% OU.3 G6.4 AO1Fil=5ms OU.4 G6.5 AO1Con=0.0% OU.5 G6.6 ANOUT1=0.0% OU.6

Analog output 1 offset

-100.0 to 100.0%

Proportional signal to the frequency which has executed the acceleration and deceleration functions and it can be different to the real output frequency. Real motor speed. PID reference value signal. Generates 6.6V working to the 100% of the reference. Signal proportional to the feedback in PID mode. Generates 6.6V at 100% of the reference value. Signal proportional to the PID controller output value. Generates 5V at 100% of the reference value. ‘G6.5 AO1Con’ (OU.5) AO1Con’ (OU.5) value.

 

YES

× × 1 +   1 1 YES

where Gain AO1 is set in parameter ‘G6.2’ and Offset AO1 is set in parameter ‘G6.3’ (OU.2 ‘G6.3’ (OU.2 and OU.3, respectively).

Analog output 1 filter

Filter for the analog output 1 value. Occasionally, the analog signal is slightly unstable. It can be improved 0 to 10000ms selecting another filter value. Note: The use of a filter can add a slight delay within the analog output

Analog output 1 constant setting

0.0 to 100.0%

Analog output 1 monitor

0.0 to 1000.0%

YES

Set a constant speed in the analog output 1, whenever it has been configured as ‘Constant’ in parameter ‘G6.1 AO1’ (OU.1). AO1’ (OU.1).

YES

Analog output 1 monitor. monitor.

YES

‘FAULT’’: This parameter allows setting when the relay output is set as 29 ‘FAULT

G6.30 OP FLT RLY=010 Relay fault output

000 to 111

OU.30

OPT

FUNCTION

001 010

Fault due to low voltage. Any faults other than low voltage. Automatic restart final failure. Final fault automatic restart. The relay will enable whenever all restarting attempts have been carried out (as set in ‘G9.9 Retry Num’, Num’, Pr.9) Pr.9) or time set in ‘G9.10 Retry Dly’ (Pr.10) Dly’ (Pr.10) has elapsed.

100

YES

Configures each relay and digital output according to the following table:

OPT DESCRIPTION FUNCTION .

G6.31 RLY1=Trip

Relay 1 control source

0

None

1

FDT-1

2

FDT-2

0 to 35 3

FDT-3

4

FDT-4

The output has no effect. Check when the output frequency has reached the user defined frequency. The relay will be enabled if the following equation is satisfied: F output > frequency – frequency – ([G9.2 ′FDTBnd′] / 2). The relay is active whenever the reference frequency is set to [G9.1 ‘FDTLvl’] and is [G9.2 ‘FDTBnd’] in bandwidth The relay will enable in the frequencies: [G9.1 ‘FDTLvl’] – ([G9.2 ‘FDTBnd’]/2) to [G9.1 ‘FDTLvl’] + ([G9.2 ‘FDTBnd’]/2). The relay will be active whenever the output frequency is greater than [G9.1 ‘FDTLvl’] remains closed until it decreases below [G9.1 ‘FDTLvl’] – ([G9.2 ‘FDTBnd’]/2).

YES

Note: continues on the next page.


49


POWER ELECTRONICS

Name / Description

Range

Function

Set on RUN

Note: comes from the previous page OPT. DESCRIPTION FUNCTION 5 6 7 8 9 10

11 12 13 14 15

16

OU.31 17

18

19 22 28 29 31 34 35 36 37 38 39

40

G6.33 DOP1=Run OU.33

50

Digital ouput 1 function

0 to 35

The relay will be active when the motor is in overload. The relay will be active in case a fault due to IOL overload protection occurs. The relay will be active in case of an underload UndrLoad warning. The relay will be active in case a fan fault ‘G9.79’ (Pr.79) is set as VentWarn occurs and parameter ‘G9.79’ (Pr.79) 1 ‘WARN’. Digital output will be enable when the motor is Stall blocked and overcharged. The relay will enable whenever the drive DC OverVolt bus voltage is higher than the protection voltage. The relay will be active whenever the drive DC LowVolt link voltage drops below the low voltage protection level. The relay will enable when the drive OverHeat temperature reaches a dangerous level. Lost Command Communications have been interrupted. The relay will enable with the start command. Run However, it will not enable during the DC brake. The relay will always enable whenever no start Stop command has been sent and no output voltage is present within the drive. The relay will enable when the reference frequency matches the output frequency, this Steady is, when the drive has reached the reference frequency. Outputs a signal while the motor is driven by the Inv. Line inverter line Outputs a signal while the motor is controlled from the communications network. See option Comm Line 16 “Exchange” of digital inputs configuration (parameters ‘G5.65‘G5.65-G5.71’, In.65-71). In.65-71). The relay will be active during a speed search Spd Srch operation. The relay will enable whenever the drive is Ready ready to start (without any warnings or trips). The relay will be enabled after the set time has Timer Out elapsed. Trip Relay is enabled when a fault trip occurs. Sets the configuration of the braking resistor DBWarn%ED (%ED: Duty cycle). Comparat Sends a signal using the value of the dig.input. BRCtrl Used to control the brake opening. The relay will enable CAP exchange options CAP Exch. according to the setting of ‘G9.62’ (Pr.62). The relay will enable FAN exchange according FAN Exch. to the setting of ‘G9.87’ (Pr.87). Fire Mode Fire mode configuration. Sends pulse signals to external devices to provide a single output value of output TO frequency, output current, output voltage or DC voltage. The relay will be active when the energy buffering operation has started because of low KEB Op. voltage of the drive DC power section due to a power failure on the input power. OverLoad

See ‘G6.31 ‘G6.31’’ (OU.31).


YES

SD300 SERIES


Name / Description

Range

Set on RUN

Function Multi-function output monitor.

G6.41 DO Sts=00

OU.50 G6.51 TRLOF=0.00s OU.51

0.00 to 100.00s

The user can specify a delay in the digital output 1 and relays disconnection. If during the connection delay time the activation condition disappears, the relay will not be enabled.

YES

Digital output disconnection delay

0.00 to 100.00s

The user can specify a delay within the digital output 1 and relays disconnection. If during the disconnection delay time, the disable condition disappears, the relay will not be disabled.

YES

0 to 1

OU.52

G6.54 TOfDl=0.00s OU.54 G6.55 TiOnD=0.00s OU.55 G6.56 TOfDl=0.00s OU.56 G6.57 FDTLv=30.00Hz OU.57 G6.58 FDTBd=10.00Hz OU.58

YES

Defines the type of contact following this order: Digital Output 1, Relay 2 and Relay 1, from left to right according to the bit assignment. NC/NO Relays logic

OU.53

No ouputs enabled Output 1 enabled Output 1 enabled Output 1 and 2 enabled

Digital output connection delay

G6.52 INV YES/NC=00

G6.53 TOnDl=0.00s

FUNCTION

00 01 10 11

00 to 11

OU.41 G6.50 TRLON=0.00s

OPTION

Digital ouputs status

Digital output connection delay on fault

0.00 to 100.00s

Digital output disconnection delay on fault

0.00 to 100.00s

Digital output connection delay

0.00 to 100.00s

Digital output disconnection delay

0.00 to 100.00s

YES

OPTION

FUNCTION

0 1

Contact normally open (NO) Contact normally closed (NC)

If a fault trip occurs, trip relay or multi-function output operates after the time delay set in ‘G6.53’ (OU.3). ‘G6.53’ (OU.3). Terminal is off with the input initialized a fter the time delay set in ‘G6.54’ (OU.54). ‘G6.54’ (OU.54).

Input a signal (On) to the timer terminal to operate a timer output (Timer out) after the time set at ‘G6.55’ ‘G6.55’ (OU.55) has passed. When the multifunction input terminal is off, multi-function output or relay turns off after the time set set at ‘G6.56’ (OU.56). ‘G6.56’ (OU.56). See also digital inputs option 38 ‘Timer In’ In’.

YES

YES

YES

YES

Relay FDT level

0.00 to Value of the output frequency for digital outputs FDT options. [G1.20]/dr.20

YES

Relay FDT band

0.00 to Detection frequency band for digital outputs FDT options. [G1.20]/dr.20

YES

Pulse output setting.

OPT. DESCRIPTION OPT. DESCRIPTION G6.61 TOM=Frequency TOM=Frequency Pulse output mode

0 to 15

OU.61

G6.62 TOGa=100.0% OU.62 G6.63 TOOfs=0.0% OU.63 G6.64 TOFil=5ms OU.64 G6.65 TOCon=0.0% OU.65 G6.66 TO=0.0% OU.66

0 1 2 3 4 5 6 7

Frequency O/pCurr O/pVolt DCLinkV Torque O/pPower Idse Iqse

8 9 10 12 13 14 15

TargetFq RampFreq SpeedFdb PIDRefVal PIDFdbVal PIDO/p Constant

Pulse output gain

-1000.0 to Adjusts output value and and offset. If frequency frequency is selected as an output, output, it 1000.0% will operate according to the following equation:

Pulse output offset

-100.0 to 100.0%

0 =

 

×   ×  

Pulse output filter

0 to 10000ms Sets filter time constant on analog output.

Pulse output constant setting

0.0 to 100.0%

Pulse output monitor

0.0 to 1000.0%

YES

YES YES

YES

If analog output item is set to constant, the analog pulse output is dependent on the set parameter values.

YES

Monitors analog output value. Displays the maximum output pulse (32kHz) as a percentage (%) of the standard.

YES


51

SD300 SERIES

POWER ELECTRONICS

5.8. Group 7 – G7: Communication Bus

CM

NOTE: Parameters CM.6 to CM.96 are only available in the integrated display. Removable display Integrated Integrated dis play G7.1 Slave Addr=1 CM.1

Name / Description Slave address

Range

Function

Set on RUN

1 to 250

Drive identifier to communicate within the network. When communicating with several equipments, each one should have a different address.

YES

Select the communication protocol:

G7.2 Prot=Modbus Prot=Modbus [27]

CM.2 [27]

RS-485 communication protocol


Modbus PE BUS 485 0 2

G7.3 BaudR=9600bps [27] Baud rate

CM.3 [27]

1200 bps 2400 bps 4800 bps 9600 bps 19200 bps 38400 bps 56 Kbps 112 Kbps

Modbus PE BUS 485

Communication protocol compatible ith Modbus-RTU Communication protocol used to communicate drives.

Sets the Modbus communications transfer rate, which must match with the bus communication master within the drive.

YES

YES

Select the communication frame structure and defines the data length, parity confirmation method and the number of stop bits:

G7.4 Mode=D8/PN/S1 [27] Communication frame structure

OPT. DESCRIPTION FUNCTION 0 to 3

CM.4 [27]

G7.5 RespDly=5ms [27] Response delay

CM.5 [27]

0 1 2 3

D8/PN/S1 D8/PN/S2 D8/PE/S1 D8/PO/S1

8-bit data / no parity check / 1 stop bit 8-bit data / no parity check / 2 stop bits 8-bit data / even parity / 1 stop bit 8-bit data / odd parity / 1 stop bit

YES

The MODBUS-RTU MODBUS-RTU communication plays the role of the slave device. The slave will reply after the time period set in this parameter. This allows the 0 to 100.0 ms master device attending the communications within a system where the master can not manage a quick slave answer.

YES

Show the software version of the optional communications card, if there is any connected.

YES

Identifier of the communications card connected to the drive.

YES

CM.6=0.00 [28]

Communication option S/W version

CM.7=1 [28]

Communication option ID

0 to 255

CM.8=12Mbps [28]

Card baud rate

-

Communications card baud rate.

YES

CM.9 [28]

Communication option LED status

-

This parameter function depends on the communications card.

YES

CM.30=3

Output parameters number

0 to 8

Configure a group of addresses to read several output parameters at once. The user must set the number of parameters and then configure them in CM.31-38.

YES

-

CM.31=40011[29]

YES

CM.32=40012 [29]

YES

CM.33=40013 [29] CM.34=40001 [29] CM.35=40001 [29] CM.36=40001 [29]

Output communication addresses 1 to 8

0 to 65535

Define the output parameter group for data transmission, so that addresses configured in CM.31-38 ca be used to send several parameters at once in the same communications frame.

YES YES YES

The size of the group is set in CM.30

YES

CM.37=40001 [29]

YES

CM.38=40001 [29]

YES

[27] Will not be displayed when P2P and MultiKD is s et. [28] Will only be displayed when a communications optional card is installed. [29] Only parameters corresponding to the value set in CM.30 will be shown (E.g., if CM.30 = 3, parameters CM.31, CM.32 and CM.33 will be shown).

52


SD300 SERIES

POWER ELECTRONICS Removable display Integrated Integrated dis play CM.50=2 CM.51=40006 [30] CM.52=40007 [30] CM.53=40001 [30] CM.54=40001 [30] CM.55=40001 [30]

Name / Description Number of input parameters

Range

Function

Set on RUN

0 to 8

Configure a group of addresses to read several input parameters at once. The user must set the number of parameters and then configure them in CM.31-38.

YES NO NO

Input communication addresses 1 to 8

0 to 65535

CM.56=40001 [30]

Define the input parameter group for data transmission, so that addresses configured in CM.51-58 ca be used to send several parameters at once in the same communications frame.

NO

The size of the group is set in CM.50

NO

NO NO

CM.57=40001 [30]

NO

CM.58=40001 [30]

NO

CM.68=NO

Field bus data swap

NO YES

CM.70=Nada CM.71=Nada CM.72=Nada CM.73=Nada CM.74=Nada CM.75=Nada CM.76=Nada

Communication multifunction input 1 to 7

0 to 54

CM.77=Nada

Swap the most significant byte with the least significant byte in order to adapt to the PLC configuration.

NO

Multi function inputs can be controlled by using the communication address 40902. Configure parameters CM.70-77 and then set the corresponding bit in address 40803 for them to operate. This inputs operate independently from those set in G5.65-71 (In.65-71).

YES

OPC. DESCRIPCIÓN OPC. DESCRIPCIÓN

YES

0 None 20 POTCLEAR 1 START(+) 21 AnalogHLD 2 START(-) 22 I-Term I -Term Clear 3 RESET 23 PIDOPLoop 4 EXTTRIP 24 PGain2 5 DISSTART 25 XCELStop 6 INCH1 26 2ndMotor 7 SPEED-L 34 Pre-Excit 8 SPEED-M 38 TimerIN 9 SPEED-H 40 disAuxRef. disAuxRef . 11 XCEL-L 46 INCH(+) 12 XCEL-M 47 INCH(-) 13 RUNEnable 49 XCEL-H 14 3-WIRE 50 PLC 15 CTR/REF2 51 FireMode 16 Exchange 52 KEB1Sel 17 UP 54 TI 18 DOWN Note: Refer to section 5.6, parameters G5.65-71 (In.65-71), to consult detailed information about each option.

YES

YES YES

YES YES

YES

CM.86=0

Communication multifunction input monitoring

Monitor inputs configured in CM.70-77.

NO

CM.90= PE BUS 485

Data frame comm. PE BUS 485 Monitor data frames status through the communication bus or the monitor Rem. display removable display

YES

CM.91=0

Received data frames counter

0 to 65535

Count the number frames that have been correctly received.

YES

CM.92=0

Frames with error counter

0 to 65535

Count the number frames that have been received with errors.

YES

CM.93=0

NAK frames counter

0 to 65535

Count the number frames that have been received with timeout.

YES

This parameter enables sendind the current drive da ta configuration to the communications card.

YES

G7.94 ComUpdate=N [31] Communications update CM.94=NO [31]

-

NO YES

[30] Only parameters corresponding to the value set in CM.50 will be shown (E.g., if CM.50 = 2, parameters CM.51 and CM.52 will be shown). [31] Solo se muestra si se ha conectado una tarjeta de c omunicaciones opcional.


53

SD300 SERIES

POWER ELECTRONICS

Removable display Integrated Integrated dis play

Name / Description

Range

Function

Set on RUN

P2P communication allows sharing input devices between different drives. To enable it, RS485 communication must be active.

P2P communication selection

CM.95=Deshabilitar todas

This parameter allows defining which devices will be master and which slave in the P2P communication. 0a3

NO

OPT. FUNCTION 0 1 2 3

Disable All P2P Master P2P Slave M-KPD Ready

When multi function outputs are used, a drive configured as P2P slave can choose whether to use its own output or the drive’s output. Digital output selection

CM.96=NO [32]

5.9. Group 8 – G8: PID Removable display Integrated Integrated dis play G8.1 ApMod=Proc PID

Name / Description Application function selection

AP.1

G8.2 UsSeqEn=N Enable PLC mode AP.2 G8.16 PIDOut=+0.0% [33] PID output AP.16 [33] G8.17 PIDRef=+50.00% [33]

000 a 111

0: None 2: Proc PID YES NO -327.68 to 327.68% -327.68 to 327.68%

PID feedback

-327.68 to 327.68%

G8.19 PIDLo=+50.00% [33] PID local

AP.19 [33]

Analog output Multi function relay Multi funtion output

Range

[28]

AP.18 [33]

001 010 100

YES

AP

PID reference

AP.17 G8.18 PIDFdb=+0.00% [33]

OPT. FUNCTION

-100.00 to 100.00%

Function

Set on RUN

Application function selection. selection. NO Set this parameter to ‘2’ (Proc ( Proc PID) to select functions for the process PID. Display the parameter groups related to a user sequence.

NO

Display the existing output value of the PID controller. The unit, gain, and scale set at ‘G8.42‘G8.42-44’ 44’ (AP.42-44) (AP.42-44) are applied.

YES

Display the existing reference value set for the PID controller. The unit, gain, and scale set at ‘G8.42‘G8.42 -44’ (AP.42-44) 44’ (AP.42-44) are applied.

YES

Display the input value of the PID controller that is included in the latest feedback. The unit, gain, and scale set at ‘G8.42‘G8.42-44’ 44’ (AP.42-44) are applied.

YES

When ‘G8.20’ ‘G8.20’ (AP.20) is set to 0 (MREF), the reference value can be entered. If the reference source is set to any other value, the setting values for ‘G8.19’ (AP.19) ‘G8.19’ (AP.19) are voided.

YES

Select the source to introduce the PID regulator set point:

OPT DESCRIPTION FUNCTION G8.20 SELREF=MREF SELREF=MREF

[33]

Select PID regulator source

AP.20

[33]

0 to 8

0

MREF

1

V1

3

V2

4

I2

5

MODBUS

7

COMMS

8 11

PLC PULSE

PID set point introduced from keypad. . PID set point introduced by the voltage analog input 1. PID set point introduced by the voltage analog input 2. PID set point introduced by the current analog input 2. PID set point introduced through the Modbus communication protocol. PID set point introduced through any of the optional communication boards. PID set point introduced through PLC. Reference signal through the pulse input.

Note: In case an unavailable option is selected, the parameter will return to its previous value.

[32] Displayed when ‘G8.1’ (AP.1) is set to 2 (Proc PID). [33] Displayed when ‘G8.1’ (AP.1 in integrated display) is set to Proc Pid.

54


NO

SD300 SERIES


Name / Description

Range

Function

Set on RUN

Select the source through which the feedback signal will be introduced to close the control loop.


G8.21 SELFBK=V1 [33]

Select feedback signal source

0 to 10

AP.21 [33]

0 2 3

V1 V2 I2

4

MODBUS

6

COMMS

7

PLC

10

PULSE

Feedback signal by voltage analog input 1. Feedback signal by voltage analog input 2. Feedback signal by current analog input 2. Feedback signal through Modbus communications integrated in the drive. Feedback signal through any optional communication boards. Feedback signal through the equipment’s PLC. Feedback signal through the pulse input.

NO

Note: In case an unavailable option is selected, the parameter will return to its previous value. G8.22 GANKp=+50.0% [33] PID controller proportional gain AP.22 [33] 23 INTEGRL=10.0ms INTEGRL=10.0ms [33] AP.23 [33] G8.24 DIFFE=0ms [33] AP.24 [33] G8.25 GAINF=+0.0% [33] AP.25 [33] G8.26 PGaSca=100.0% [33]

AP.26 [33]

PID controller integration time

0.0 to 1000.0%

0 to 200.0s

YES

Set the regulator integration time. In case greater precision is needed, increase this value.

YES

Note: Increasing this value may slow down the system. PID controller differential time

0.0 to 1000ms

Set the regulator differential time. Whenever a greater response is needed, this value can be increased.

YES

Note: Increasing too much this value can cause a precision loss. PID output fine adjustment

0.0 to 100.0%

Apply a fine adjustment at the PID output. Use this p arameter when an adjustment for the proportional constant below 0.1% is required.

YES

Proportional gain scale

This parameter, along with ‘G8.22’ (AP.22) ‘G8.22’ (AP.22) allow setting output ratio for ‘G8.22’ (AP.22) is set to 50%, 0.0 to 100.0% errors between reference and feedback. If ‘G8.22’ (AP.22) then 50% of the error is output. For ratios below 0.1% use ‘G8.26’ (AP.26). ‘G8.26’ (AP.26).

NO

PID Filter

Used when the output of the PID controller changes too fast or the entire system is unstable, due to severe oscillation. In general, a lower value 0 to 1000ms (default value=0) is used to speed up response time, but in some cases a higher value increases stability. The higher the value, the more stable the PID controller output is, but the slower the response time.

YES

G8.27 PIDFl=0ms [33] AP.27 [33]

Set PID Mode.

G8.28 PIDMd=Process PIDMd=Process [33] PID Mode

AP.28 [33] G8.29 MxSL=+60.00Hz [33] AP.29 [33] G8.30 MnSL=-60.00Hz MnSL=-60.00Hz [33] AP.30 [33]

Set the value of the proportional gain controller. This value should be increased whenever a greater control response is needed. Note: Increasing too much this value can cause a greater system instability.

Upper limit PID output Lower limit PID output

Process Normal

[G8.30] to 300.00Hz

OPT. FUNCTION 0 1

NO

Process Normal

Set the PID output upper limit.

YES

-300.00Hz to Set the PID output lower limit. [G8.29]

YES

Define whether to invert the PID output or not.

OPTION

G8.31 INVERT PID=N [33]

Invert PID

AP.31 [33]

0: YES 1: NO

YES

NO

FUNCTION The PID regulator answers in normal mode. Therefore, when the feedback value exceeds the reference signal, it will decrease its speed. However, if the feedback is lower than the reference signal value, the speed will be increased. The PID regulator answers in inverse mode. Therefore, when the feedback exceeds the reference signal, speed will be increased. However, when the feedback value is lower than the reference signal, the speed will be decreased.

NO


55


POWER ELECTRONICS

Name / Description

Range

Set on RUN

Function

G8.32 OutSc=+100.00% [33]

PID output scale

AP.32

[33]

NO

PrePID end reference

0.0 to 100.0% Set feedback level in PID mode.

NO

AP.34

AP.37 G8.38 SlpSp=0.00Hz AP.38 G8.39 LPPon=+35% AP.39

NO

PrePID reference [33]

G8.37 LPTSlp=60.0s LPTSlp=60.0s

Set the PID regulator output magnitude.

Set PID controller motion frequency. Pre-PID function allows configuring the drive to start at a fixed speed 0.00 to (‘G8.34’, AP.34) until PID feedback is above the set level (‘G8.35’, AP.35). [G1.20]/dr.20 If at a determined moment (‘G8.36’, AP.36) the drive does not reach the feedback level set in AP.35, fault F23 ‘Pipe Fill Flt’ will be triggered.

G8.34 PPIDR=0.00Hz [33]

G8.35 PPIDE=0.0% AP.35 G8.36 PPIDTim=600s AP.36

0.1 to 1000.0%

PrePID delay

0 to 9999s

Set the PrePID time before triggering a fault F23 ‘Pipe Fill Flt’. Flt’.

YES

Sleep mode activation delay

Set the delay time before enabling the sleep mode. If the drive operates at 0.0 to 999.9s a speed value under the value of ‘G8.38’ G8.38’ (AP.38), (AP.38), it will stop running and enter in sleep mode.

YES

Sleep mode activation speed

Set the speed under which if a time period greater than the one defined in 0.00Hz to parameter ‘G8.37’ G8.37’ (AP.37), (AP.37), the drive will stop operating and enter in sleep [G1.20]/dr.20 mode.

YES

Awakening level

0 to 100%

Set the resuming PID PID control level after after a suspension period period (sleep mode).

YES

Set PID wake-up mode, according to the following table:

OPT

G8.40 WkUPID=Below PID WakeUp mode

Below Above Beyond

DESCRIPTION

0

Below

1

Above

2

Beyond

FUNCTION The PID operation starts when the frequence is lower than the value set in ‘G8.39’ G8.39’ (AP.39). (AP.39). The PID operation starts when the frequence is higher than the value set in ‘G8.39’ G8.39’ (AP.39). The PID operation starts when the difference between the reference value and the feedback variable is greater than the value set in G8.39 (AP.39).

AP.40

YES

Set PID controller unit, according to the following table:

OPT DESCRIPTION

G8.42 PIDUn=%

PID unit

0 to 12

AP.42

0 1 2 3 4 5 6

OPT DESCRIPTION

% Bar mBar Pa kPa Hz rpm

7 8 9 10 11 12

V I kW HP °C ºF

YES

Note: this parameter can only be adjusted in the removable LCD display. G8.43 PIDuG=100.00% AP.43

PID unit gain

0.00 to 300.00%

Allows setting the PID unit gain.

YES

Adjusts the size to fit the unit selected at ‘G8.21’ (AP.21). ‘G8.21’ (AP.21).

G8.44 PIDUnSc=x1

OPT DESCRIPTION PID scale unit

0 to 4

AP.44 G8.45 GaKp2=100.0% AP.45

56

0 1 2 3 4

x 100 x 10 x1 x 0.1 x 0.01

Set the value of the proportional gain controller 2. This value should be Proportional gain 2 0.0 to 100.0% increased whenever a greater control response is needed. Note: Increasing too much this value can cause a greater system instability.


YES

NO

SD300 SERIES

POWER ELECTRONICS The following figure shows the PID operation sleep mode setting details:

5.10. Group 9 – G9: Protections Removable display Integrated Integrated di splay

Name / Description

Pr

Range

Function

Set on RUN

Select the load type.

G9.4 Load Duty=Hevy Load duty type

NRML HEVY


NRML

1

HEVY

Pr.4

Selects the normal load type (variable torque) for applications such as fans or pumps. Selects the heavy load type (constant torque) for applications such as elevators and cranes.

NO

Select phase loss protection type.


G9.5 LSS PH=NONE

0 1

Phase loss type

0 to 4

Pr.5

G9.6 Ripple V=15V Pr.6 G9.7 FlDecT=3.0s Pr.7 G9.8 Str Aft Rst=N Pr.8 G9.9 Retry Num=0 Pr.9

Ripple voltage Fault deceleration time Start after restart Retry attempts number

G9.10 RetryDly=1.0s 34 Retry delay

Pr.10 [34]

1 to 100V

NONE OUTPUT

Phase loss protection disabled. Output phase loss protection enabled. Input phase loss protection enabled. For its 2 INPUT correct operation, the user should set the parameter ‘G9.6’ (Pr.6). ‘G9.6’ (Pr.6). Input and output phase loss protection 3 ALL enabled. For its correct operation, set the parameter ‘G9.6’ (Pr.6). ‘G9.6’ (Pr.6). Caution: Users should ensure that disabling this protection does not compromise the operation of the installation and/or equipment. Set the DC Bus ripple voltage that must be exceeded to get a phase loss phase input input fault when ‘G9.5’ (Pr.5) ‘G9.5’ (Pr.5) is set as “INPUT” or “ALL”. This value is set following customer’s requirements.

0.0 to 600.0s Deceleration time at fault trip. Parameters ‘G9.9’ and ‘G9.10’ (Pr.9 ‘G9.10’ (Pr.9 and Pr.10) only operate when ‘G9.8 ‘G9.8’ (Pr.8) is set to 1(Yes). ‘G9.9’ (Pr.9). The number of attempts to try the auto restart is set at ‘G9.9’ (Pr.9). If a fault trip occurs during operation, the drive automatically restarts after 0 to 10 the set time programmed at ‘G9.10’ (Pr.10). ‘G9.10’ (Pr.10). At each restart, the drive counts the number of tries and subtracts it from the number set at ‘G9.9 ‘G9.9’ (Pr.9) until the retry number count reaches 0. After an auto restart, if a fault trip does not occur within 60 secs, it will increase 0.0 to 60.0s the restart count number. The maximum count number is limited by ‘G9.10’ (Pr.10). N Y

NO

NO

YES

YES

YES

YES

[34] Displayed when ‘G9.9’ (PR.9 in integrated display) is higher than zero.


57

SD300 SERIES Removable display Integrated Integrated di splay

POWER ELECTRONICS

Name / Description

Range

Function

Set on RUN

Set the action to be taken if the drive loses a speed reference:

OPT. DESCRIPTION FUNCTION G9.12 RIRLs=None

Response in case of a speed reference loss

0 to 5

0

None

1

Free-Run

2

Dec

3

Hold Input

4

Hold Output

5

Lost Preset

Pr.12

Protection is disabled. The drive cuts the output voltage and allows the motor free run. The motor decelerates and then stops at the time set at ‘G9.7’. The drive will keep operating to the input value, mean value obtained from the last 10 seconds until the moment the reference lo s has been detected. The drive will keep operating to the input value, mean value obtained from the last 10 seconds until the moment the reference loss has been detected. The drive operates to the frequency defined in parameter ‘G9.14’ (Pr.14). ‘G9.14’ (Pr.14).

YES

Caution: Users should ensure that disabling this protection does not compromise the operation of the equipment.

G9.13 RfLsDl=1.0s [35] Pr.13 [35] G9.14 RfLRf=0.00Hz [35] Pr.14 [35] G9.15 AILL=Half [35] Pr.15 [35]

Lost reference delay

0.1 to 120.0s

Delay time setting after which the speed reference loss protection will enable.

YES

Reference for lost reference

In order to set the frequency value at which the drive will operate in case a [G1.19] to speed reference loss occurs. Therefore, the parameter ‘G9.12 RIRLs’ [G1.20]/dr.20 (Pr.12) must be set to ‘LostPreset’.

YES

AI Lost Level

Half Below

G9.17 OlWarnSel=YES OlWarnSel=YES Overload warning select

YES NO

Pr.17 G9.18 OLWrnL=+150% OLWrnL=+150% Pr.18 G9.19 OLWrnT=10.0s OLWrnT=10.0s Pr.19

Overload warning level Overload warning time

Analog input loss decision decision level.

YES

If the overload reaches the warning level, the terminal block multi-function output terminal and relay are used to output a warning signal. If 1 (Yes) is selected, it will operate. If 0 (No) is selected, it will not operate.


YES

Overload warning disabled.

1

NO

Overload warning enabled.

The overload warning is a combination of the parameters ‘G9.18’, ‘G9.19’ and ‘G9.20’ (Pr.18-20). ‘G9.20’ (Pr.18-20). The drive will enable some of the digital outputs configured as ‘OverLoad’ whenever whenever the current flowing within the motor is greater than the value defined in parameter ‘G9.18 OLWrnL’ (Pr.18) OLWrnL’ (Pr.18) during 0.0 to 30.0s the time established in parameter ‘G9.19 OLWrnT’ (Pr.19). OLWrnT’ (Pr.19). 30 to 200%

YES

YES YES

The drive will take the following actions in case an overload fault occurs:

G9.20 OLTS=Freerun

OPT. DESCRIPTION FUNCTION 0 Overload trip select

0 to 2

1 2

Pr.20

G9.21 OLLevel=180% Pr.21 G9.22 OLTrpT=60.0s OLTrpT=60.0s Pr.22

Overload level Overload trip time

Protection is disabled. The drive’ drive’s output is cut, having as a FreeRun consequence the motor free run. A deceleration until stop is produced in the Dec time defined in parameter ‘G9.7’ Pr.7). ‘G9.7’ Pr.7). Caution: Users should ensure that disabling this protection does not compromise the operation of the i nstallation and/or equipment.

The overload warning protection is a combination of the parameters ‘G9.20’, ‘G9.21’ and ‘G9.22’ (Pr20-22). ‘G9.22’ (Pr20-22). The drive will carry out the action selected in parameter ‘G9.20 OLTS’ (Pr.20) OLTS’ (Pr.20) whenever the current flow within the motor is greater than the pa rameter ‘G9.21 OLLevel’ (Pr.21) OLLevel’ (Pr.21) value during the time 0.0 to 60.0s defined in parameter ‘G9.22 OLTrpT’ OLTrpT ’ (Pr.22). 30 to 200%

G9.25 EnableUL=YES EnableUL=YES Enable underload

None

YES NO

Pr.25

YES YES

Sets the underload warning options. Set to 1(Yes) and set the multi-function output terminals (at ‘G6.31 ‘G6.31’’ and ‘G6.33 ‘G6.33’’; OU.31 and OU.33) to ‘Underload’ Underload’. The warning signals are output when an underload condition arises.


YES

Underload warning disabled.

1

NO

Underload warning enabled.

[35] Displayed when ‘G9.12’ is not set to None.

58

YES


YES

SD300 SERIES

POWER ELECTRONICS Removable display Integrated Integrated di splay G9.26 ULWnDl=10.0s Pr.26

Name / Description

Range

Function

Underload warning Set delay time when enabling the underload warning. The drive will wait this 0.0 to 600.0s delay time before enabling the warning.

Set on RUN YES

Set the underload fault trip protection.

G9.27 ULFM=None Underload fault mode

Pr.27 G9.28 ULFlDl=30.0 Pr.28 G9.29 UlMnL=+30% Pr.29

Underload fault delay

None Free-Run Dec


None

1

Free-Run

2

Dec

•

G9.30 ULMxL=+30% Pr.30

Underload maximum level

YES

Normal Duty: At ‘G9.29’ ‘G9.29’ (Pr.29), underload rate is decided based on twice the operation frequency of the motor rated slip speed (‘G8.12’). At ‘G9.30’ (Pr.30), ‘G9.30’ (Pr.30), the underload rate is determined based on the frequency set at ‘G4.18’ (Cn.18). ‘G4.18’ (Cn.18). Upper and lower limits are based on the drive rated current.

10 to 100%

YES

Heavy Duty: ‘G9.29’ (Pr.29) ‘G9.29’ (Pr.29) is not supported. At ‘G9.30’ (Pr.30), ‘G9.30’ (Pr.30), underload level is decided based on the motor rated current.

10 to 100%

YES

The motor decelerates and stops.

0.0 to 600.0s Set the delay time before triggering the underload fault. •

Underload minimum level

Protection is disabled. Output is blocked in an underload fault trip situation.

YES

The drive will carry out one of the following actions whenever a fault is present due to the fact that no motor has been connected to the drives output terminal:

G9.31 NoMD=None Action in case no motor is detected

None Free-Run Dec

Pr.31


None

1

Free-Run

2

Dec

Protection is disabled. The drive’ drive’s output is cut, having as a consequence the motor free run. The motor decelerates and stops.

YES

Caution: Users should ensure that disabling this protection does not compromise the operation of the i nstallation and/or equipment.

G9.32 NoMtrLv=+5% Pr.32 G9.33 NoMtrDl=3.0s Pr.33

No motor fault level No motor fault delay

The fault protection if no motor is detected is a combination of parameters ‘G9.31’, ‘G9.32’ and ‘G9.33’ (Pr.31-33). ‘G9.33’ (Pr.31-33). The drive will carry out the action set in parameter ‘G9.31 NoMD’ whenever wh enever the current flowing within the motor does not exceed the value defined in parameter ‘G9.32 NoMtrLvl’ 0.1 to 10.0s NoMtrDl’ (Pr.33). (Pr.32) during the time defined in parameter ‘G9.33 NoMtrDl’ (Pr.33). 1 to 100%

YES YES

The drive will carry out one of the following actions in case of a motor thermo-electronic fault:

G9.40 ThMM=None Action in case of thermo-electronic fault

None Free-Run Dec

Pr.40


None

1

Free-Run

2

Dec

The ETH function is not activated. The drive output is blocked. The motor coasts to a halt (free-run). The drive decelerates the motor until it stops.

YES

Select the drive mode of the cooling fan attached to the motor.


G9.41 MTCOOL=SELF MTCOOL=SELF Motor cooling mode at zero speed

SELF FORCED

Pr.41

1

G9.43 ETHcont=+120% Pr.43

SELF

FORCED

Additional power is supplied to operate the cooling fan. This provides extended operation at low speeds. Motors designed for drives typically have this design.

YES

Overcurrent level during 1min

Set the current level which flows continuously during one minute in % referenced to the motor nominal current. The motor nominal current is set 50 to 200% in parameter ‘G2.13 MTRCUR’ (bA.13). MTRCUR’ (bA.13). Whenever this limit is over passed, the thermo-electronic protection will be enabled, and the action defined in parameter ‘G9.40 ThMM’ (Pr.40) ThMM’ (Pr.40) will be executed.

YES

Continuous overcurrent level

50 to 200%

Set the overcurrent level under which the drive is able to work without enabling the thermo-electronic protection.

YES

G9.42 ETH1min=150% Pr.42

0

As the cooling fan is connected to the motor axis, the cooling effect varies based on motor speed. Most universal induction motors have this design.


59

SD300 SERIES Removable display Integrated Integrated di splay

POWER ELECTRONICS

Name / Description

Range

Function

Set on RUN

Define trip mode in free run.

G9.45 BSMod=FreeRun BSMod=FreeRun Free run trip mode

Pr.45

FreeRun Dec


FreeRun

1

Dec

The drive cuts the output voltage and allows the motor free run. The motor decelerates and then stops.

NO

Stall prevention can be configured for acceleration, deceleration, or while operating a motor at constant speed.

G9.50 StallPR=00

OPT DESCRIPTION FUNCTION Stall prevention

00 to 11

00 01

Pr.50

10 11

G9.51 StFr1=60Hz Pr.51 G9.52 StlLev1=180% Pr.52 G9.53 StFr2=60Hz Pr.53 G9.54 StlLev2=180% Pr.54 G9.55 StFr3=60Hz Pr.55 G9.56 StlLev3=180% Pr.56 G9.57 StFr4=60Hz Pr.57 G9.58 StlLev4=180% Pr.58 G9.59 FB Kp=0% Pr.59 G9.60 CAPDgLV=0% Pr.60

Accelerating

Stall protection during during acceleration.

At constant speed At deceleration FluxBraking

Stall protection while operating at a constant speed. Stall protection during deceleration. Flux braking during deceleration.

NO

Speed for stall protection 1

[G1.19] to [G9.53] Hz

YES

Level for stall protection 1

30 to 250%

NO


[G5.51] to [G9.55] Hz

YES

Level for stall protection 2 Speed for stall protection 3 Level for stall protection 3

Additional stall protection levels can be configured configured for different frequencies, frequencies, based on the load type. 30 to 250% The stall level can be set above the base frequency. The lower and upper limits are set using numbers that correspond in ascending order. For [G5.53] to example, the range for Stall Frequency 2 (Stall Freq 2) becomes the lower [G9.57] Hz limit for Stall Frequency 1 (Stall Freq 1) and the upper limit for Stall Frequency 3 (Stall Freq 3). 30 to 250%

NO YES

NO


[G5.55] to [G1.20]/dr.20 Hz

YES


30 to 250%

NO

Flux braking gain

0 to 150[%] Set flux braking gain.

YES

CAP diagnosis level

10 to 100[%] Set capacitors diagnosis percentage.

YES

This parameter allows performing a capacitor diagnosis.

G9.61 CAPDg=+0%[36]

OPT DESCRIPTION 0 Nonde 1 RefDiag (*) 2 PreDiag 3 InitDiag (*) Note: This option is used to set a capacitance reference. It is recommended to use it when the drive is operated for the first time.

Capacitor diagnosis mode

0 to 3

CAP exchange warning level

0.0 to 95.0%

Sets the capacitor exchange warning level. The warning “ECAP” will be displayed when this value is reached.

NO

Capacitance reference

0.0 to 100.0%

This parameter shows the capacitance reference measured in G9.61. This value must be equal to 100.0% when the drive is operated for the first time.

YES

Pr.66

Braking resistor configuration

0 to 30%

Set braking resistor configuration (%ED: Duty cycle). Braking resistor configuration sets the rate at which the braking resistor operates for one operation cycle.

YES

G9.73 SpdDev=N Pr.73

Speed deviation fault

N Y

Fault due to speed deviation.

YES

Pr.61 [36] G9.62 CAPExLv=0% [36] Pr.62 [36] G9.63 CAPDgL=0.0% [36] Pr.63 [36] G9.66 DBWarnED=+0%

[36] These parameters are displayed when ‘G9.60’ is set to more than 0.

60


NO

SD300 SERIES

POWER ELECTRONICS Removable display Integrated Integrated di splay G9.74 SpdDevLv=50 37 Pr.74 [37] G9.75 SpdDevTi=60 [37] Pr.75 [37]

Name / Description

Range

Set on RUN

Speed deviation band

1 to 20

Speed deviation band.

YES

Speed deviation time

1 to 120

Speed deviation time.

YES

Select the action to carry out in case a fault within the cooling fan is detected:

G9.79 FANTrip=Warn FANTrip=Warn Action in case of fan trip

Trip Warn

Pr.79


Trip

1

Warn

The drive generates a Fan-trip. The drive will enable the relay configured as ‘VentWarn’.

YES

Enable an optional card fault (if any is used). Set the operation mode for the drive when a communication error occurs between the option card and the drive, or when the optional card is detached during operation.

G9.80 TrpMd=FreeRun TrpMd=FreeRun Optional card trip mode

0 to 2

Pr.80

G9.81 LVT Dly=0.0s Pr.81 G9.82 LV2 On=YES Pr.82 G9.86 FanTi=0% Pr.86 G9.87 FanELv=90.0% Pr.87 G9.88 FanTiRst=N 38 Pr.88 [38]

Function

Low voltage trip delay Enable low voltage trip


None

1

FreeRun

2

Dec

No operation. The drive output is blocked and fault trip information is shown on the display. Motor decelerates to the value set at ‘G9.7’ (Pr.7).

0.0 to 60.0s It allows setting a delay for low voltage fault. YES NO

When this parameter is set to NO and a low voltage situation occurs, the drive trips.

Fan use percentage

0.0 to 100.0% This parameter allows showing the accumulated percent of fan usage.

Fan exchange warning level

0.0 to 100.0%

Fan time reset

YES NO

YES

NO

NO YES

Set fan exchange warning level. When the value is reached, the EFAN warning appears.

YES

Sets the fan reset time.

NO

Shows the status of capacitor fans.

G9.89 CAP FAN St=0 CAP fan status

00 to 11

Pr.89

OPT

DESCRIPTION FUNCTION

00

None

01 10

CAP warning FAN warning

There are no warnings neither in the capacitors nor in fans. There is a warning in the capacitor. There is a warning in the fan.

YES

[37] Displayed when ‘G9.73’ is set to YES. [38] Will only be shown in the internal display.


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5.11. Group 10 – G10: Second Motor

M2

This group appears if any of ‘G5.65’ – ‘G5.71’ (ln.65-71 in integrated display) is set to 26 (second motor).

In the following table, data shaded in grey will be displayed d isplayed when a related code has been selected. Removable display Integrated Integrated dis play

Name / Description

G10.4 AccTi=20.0s M2.4

Function

Set on RUN

Motor 2 acceleration ramp

Set the acceleration ramp for second motor adjustment. The established setting within the parameter is the time required to reach the maximum 0.0 to 600.0s frequency value, starting form 0Hz.This ramp will be set according to the process necessities.

YES

Motor 2 deceleration ramp

Set the deceleration ramp for second motor adjustment. The established setting within the parameter is the time required to reach the maximum 0.0 to 600.0s frequency value, starting form 0Hz.This ramp will be set according to the process necessities.

YES

G10.5 DECEL=30.0s M2.5

Range

G10.6 MTR2PWR=4.0Kw MTR2PWR=4.0Kw

Motor 2 rated power

M2.6

G10.7 MTRFRQ=60.00Hz Motor 2 frequency M2.7

0.2 kW 0.4 kW 0.75 kW 1.1 kW 1.5 kW 2.2 kW 3.0 kW 3.7 kW 4.0 kW 5.5 kW 7.5 kW 11.0 kW 15.0 kW 18.5 kW 22.0 kW 30.0 kW

Set the second motor rated power according to its nameplate.

NO

30.00 to 400.00Hz

Set the second motor frequency to rated value according to its nameplate.

NO

Define the drive control type.


G10.8 Ctr. T=V/Hz Control type selection

0 to 4

M2.8 G10.10 POLE Numbr=4 (*)

Poles number

0

V/Hz

2

SlipCom

4

S-less1

Scalar control mode. Drive carries out the control applying a voltage / frequency ramp to the motor. Slip compensation mode. This mode reduces the effect of motor slip. Sensorless control mode.

2, 4, 6… 48 Set the number number of poles in the motor according to its nameplate.

NO

NO

M2.10 G10.11 RtSlp=64rpm (*) Rated Slip M2.11 G10.12 MTRCUR=8.6A (*) Motor nominal current M2.12 G10.13 NOLODC=3.1A (*) M2.13

No load current

G10.14 MTR VOLT=0V (*) Motor 2 voltage M2.14 G10.15 EFFICIEN=+84% (*)

Motor 2 efficiency

M2.15 G10.16 InertiaRate=0 (*) Motor 2 inertia rate M2.16 G10.17 Rs=138.8mΩ (*) Stator resistor M2.17

62

0 to 3000rpm

When facing a heavy load capable of producing a big slip during the start, configure this parameter to compensate the motor slip.

NO

1.0 to 200.0A Set the motor nominal current in accordance accordance with the nameplate.

NO

Set the measured current at rated frequency without load. If any difficulties 0.5 to 200.0A are found when measuring the current without load, this setting should be between 30% and 50% of the motor nameplate rated current.

NO

180 to 480V Set the motor rated voltage according to its nameplate.

NO

70 to 100% Set the motor efficiency according to its nameplate.

NO

0 to 8 (*)

Set the load inertia rate. Stator resistor fine setting.


NO NO

SD300 SERIES


Name / Description

Range

Function

Set on RUN

G10.18 LSigma=1.244m (*)

M2.18 G10.19 Ls=16.45mH (*) M2.19 G10.20 Tr=228ms 39 M2.20 [39]

Leak inductor

(*)

Leak inductor fine setting.

NO

Stator inductor

(*)

Inductor stator fine setting.

NO

Rotor time constant

25 to 5000ms Rotor time constant fine fine setting.

NO

Set V/F pattern according to the following table:

G10.25 V/FPn=Linear

OPT. DESCRIPTION FUNCTION 0 V/F pattern

0 to 3

M2.25

G10.26 FWBoost=+2.0% M2.26 G10.27 RVBoost=+2.0% M2.27 G10.28 StlLev1=150% M2.28

Square

2

V/F User

3

Square2

NO

Define a customized V/F pattern. Output voltage increases quadratically according to the frequency. K=2.

0.0 to 15.0% Set the intensified torque in forward direction.

NO

Torque in reverse direction

0.0 to 15.0% Set the intensified torque in reverse direction.

NO

Stall prevention level motor 2

30 to 150% Set the stall prevention level.

NO

Set the current level which flows continuously during one minute in % referenced to the motor nominal current. The motor nominal current is set 100 to 200% in parameter ‘G10.12 ‘G10.12 MTRCUR’ MTRCUR’ (M2.12). Whenever this limit is over passed, the thermo-electronic protection will be enabled, and the action defined in par ameter ameter ‘G9.40 ThMM’ (Pr.40) ThMM’ (Pr.40) will be executed.

NO

Set the overcurrent level under which the drive is able to work without enabling the thermo-electronic protection.

NO

overcurrent level during 1 minute

G10.30 ETHcont=+100% Motor 2 M2.30

1

Output voltage increases and decreases at constant rate proportional to voltage/frequency (V/F) relation Output voltage increases quadratically according to the frequency. K=1.5.

Torque in forward direction

G10.29 ETH1min=+150% Motor 2 M2.29

Linear

continuous overcurrent level

50 to 150%

(*) These values depend on the motor setting.

[39] Displayed when ‘G10.8’ (M2.8 in integrated display) is set to S-less.


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5.12. Group 11 – G11: PLC Sequence

US

This group appears when ‘G8.2’ (AP.2) is set to 1 (NO) or CM.95 is set to t o 2 (P2P Master) (*). A PLC sequence creates a simple sequence from a combination of different differe nt function blocks. The sequence can comprise of a maximum of 18 steps using 29 function blocks and 30 parameters. One loop refers to a single execution of a user configured sequence s equence that contains a maximum of 18 steps. Users can select a Loop Time of between 10-1,000ms. The parameters for configuring PLC sequences configuration can be found in groups 11 and 12 of the removable display; which are equivalent to groups US (for user sequence settings) and UF (for function block settings). Removable display Integrated Integrated dis play

Name / Description

Range

Function This parameter allows setting the run and stop sequences.

G11.1 OpComm=Stop OpComm=Stop

OPT. DESCRIPTION FUNCTION PLC operation mode

0 to 2

US.1

0 1

Stop Run

2 Run DI

G11.2 LoopTime=0.02s LoopTime=0.02s PLC loop time

US.2 G11.11 LkOut1=0 US.11 G11.12 LkOut2=0 US.12

Set on RUN

Output link address for PLC function 1 Output link address for PLC function 2

0.01s 0.02s 0.05s 0.1s 0.5s 1s

Stop PLC sequence. The sequence will run continuously with the loop time set in ‘G11.2’ (US.2). The sequence will run continuously with the loop time set in ‘G11.2’ (US.2) while the digital input set as 50 “PLC” is active.

Set the PLC sequence loop time.

NO

NO

Use registers ‘G11.11’ to ‘G11.28’ ‘G11.28’ (US.11-28) to set the parameters to connect the 18 function blocks. If the input value is 0 , an output value cannot be used. 0 to 65535

NO To use the output value in step 1 for the frequency reference (Cmd Frequency), enter the communication address (0x1101) of the Cmd frequency as the Link UserOut1 parameter. …

G11.27 LkOut17=0 US.27 G11.28 LkOut18=0 US.28 G11.31 UFInp1=0 US.31 G11.32 UFInp2=0 US.32

Output link addr. PLC function 17 0 to 65535

See G11.11 (US.11).

NO

Output link addr. PLC function 18 PLC input value 1

PLC input value 2

Use registers ‘G11.31’ to ‘G11.60’ (US.31-60 ‘G11.60’ (US.31-60 to set 30 void parameters. -9999 to 9999 Use when constant (Const) parameter input is needed in the user function block.

NO

…

G11.60 UFInp30=0 US.60 G11.80 InV1=0.000 US.80 G11.81 InI2=+0.000 US.81 G11.82 DIValue=0 US.82 G11.85 AOVal=0.000 US.85 G11.88 DOValue=0 US.88

64

PLC input value 30 -9999 to 9999 See G11.31 (US.31).

NO

Analogue input V1 0 to 12.000% Allows setting the analog input V1 voltage value. value

NO

Analogue input I2 value

NO

-12.000 to Allows setting the analog analog input I2 voltage or current values. 12.000%

Digital inputs value

0 to 127

Analogue output value

0.000 to 10.000%

Digital output value

0 to 3

Allows setting the digital inputs voltage value.

NO

Allows setting the analog analog output AO voltage or current values.

NO

Allows setting the digital output Q1 voltage value.

NO


SD300 SERIES

POWER ELECTRONICS

5.13. Group 12 – G12: PLC Function

UF

This group appears when ‘G8.2’ (AP.2) is set to 1 (Yes) or ‘G7.95’ is set to 2 (P2P Master). Set user defined functions for the 18 function blocks. If the function block setting is invalid, the output of the User Output is -1. All outputs are read only, and can be used with the user output link of the G11 (US in the integrated display) group. Removable display Integrated Integrated dis play

Name / Description

Range

Function

Set on RUN

Choose the function to perform in the function block, according to the following table:

OPT. DESCRIPTION FUNCTION 0 1 2 3 4 5 6 7 8 9 10

11

12

G12.1 Func1=NOP

PLC function 1

0 to 28 13

14

15

16 17 18

No operation ADD Addition, (A + B) + C SUB Substraction, (A – (A – B) B) – – C C Addition and substraction compound, ADDSUB (A + B) – B) – C C Smallest value of the input values, MIN MIN(A, B, C). Largest value of the input values, MAX MAX(A, B, C). ABS Absolute value of the the A parameter, | A | NEGATE Negative value of the A parameter, -( A ). Compound multiplication and division, MPYDIV (A x B)/C. REMAINDER Remainder operation of A and B, A % B Comparison operation: if (A > B) the output is C; if (A /= B) output is C; if (A
NO

Note: Continues in the next page.


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POWER ELECTRONICS

Name / Description

Range

Function

Set on RUN

Note: Comes from the previous page. OPT. DESCRIPTION FUNCTION 19

20

21

22

23

24

UF.1

25

26

27

28

G12.2 Inpt1A=0 UF.2 G12.3 Inpt1B=0 UF.3 G12.4 Inpt1C=0 UF.4 G12.5 Outp1=+0 UF.5

66

ANDOR

Outputs the result of the AND/OR operation, (A andB) | C.

Output a value after selecting one of two inputs, if (A) then B, otherwise C. SWITCH If the input at A is 1, the output will be B. If the input at A is 0, the output parameter will be C. Test the B bit of the A parameter, BITTEST(A, B). If the B bit of the A input is 1, the output is 1. If it is 0, then the output is 0. BITTEST –16. If the The input value of B must be between 0 –16. value is higher than 16, it will be recognized as 16. If input at B is 0, the output is always 0. Set the B bit of th e A parameter, BITSET(A, B). Output the changed value after setting the B bit to input at A. BITSET The input value of B must be between 0 –16. –16. If the value is higher than 16, it will be recognized as 16. If the input at B is 0, the output is always 0. Clear the B bit of the A parameter, BITCLEAR(A, B). Output the changed value after clearing the B bit to input at A. BITCLEAR The input value of B must be between 0 –16. –16. If the value is higher than 16, it will be recognized as 16. If the input at B is 0, the output is always 0. Output the input at A as the B filter gains time constant, B x ‘G11.2 ‘G11.2’. LOWPASSFILTER In the above formula, set the time when the output of A reaches 63.3% C stands for the filter operation. If it is 0, the operation is started. P, I gain = A, B parameter input, then output as C. Conditions for PI_PROCESS output: PI_CONTORL

PI_PROCESS

C = 0: Const PI, C = 1: PI_PROCESS-B >= PI_PROCESS-OUT >= 0, C = 2: PI_PROCESS-B >= PI_PROCESS-OUT >= (PI_PROCESS-B),

P gain = A/100, I gain = 1/(Bx Loop Time), If there is an error with PI se ttings, output is -1. A is an input error, B is an output limit, C is the value of Const PI output. Range of C is 0 to 32767.

UPCOUNT

Upcounts the pulses and then output the value UPCOUNT(A, B, C). After receiving a trigger input (A), outputs are upcounted by C conditions. If the B inputs is 1, do not operate and display 0. If the B inputs is 0, operate. If C is 0, upcount when A changes from 0 to 1. If C is 1, upcount when A is changed from 1 to 0. If C is 2, upcount whenever the input at A changes. Output range is: 0 to 32767.

DOWNCOUNT

Downcounts the pulses and then output the valueDOWNCOUNT(A, B, C). After receiving a trigger input (A), outputs are downcounted by C conditions. If the B input is 1, do not operate and display the initial value of C. If the B input is 0, operate. Downcounts when the A parameter changes from 0 to 1.

Input A for PLC function 1

0 to 65535

Communication address of the first input parameter of the PLC function.

NO

Input B for PLC function 1

0 to 65535

Communication address of the second input parameter of the PLC function.

NO

Input C for PLC function 1

0 to 65535

Communication address of the third input parameter of the PLC function.

NO

Output PLC function 1

-32767 to 32767

Output value (Read Only) after performing the function block.

NO


SD300 SERIES

POWER ELECTRONICS Removable display Integrated Integrated dis play G12.6 Func2=NOP UF.6 G12.7 Inpt2A=0 UF.7 G12.8 Inpt2B=0 UF.8 G12.9 Inpt2C=0 UF.9 G12.10 Outp2=+0 UF.10

Name / Description

Range

Function

Set on RUN

PLC function 2

See G12.1

See G12.1 (UF.1)

NO


See G12.2

See G12.2 (UF.2)

NO


See G12.3

See G12.3 (UF.3)

NO


See G12.4

See G12.4 (UF.4)

NO


See G12.5

See G12.5 (UF.5)

NO

…

G12.86 Func18=NOP UF.86 G12.87 Inpt18A=0 UF.87 G12.88 Inpt18B=0 UF.88 G12.89 Inpt18C=0 UF.89 G12.90 Outp18=+0 UF.90

PLC function 18

See G12.1

See G12.1 (UF.1)

NO


See G12.2

See G12.2 (UF.2)

NO


See G12.3

See G12.3 (UF.3)

NO


See G12.4

See G12.4 (UF.4)

NO


See G12.5

See G12.5 (UF.5)

NO


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5.14. Group 13 – G13: Fault History This group is only shown in the removable LCD display. For the integrated display, faults are shown in parameters Pr.90 to Pr9.96. Removable display Integrated Integrated dis play

Name / Description

Range

Set on RUN

Function This screen will be automatically displayed every time the drive trips with a new fault. Shows the current fault status of the drive. In case there is no fault the screen will display the message ‘No Fault’. By pressing the ‘*’ key the fault number will be displayed. The drive resets pressing the display STOP-RESET STOP-RESET key or using an external reset when available. Faults can be automatically reset using the Auto Reset function. function. The following table shows all of the possible faults:

Fault = No Fault

G13.1 /Current Fault status visualization

-

COD

FAULT

COD

FAULT

0 1 2 3 4 5 6 7 8 10 11 12 13 14 15 16 17 18 19 20

No Fault OverLoad UnderLoad Inv OverLoad E-Thermal Ground Fault Output Ph Loss Input Ph Loss OverSpeed NTC OverCurrent OverVoltage External Trip Arm Short OverHeat Fuse Open MC Fail Encoder Error PTC FAN Trip

22 23 24 25 26 27 28 29 30 33 34 35 36 49 50 51 52

Param_Wr_Err Pipe Fill Flt IO Board Fail External Brake No Motor Slot 1 Fail Slot 2 Fail Slot 3 Fail STO Fault Free Run Low Voltage Lost Command KeypadLostCMD ADC Error EEPROM Error Watchdog-1 Err Watchdog-2 Err

-

Note: For further information about faults see section 3, Warning & Fault Messages. Messages.

FAULT 1 INFO [40]

FAULT 2 INFO [40]

The first group (FAULT INFO 1) shows the information of the last fault and will be used as the first fault history register.

G13.2 / Fault History Register 1

-


-

The last five faults, listed in chronological order, are shown as new faults occur, with the most recent fault in the first place (FAULT INFO 1). Every time a fault is produced, the drive shows the (FAULT INFO 1) screen, moving the previous fault to the next register position (FAULT INFO 2). The rest of stored faults will move down a position. The oldest fault message (FAULT INFO 5) will be lost.

-

These groups enable accessing to the extended information of each of the last five faults registers. This information displays the drive status in the moment the fault has been produced.

FAULT 3 INFO [40]


OPT. -

FAULT 4 INFO [40]


-

FAULT 5 INFO [40]


-

FUNCTION

X Fault= X Op Fq= X Out I= X DC Volt= X Temp= X DI= X DO Sta=

Fault register X display Output frequency value when fault occurred. Output current value when fault occurred Bus voltage value when fault occurred Equipments temperature when fault occurred. Digital inputs status values when fault occurred. Digital outputs status values when fault occurred Number of days the drive had been turned on when the X On Days= fault occurred. Number of minutes the drive had been turned on when X On Min= the fault occurred. Number of days the drive had been turned on when the X RUN Days= fault occurred. Number of minutes the drive had been turned on when X RUN Min= the fault occurred.

[40] These groups will be displayed as new faults occur

68


-

-

-

SD300 SERIES


Name / Description

Range

Function

Set on RUN

OPT. FUNCTION Clr FaultHist= N

G13.7 / Clear Fault History

NO NO YES

YES

Function disabled. Deletes the fault history (the last five faults). The screen will return to the default value ‘NO ‘ NO’’ once all of the faults have been deleted.

NO

In order to select if Low Voltage fault must be saved in the fault history register or not.

ENB/DIS LV Flt= D

G13.8 / Low Voltage fault register

OPT. DESCRIPTION FUNCTION D E

The Low Voltage fault will not be saved in the fault history. The Low Voltage fault will be saved in the E ENABLED fault history. Note: If the drive losses power completely before displaying the fault, the Low Voltage fault will not be saved despite having enabled this parameter. D

DISABLED

NO


69

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6. MODBUS COMMUNICATION To control the variable speed drive with a PLC or a computer. the industrial standard communications protocol of Modicon, Modbus, is used. Connect the communication cables (*) and set the communication parameters on the drive according to the guidelines within this section.

6.1. Introduction Various drives, or other slave devices, can be connected in a RS485 network to be controlled by a PLC or computer. This way, parameter setting and monitoring can be done from a computer, via a user program. To communicate, any kind of RS485 converter can be used. Specifications depend on the manufacturer.

Figure 6.1 RS485 network system configuration

The purpose of the Serial Communication Network of the SD300 is to integrate the drive into a network compatible with the Modbus communications protocol. This is possible using the RS485 physical communications port or USB port. Modbus communication system allows SD300 drives to be controlled and/or monitored as a slave by a Modbus master from a remote location. RS485 network allows connecting up to 16 equipments in the same network. SD300 drives operate as a peripheral slave when connected to Modbus system. This means that the drive does not start the communication task, the master does. Practically all of the operating modes, parameters and drive characteristics are accessible through serial communications. For example, master can give start and stop order to the drive, control SD300 status, read the current used by the motor etc., in short, the master can access all of the features of the drive.

(*) For detailed instructions on how t o make the connections, please refer to the Hardware Hardware and Installation Manual

70

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6.2. Supported Modbus Function Codes Serial communications protocol provided by SD300 drive adhere to Modbus. The drive uses reading and writing functions between all of the functions that exist in Modbus protocol. The used functions by the drive are the following ones: Function

Description

3 4 6 16

Registers Reading Read Input Register Write Single Register Registers Writing

The implementation of this function code in the drive allows reading up to 120 registers into a Parameters Group in a frame. If you want to access to a consecutive memory registers. but belonging to different groups. you should access in so many frames as groups are involved.

6.2.1. Modbus Function Code Nº 3: Registers Reading This function code allows the Modbus controller (master) to read the content of the data registers indicated in the drive (slave). This function code only admits unicast addressing. Broadcast or groupcast addressing are not possible with this function code. The implementation of this function code in the drive allows reading up to 120 registers with consecutive addresses of the drive in a single frame. Next. a frame is shown where the master tries to read the content of 3 registers of a drive where the current used by each phase is. The information that should be attached in the ask frame is the following: Data address of the drive. ▪ Modbus function code (3 Registers reading). ▪ Starting Data Data address. ▪ Registers number for reading. ▪ CRC-16 code. ▪

The answer of the drive (slave) should contain the following fields: Data address of the slave. ▪ Modbus function code (3 Registers reading). ▪ Bytes number for reading. ▪ Bytes number / 2 registers. ▪ CRC-16 code. ▪

Each register consists of 2 bytes (2x8bits=16 bits). This is the default length for all registers. Example:

Suppose that we want to read the motor current (nameplate data) via communications. This data corresponds to the parameter G2.13 ‘MTR CUR=0.0A’. The frame that should be transmitted is: Modbus Addr Ad dress ess

Modbus Function Code

Starting Data Addr Ad dr ess (44622)

Registers Number

CRC-1 CRC-16 6

0x0A

0x03

0x0120D

0x0001

0x2493

Suppose that instantaneous current of the equipment is 8.2 A. (Modbus value 82 decimal = 0x52 Hexadecimal). The answer of the slave will be: Modbus Addr Ad dress ess

Modbus Function Code

Bytes Number

Data (address 20) (=110)

CRC-16

0x0A

0x03

0x02

0x0052

0x9C78


71

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6.2.2. Modbus Function Code Nº 16: Registers Writing This function code allows the Modbus controller (master) to write the content of the data registers indicated in the drive (slave). whenever those registers are not of Read only. Registers writing by the master does not impede the later modification of those registers by the slave. The implementation of this function code in the drive allows writing up to 5 registers of the drive in a single frame. Next. a frame is shown where the master tries to write the content of 1 register that stores the acceleration time. The information that should be attached in the ask frame is the following one: Data address of the slave. ▪ Modbus function code (16 Registers writing). ▪ Starting Data Data Address. Address. ▪ Registers number for writing. writing. ▪ Bytes number for writing. writing. ▪ Content of registers for writing. ▪ CRC-16 code. ▪

The answer of the slaves includes: Data address of the slave. ▪ Modbus function code (16 Registers writing). ▪ Starting Data Data Address. Address. ▪ Written registers number. number. ▪ CRC-16 code. ▪

6.3. Addressing Modes 6.3.1. Broadcast Addressing Mode Broadcast addressing mode allows the master to access at the same time to all of the slaves connected to the Modbus network. The Modbus function code that admits this global addressing mode is: Function

Description

16

Registers Writing

In order to access to all of the equipments connected in a Modbus network. you must use the address 0. When this address is used. all of the slaves in the Modbus network make the required task but they do not prepare any answer.

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6.4. Summary of Modbus Addresses 6.4.1. Common Area Modbus Address

Parameter

Scale

Units

R/W

Data Values

0h0000

Inverter Model

-

-

R

40001

0h0001

Drive Power Rating

-

-

R

40002

0h0002

Drive Input Voltage

-

-

R

40003

0h0003

SW Version

-

-

R

40005

0h0005

Reference Frequency

0.01

Hz

R/W

B: SD300 0: 0.75kW 1: 1.5kW 2: 2.2kW 3: 3.7kW 4: 5.5kW 5: 7.5kW 6: 11kW 7: 15kW 8: 18.5kW 9: 22kW 0: 220VAC 1: 400VAC (Ex) 0x0100: Version 1.0 (Ex) 0x0101: Version 1.1 Starting Frequency to Max Frequency Bit 0: Stop Bit 1: Forward Start Bit 2: Reverse Start Bit 3: Fault Reset Bit 4: Emergency Stop Bit 5: Not used Bit 6 – 6 – 8: 8: Setpoint Introduction 0: Local 1: Start/Stop-1 2: Start/Stop-2 3: RS485 integrated 4: Communications Option 5: PLC Option Bit 9 – 9 – 14: 14: Reference Frequency 0: Local Reference 1: Not used 2: Step frequency 1 3: Step frequency 2 4: Step frequency 3 5: Step frequency 4 6: Step frequency 5 7: Step frequency 6 8: Step frequency 7 9: Step frequency 8 10: Step frequency 9 11: Step frequency 10 12: Step frequency 11 13: Step frequency 12 14: Step frequency 13 15: Step frequency 14 16: Step frequency 15 17: Up Speed 18: Down Speed 19: Constant 20 – 20 – 21: 21: Reserved 22: Analog V1 23: Analog I1 24: Analog V2 25: Analog I2 26: Reserved 27: RS485 28: Communication Option 29: PLC Option 30: Fix Frequency 31: PID Bit 15: Not used

Decimal

Hexadecimal

40000

R/W

-

40006

0h0006

Start / Stop Command

-

-

R

40007 40008 40009 40010 40011 40012

0h0007 0h0008 0h0009 0h000A 0h000B 0h000C

Acceleration Time Deceleration Time Output Current Output Frequency Output Voltage DC Bus Voltage

0.1 0.1 0.1 0.01 1 1

Sec Sec A Hz V V

R/W R/W R R R R


73

SD300 SERIES Modbus Address Decimal

Hexadecimal

40013

0h000D

POWER ELECTRONICS

Parameter

Scale

Units

R/W

Output Power

0.1

kW

R

40014

0h000E

Drive Status

-

-

R

40015

0h000F

Fault information

-

-

R

40016

0h0010

Digital Inputs Status

-

-

R

40017

0h0011

Digital Outputs Status

-

-

R

40018 40019 40020 40021

0h0012 0h0013 0h0014 0h0015

V1 V2 I2 RPM

0.1 0.1 0.1 1

% % % rpm

R R R R

40026

0h001A

Display unit

-

-

R

40027

0h001B

Number of poles

-

-

R

Data Values Bit 0: Stop Bit 1: Start (+) Bit 2: Start (-) Bit 3: Fault Bit 4: Accelerating Bit 5: Decelerating Bit 6: Steady Status Bit 7: DC Brake Bit 8: Stop Bit 9: Fix Frequency Bit 10: Open Brake Bit 11: Start (+) Command Bit 12: Start (-) Command Bit 13: Start / Stop by Communication Bit 14: Freq. Reference by Communication Bit 15: 0-Remote; 1-Local Bit 0: Latch type fault Bit 3: Level type fault Bit 10: Hardware diagnosis Bit 0: P1 Bit 1: P2 Bit 2: P3 Bit 3: P4 Bit 4: P5 Bit 5: P6 Bit 6: P7 Bit 7: P8 Bit 0: Relay 1 Bit 1: Multifunction output Voltage input V1 Voltage Input V2 (Option I/O) Current Input I2 Speed Output 0: Hz 1: rpm Motor poles visualization

Notes:

1. Start / Stop order through communications (address 40006/0h0006) Every bit is enabled when they change their status from 0 to 1. For example, the drive stops due to a fault during start. Until the fault has been reset and the start order is given, the drive will not operate. 2. Addresses 40005/0h0005 and 40006/0h0006 The values stored in these addresses will be deleted if the drive losses it power supply. Th ese addresses will only keep their values while the equipment remains powered.

6.4.2. Monitoring Parameters NOTE: These are read-only parameters Modbus Address

74

Parameter

Scale

Units

Values

0h0300

Drive model

-

-

40769

0h0301

Rated power

-

-

40770

0h0302

Input voltage

-

-

40771

0h0303

SW Version

-

-

SD300: 006h 0.75kW: 3200h 1.5 kW: 4015h 2.2 kW: 4022h 3.7 kW: 4037h 5.5 kW: 4055h 7.5 kW: 4075h 11 kW: 40B0h 15 kW: 40F0h 18.5 kW: 4125h 22 kW: 4160h 220VAC: 0221h 400VAC: 0431h (Ex) 0x0100: Version 1.0 (Ex) 0x0101: Version 1.1

Decimal

Hexadecimal

40768


SD300 SERIES

POWER ELECTRONICS Modbus Address Decimal

Hexadecimal

Parameter

Scale

Units

40773

0h0305

Drive operation state

-

-

40774

0h0306

Drive operation frequency command source

-

40775 40776 40784 40785 40786 40787 40788 40789 40790 40791 40792 40793 40794 40795 40796 40797

0h0307 0h0308 0h0310 0h0311 0h0312 0h0313 0h0314 0h0315 0h0316 0h0317 0h0318 0h0319 0h031A 0h031B 0h031C 0h031D

SW Version SW Version Output current Output frequency Output rpm Motor speed feedback Output voltage DC bus voltage Output power Output torque PID reference PID feedback Motor 1 poles number Motor 2 poles number Poles number of the selected motor Select Hz/rpm

0.1 0.01 0 0 1 1 0.1 0.1 0.1 0.1 -

A Hz rpm rpm V V kW % % % -

40800

0h0320

Digital inputs information

40801

0h0321

Digital outputs information

-

-

40802

0h0322

Communication addresses information

-

-

40803

0h0323

Selected motor

-

-

40804 40805

0h0324 0h0325

V1 V2

0.1 0.1

% %

Values Bit 0 – 0 – 3: 3: 0: Stopped 1: Operating in forward direction 2: Operating in reverse direction 3: DC operating (0 speed control) Bit 4 – 4 – 7 7 1: Speed searching 2: Accelerating 3: Operating at constant rate 4: Decelerating 5: Decelerating to stop 6: H/W OCS 7: S/W OCS 8: Dwell operation Bit 12 – 12 – 15 15 0: Normal state 4: A warning has occurred 8: A fault has occurred. Drive will operate according to the setting of Pr.30. Bit 0 – 0 – 7: 7: Frequency command command source 0: Keypad speed 1: Keypad torque 2-4: Up/Down operation speed 5: V1, 7: V2, 8: I2, 9: Pulse 10: Built-in RS 485 11: Optional communication card 12: PLC 13: Jog 14: PID 25-39: Multi-step speed frequency Bit 8 – 8 – 15: 15: Operation command source 0: Keypad 1: Optional communication card 2: PLC 3: Built-in RS 485 4: Terminal block (Ex) 0x0100: Version 1.0 (Ex) 0x0101: Version 1.1 -32768 rpm – rpm – 32767 32767 rpm (directional) Visualization of motor 1 poles Visualization of motor 2 poles Visualization of selected motor poles 0: Hz, 1: rpm Bit 0: P1 Bit 1: P2 Bit 2: P3 Bit 3: P4 Bit 4: P5 Bit 5: P6 Bit 6: P7 Bit 0: Relay 1 Bit 1: Multi function output Bit 0: Input 1 (CM.70) Bit 1: Input 2 (CM.71) Bit 2: Input 3 (CM.72) Bit 3: Input 4 (CM.73) Bit 4: Input 5 (CM.74) Bit 5: Input 6 (CM.75) Bit 6: Input 7 (CM.76) Bit 7: Input 8 (CM.77) 0: Motor 1 1: Motor 2 Analog voltage input V1 Analog voltage input V2


75

SD300 SERIES Modbus Address Decimal

40806 40807 40808 40813 40814 40815

76

Hexadecimal

POWER ELECTRONICS

Parameter

0h0326 I2 0h0327 AO1 0h0328 AO2 0h032D Drive temperature 0h032E Drive power consumption 0h032F Drive power consumption

Scale

Units

Values

0.1 0.1 0.1 1 1 1

% % % ºC kWh kWh

Analog current input I2 Analog output 1 Analog output 2 -

40816

0h0330

Latch type trip 1 information

-

-

40817

0h0331

Latch type trip 2 information

-

-

40818

0h0332

Level type trip information

-

-

40819

0h0333

HW diagnosis trip information

-

-

40820

0h0334

Warning information

-

-

40832

0h0340

Days ON

0

Días

40833

0h0341

Minutes ON

0

Minutos

40834

0h0342

Days on run

0

Días

40835

0h0343

Minutes on run

0

Minutos

40836

0h0344

Fan runtime days

0

Días

40837

0h0345

Fan runtime minutes

0

Minutos

40842

0h034A

Optional card

-

-


Bit 0: Overload Bit 1: Underload Bit 2: Inverter Overload Bit 3: E-Thermal Bit 4: Ground Fault Bit 5: Output open-phase Bit 6: Input open-phase Bit 9: NTC Bit 10: Overcurrent Bit 11: Overvoltage Bit 12: External trip Bit 13: Arm short Bit 14: Over Heat Bit 15: Open fuse Bit 0: MC Fail trip Bit 2: PTC trip Bit 3: Fan trip Bit 5: Error while writing parameter Bit 6: Pre PID trip Bit 7: External card contact fault Bit 8: External brake trip Bit 9: No motor trip Bit 10: External card fault Bit 0: Free run fault Bit 1: Low voltage Bit 2: Lost command Bit 3: Display lost command Bit 4: Safety A Bit 5: Safety B Bit 0: ADC error Bit 1: EEPROM error Bit 2: Watchdog1 Bit 3: Watchdog 2 Bit 5: Full queue Bit 0: Overload Bit 1: Underload Bit 2: Drive overload Bit 3: Lost command Bit 4: Fan running Bit 5: DB Bit 6: Wrong encoder installation Bit 7: Encoder disconnection Bit 8: Keypad lost Bit 9: Auto tuning failed Total number of days the drive has been powered on. Total number of minutes the drive has been powered on, excluding the total number of days. Total number of days the drive has been driving the motor. Total number of minutes the drive has been driving the motor, excluding the total number of days. Total number of days the heat sink fan has been running. Total number of minutes the heat sink fan has been running, excluding the total number of days. 0: None 9: CANopen

SD300 SERIES

POWER ELECTRONICS

6.4.3. Control Parameters NOTE: These parameters are read and write. Modbus Address

Parameter

Scale

Units

Values

0h0380 0h0381

Frequency command Rpm command

0.01 1

Hz rpm

40898

0h0382

Operation command

-

-

40899 40900

0h0383 0h0384

Acceleration time Deceleration time

0.1 0.1

s s

40901

0h0385

Communications addresses control (0: Off, 1: On)

40902

0h0386

40904 40905 40906 40907 40912 40913 40914 40915 40916 40917

0h0388 0h0389 0h038A 0h038B 0h0390 0h0391 0h0392 0h0393 0h0394 0h0395

Digital outputs control (0: Off, 1: On) PID reference PID feedback Motor rated current Motor rated voltage Torque reference Torque limit positive forward Torque limit negative forward Torque limit positive reverse Torque limit negative reverse Torque bias

0.1 0.1 0.1 1 0.1 0.1 0.1 0.1 0.1 0.1

% % A V % % % % % %

Frequency command setting Rpm command setting Bit 0 0: Stop command 1: Run command Bit 1 0: Reverse command 1: Forward command Bit 2: 0  1: Trip initialization Bit 3: 0  1: Free-run stop Acceleration time setting setting Deceleration time setting Bit 0: Input 1 (CM.70) Bit 1: Input 2 (CM.71) Bit 2: Input 3 (CM.72) Bit 3: Input 4 (CM.73) Bit 4: Input 5 (CM.74) Bit 5: Input 6 (CM.75) Bit 6: Input 7 (CM.76) Bit 7: Input 8 (CM.77) Bit 0: Relay 1 Bit 1: Multi function output PID reference command PID feedback value Torque command Torque limit in forward direction Regenerative torque limit in forward direction Torque limit in reverse direction Regenerative torque limit in reverse direction Torque bias

Decimal

Hexadecimal

40896 40897

6.4.4.

Memory Control Area NOTE: These parameters are read and write. Parameter

Scale

Units

Set on run

0h03E0 0h03E1

Save parameters Monitor mode initialization

-

-

YES NO

40994

0h03E2

Initialize parameters

-

-

YES

40995 40997 40998

0h03E3 0h03E5 0h03E6

Display changed parameters Delete fault history Delete user registered codes

-

-

NO NO NO

40999

0h03E7

Hide parameter mode

0

Hex

NO

41000

0h03E8

Lock parameter mode

0

Hex

NO

41001 41002 41003

0h03E9 0h03EA 0h03EB

-

NO NO NO

41004

0h03EC

Easy parameter setup Initialize power consumption Initialize operation accumulative time Initialize fan operation accumulative time

0: No, 1: YES 0: No, 1: YES 0: No, 1: Todos. By groups: 2: Operation, 3: bA, 4: Ad, 5: Cn, 6: In, 7: OU, 8: CM, 9: AP, 12: Pr, 13: M2. Note: Setting is prohibited during fault trip interruptions. 0: No, 1: YES 0: No, 1: YES 0: No, 1: YES Write: 0-9999 Read: 0: Unlock, 1: Lock Write: 0-9999 Read: 0: Unlock, 1: Lock 0: No, 1: YES 0: No, 1: YES 0: No, 1: YES

-

NO

0: No, 1: YES

Modbus Address Decimal

Hexadecimal

40992 40993

Modbus Address


77

SD300 SERIES

POWER ELECTRONICS

6.4.5. Programming Parameters Parameter

Screen

Description

G1.1 / 0.00

1 LCLSP=0.00Hz LCLSP=0.00Hz

G1.2 / dr.2 G1.3 / ACC G1.4 / dEC


Hexadecimal

Local speed

44353

0h1101

2 LclTQ=0.0% 3 ACC1=20.0s ACC1=20.0s 4 DECEL1=30.0s DECEL1=30.0s

Local torque Acceleration Ramp Deceleration Ramp

44354 44355 44356

0h1102 0h1103 0h1104

G1.6 / dru

6 CONTROL MODE1=REMOTE

Control mode 1

44358

0h1106

G1.7 / Frq

7 REF1 SP= LOCAL

Speed reference 1

44359

0h1107

G1.8 / dr.8

8 REF1 TQ= LOCAL

Torque reference 1

44360

0h1108

G1.9 / dr.

9 Ctr.T=V/Hz Ctr.T=V/Hz

Control type

44361

0h1109

G1.10 / dr.10

10 Torq CTRL=N

Torque control

44362

0h110A

G1.11 / dr.11

11 InchF=10.00Hz InchF=10.00Hz

Inch Frequency

44363

0h110B

G1.12 / dr.12 G1.13 / dr.13

12 InchAcT=20.0s 13 InchDeT=30.0s InchDeT=30.0s

INCH acceleration time INCH deceleration time

44364 44365

0h110C 0h110D

G1.14 / dr.14

14 MTRPWR= MTRPWR= (*)

Motor power

44366

0h110E

G1.15 / dr.15

15 TqBoost=Manual

Torque boost

44367

0h110F

G1.16 / dr.16 G1.17 / dr.17 G1.18 / dr.18 G1.19 / dr.19 G1.20 / dr.20

16 FWBoost=2.0% FWBoost=2.0% 17 RVBoost=2.0% 18MTRFRQ=60.00Hz 18MTRFRQ=60.00Hz 19 STRFRQ=0.5Hz STRFRQ=0.5Hz 20 MxSpL=60.00Hz MxSpL=60.00Hz

Start torque in forward direction Start torque in reverse direction. Motor frequency Start frequency Max speed limit

44368 44369 44370 44371 44372

0h1110 0h1111 0h1112 0h1113 0h1114

G1.21

21 Hz/Rpm=Hz

Hz/Rpm Display

44373

0h1115

(*) This value depends on the motor setting .

78


Range

Modbus Range

[G1.19] to [G1.20] (dr.19 to dr.20) -180.0 to 180.0% 0.0 to 600.0s 0.0 to 600.0s LOCAL REMOTE REMOTE2 MODBUS COMMS PLC LOCAL V1 V2 I2 MDBUS COMMS PLC PULSE LOCAL V1 V2 I2 MDBUS COMMS PLC PULSE V/Hz SlipCom S-less1 N/Y [G1.19] to [G1.20] (dr.19 to dr.20) 0.0 to 600.0s 0.0 to 600.0s 0.2 kW 0.4 kW 0.75 kW 1.1 kW 1.5 kW 2.2 kW 3.0 kW 3.7 kW 4.0 kW 5.5 kW 7.5 kW 11.0 kW 15.0 kW 18.5 kW 22.0 kW 30.0 kW Manual Auto1 Auto2 0.0 to 15.0% 0.0 to 15.0% 30.00 to 400.00Hz 0.01 to 10.00Hz 40.00 to 400.00Hz Hz Rpm

[G1.19] to [G1.20] (dr.19 to dr.20) -1800 to 1800 0 to 6000 0 to 6000 0 1 3 4 5 6 0 2 4 5 6 8 9 12 0 2 4 5 6 8 9 12 0 2 4 0/1 [G1.19] to [G1.20] (dr.19 to dr.20) 0 to 6000 0 to 6000 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 0 1 2 0 to 150 0 to 150 3000 to 40000 1 to 1000 4000 to 40000 0 1

SD300 SERIES

POWER ELECTRONICS Parameter

Screen

Description


Hexadecimal

1.80 / dr.80

80 SelRngEnt=Run SelRngEnt=Run Freq

Select ranges at power input

44432

0h1150

G1.81 / dr.81

81 SelCod=Volt V

Select monitor code

44433

0h1151

G1.89 / dr.89

89 DspChng=All

Display changed parameters

40995

0h3E3

G1.90 / dr.90

90 ESC Func= Mov. In. Pos.

ESC key function

44442

0h115A

G1.91

91 Eloader=None

Eloader function

44443

0h115B

G1.93 / dr.93

93 INITIALIS=No INITIALIS=No

Parameter initialization

44445

0h115D

G1.94 / dr.94 G1.95 / dr.95 G1.97 / dr.97 G1.98 / dr.98 G1.99 / dr.99

94 PswRg=0 95 PrmLock=0 97 SoftVer=0 98 IOSwVer=0 IOSwVer=0 99 IOHwVer=0 IOHwVer=0

Register password Lock password Software version IO Software version Hardware version

44446 44447 44449 44450 44451

0h115E 0h115F 0h1161 0h1162 0h1163

G2.1 / bA.1

1 REF2 SP=None

Alt Speed Ref

44609

0h1201

G2.2 / bA.2

2 AuxCalcType=M+(G*A) AuxCalcType=M+(G*A)

Aux Calc Type

44610

0h1202

G2.3 / bA.3

3 AuxRfG=100.0% AuxRfG=100.0%

Aux. Ref. Gain

44611

0h1203

G2.4 / bA.4

4 CONTROL MODE2=REMOTE

Alt Ctrl Mode

44612

0h1204

Range

Modbus Range

Run Freq. Accel. Time Decel. Time Cmd Source Ref. Source MultiStep 1 MultiStep 2 MultiStep 3 Oupt. Curr. Motor RPM DC Voltage User Sel. 1 Out of Order Sel. Run Dir. Oupt. Curr. 2 Motor2 RPM DC Voltage2 User Sel. 2 Volt V Pow kW Tq kgf All Chang Mov. In. Pos. JOG Key Local/Rem. None Download Upload No All dr bA Ad Cn In OU CM AP Pr M2 run 0 to 9999 0 to 9999 0 to 9999 0 to 65535 0 to 65535 None V1 V2 I2 Pulse M+(G*A) Mx (G*A) M/(G*A) M+[M*(G*A)] M+G*2(A-50%) Mx[G*2(A-50%) M/[G*2(A-50%)] M+M*G*2(A-50%) -200.0 to 200.0 LOCAL REMOTE REMOTE2 MODBUS COMMS PLC

0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 0 1 2 0 1 0 1 2 0 1 2 0 1 2 3 4 5 6 7 8 9 12 13 16 0 to 9999 0 to 9999 0 to 9999 0 to 65535 0 to 65535 0 1 3 4 6 0 1 2 3 4 5 6 7 -2000 to 2000 0 1 3 4 5 6


79

SD300 SERIES

Parameter

80

Screen

POWER ELECTRONICS Description


Hexadecimal

G2.5 / bA.5

5 REF2 SP=LOCAL

Alt Speed Ref

44613

0h1205

G2.6 / bA.6

6 REF2 TQ= LOCAL

Torque Ref2

44614

0h1206

G2.7 / bA.7

7 V/FPn=Linear

V/F Pattern

44615

0h1207

G2.8 / bA.8

8 RmpT= MaxFreq

Ramp T Mode

44616

0h1208

G2.9 / bA.9

9 TimScl=0.1s

Time scale

44617

0h1209

G2.10 / bA.10

10 I/P Freq=60Hz

Input Frequency

44618

0h120A

G2.11 / bA.11 G2.12 / bA.12 G2.13 / bA.13 G2.14 / bA.14 G2.15 / bA.15 G2.16 / bA.16 G2.17 / bA.17 G2.18 / bA.18

11 POLE Numbr=4 12 RtSlp=40rpm 13 MTRCUR=3.6A MTRCUR=3.6A 14 NOLODC=1.6A NOLODC=1.6A 15 MTR VOLT=0V 16 EFFICIEN=72% EFFICIEN=72% 17 InertiaRate=0 18 TrimPwr%=100% TrimPwr%=100%

POLE Number Rated Slip Motor Current No load Current Motor Voltage Efficiency Inertia Rate Trim Power %

44619 44620 44621 44622 44623 44624 44625 44626

0h120B 0h120C 0h120D 0h120E 0h120F 0h1210 0h1211 0h1212

G2.19 / bA.19

19 ACi/Volt=380V

AC Input Volt

44627

0h1213

G2.20 / bA.20

20 AutoTuning=None AutoTuning=None

Auto tuning

44628

0h1214

G2.21 / bA.21 G2.22 / bA.22 G2.23 / bA.23 G2.24 / bA.24 G2.25 / bA.25 G2.26 / bA.26 G2.31 / bA.31 G2.41 / bA.41 G2.42 / bA.42 G2.43 / bA.43 G2.44 / bA.44 G2.45 / bA.45 G2.46 / bA.46 G2.47 / bA.47 G2.48 / bA.48 G2.50 / St1 G2.51 / St2 G2.52 / St3 G2.53 / bA.53 G2.54 / bA.54 G2.55 / bA.55 G2.56 / bA.56 G2.70 / bA.70 G2.71 / bA.71 G2.72 / bA.72 G2.73 / bA.73 G2.74 / bA.74 G2.75 / bA.75 G2.76 / bA.76 G2.77 / bA.77 G2.78 / bA.78 G2.79 / bA.79 G2.80 / bA.80 G2.81 / bA.81 G2.82 / bA.82 G2.83 / bA.83

21 Rs=0 22 LSigma=0mH 23 Ls=0mH 24 Tr=145ms 25 Ls Scl=100% 26 Tr Scl=100% 31 LsR Scl=80% 41 UsFq1=15.00Hz UsFq1=15.00Hz 42 User V1=25% 43 UsFq2=30.00Hz UsFq2=30.00Hz 44 User V2=50% 45 UsFq3=45.00Hz UsFq3=45.00Hz 46 User I2=75% 47 UsFrq4=0.00Hz UsFrq4=0.00Hz 48 User V4=0% 50 MREF1=10.00% MREF1=10.00% 51 MREF2=20.00% MREF2=20.00% 52 MREF3=30.00% MREF3=30.00% 53 MREF4=40.00% MREF4=40.00% 54 MREF5=50.00% MREF5=50.00% 55 MREF6=60.00% MREF6=60.00% 56 MREF7=60.00% MREF7=60.00% 70 ACC2=20.0s 71 DEC2=30.0s 72 ACC3=20.0s 73 DEC3=30.0s 74 ACC4=20.0s 75 DEC4=30.0s 76 ACC5=20.0s 77 DEC5=30.0s 78 ACC6=20.0s 79 DEC6=30.0s 80 ACC7=20.0s 81 DEC7=30.0s 82 ACC8=20.0s 83 DEC8=30.0s

Stator Resistor Leak Inductor Stator Inductor Rotor Time Const Stator Ind. Sca. Rotor Ti Co Sca. Regen. Ind. Scl. User Frequency 1 User Voltage 1 User Frequency 2 User Voltage 2 User Frequency 3 User Voltage 3 User Frequency 4 User Voltage 4 Multi-Reference1 Multi-Reference2 Multi-Reference3 Multi-Reference4 Multi-Reference5 Multi-Reference6 Multi-Reference7 Acc Ramp 2 Decel Ramp 2 Acc Ramp 3 Decel Ramp 3 Acc Ramp 4 Decel Ramp 4 Acc Ramp 5 Decel Ramp 5 Acc Ramp 6 Decel Ramp 6 Acc Ramp 7 Decel Ramp 7 Acc Ramp 8 Decel Ramp 8

44629 44630 44631 44632 44633 44634 44639 44649 44650 44651 44652 44653 44654 44655 44656 44658 44659 44660 44661 44662 44663 44664 44678 44679 44680 44681 44682 44683 44684 44685 44686 44687 44688 44689 44690 44691

0h1215 0h1216 0h1217 0h1218 0h1219 0h121A 0h121F 0h1229 0h122A 0h122B 0h122C 0h122D 0h122E 0h122F 0h1230 0h1232 0h1233 0h1234 0h1235 0h1236 0h1237 0h1238 0h1246 0h1247 0h1248 0h1249 0h124A 0h124B 0h124C 0h124D 0h124E 0h124F 0h1250 0h1251 0h1252 0h1253


Range

Modbus Range

LOCAL V1 V2 I2 MDBUS COMMS PLC PULSE Linear Square V/F Us Square2 MaxFreq DeltaFreq 0.01s 0.1s 1s 60Hz 50Hz 2 to 48 0 to 3000rpm 1.0 to 200.0A 0.5 to 200.0A 180 to 480V 70 to 100% 0 to 8 70 to 130% 170 to 230V 320 to 480V None All Allst Rs+Lsig Tr

0 2 3 4 6 8 9 12 0 1 2 3 0 1 0 1 2 0 1 2 to 48 0 to 3000 10 to 2000 5 to 2000 180 to 480 70 to 100 0 to 8 70 to 130 170 to 230 320 to 480 0 1 2 3 6 0 to 9999 0 to 9999 0 to 9999 25 to 5000 50 to 150 50 to 150 70 to 100 0.00 to [G1.20]/dr.20 0 to 100 0.00 to [G1.20]/dr.20 0 to 100 0.00 to [G1.20]/dr.20 0 to 100 0.00 to [G1.20]/dr.20 0 to 100

Depend on motor settings 25 to 5000ms 50 to 150% 50 to 150% 70 to 100% 0.00 to [G1.20]/dr.20 0 to 100% 0.00 to [G1.20]/dr.20 0 to 100% 0.00 to [G1.20]/dr.20 0 to 100% 0.00 to [G1.20]/dr.20 0 to 100%

0.00 to [G1.20]/dr.20 0.00 to [G1.20]/dr.20

0.0 to 600.0s

0 to 6000

SD300 SERIES


Screen

Description

G3.1 / Ad.1 G3.2 / Ad.2 G3.3 / Ad.3 G3.4 / Ad.4 G3.5 / Ad.5 G3.6 / Ad.6

1 AccPn=Linear 2 DecPn=Linear 3 AccSSrt=40% AccSSrt=40% 4 AccSEnd=40% AccSEnd=40% 5 DecSSrt=40% DecSSrt=40% 6 DecSEnd=40% DecSEnd=40%

G3.7 / Ad.7


Hexadecimal

Acceleration pattern Deceleration pattern S curve start acceleration slope S curve stop acceleration slope S curve start deceleration slope S curve stop deceleration slope

44865 44866 44867 44868 44869 44870

0h1301 0h1302 0h1303 0h1304 0h1305 0h1306

7 START=RAMP START=RAMP

Motor start mode

44871

0h1307

G3.8 / Ad.8

8 STOP=RAMP

Stop mode

44872

0h1308

G3.9 / Ad.9

9 FWR/RV=None FWR/RV=None

Allow speed invertion

44873

0h1309

G3.10 / Ad.10

10 Run Aft VlF=N

Power-on Run

44874

0h130A


12 DCSt T=0.00s 13 DC Curr=50% 14 PreDCT=0.10s PreDCT=0.10s 15 DCBrkT=1.00s DCBrkT=1.00s 16 DCBkCur=50% DCBkCur=50% 17 DCBkF=5.00Hz DCBkF=5.00Hz

Time to DC Start Current injection DC start Pre DC Brake Time DC brake Time Current level DC brake Frequency start DC brake

44876 44877 44878 44879 44880 44881

0h130C 0h130D 0h130E 0h130F 0h1310 0h1311

G3.20 / Ad.20

20 AcDF=5.00Hz AcDF=5.00Hz

Acceleration dwell frequency

44884

0h1314

G3.21 / Ad.21

21 AccDWT=0.0s

Acceleration dwell time

44885

0h1315

G3.22 / Ad.22

22 DeDF=5.00Hz

Deceleration dwell frequency

44886

0h1316

G3.23 / Ad.23

23 DecDWT=0.0s

Deceleration dwell time

44887

0h1317

G3.24 / Ad.24

24 UseFrqLimit=N

Use frequency limit

44888

0h1318

G3.25 / Ad.25

25 FLtLo=0.50Hz

Frequency lower limit

44889

0h1319

G3.26 / Ad.26

26 FLtHi=[G1.20]Hz FLtHi=[G1.20]Hz

Frequency higher limit

44890

0h131A

G3.27 / Ad.27

27 Jump Freq=N

Jump frequency activation

44891

0h131B

G3.28 / Ad.28

28 JmpL1=10.00Hz JmpL1=10.00Hz


44892

0h131C

G3.29 / Ad.29

29 JmpH1=15.00Hz JmpH1=15.00Hz


44893

0h131D

G3.30 / Ad.30



44894

0h131E

G3.31 / Ad.31



44895

0h131F

G3.32 / Ad.32



44896

0h1320

G3.33 / Ad.33



44897

0h1321


41 RlsCur=50.0% RlsCur=50.0% 42 RlsDly=1.00s 44 FwdFq=1.00Hz 45 RevFq=1.00Hz 46 BEngDly=1.00s 47 BEngF=2.00Hz BEngF=2.00Hz

Open brake current Delay before brake opening Brake opening forward freq. Brake opening reverse freq. Delay before brake closing Brake closing frequncy

44905 44906 44908 44909 44910 44911

0h1329 0h132A 0h132C 0h132D 0h132E 0h132F

G3.50 / Ad.50

50 FLX MIN=NONE MIN=NONE

Minimum flux mode

44914

0h1332

G3.51 / Ad.51 G3.60 / Ad.60

51 FluxLVEL=0% 60 XclCF=0.00Hz

Mín. flux level in manual mode Acceleration dwell frequency

44915 44924

0h1333 0h133C

G3.64 / Ad.64

64 FAN=During FAN=During Run

Fan operating mode

44928

0h1340

G3.65 / Ad.65

65 SaveMot Frq=N

Save motorized potentiometer frequency

44929

0h1341

G3.66 / Ad.66

66 SLCOM=None SLCOM=None

Select comparator source

44930

0h1342

G3.67 / Ad.67

67 ScON=90.00%

44931

0h1343

G3.68 / Ad.68

68 SC OF=10.00%

Output activation level comparator mode Output deactivation level comparator mode

44932

0h1344

Range

Modbus Range

Linear 0 S-curve 1 1 to 100% 1 to 100 1 to 100% 1 to 100 1 to 100% 1 to 100 1 to 100% 1 to 100 RAMP 0 DCSTART 1 RAMP 0 DC BRAKE 1 SPIN 2 POW BRKE 4 None 0 FWDPrev 1 REVPrev 2 N 0 Y 1 0.00 to 60.00s 0 to 6000 0 to 200% 0 to 200 0.00 to 60.00s 0 to 6000 0.00 to 60.00s 0 to 6000 0 to 200% 0 to 200 [G1.19]/dr.19 to 60.00 [G1.19]/dr.19 to 6000 [G1.19] to [G1.20] [G1.19] to [G1.20] (dr.19 to dr.20) (dr.19 to dr.20) 0.0 to 60.0 0 to 600 [G1.19] to [G1.20] [G1.19] to [G1.20] (dr.19 to dr.20) (dr.19 to dr.20) 0.0 to 60.0S 0 to 600 NO 0 YES 1 0.00 to [G3.26]/Ad.26 0 to [G3.26]/Ad.26 [G3.25] to [G1.20] [G3.25] to [G1.20] (Ad.25 to dr.20) (Ad.25 to dr.20) NO 0 YES 1 0.00 to [G3.29]/Ad.29 0 to [G3.29]/Ad.29 [G3.28] to [G1.20] [G3.28] to [G1.20] (Ad.28 to dr.20) (Ad.28 to dr.20) 0.00 to [G3.31]/Ad.31 0 to [G3.31]/Ad.31 [G3.30] to [G1.20] [G3.30] to [G1.20] (Ad.30 to dr.20) (Ad.30 to dr.20) 0.00 to [G3.33]/Ad.33 0 to [G3.33]/Ad.33 [G3.32] to [G1.20] [G3.32] to [G1.20] (Ad.32 to dr.20) (Ad.32 to dr.20) 0.0 to 180.0% 0 to 1800 0.00 to 10.00s 0 to 1000 0.00 to [G1.20]/dr.20 0 to [G1.20]/dr.20 0.00 to [G1.20]/dr.20 0 to [G1.20]/dr.20 0.00 to 10.00s 0 to 10s 0.00 to [G1.20]/dr.20 0 to [G1.20]/dr.20 NONE 0 MANU 1 AUTO 2 0 to 30% 0 to 30 0.00 to [G1.20]/dr.20 0 to [G1.20]/dr.20 DuringRun 0 Always ON 1 Temp Ctrl 2 N 0 Y 1 None 0 V1 1 V2 3 I2 4 Pulse 6 [G3.68]/Ad.68 to - G3.68]/Ad.68 to 100.00 100.00 -100.00 to -10000 to [G3.67]/Ad.67 [G3.67]/Ad.67


81

SD300 SERIES

82

POWER ELECTRONICS

Parameter

Screen

Description

G3.70 / Ad.70

70 RunEMod=Always RunEMod=Always Enable

G3.71 / Ad.71

Modbus Address

Range

Modbus Range

0h1415 0h1416

Always Enable DI Dependent Free-Run Q-Stop Q-Stop Res 0.0 to 600.0s NO YES 300 to 400V 600 to 800V 0.00 to 10.00Hz 0.0 to 100.0% 0.0 to 3000.0ms None Fire Mode Fire Mode Test 0.00 to 60.00Hz Forward Reverse 0.7 to 15.0 Normal PWM LowLeakage PWM 0.00 to 60.00s 100.0 to 500.0% 0.00 to 60.00s NO YES 0 to 5000% 10 to 9999ms

0 1 0 1 2 0 to 6000 0 1 300 to 400 600 to 800 0 to 1000 0 to 1000 0 to 30000 0 1 2 0 to 6000 0 1 7 to 150 0 1 0 to 6000 1000 to 5000 0 to 6000 0 1 0 to 5000 10 to 9999

45143

0h1417

1.0 to 1000.0%

10 to 10000

45144 45145 45146 45147 45148 45149 45150 45151 45152 45168 45169 45172

0h1418 0h1419 0h141A 0h141B 0h141C 0h141D 0h141E 0h141F 0h1420 0h1430 0h1431 0h1434

Torque limit reference

45173

0h1435

54 TLpsFW=180.0% TLpsFW=180.0% 55 TLngFW=180.0% TLngFW=180.0% 56 TLpsRV=180.0% TLpsRV=180.0% 57 TLngRV=180.0% TLngRV=180.0%

Forward positive torque limit Forward negative torque limit Reverse positive torque limit Reverse negative torque limit

45174 45175 45176 45177

0h1436 0h1437 0h1438 0h1439

G4.62 / Cn.62

62 SpLiRf=LOCAL SpLiRf=LOCAL

Speed limit reference

45182

0h143E

G4.63 / Cn.63 G4.64 / Cn.64 G4.65 / Cn.65

63 SpL(+)=50.00Hz SpL(+)=50.00Hz 64 SpL(-)=50.00Hz SpL(-)=50.00Hz 65 SpLGa=500%

Forward speed limit Reverse speed limit Speed limit gain

45183 45184 45185

0h143F 0h1440 0h1441

G4.70 / Cn.70

70 SSMode=Flying SSMode=Flying Start1

Speed search mode selection

45190

0h1446

G4.71 / Cn.71 G4.72 / Cn.72 G4.73 / Cn.73 G4.74 / Cn.74

71 Srch Mod=0000 72 Srch I=150% 73 Kp Srch=100/600 Srch=100/600 74 Ki Srch=100/600

Search mode Speed search mode current Speed search mode prop. gain Speed search integral gain

45191 45192 45193 45194

0h1447 0h1448 0h1449 0h144A

1.0 to 1000.0% 10 to 999ms 1 to 200% 1 to 200% 0 to 32767 100 to 1000 100 to 10000 10 to 1000 10 to 1000 10 to 10000 10 to 10000 0 to 2000ms LOCAL V1 V2 I2 MDBUS COMMS PLC Pulse 0.0 to 200.0% 0.0 to 200.0% 0.0 to 200.0% 0.0 to 200.0% LOCAL V1 V2 I2 MDBUS COMMS PLC 0.00 to 400.00Hz 0.00 to 400.00Hz 100 to 5000% Flying Start1 Flying Start2 00 to 15 80 to 200% 0 to 9999 0 to 9999

10 to 10000 10 to 9999 1 to 200 1 to 200 0 to 32767 100 to 1000 100 to 10000 10 to 1000 10 to 1000 10 to 10000 10 to 10000 0 to 2000 0 2 4 5 6 8 9 12 0 to 2000 0 to 2000 0 to 2000 0 to 2000 0 2 4 5 6 7 8 0 to 40000 0 to 40000 100 to 5000 0 1 0 to 15 80 to 200 0 to 9999 0 to 9999

Decimal

Hexadecimal

Safe operation selection

44934

0h1346

71 RunDStp=Free RunDStp=Free Run

Safe operation stop

44935

0h1347

G3.72 / Ad.72

72 QStpT=5.0s

Q-Stop Time

44936

0h1348

G3.74 / Ad.74

74 RegAvdSel=N

Enable regeneration prevention

44938

0h134A

G3.75 / Ad.75

75 VlRegL=350V / 700V

Regeneration prevention level

44939

0h134B

G3.76 / Ad.76 G3.77 / Ad.77 G3.78 / Ad.78

76 CpFrL=1.00Hz 77 RegAvP=50.0% RegAvP=50.0% 78 RgAvI=50.0ms

Compare frequency limit P gain regeneration prevention I gain regeneration prevention

44940 44941 44942

0h134C 0h134D 0h134E

G3.80 / Ad.80

80 FireModSel=None FireModSel=None

Fire mode selection

44944

0h1350

G3.81 / Ad.81

81 FMdFr=60.00Hz FMdFr=60.00Hz

Fire mode frequency

44945

0h1351

G3.82 / Ad.82

82 FModD=Forward FModD=Forward

Fire mode direction

44946

0h1352

G4.4 / Cn.4

4 FREQ=2.0 / 3.0kHz

Modulation frequency

45124

0h1404

G4.5 / Cn.5

5 PWM=Normal PWM=Normal PWM

Modulation mode

45125

0h1405

G4.9 / Cn.9 G4.10 / Cn.10 G4.11 / Cn.11

9 PreExT=1.00s PreExT=1.00s 10 PreExF=100.0% PreExF=100.0% 11 PwofDl=0.00s PwofDl=0.00s

Pre-excitation time Pre-excitation time Power off delay

45129 45130 45131

0h1409 0h140A 0h140B

G4.20 / Cn.20

20 SL2GaViSel=N

Sensorless control gain 2

45140

0h1414

G4.21 / Cn.21 G4.22 / Cn.22

21 ASR P1=500% 22 ASR I1=300ms

45141 45142

G4.23 / Cn.23

23 ASR P2=120.0%

G4.24 / Cn.24 G4.25 / Cn.25 G4.26 / Cn.26 G4.27 / Cn.27 G4.28 / Cn.28 G4.29 / Cn.29 G4.30 / Cn.30 G4.31 / Cn.31 G4.32 / Cn.32 G4.48 / Cn.48 G4.49 / Cn.49 G4.52 / Cn.52

24 ASR I2=30.0% 25 ASR I1=300ms 26 P Flux=50% 27 I Flux=50% 28 SpEsP1=100 29 SpEsI1=500 30 SpEsI2=2000 31 ACR P2=500 32 ACR I2=500 48 ACR P1=1200 49 ACR I1=120 52 OuFVec=0ms

ASR proportional gain 1 ASR integral time 1 Independent controller prop. gain 2 Indep. controller integral gain 2 Integral time sensorless contr. Flux estimator proportional gain Flux estimator integral gain Speed estimator prop. gain 1 Speed estimator integral gain 1 Speed estimator integral gain 2 Sensorless cont. prop. gain Sensorless cont. integral gain Controller P gain Controller I gain Output filter vector

G4.53 / Cn.53

53 TqLimRef=LOCAL TqLimRef=LOCAL

G4.54 / Cn.54 G4.55 / Cn.55 G4.56 / Cn.56 G4.57 / Cn.57


SD300 SERIES


Screen

Description

G4.75 / Cn.75 G4.76 / Cn.76

75 SrchDly=1.0s 76 SpEsGa=100%

G4.77 / Cn.77


Hexadecimal

Speed search delay Speed estimator gain

45195 45196

0h144B 0h144C

77 KEB Sel=No

KEB Select

45197

0h144D

G4.78 / Cn.78

78 KEBStr=125.0% KEBStr=125.0%

Initial value for KEB operation

45198

0h144E

G4.79 / Cn.79

79 KEBStp=130.0% KEBStp=130.0%

Value to stop KEB operation

45199

0h144F

G4.80 / Cn.80 G4.81 / Cn.81 G4.85 / Cn.85 G4.86 / Cn.86 G4.87 / Cn.87 G4.88 / Cn.88 G4.89 / Cn.89 G4.90 / Cn.90 G4.91 / Cn.91 G4.92 / Cn.92 G4.93 / Cn.93 G4.94 / Cn.94 G4.95 / Cn.95

80 KEBPGn=10000 KEBPGn=10000 81 KEBIGn=500 85 FlxPrGa1=370 86 FlxPrGa2=0 87 FlxPrGa3=100 88 FlxInGa1=50 89 FlxInGa2=50 90 FlxInGa3=50 91 SLVoCmp1=20 SLVoCmp1=20 92 SLVoCmp2=20 SLVoCmp2=20 93 SLVoCmp3=20 SLVoCmp3=20 94 FWFrS=100.0% FWFrS=100.0% 95 FcFrS= 2.00Hz

KEB proportional gain KEB integral gain Flux proportional gain 1 Flux proportional gain 2 Flux proportional gain 3 Flux integral gain 1 Flux integral gain 2 Flux integral gain 3 SL voltage compensation 1 SL voltage compensation 2 SL voltage compensation 3 SL fluctuation frequency SL switching frequency

45200 45201 45205 45206 45207 45208 45209 45210 45211 45212 45213 45214 45215

0h1450 0h1451 0h1455 0h1456 0h1457 0h1458 0h1459 0h145A 0h145B 0h145C 0h145D 0h145E 0h145F

G5.1 / In.1

1 MxFA=[G1.20]/dr.20Hz MxFA=[G1.20]/dr.20Hz

Analog input max. freq

45377

0h1501

G5.2 / In.2 G5.5 / In.5

2 MaxTrq=100.0% 5 AnlgIN1=0.00V

Analog input max. torque V1 Monitor

45378 45381

0h1502 0h1505

G5.6 / In.6

6 An1PT=0-10V

V1 polarity

45382

0h1506

G5.7 / In.7 G5.8 / In.8 G5.9 / In.9 G5.10 / In.10 G5.11 / In.11 G5.12 / In.12 G5.13 / In.13 G5.14 / In.14 G5.15 / In.15

7 Ain1LP=10ms 8 A1MnV=0.00V 9 A1MnR=0.00% A1MnR=0.00% 10 An1MxV=10.00V 11 A1MxR=10.00% A1MxR=10.00% 12 A1NMn=-10.00V A1NMn=-10.00V 13 A1MnR=-10.00% A1MnR=-10.00% 14 A1MxV=-10.00V 15 A1Mx=-10.00%

V1 filter V1 minimum voltage V1 minimum reference V1 maximum voltage V1 maximum reference V1 minimum negative voltage V1 minimum negative reference V1 maximum negative voltage V1 maximum neg. reference

45383 45384 45385 45386 45387 45388 45389 45390 45391

0h1507 0h1508 0h1509 0h150A 0h150B 0h150C 0h150D 0h150E 0h150F

G5.16 / In.1

16 V1 Invert=N

V1 Inverting

45392

0h1510

G5.17 / In.17 G5.35 / In.35 G5.37 / In.37 G5.38 / In.38 G5.39 / In.39 G5.40 / In.40 G5.41 / In.41

17 A1DeLl=0.04% 35 AngIN2=0.00V 37 A2LPF=10ms 38 A2MnC=0.00V 39 A2MnR=0.00% 40 A2MxC=10.00V A2MxC=10.00V 41 A2MxR=100.00% A2MxR=100.00%

Adjust V1 quantification V2 Monitor V2 filter V2 minimum voltage V2 minimum reference V2 maximum voltage V2 maximum reference

45393 45411 45413 45414 45415 45416 45417

0h1511 0h1523 0h1525 0h1526 0h1527 0h1528 0h1529

G5.46 / In.46

46 V2 Invert=N

V2 Inverting

45422

0h152E

G5.47 / In.47 G5.50 / In.50 G5.52 / In.52 G5.53 / In.53 G5.54 / In.54 G5.55 / In.55 G5.56 / In.56

47 A2DeLl=0.04% 50 AnI2=0.00mA 52 AI2LF=10ms 53 A3MnC=4.00mA 54 A3MnR=0.00% 55 A2MxC=10.00mA A2MxC=10.00mA 56 A2MxR=100.00% A2MxR=100.00%

Adjust I2 visualization I2 Monitor I2 filter I2 minimum current I2 minimum reference I2 maximum current I2 maximum reference

45423 45426 45428 45429 45430 45431 45432

0h152F 0h1532 0h1534 0h1535 0h1536 0h1537 0h1538

G5.61 / In.61

61 I2 Invert=N

I2 Inverting

45437

0h153D

G5.62 / In.62

62 A2DeLl=0.04%

Adjust I2 visualization

45438

0h153E

G5.65 / In.65

65 DI1= START(+) START(+)

Digital input 1

45441

0h1541

G5.66 / In.66

66 DI2=START(-) DI2=START(-)

Digital input 2

45442

0h1542

Range

Modbus Range

0.0 to 60.0s 50 to 150% No KEB1 KEB2 110.0 to 200.0% [G4.78]/Cn.78 to 210.0% 1 to 20000 1 to 20000 100 to 700 0 to 100 0 to 500 0 to 200 0 to 200 0 to 200 0 to 60 0 to 60 0 to 60 80.0 to 110.0% 0.00 to 8.00Hz [G1.19] to [G1.20] (dr.19 to dr.20) 0.0 to 200.0 0.00 to 12.00% 0-10V -/+10V 0 to 10000ms 0.00 to 10.00V 0.00 to 100.00% 0.00 to 10.00V 0.00 to 100.00% -10.00 to 0.00V -100.00 to 0.00% -10.00 to 0.00V -100.00 to 0.00% NO YES 0.04 to 10.00% 0.00 to 12.00V 0 to 10000ms 0.00 to 10.00V 0.00 to 100.00% 0.00 to 10.00V 0.00 to 100.00% NO YES 0.04 to 10.00% 0.00 to 24.00mA 0 to 10000ms 0.00 to 20.00mA 0.00 to 100.00% 0.00 to 24.00mA 0.00 to 100.00 N Y 0.04 to 10.00%

0 to 600 50 to 150 0 1 2 1100 to 2000

None START(+) START(-) RESET EXT TRIP DIS START INCH 1 SPEED-L SPEED-M

[G4.78]/Cn.78 to 2100 1 to 20000 1 to 20000 100 to 700 0 to 100 0 to 500 0 to 200 0 to 200 0 to 200 0 to 60 0 to 60 0 to 60 800 to 1100 0 to 800 [G1.19] to [G1.20] (dr.19 to dr.20) 0 to 2000 0 to 1200 0 1 0 to 10000 0 to 1000 0 to 10000 0 to 1000 0 to 10000 -1000 to 0 -10000 to 0 -1000 to 0 -10000 to 0 0 1 4 to 1000 0 to 1200 0 to 10000 0 to 1000 0 to 10000 0 to 1000 0 to 10000 0 1 4 to 1000 0 to 2500 0 to 10000 0 to 2000 0 to 10000 0 to 1000 0 to 10000 0 1 4 to 1000 0 1 2 3 4 5 6 7 8


83

SD300 SERIES

Parameter

84

Screen



Hexadecimal

Range

Modbus Range 9 11 12 13 14 15 16 17 18 19 20 21 22 24 25 26 34 38 40 46 47 49 50 51 52 54 0 to 10000 0 to 10000

G5.67 / In.67

67 DI3=RESET DI3=RESET

Digital input 3

45443

0h1543

G5.68 / In.68

68 DI4=RESET DI4=RESET

Digital input 4

45444

0h1544

G5.69 / In.69

69 DI5=SPEED-L DI5=SPEED-L

Digital input 5

45445

0h1545

G5.70 / In.70

70 DI6=SPEED-M DI6=SPEED-M

Digital input 6

45446

0h1546

G5.71 / In.71

71 DI7=SPEED-H DI7=SPEED-H

Digital input 7

45447

0h1547

G5.85 / In.85 G5.86 / In.86

85 DIOnF=10ms 86 DIOfF=3ms

Digital input activation delay Digital input deactivation delay

45461 45462

0h1555 0h1556

G5.87 / In.87

87 DCTy=0000

Digital input contact type

45463

0h1557

G5.89 / In.89

89 DiScan=1ms

Di Scan Time

45465

0h1559

G5.90 / In.90

90 StDI=0000

Digital inputs status

45466

0h155A

G5.91 / In.91 G5.92 / In.92 G5.93 / In.93

91 TIPls=0.00kHz 92 TIFlt=400ms 93 TIMn=0.00kHz

45467 45468 45469

0h155B 0h155C 0h155D

G5.94 / In.94

94 TIMnR=0.00%

45470

0h155E

0.00 to 100.00%

0 to 10000

G5.95 / In.95

95 TIMx=32.00kHz

45471

0h155F

0.00 to 32.00kHz

0 to 3200

G5.96 / In.96

96 TIMxR=100.00% TIMxR=100.00%

TI Monitor TI Filter TI minimum input frequency TI minimum input frequency percentage TI maximum input frequency TI maximum input frequency percentage

SPEED-H XCEL-L XCEL-M RUN Enable 3-WIRE CTR/REF 2 Exchange UP DOWN RESERVED POT CLEAR AnalogHLD PIDOPLoop P Gain 2 XCEL Stop 2nd Motor Pre-Excit Timer IN disAuxRef. INCH(+) INCH(-) XCEL-H PLC Fire Mode KEB1 Sel TI 0 to 10000ms 0 to 10000ms 0: Contact normally open (NO) 1: Contact normally closed (NC) 1 to 5000ms 0: Disabled 1: Enabled 0.00 to 50.00kHz 0 to 9999 0.00 to 32.00kHz

45472

0h1560

0.00 to 100.00%

0 to 10000

G5.97 / In.97

97 TI Invert=N

TI Inverting

45473

0h1561

G5.98 / In.98

98 TIDeLl=0.04%

TI noise reduction level

45474

0h1562

G5.99 / In.99

99 IOSWST=00 IOSWST=00

Input mode setting

45475

0h1563

G6.1 / OU.1

1 AO1=Frequency

Analog output 1 mode selection

45633

0h1601

G6.2 / OU.2 G6.3 / OU.3 G6.4 / OU.4 G6.5 / OU.5 G6.6 / OU.6

2 AO1Ga=100.0% 3 AO1Ofs=0.0% 4 AO1Fil=5ms 5 AO1Con=0.0% AO1Con=0.0% 6 ANOUT1=0.0% ANOUT1=0.0%

Analog output 1 gain Analog output 1 offset Analog output 1 filter Analog output 1 constant Analog output 1 monitor

45634 45635 45636 45637 45638

0h1602 0h1603 0h1604 0h1605 0h1606

G6.30 / OU.30

30 OP FLT RLY=010

Relay fault output

45662

0h161E

NO YES 0.04 to 10.00% V2, NPN V2, PNP I2, NPN I2, PNP Frequency O/pCurr O/pVolt DCLinkV Torque O/pPower Idse Iqse TargetFq RampFreq Speed Fdb PIDRefVal PIDFdbVal PIDO/p Constant -1000.0 to 1000.0% -100.0 to 100.0% 0 to 10000ms 0.0 to 100.0% 0.0 to 1000.0% Low voltage Other than low voltage Automatic restart

0 1 4 to 1000 00 01 10 11 0 1 2 3 4 5 6 7 8 9 10 12 13 14 15 -10000 to 10000 -1000 to 1000 0 to 10000 0 to 1000 0 to 10000 001 010


0000 to 1111 1 to 5000 0000 to 1111 0 to 5000 0 to 9999 0 to 3200

100

SD300 SERIES


Screen

Description


Hexadecimal

Range

Modbus Range 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 22 28 29 31 34 35 36 37 38 39 40 0 to 3 0 to 10000 0 to 10000

G6.31 / OU.31

31 RLY1=Trip

Relay 1 control source

45663

0h161F

G6.33 / OU.33

33 DOP1=Run

Digital ouput 1 function

45665

0h1621

G6.41 / OU.41 G6.50 / OU.50

41 DO Sts=00 50 TRLON=0.00s

45673 45682

0h1629 0h1632

G6.51 / OU.51

51 TRLOF=0.00s

Digital ouputs status Digital output connection delay Digital output disconnection delay

None FDT-1 FDT-2 FDT-3 FDT-4 OverLoad IOL UndrLoad VentWarn Stall OverVolt LowVolt OverHeat Lost Command Run Stop Steady Inv. Line Comm Line Spd Srch Ready Timer Out Trip DBWarn%ED COMPARAT BRCtrl CAP Exch. FAN Exch. Fire Mode TO KEB Op. 00 to 11 0.00 to 100.00s

45683

0h1633

0.00 to 100.00s

G6.52 / OU.52

52 INV YES/NC=00 YES/NC=00

NC/NO Relays logic

45684

0h1634

0: Contact normally open (NO) 00 a 11 1: Contact normally closed (NC)

45685

0h1635

0.00 to 100.00s

0 to 10000

45686

0h1636

0.00 to 100.00s

0 to 10000

45687

0h1637

0.00 to 100.00s

0 to 10000

45688

0h1638

0.00 to 100.00s

0 to 10000

57 FDTLv=30.00Hz FDTLv=30.00Hz 58 FDTBd=10.00Hz FDTBd=10.00Hz

Digital output connection delay on fault Digital output disconnection delay on fault Digital output connection delay Digital output disconnection delay Relay FDT level Relay FDT band

45689 45690

0h1639 0h163A

G6.61 / OU.61

61 TOM=Frequency

Pulse output mode

45693

0h163D

G6.62 / OU.62 G6.63 / OU.63 G6.64 / OU.64 G6.65 / OU.65 G6.66 / OU.66 G7.1 / CM.1

62 TOGa=100.0% 63 TOOfs=0.0% 64 TOFil=5ms 65 TOCon=0.0% 66 TO=0.0% 1 Slave Addr=1

Pulse output gain Pulse output offset Pulse output filter Pulse output constant setting Pulse output monitor Slave address

45694 45695 45696 45697 45698 45889

0h163E 0h163F 0h1640 0h1641 0h1642 0h1701

G7.2 / CM.2

2 Prot=Modbus

RS-485 communication protocol

45890

0h1702

0.00 to [G1.20]/dr.20 0.00 to [G1.20]/dr.20 Frequency O/pCurr O/pVolt DCLinkV Torque O/pPower Idse Iqse TargetFq RampFreq Speed Fdb PIDRefVal PIDFdbVal PIDO/p Constant -1000.0 to 1000.0% -100.0 to 100.0% 0 to 10000ms 0.0 to 100.0% 0.0 to 1000.0% 1 to 250 Modbus PE BUS 485

0 to [G1.20]/dr.20 0 to [G1.20]/dr.20 0 1 2 3 4 5 6 7 8 9 10 12 13 14 15 -10000 to 10000 -1000 to 1000 0 to 10000 0 to 1000 0 to 10000 1 to 250 0 1

G6.53 / OU.53

53 TOnDl=0.00s

G6.54 / OU.54

54 TOfDl=0.00s

G6.55 / OU.55

55 TiOnD=0.00s

G6.56 / OU.56

56 TOfDl=0.00s

G6.57 / OU.57 G6.58 / OU.58


85

SD300 SERIES

Parameter

Screen



Hexadecimal

G7.3 / CM.3

3 BaudR=9600bps BaudR=9600bps

BaudRate

45891

0h1703

G7.4 / CM.4

4 Mode=D8/PN/S1 Mode=D8/PN/S1

Communication frame structure

45892

0h1704

G7.5 / CM.5

5 RespDly=5ms

45893

CM.6

-

0h1705 0h1706

CM.7 CM.8 CM.9 CM.30 CM.31 CM.32 CM.33 CM.34 CM.35 CM.36 CM.37 CM.38 CM.50 CM.51 CM.52 CM.53 CM.54 CM.55 CM.56 CM.57 CM.58

-

Response delay Communication option S/W version Communication option ID Card baud rate Comm. option LED status Output parameters number

CM.68

-

CM.70

-

0h1707 0h1708 0h1709 0h171E 0h171F 0h1720 0h1721 0h1722 0h1723 0h1724 0h1725 0h1726 0h1732 0h1733 0h1734 0h1735 0h1736 0h1737 0h1738 0h1739 0h173A

-

0h1744

-

-

0h1746

CM.71

-

-

0h1747

CM.72

-

-

0h1748

CM.73

-

-

0h1749

Output communication addresses 1 to 8

Number of input parameters

Input communication addresses 1 to 8

Field bus data swap

Communication multifunction input 1 to 7

86

CM.74

-

-

0h174A

CM.75

-

-

0h174B

CM.76

-

-

0h174C

CM.77

-

-

0h174D


Range

Modbus Range

1200 bps 2400 bps 4800 bps 9600 bps 19200 bps 38400 bps 56 Kbps 115 Kbps D8/PN/S1 D8/PN/S2 D8/PE/S1 D8/PO/S1 0 to 100.0 ms

0 1 2 3 4 5 6 7 0 1 2 3 0 to 1000

-

-

0 to 255 0 to 8

0 to 255 0 to 8

0000 to FFFF

0000 to FFFF

0 to 8

0 to 8

0000 to FFFF

0000 to FFFF

NO YES None START(+) START(-) RESET EXTTRIP DISSTART INCH1 SPEED-L SPEED-M SPEED-H XCEL-L XCEL-M RUNEnable 3-WIRE CTR/REF2 Exchange UP DOWN POTCLEAR AnalogHLD I-Term Clear PIDOPLoop PGain2 XCELStop 2ndMotor Pre-Excit TimerIN disAuxRef. INCH(+) INCH(-) XCEL-H PLC FireMode KEB1Sel TI

0 1 0 1 2 3 4 5 6 7 8 9 11 12 13 14 15 16 17 18 20 21 22 23 24 25 26 34 38 40 46 47 49 50 51 52 54

SD300 SERIES


Screen

Description

CM.86

-

CM.90

Modbus Address

Range

Modbus Range

0h1756

-

-

-

0h175A

Received data frames counter Frames with error counter NAK frames counter

-

0h175B 0h175C 0h175D

94 Actualizar comms=N

Communications update

-

-

CM.95

-

P2P communication selection

-

0h1760

CM.96

-

Digital output selection

-

-

G8.1 / AP.1

1 ApMod=Proc PID

Application function selection

46145

0h1801

G8.2 / AP.2

2 UsSeqEn=N

Enable PLC mode

-

-

G8.16 / AP.16 G8.17 / AP.17 G8.18 / AP.18 G8.19 / AP.19

16 PIDOut=+0.0% PIDOut=+0.0% 17 PIDRef=+50.00% PIDRef=+50.00% 18 PIDFdb=+0.00% PIDFdb=+0.00% 19 PIDLo=+50.00% PIDLo=+50.00%

PID output PID reference PID feedback PID local

46160 46161 46162 46163

0h1810 0h1811 0h1812 0h1813

G8.20 / AP.20

20 SELREF=MREF SELREF=MREF

Select PID regulator source

46164

0h1814

G8.21 / AP.21

21 SELFBK=V1 SELFBK=V1

Select feedback signal source

46165

0h1815

G8.22 / AP.22 G8.23 / AP.23 G8.24 / AP.24 G8.25 / AP.25 G8.26 / AP.26 G8.27 / AP.27

22 GANKp=+50.0% GANKp=+50.0% 23 INTEGRL=10.0s INTEGRL=10.0s 24 DIFFE=0ms 25 GAINF=+0.0% GAINF=+0.0% 26 PGaSca=100.0% PGaSca=100.0% 27 PIDFl=0ms

PID controller proportional gain PID controller integration time PID controller differential time PID output fine adjustment Proportional gain scale PID Filter

46166 46167 46168 46169 46170 46171

0h1816 0h1817 0h1818 0h1819 0h181A 0h181B

G8.28 / AP.28

28 PIDMd=Process PIDMd=Process

PID Mode

46172

0h181C

G8.29 / AP.29

29 MxSL=+60.00Hz MxSL=+60.00Hz

Upper limit PID output

46173

0h181D

G8.30 / AP.30

30 MnSL=-60.00Hz MnSL=-60.00Hz

Lower limit PID output

46174

0h181E

G8.31 / AP.31

31 INVERT PID=N

Invert PID

46175

0h181F

G8.32 / AP.32 G8.34 / AP.34 G8.35 / AP.35 G8.36 / AP.36 G8.37 / AP.37

32 OutSc=+100.00% OutSc=+100.00% 34 PPIDR=0.00Hz PPIDR=0.00Hz 35 PPIDE=0.0% PPIDE=0.0% 36 PPIDTim=600s PPIDTim=600s 37 LPTSlp=60.0s

PID output scale PrePID reference PrePID end reference PrePID delay Sleep mode activation delay

46176 46178 46179 46180 46181

0h1820 0h1822 0h1823 0h1824 0h1825

0 1 0 to 65535 0 to 65535 0 to 65535 0 1 0 1 2 3 001 010 100 0 2 0 1 32768 to 32768 32768 to 32768 32768 to 32768 10000 to 10000 0 1 3 4 5 7 8 11 0 2 3 4 6 7 10 0 to 10000 0 to 2000 0 to 10000 0 to 10000 0 to 1000 0 to 10000 0 1 [G8.30]/AP.30 to 30000 -30000 to [G8.29]/AP.29 0 1 1 to 10000 0 to 40000 0 to 1000 0 to 9999 0 to 9999

G8.38 / AP.38

38 SlpSp=0.00Hz

Sleep mode activation speed

46182

0h1826

G8.39 / AP.39

39 LPPon=+35%

Awakening level

46183

0h1827

G8.40 / AP.40

40 WkUPID=Below WkUPID=Below

PID WakeUp Mode

46184

0h1828

PE BUS 485 Rem. display 0 to 65535 0 to 65535 0 to 65535 NO YES Disable All P2P Master P2P Slave M-KPD Ready Analog output Multi function relay Multi funtion output None Proc PID N Y -327.68 to 327.68% -327.68 to 327.68% -327.68 to 327.68% -100.00 to 100.00% MREF V1 V2 I2 MODBUS COMMS PLC PULSE V1 V2 I2 MODBUS COMMS PLC PULSE 0.0 to 1000.0% 0 to 200.0s 0.0 to 10000ms 0.0 to 1000.0% 0.0 to 100.0% 0 to 10000ms Process Normal [G8.30]/AP.30 to 300.00Hz -300.00Hz to [G8.29]/AP.29 NO YES 0.1 to 1000.0% 0.00 to [G1.20]/dr.20 0.0 to 100.0% 0 to 9999s 0.0 to 999.9s 0.00Hz to [G1.20]/dr.20 0 to 100% Below Above Beyond

Decimal

Hexadecimal

Communication multifunction input monitoring

-

-

Data frame comm. monitor

CM.91 CM.92 CM.93

-

G7.94 / CM.94

0 to [G1.20]/dr.20 0 to 100 0 1 2


87

SD300 SERIES

Parameter

88

Screen



Hexadecimal

G8.42 / AP.42

42 PIDUn=%

PID unit

46186

0h182A

G8.43 / AP.43

43 PIDuG=100.00% PIDuG=100.00%

PID unit gain

46187

0h182B

G8.44 / AP.44

44 PIDUnSc=x1 PIDUnSc=x1

PID scale unit

46188

0h182C

G8.45 / AP.45

45 GaKp2=100.0% GaKp2=100.0%

Proportional gain

46189

0h182D

G9.4 / Pr.4

4 Load Duty=Hevy

Load duty type

46916

0h1B04

G9.5 / Pr.5

5 LSS PH=NONE PH=NONE

Phase loss type

46917

0h1B05

G9.6 / Pr.6 G9.7 / Pr.7

6 Ripple V=15V 7 FlDecT=3.0s

Ripple voltage Fault deceleration time

46918 46919

0h1B06 0h1B07

G9.8 / Pr.8

8 Str Aft Rst=N

Start after restart

46920

0h1B08

G9.9 / Pr.9 G9.10 / Pr.10

9 Retry Num=0 10 RetryDly=1.0s

Retry attempts number Retry delay

46921 46922

0h1B09 0h1B0A

G9.12 / Pr.12

12 RIRLs=None RIRLs=None

Response in case of a speed reference loss

46924

0h1B0C

G9.13 / Pr.13

13 RfLsDl=1.0s

Lost reference delay

46925

0h1B0D

G9.14 / Pr.14

14 RfLRf=0.00Hz

Reference for lost reference

46926

0h1B0E

G9.15 / Pr.15

15 AILL=Half

AI Lost Level

46928

0h1B10

G9.17 / Pr.17

17 OlWarnSel=YES OlWarnSel=YES

Overload warning select

46929

0h1B11

G9.18 / Pr.18 G9.19 / Pr.19

18 OLWrnL=+150% OLWrnL=+150% 19 OLWrnT=10.0s OLWrnT=10.0s

Overload warning level Overload warning time

46930 46931

0h1B12 0h1B13

G9.20 / Pr.20

20 OLTS=Freerun OLTS=Freerun

Overload trip select

46932

0h1B14

G9.21 / Pr.11 G9.22 / Pr.22

21 OLLevel=180% 22 OLTrpT=60.0s

Overload level Overload trip time

46933 46934

0h1B15 0h1B16

G9.25 / Pr.25

25 EnableUL=YES EnableUL=YES

Enable underload

46937

0h1B19

G9.26 / Pr.26

26 ULWnDl=10.0s

Underload warning delay

46938

0h1B1A

G9.27 / Pr.27

27 ULFM=None ULFM=None

Underload fault mode

46939

0h1B1B

G9.28 / Pr.28 G9.29 / Pr.29 G9.30 / Pr.30

28 ULFlDl=30.0 29 UlMnL=+30% 30 ULMxL=+30%

Underload fault delay Underload minimum level Underload maximum level

46940 46941 46942

0h1B1C 0h1B1D 0h1B1E

G9.31 / Pr.31

31 NoMD=None NoMD=None

Action in case no motor motor is detected

46943

0h1B1F

G9.32 / Pr.32 G9.33 / Pr.33

32 NoMtrLv=+5% 33 NoMtrDl=3.0s

No motor fault level No motor fault delay

46944 46945

0h1B20 0h1B21

G9.40 / Pr.40

40 ThMM=None

Action in case of thermothermoelectronic fault

46952

0h1B28

G9.41 / Pr.41

41 MTCOOL=SELF MTCOOL=SELF

Motor cooling mode at zero speed

46953

0h1B29


Range

Modbus Range

% Bar mBar Pa kPa Hz rpm V I kW HP °C ºF 0.00 to 300.00% x100 x10 x1 x 0.1 x 0.01 0.0 to 1000.0% NRML HEVY NONE OUTPUT INPUT ALL 1 to 100V 0.0 to 600.0s N Y 0 to 10 0.0 to 60.0s None Free-Run Dec Hold Input Hold Output Lost Preset 0.1 to 120.0s [G1.19] to [G1.20] (dr.19 to dr.20) Half Below NO YES 30 to 180% 0.0 to 30.0s None Free-Run Dec 30 to 200% 0.0 to 60.0s NO YES 0.0 to 600.0s None Free-Run Dec 0.0 to 600.0s 10 to 100% 10 to 100% None Free-Run Dec 1 to 100% 0.1 to 10.0s None Free-Run Dec SELF FORCED

0 1 2 3 4 5 6 7 8 9 10 11 12 0 to 30000 0 1 2 3 4 0 to 10000 0 1 0 1 2 3 1 to 100 0 to 6000 0 1 0 to 10 0 to 600 0 1 2 3 4 5 0 to 1200 [G1.19] to [G1.20] (dr.19 to dr.20) 0 1 0 1 30 to 180 0 to 300 0 1 2 30 to 200 0 to 600 0 1 0 to 6000 0 1 2 0 to 6000 10 to 100 10 to 100 0 1 2 1 to 100 1 to 100 0 1 2 0 1

SD300 SERIES


Screen

Description

G9.42 / Pr.42 G9.43 / Pr.43

42 ETH1min=150% ETH1min=150% 43 ETHcont=+120% ETHcont=+120%

G9.45 / Pr.45


Hexadecimal

Overcurrent level during 1min Continuous overcurrent level

46954 46955

0h1B2A 0h1B2B

45 BSMod=FreeRun BSMod=FreeRun

Free run trip mode

46957

0h1B2D

G9.50 / Pr.50

50 StallPR=00

Stall prevention

46962

0h1B32

G9.51 / Pr.51

51 StFr1=60Hz


46963

0h1B33

G9.52 / Pr.52

52 StlLev1=180%


46964

0h1B34

G9.53 / Pr.53

53 StFr2=60Hz


46965

0h1B35

G9.54 / Pr.54

54 StlLev2=180%


46966

0h1B36

G9.55 / Pr.55

55 StFr3=60Hz


46967

0h1B37

G9.56 / Pr.56

56 StlLev3=180%


46968

0h1B38

G9.57 / Pr.57

57 StFr4=60Hz


46969

0h1B39

G9.58 / Pr.58 G9.59 / Pr.59 G9.60 / Pr.60

58 StlLev4=180% 59 FB Kp=0% 60 CAPDgLV=0% CAPDgLV=0%

Level for stall protection 4 Flux braking gain CAP diagnosis level

46970 46971 46972

0h1B3A 0h1B3B 0h1B3C

G9.61 / Pr.61

61 CAPDg=+0% CAPDg=+0%

Capacitor diagnosis mode

46973

0h1B3D

G9.62 / Pr.62 G9.63 / Pr.63 G9.66 / Pr.66

62 CAPExLv=0% CAPExLv=0% 63 CAPDgL=0.0% CAPDgL=0.0% 66 DBWarnED=+0% DBWarnED=+0%

CAP exchange warning level Capacitance reference Braking resistor configuration

46974 46975 46978

0h1B3E 0h1B3F 0h1B42

G9.73 / Pr.73

73 SpdDev=N

Speed deviation fault

46946

0h1B22

G9.74 / Pr.74 G9.75 / Pr.75

74 SpdDevLv=50 75 SpdDevTi=60

Speed deviation band Speed deviation time

46947 46948

0h1B23 0h1B24

G9.79 / Pr.79

79 FANTrip=Warn FANTrip=Warn

Action in case of fan trip

46991

0h1B4F

G9.80 / Pr.80

80 TrpMd=FreeRun TrpMd=FreeRun

Optional card trip mode

46992

0h1B50

G9.81 / Pr.81

81 LVT Dly=0.0s

Low voltage trip delay

46993

0h1B51

G9.82 / Pr.82

82 LV2 On=YES

Enable low voltage trip

46994

0h1B52

G9.86 / Pr.86 G9.87 / Pr.87

86 FanTi=0% 87 FanELv=90.0%

Fan use percentage Fan exchange warning level

46998 46999

0h1B56 0h1B57

G9.88 / Pr.88

88 FanTiRst=N

Fan time reset

47000

0h1B58

G9.89 / Pr.89

89 CAP FAN St=0

CAP fan status

47001

0h1B59

G10.4 / M2.4 G10.5 / M2.5

4 AccTi=20.0s 5 DECEL=30.0s DECEL=30.0s

Motor 2 acceleration ramp Motor 2 deceleration ramp

47172 47173

0h1C04 0h1C05

G10.6 / M2.6

6 MTR2PWR=4.0kW MTR2PWR=4.0kW

Motor 2 rated power

47174

0h1C06

G10.7 / M2.7

7 MTRFRQ=60.00Hz MTRFRQ=60.00Hz

Motor 2 frequency

47175

0h1C07

G10.8 / M2.8

8 Ctr. T=V/Hz

Control type selection

47176

0h1C08

Range

Modbus Range

120 to 200% 50 to 150% FreeRun Dec Accelerating At constant speed At deceleration FluxBraking [G1.19] to [G9.53] (dr.19 to Pr.53) Hz 30 to 250% [G5.51] to [G9.55] (In.51 to Pr.55) Hz 30 to 250% [G5.53] to [G9.57] (In.53 to Pr.57) Hz 30 to 250% [G5.55] to [G1.20] (In.55 to dr.20) Hz 30 to 250% 0 to 150% 0 to 100% Nonde RefDiag PreDiag InitDiag 0.0 to 95.0% 0.0 to 100.0% 0 to 30% N Y 1 to 20 1 to 120 Trip Warn None Free-Run Dec 0.0 to 60.0s NO YES 0.0 to 100.0% 0.0 to 100.0% N Y None CAP warning FAN warning 0.0 to 600.0s 0.0 to 600.0s 0.2kW 0.4kW 0.75kW 1.1kW 1.5kW 2.2kW 3.0kW 3.7kW 4.0kW 5.5kW 7.5kW 11.0kW 15.0kW 18.5kW 22.0kW 30.0kW 30.00 to 400.00Hz V/Hz SlipCom S-less1

120 to 200 50 to 150 0 1 00 01 10 11 [G1.19] to [G9.53] (dr.19 to Pr.53) 30 to 250 [G5.51] to [G9.55] (In.51 to Pr.55) 30 to 250 [G5.53] to [G9.57] (In.53 to Pr.57) 30 to 250 [G5.55] to [G1.20] (In.55 to dr.20) 30 to 250 0 to 150 0 to 100 0 1 2 3 0 to 950 0 to 1000 0 to 30 0 1 1 to 20 1 to 120 0 1 0 1 2 0 to 600 0 1 0 to 1000 0 to 1000 0 1 00 01 10 0 to 6000 0 to 6000 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 3000 to 40000 0 2 4


89

SD300 SERIES

Parameter

90

Screen



Hexadecimal

G10.10 / M2.10

10 POLE Numbr=4

Poles number

47178

0h1C0A

G10.11 / M2.11 G10.12 / M2.12 G10.13 / M2.13 G10.14 / M2.14 G10.15 / M2.15 G10.16 / M2.16 G10.17 / M2.17 G10.18 / M2.18 G10.19 / M2.19 G10.20 / M2.20

11 RtSlp=64rpm 12 MTRCUR=8.6A MTRCUR=8.6A 13 NOLODC=3.1A NOLODC=3.1A 14 MTR VOLT=0V 15 EFFICIEN=+84% EFFICIEN=+84% 16 InertiaRate=0 17 Rs=138.8mΩ* 18 LSigma=1.244mH 19 Ls=16.45mH 20 Tr=228ms

Rated slip Motor nominal current No load current Motor 2 voltage Motor 2 efficiency Motor 2 inertia rate Stator resistor Leak inductor Stator inductor Rotor time constant

47179 47180 47181 47182 47183 47184 47185 47186 47187 47188

0h1C0B 0h1C0C 0h1C0D 0h1C0E 0h1C0F 0h1C10 0h1C11 0h1C12 0h1C13 0h1C14

G10.25 / M2.25

25 V/FPn=Linear

V/F pattern

47193

0h1C19

G10.26 / M2.26 G10.27 / M2.27 G10.28 / M2.28 G10.29 / M2.29 G10.30 / M2.30

26 FWBoost=+2.0% FWBoost=+2.0% 27 RVBoost=+2.0% RVBoost=+2.0% 28 StlLev1=150% 29 ETH1min=+150% ETH1min=+150% 30 ETHcont=+100% ETHcont=+100%

Torque in forward direction Torque in reverse direction Stall prevention level motor 2 Motor 2 overcurrent level 1 min Motor 2 continuous overcurrent

47194 47195 47196 47197 47198

0h1C1A 0h1C1B 0h1C1C 0h1C1D 0h1C1E

G11.1 / US.1

1 OpComm=Stop OpComm=Stop

PLC operation mode

47425

0h1D01

G11.2 / US.2

2 LoopTime=0.02s

PLC loop time

47426

0h1D02

G11.11 / US.11 G11.12 / US.12 G11.13 / US.13 G11.14 / US.14 G11.15 / US.15 G11.16 / US.16 G11.17 / US.17 G11.18 / US.18 G11.19 / US.19 G11.20 / US.20 G11.21 / US.21 G11.22 / US.22 G11.23 / US.23 G11.24 / US.24 G11.25 / US.25 G11.26 / US.26 G11.27 / US.27 G11.28 / US.28 G11.31 / US.31 G11.32 / US.32 G11.33 / US.33 G11.34 / US.34 G11.35 / US.35 G11.36 / US.36 G11.37 / US.37 G11.38 / US.38 G11.39 / US.39 G11.40 / US.40 G11.41 / US.41 G11.42 / US.42 G11.43 / US.43 G11.44 / US.44 G11.45 / US.45 G11.46 / US.46 G11.47 / US.47 G11.48 / US.48 G11.49 / US.49 G11.50 / US.50

11 LkOut1=0 12 LkOut2=0 13 LkOut3=0 14 LkOut4=0 15 LkOut5=0 16 LkOut6=0 17 LkOut7=0 18 LkOut8=0 19 LkOut9=0 20 LkOut10=0 21 LkOut11=0 22 LkOut12=0 23 LkOut13=0 24 LkOut14=0 25 LkOut15=0 26 LkOut16=0 27 LkOut17=0 28 LkOut18=0 31 UFInp1=0 32 UFInp2=0 33 UFInp3=0 34 UFInp4=0 35 UFInp5=0 36 UFInp6=0 37 UFInp7=0 38 UFInp8=0 39 UFInp9=0 40 UFInp10=0 41 UFInp11=0 42 UFInp12=0 43 UFInp13=0 44 UFInp14=0 45 UFInp15=0 46 UFInp16=0 47 UFInp17=0 48 UFInp18=0 49 UFInp19=0 50 UFInp20=0

Output link address PLC func. 1 Output link address PLC func. 2 Output link address PLC func. 3 Output link address PLC func. 4 Output link address PLC func. 5 Output link address PLC func. 6 Output link address PLC func. 7 Output link address PLC func. 8 Output link address PLC func. 9 Output link addr. PLC func. 10 Output link addr. PLC func. 11 Output link addr. PLC func. 12 Output link addr. PLC func. 13 Output link addr. PLC func. 14 Output link addr. PLC func. 15 Output link addr. PLC func. 16 Output link addr. PLC func. 17 Output link addr. PLC func. 18 PLC input value 1 PLC input value 2 PLC input value 3 PLC input value 4 PLC input value 5 PLC input value 6 PLC input value 7 PLC input value 8 PLC input value 9 PLC input value 10 PLC input value 11 PLC input value 12 PLC input value 13 PLC input value 14 PLC input value 15 PLC input value 16 PLC input value 17 PLC input value 18 PLC input value 19 PLC input value 20

47435 47436 47437 47438 47439 47440 47441 47442 47443 47444 47445 47446 47447 47448 47449 47450 47451 47452 47455 47456 47457 47458 47459 47460 47461 47462 47463 47464 47465 47466 47467 47468 47469 47470 47471 47472 47473 47475

0h1D0B 0h1D0C 0h1D0D 0h1D0E 0h1D0F 0h1D10 0h1D11 0h1D12 0h1D13 0h1D14 0h1D15 0h1D16 0h1D17 0h1D18 0h1D19 0h1D1A 0h1D1B 0h1D1C 0h1D1F 0h1D20 0h1D21 0h1D22 0h1D23 0h1D24 0h1D25 0h1D26 0h1D27 0h1D28 0h1D29 0h1D2A 0h1D2B 0h1D2C 0h1D2D 0h1D2E 0h1D2F 0h1D30 0h1D31 0h1D32


Range

Modbus Range

2 4 … 48 0 to 3000rpm 1.0 to 200.0A 0.5 to 200.0A 180 to 480V 70 to 100% 0 to 8

2 4 … 48 0 to 3000 10 to 2000 5 to 2000 180 to 480 70 to 100 0 to 8 0 to 9999 0 to 9999 0 to 9999 5000 0 1 2 3 0 to 150 0 to 150 30 to 150 100 to 200 50 to 150 0 1 2 0 1 2 3 4 5 0 to 65535 0 to 65535 0 to 65535 0 to 65535 0 to 65535 0 to 65535 0 to 65535 0 to 65535 0 to 65535 0 to 65535 0 to 65535 0 to 65535 0 to 65535 0 to 65535 0 to 65535 0 to 65535 0 to 65535 0 to 65535 -9999 to 9999 -9999 to 9999 -9999 to 9999 -9999 to 9999 -9999 to 9999 -9999 to 9999 -9999 to 9999 -9999 to 9999 -9999 to 9999 -9999 to 9999 -9999 to 9999 -9999 to 9999 -9999 to 9999 -9999 to 9999 -9999 to 9999 -9999 to 9999 -9999 to 9999 -9999 to 9999 -9999 to 9999 -9999 to 9999

Depend on motor setting 25 to 5000ms Linear Square V/F User Square2 0.0 to 15.0% 0.0 to 15.0% 30 to 150% 100 to 200% 50 to 150% Stop Run Run DI 0.01s 0.02s 0.05s 0.1s 0.5s 1s 0 to 65535 0 to 65535 0 to 65535 0 to 65535 0 to 65535 0 to 65535 0 to 65535 0 to 65535 0 to 65535 0 to 65535 0 to 65535 0 to 65535 0 to 65535 0 to 65535 0 to 65535 0 to 65535 0 to 65535 0 to 65535 -9999 to 9999 -9999 to 9999 -9999 to 9999 -9999 to 9999 -9999 to 9999 -9999 to 9999 -9999 to 9999 -9999 to 9999 -9999 to 9999 -9999 to 9999 -9999 to 9999 -9999 to 9999 -9999 to 9999 -9999 to 9999 -9999 to 9999 -9999 to 9999 -9999 to 9999 -9999 to 9999 -9999 to 9999 -9999 to 9999

SD300 SERIES


Screen

Description

G11.51 / US.51 G11.52 / US.52 G11.53 / US.53 G11.54 / US.54 G11.55 / US.55 G11.56 / US.56 G11.57 / US.58 G11.58 / US.58 G11.59 / US.59 G11.60 / US.60 G11.80 / US.80 G11.81 / US.81 G11.82 / US.82 G11.85 / US.85 G11.88 / US.88

51 UFInp21=0 52 UFInp22=0 53 UFInp23=0 54 UFInp24=0 55 UFInp25=0 56 UFInp26=0 57 UFInp27=0 58 UFInp28=0 59 UFInp29=0 60 UFInp30=0 80 InV1=0.000 81 InI1=+0.000 82 DIValue=0 85 AOVal=0.000 88 DOValue=0

G12.1 / UF.1

G12.2 / UF.2 G12.3 / UF.3 G12.4 / UF.4 G12.5 / UF.5 G12.6 / UF.6 G12.7 / UF.7 G12.8 / UF.8 G12.9 / UF.9 G12.10 / UF.10 G12.11 / UF.11 G12.12 / UF.12 G12.13 / UF.13 G12.14 / UF.14 G12.15 / UF.15 G12.16 / UF.16 G12.17 / UF.17 G12.18 / UF.18 G12.19 / UF.19 G12.20 / UF.20 G12.21 / UF.21 G12.22 / UF.22 G12.23 / UF.23 G12.24 / UF.24 G12.25 / UF.25 G12.26 / UF.26 G12.27 / UF.27 G12.28 / UF.28


Hexadecimal

PLC input value 21 PLC input value 22 PLC input value 23 PLC input value 24 PLC input value 25 PLC input value 26 PLC input value 27 PLC input value 28 PLC input value 29 PLC input value 30 Analogue input V1 value Analogue input I2 value Digital inputs value Analogue output value Digital output value

47475 47476 47477 47478 47479 47480 47481 47482 47483 47484 47504 47505 47506 47509 47512

0h1D33 0h1D34 0h1D35 0h1D36 0h1D37 0h1D38 0h1D39 0h1D3A 0h1D3B 0h1D3C 0h1D50 0h1D51 0h1D52 0h1D55 0h1D58

1 Func1=NOP

PLC function 1

47681

0h1E01

2 Inpt1A=0 3 Inpt1B=0 4 Inpt1C=0 5 Outp1=+0 6 Func2=NOP 7 Inpt2A=0 8 Inpt2B=0 9 Inpt2C=0 10 Outp2=+0 11 Func3=NOP 12 Inpt3A=0 13 Inpt3B=0 14 Inpt3C=0 15 Outp3=+0 16 Func4=NOP 17 Inpt4A=0 18 Inpt4B=0 19 Inpt4C=0 20 Outp4=+0 21 Func5=NOP 22 Inpt5A=0 23 Inpt5B=0 24 Inpt5C=0 25 Outp5=+0 26 Func6=NOP 27 Inpt6A=0 28 Inpt6B=0

Input A for PLC function 1 Input B for PLC function 1 Input C for PLC function 1 Output PLC function 1 PLC function 2 Input A for PLC function 2 Input B for PLC function 2 Input C for PLC function 2 Output PLC function 2 PLC function 3 Input A for PLC function 3 Input B for PLC function 3 Input C for PLC function 3 Output PLC function 3 PLC function 4 Input A for PLC function 4 Input B for PLC function 4 Input C for PLC function 4 Output PLC function 4 PLC function 5 Input A for PLC function 5 Input B for PLC function 5 Input C for PLC function 5 Output PLC function 5 PLC function 6 Input A for PLC function 6 Input B for PLC function 6

47682 47683 47684 47685 47686 47687 47688 47689 47690 47691 47692 47693 47694 47695 47696 47697 47698 47699 47700 47701 47702 47703 47704 47705 47706 47707 47708

0h1E02 0h1E03 0h1E04 0h1E05 0h1E06 0h1E07 0h1E08 0h1E09 0h1E0A 0h1E0B 0h1E0C 0h1E0D 0h1E0E 0h1E0F 0h1E10 0h1E11 0h1E12 0h1E13 0h1E14 0h1E15 0h1E16 0h1E17 0h1E18 0h1E19 0h1E1A 0h1E1B 0h1E1C

Range

Modbus Range

-9999 to 9999 -9999 to 9999 -9999 to 9999 -9999 to 9999 -9999 to 9999 -9999 to 9999 -9999 to 9999 -9999 to 9999 -9999 to 9999 -9999 to 9999 0 to 12.000% -12.000 to 12.000% 0 to 127 0.000 to 10.000% 0 to 3 NOP ADD SUB ADDSUB MIN MAX ABS NEGATE MPYDIV REMAINDER COMPARE-GT COMPARE-GEQ COMPARE-EQUAL COMPARE-NEQUAL TIMER LIMIT AND OR XOR ANDOR SWITCH BITTEST BITSET BITCLEAR LOWPASSFILTER PI_CONTORL PI_PROCESS UPCOUNT DOWNCOUNT 0 to 65535 0 to 65535 0 to 65535 -32767 to 32767 See G12.1 / UF.1 See G12.2 / UF.2 See G12.3 / UF.3 See G12.4 / UF.4 See G12.5 / UF.5 See G12.1 / UF.1 See G12.2 / UF.2 See G12.3 / UF.3 See G12.4 / UF.4 See G12.5 / UF.5 See G12.1 / UF.1 See G12.2 / UF.2 See G12.3 / UF.3 See G12.4 / UF.4 See G12.5 / UF.5 See G12.1 / UF.1 See G12.2 / UF.2 See G12.3 / UF.3 See G12.4 / UF.4 See G12.5 / UF.5 See G12.1 / UF.1 See G12.2 / UF.2 See G12.3 / UF.3

-9999 to 9999 -9999 to 9999 -9999 to 9999 -9999 to 9999 -9999 to 9999 -9999 to 9999 -9999 to 9999 -9999 to 9999 -9999 to 9999 -9999 to 9999 0 to 12000 -12000 to 12000 0 to 127 0 to 10000 0 to 3 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 0 to 65535 0 to 65535 0 to 65535 -32767 to 32767 See G12.1 / UF.1 See G12.2 / UF.2 See G12.3 / UF.3 See G12.4 / UF.4 See G12.5 / UF.5 See G12.1 / UF.1 See G12.2 / UF.2 See G12.3 / UF.3 See G12.4 / UF.4 See G12.5 / UF.5 See G12.1 / UF.1 See G12.2 / UF.2 See G12.3 / UF.3 See G12.4 / UF.4 See G12.5 / UF.5 See G12.1 / UF.1 See G12.2 / UF.2 See G12.3 / UF.3 See G12.4 / UF.4 See G12.5 / UF.5 See G12.1 / UF.1 See G12.2 / UF.2 See G12.3 / UF.3


91

SD300 SERIES

92

POWER ELECTRONICS

Parameter

Screen

Description

G12.29 / UF.29 G12.30 / UF.30 G12.31 / UF.31 G12.32 / UF.32 G12.33 / UF.33 G12.34 / UF.34 G12.35 / UF.35 G12.36 / UF.36 G12.37 / UF.37 G12.38 / UF.38 G12.39 / UF.39 G12.40 / UF.40 G12.41 / UF.41 G12.42 / UF.42 G12.43 / UF.43 G12.44 / UF.44 G12.45 / UF.45 G12.46 / UF.46 G12.47 / UF.47 G12.48 / UF.48 G12.49 / UF.49 G12.50 / UF.50 G12.51 / UF.51 G12.52 / UF.52 G12.53 / UF.53 G12.54 / UF.54 G12.55 / UF.55 G12.56 / UF.56 G12.57 / UF.57 G12.58 / UF.58 G12.59 / UF.59 G12.60 / UF.60 G12.61 / UF.61 G12.62 / UF.62 G12.63 / UF.63 G12.64 / UF.64 G12.65 / UF.65 G12.66 / UF.66 G12.67 / UF.67 G12.68 / UF.68 G12.69 / UF.69 G12.70 / UF.70 G12.71 / UF.71 G12.72 / UF.72 G12.73 / UF.73 G12.74 / UF.74 G12.75 / UF.75 G12.76 / UF.76 G12.77 / UF.77 G12.78 / UF.78 G12.79 / UF.79 G12.80 / UF.80 G12.81 / UF.81 G12.82 / UF.82 G12.83 / UF.83 G12.84 / UF.84 G12.85 / UF.85 G12.86 / UF.86 G12.87 / UF.87 G12.88 / UF.88 G12.89 / UF.89 G12.90 / UF.90

29 Inpt6C=0 30 Outp6=+0 31 Func7=NOP 32 Inpt7A=0 33 Inpt7B=0 34 Inpt7C=0 35 Outp7=+0 36 Func8=NOP 37 Inpt8A=0 38 Inpt8B=0 39 Inpt8C=0 40 Outp8=+0 41 Func9=NOP 42 Inpt9A=0 43 Inpt9B=0 44 Inpt9C=0 45 Outp9=+0 46 Func10=NOP 47 Inpt10A=0 48 Inpt10B=0 49 Inpt10C=0 50 Outp10=+0 51 Func11=NOP 52 Inpt11A=0 53 Inpt11B=0 54 Inpt11C=0 55 Outp11=+0 56 Func12=NOP 57 Inpt12A=0 58 Inpt12B=0 59 Inpt12C=0 60 Outp12=+0 61 Func13=NOP 62 Inpt13A=0 63 Inpt13B=0 64 Inpt13C=0 65 Outp13=+0 66 Func14=NOP 67 Inpt14A=0 68 Inpt14B=0 69 Inpt14C=0 70 Outp14=+0 71 Func15=NOP 72 Inpt15A=0 73 Inpt15B=0 74 Inpt15C=0 75 Outp15=+0 76 Func16=NOP 77 Inpt16A=0 78 Inpt16B=0 79 Inpt16C=0 80 Outp16=+0 81 Func17=NOP 82 Inpt17A=0 83 Inpt17B=0 84 Inpt17C=0 85 Outp17=+0 86 Func18=NOP 87 Inpt18A=0 88 Inpt18B=0 89 Inpt18C=0 90 Outp18=+0

Input C for PLC function 6 Output PLC function 6 PLC function 7 Input A for PLC function 7 Input B for PLC function 7 Input C for PLC function 7 Output PLC function 7 PLC function 8 Input A for PLC function 8 Input B for PLC function 8 Input C for PLC function 8 Output PLC function 8 PLC function 9 Input A for PLC function 9 Input B for PLC function 9 Input C for PLC function 9 Output PLC function 9 PLC function 10 Input A for PLC function 10 Input B for PLC function 10 Input C for PLC function 10 Output PLC function 10 PLC function 11 Input A for PLC function 11 Input B for PLC function 11 Input C for PLC function 11 Output PLC function 11 PLC function 12 Input A for PLC function 12 Input B for PLC function 12 Input C for PLC function 12 Output PLC function 12 PLC function 13 Input A for PLC function 13 Input B for PLC function 13 Input C for PLC function 13 Output PLC function 13 PLC function 14 Input A for PLC function 14 Input B for PLC function 14 Input C for PLC function 14 Output PLC function 14 PLC function 15 Input A for PLC function 15 Input B for PLC function 15 Input C for PLC function 15 Output PLC function 15 PLC function 16 Input A for PLC function 16 Input B for PLC function 16 Input C for PLC function 16 Output PLC function 16 PLC function 17 Input A for PLC function 17 Input B for PLC function 17 Input C for PLC function 17 Output PLC function 17 PLC function 18 Input A for PLC function 18 Input B for PLC function 18 Input C for PLC function 18 Output PLC function 18



Hexadecimal

47709 47710 47711 47712 47713 47714 47715 47716 47717 47718 47719 47720 47721 47722 47723 47724 47725 47726 47727 47728 47729 47730 47731 47732 47733 47734 47735 47736 47737 47738 47739 47740 47741 47742 47743 47744 47745 47746 47747 47748 47749 47750 47751 47752 47753 47754 47755 47756 47757 47758 47759 47760 47761 47762 47763 47764 47765 47766 47767 47768 47769 47770

0h1E1D 0h1E1E 0h1E1F 0h1E20 0h1E21 0h1E22 0h1E23 0h1E24 0h1E25 0h1E26 0h1E27 0h1E28 0h1E29 0h1E2A 0h1E2B 0h1E2C 0h1E2D 0h1E2E 0h1E2F 0h1E30 0h1E31 0h1E32 0h1E33 0h1E34 0h1E35 0h1E36 0h1E37 0h1E38 0h1E39 0h1E3A 0h1E3B 0h1E3C 0h1E3D 0h1E3E 0h1E3F 0h1E40 0h1E41 0h1E42 0h1E43 0h1E44 0h1E45 0h1E46 0h1E47 0h1E48 0h1E49 0h1E4A 0h1E4B 0h1E4C 0h1E4D 0h1E4E 0h1E4F 0h1E50 0h1E51 0h1E52 0h1E53 0h1E54 0h1E55 0h1E56 0h1E57 0h1E58 0h1E59 0h1E5A

Range

Modbus Range

See G12.4 / UF.4 See G12.5 / UF.5 See G12.1 / UF.1 See G12.2 / UF.2 See G12.3 / UF.3 See G12.4 / UF.4 See G12.5 / UF.5 See G12.1 / UF.1 See G12.2 / UF.2 See G12.3 / UF.3 See G12.4 / UF.4 See G12.5 / UF.5 See G12.1 / UF.1 See G12.2 / UF.2 See G12.3 / UF.3 See G12.4 / UF.4 See G12.5 / UF.5 See G12.1 / UF.1 See G12.2 / UF.2 See G12.3 / UF.3 See G12.4 / UF.4 See G12.5 / UF.5 See G12.1 / UF.1 See G12.2 / UF.2 See G12.3 / UF.3 See G12.4 / UF.4 See G12.5 / UF.5 See G12.1 / UF.1 See G12.2 / UF.2 See G12.3 / UF.3 See G12.4 / UF.4 See G12.5 / UF.5 See G12.1 / UF.1 See G12.2 / UF.2 See G12.3 / UF.3 See G12.4 / UF.4 See G12.5 / UF.5 See G12.1 / UF.1 See G12.2 / UF.2 See G12.3 / UF.3 See G12.4 / UF.4 See G12.5 / UF.5 See G12.1 / UF.1 See G12.2 / UF.2 See G12.3 / UF.3 See G12.4 / UF.4 See G12.5 / UF.5 See G12.1 / UF.1 See G12.2 / UF.2 See G12.3 / UF.3 See G12.4 / UF.4 See G12.5 / UF.5 See G12.1 / UF.1 See G12.2 / UF.2 See G12.3 / UF.3 See G12.4 / UF.4 See G12.5 / UF.5 See G12.1 / UF.1 See G12.2 / UF.2 See G12.3 / UF.3 See G12.4 / UF.4 See G12.5 / UF.5

See G12.4 / UF.4 See G12.5 / UF.5 See G12.1 / UF.1 See G12.2 / UF.2 See G12.3 / UF.3 See G12.4 / UF.4 See G12.5 / UF.5 See G12.1 / UF.1 See G12.2 / UF.2 See G12.3 / UF.3 See G12.4 / UF.4 See G12.5 / UF.5 See G12.1 / UF.1 See G12.2 / UF.2 See G12.3 / UF.3 See G12.4 / UF.4 See G12.5 / UF.5 See G12.1 / UF.1 See G12.2 / UF.2 See G12.3 / UF.3 See G12.4 / UF.4 See G12.5 / UF.5 See G12.1 / UF.1 See G12.2 / UF.2 See G12.3 / UF.3 See G12.4 / UF.4 See G12.5 / UF.5 See G12.1 / UF.1 See G12.2 / UF.2 See G12.3 / UF.3 See G12.4 / UF.4 See G12.5 / UF.5 See G12.1 / UF.1 See G12.2 / UF.2 See G12.3 / UF.3 See G12.4 / UF.4 See G12.5 / UF.5 See G12.1 / UF.1 See G12.2 / UF.2 See G12.3 / UF.3 See G12.4 / UF.4 See G12.5 / UF.5 See G12.1 / UF.1 See G12.2 / UF.2 See G12.3 / UF.3 See G12.4 / UF.4 See G12.5 / UF.5 See G12.1 / UF.1 See G12.2 / UF.2 See G12.3 / UF.3 See G12.4 / UF.4 See G12.5 / UF.5 See G12.1 / UF.1 See G12.2 / UF.2 See G12.3 / UF.3 See G12.4 / UF.4 See G12.5 / UF.5 See G12.1 / UF.1 See G12.2 / UF.2 See G12.3 / UF.3 See G12.4 / UF.4 See G12.5 / UF.5

SD300 SERIES

POWER ELECTRONICS

6.4.6. Visualization Parameters Visualization parameters slightly differ depending on the display that is being used (integrated or removable). Modbus

Parameter Screen

Description

SV1.1

Mtr Iout=0.0

Current running through the motor.

SV1.2

Mtr Freq= 0.00Hz

Motor frequency

SV1.3

Mtr Sp= 0rpm

SV1.4

Mtr FBSp=+0rpm

SV1.5

Mtr Vout=0V

Motor speed in rpm Motor encoder speed (only shown if an encoder board has been installed). Motor voltage

SV1.6

Mtr Pow = 0.00kW

Motor instantaneous power consumption

SV1.7

Mtr Torq = 0.0%

Applied torque to the motor.

SV2.1

Bus vol = 528V

DC voltage measured in the drive bus.

SV2.2

Temperature = 27ºC

Internal temperature of the drive.

SV3.1

ANLG IN V1 = +0.00V

Voltage analog input 1 mean value.

SV3.2

ANLG IN V2 = +0.00V

Voltage analog input 2 mean value.

SV3.3

ANLG IN I2 = +0.00mA Current analog input 2 mean value.

SV3.4

DigI= 0000000

Activation or rest status of the Digital Inputs.

SV3.5

ANL OUT1 = 0.0%

SV3.6

DOstatus= 0-00

SV4.1

Inv.Power

SV4.2

Inv. S/W

SV4.3

SW Disp

SV5.1

S=0.0% F=0.0%

SV5.2

PID Out=+0.00%

Analog output 1 value Status of the digital outputs in the following order: SD-Relay2 Relay1. Drive power in kW. Latest software version installed in the drive Ex. 0xE6 = v2.30. Latest software version installed in the display. PID set point value of the analog PID (left) and the sensor value that sends the feedback signal (right). PID Output.

SV6.1

Operating time

Total runtime in days and minutes.

Address

Modbus Range

Decimal

Hexadecimal

40784 40785 40786

0h0310 0h0311 0h0312

Real value = (Modbus value / 10)

40787

0h0313

Real value = Modbus value

40788 40790 40791 40789 44099 45381 45411 45426 40016 45638

0h0314 0h0316 0h0317 0h0315 0h1003 0h1505 0h1523 0h1532 0h0010 0h1606


40017

0h0011


40001

0h0001


40771

0h0303


-

-

S: 40792 F: 40793

Real value = (Modbus value / 100) Real value = Modbus value

Real value = (Modbus value / 100) Real value = (Modbus value / 10) Real value = Modbus value Real value = Modbus value Real value = (Modbus value / 100) Real value = (Modbus value / 100) Real value = (Modbus value / 100) Real value = Modbus value Real value = (Modbus value / 10)

-

C: 0h0318 Real value = (Modbus value / 10) R: 0h0319

46160 0h1810 Real value = (Modbus value / 100) Days: 40832 Days: 0h0340 Real value = Modbus value Min.: 40833 Min.: 0h0341 MWh: Real value = Modbus value

SV6.2

Consumed Energy

Total consumed energy, in MWh and kWh.

MWh: 40815 MWh: 0h032F kWh: Real value = (Modbus value / kWh: 40814 kWh: 0h032E 10)

In the case of the integrated display, there is a specific group of parameters which summarize data when a warning or fault occurs. These are: Parameter Description Pr.90 Pr.91 Pr.92 Pr.93 Pr.94 Pr.95 Pr.96

Warning information Fifth fault Fourth fault Third fault Second fault First fault Delete fault history


Hexadecimal

47003 47004 47005 46917 46918 46919 46920

0h1B5A 0h1B5B 0h1B5C 0h1B04 0h1B05 0h1B06 0h1B07

Modbus Range

See fault descriptions and codes in sections 3.2.1, 5.9, and at the beginning of this section (6.5.2).

0 to 1


93

SD300 SERIES

POWER ELECTRONICS

7. CONFIGURATION REGISTER VARIABLE SPEED DRIVE: SERIAL Nº: APPLICATION: DATE: CUSTOMER: NOTES:

PARAMETER 1 LCLSP=0.00Hz

DEFAULT VALUE 0.00Hz

2 LclTQ=0.0%

0.0%

3 ACC1=20.0s

20.0s

4 DECEL1=30.0s

30.0s

6 CONTROLMODE1=REMOTE CONTROLMODE1=REMOTE

REMOTE

7 REF1 SP= LOCAL

LOCAL

8 REF1 TQ= LOCAL

LOCAL

9 Ctr.T=V/Hz

94

SD300. MODEL:

V/Hz

10 Torq CTRL=N

N

11 InchF=10.00Hz

10.00Hz

12 InchAcT=20.0s

20.0s

13 InchDeT=30.0s

30.0s

SETTING 1

SETTING 2

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

G1 (dr): Drive

SD300 SERIES

POWER ELECTRONICS PARAMETER

DEFAULT VALUE

14 MTRPWR= (*)

_._kW

15 TqBoost=Manual

Manual

16 FWBoost=2.0%

2.0%

17 RVBoost=2.0%

2.0%

18MTRFRQ=60.00Hz

60.00Hz

19 STRFRQ=0.5Hz

0.5Hz

20 MxSpL=60.00Hz MxSpL=60.00Hz

60.00Hz

21 Hz/Rpm=Hz 80 SelRngEnt=Run Freq.

Hz Run Freq.

81 SelCod=Volt V

Volt V

89 DspChng=All

All

90 ESC Func= Mov. In. Pos.

Mov. In. Pos.

91 Eloader=None

None

93 INITIALIS=No

No

94 PswRg=0

0

95 PrmLock=0

0

97 SoftVer=0

0

98 IOSwVer=0

0

99 IOHwVer=0

0

SETTING 1

SETTING 2

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

G2 (bA): Basic Functions 1 REF2 SP=None

None

2 AuxCalcType=M+(G*A) AuxCalcType=M+(G*A)

M+(G*A)

3 AuxRfG=100.0%

100.0%

4 CONTROLMODE2=REMOTE CONTROLMODE2=REMOTE

REMOTE

5 REF2 SP=LOCAL

LOCAL

6 REF2 TQ= LOCAL

LOCAL

7 V/FPn=Linear

Linear

8 RmpT= MaxFreq

MaxFreq

9 TimScl=0.1s

0.1s

10 I/P Freq=60Hz

60Hz

11 POLE Numbr=4 12 RtSlp=40rpm

4 40rpm

13 MTRCUR=3.6A

3.6A

14 NOLODC=1.6A

1.6A

* This value depends on the motor setting

CONFIGURATION REGISTER

95

SD300 SERIES PARAMETER

DEFAULT VALUE

15 MTR VOLT=0V

0V

16 EFFICIEN=72%

72%

17 InertiaRate=0 18 TrimPwr%=100% TrimPwr%=100% 19 ACi/Volt=220V / 380V 20 AutoTuning=None AutoTuning=None 21 Rs=0 (*)

0 100% 220V220 440V380 None 0

22 LSigma=0mH

__mH

23 Ls=0mH

__mH

24 Tr=145ms

145ms

25 Ls Scl=100%

100%

26 Tr Scl=100%

100%

31 LsR Scl=80%

80%

41 UsFq1=15.00Hz 42 User V1=25% 43 UsFq2=30.00Hz 44 User V2=50% 45 UsFq3=45.00Hz 46 User I2=75% 47 UsFrq4=0.00Hz 48 User V4=0%

96

POWER ELECTRONICS

15.00Hz 25% 30.00Hz 50% 45.00Hz 75% 0.00Hz 0%

50 MREF1=10.00%

10.00%

51 MREF2=20.00%

20.00%

52 MREF3=30.00%

30.00%

53 MREF4=40.00%

40.00%

54 MREF5=50.00%

50.00%

55 MREF6=60.00%

60.00%

56 MREF7=60.00%

60.00%

70 ACC2=20.0s

20.0s

71 DEC2=30.0s

30.0s

72 ACC3=20.0s

20.0s

73 DEC3=30.0s

30.0s

74 ACC4=20.0s

20.0s

75 DEC4=30.0s

30.0s

SETTING 1

SETTING 2

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

SD300 SERIES


DEFAULT VALUE

76 ACC5=20.0s

20.0s

77 DEC5=30.0s

30.0s

78 ACC6=20.0s

20.0s

79 DEC6=30.0s

30.0s

80 ACC7=20.0s

20.0s

81 DEC7=30.0s

30.0s

82 ACC8=20.0s

20.0s

83 DEC8=30.0s

30.0s

SETTING 1

SETTING 2

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

___________ ___________________ ________

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

G3 (Ad): Expanded Functions 1 AccPn=Linear

Linear

2 DecPn=Linear

Linear

3 AccSSrt=40%

40%

4 AccSEnd=40%

40%

5 DecSSrt=40%

40%

6 DecSEnd=40%

40%

7 START=RAMP

RAMP

8 STOP=RAMP

RAMP

9 FWR/RV=None

None

10 Run Aft VlF=N

N

12 DCSt T=0.00s

0.00s

13 DC Curr=50%

50%

14 PreDCT=0.10s

0.10s

15 DCBrkT=1.00s

1.00s

16 DCBkCur=50%

50%

17 DCBkF=5.00Hz

5.00Hz

20 AcDF=5.00Hz

5.00Hz

21 AccDWT=0.0s

0.0s

22 DeDF=5.00Hz

5.00Hz

23 DecDWT=0.0s

0.0s

24 UseFrqLimit=N

N

25 FLtLo=0.50Hz

0.50Hz

26 FLtHi=[G1.20]/dr.20Hz FLtHi=[G1.20]/dr.20Hz 27 Jump Freq=N

[G1.20]/dr.20Hz N

28 JmpL1=10.00Hz

10.00Hz

29 JmpH1=15.00Hz

15.00Hz


97


POWER ELECTRONICS DEFAULT VALUE

30 JmpL2=20.00Hz

20.00Hz

31 JmpH2=25.00Hz

25.00Hz

32 JmpL3=30.00Hz

30.00Hz

33 JmpH3=35.00Hz

35.00Hz

41 RlsCur=50.0%

50.0%

42 RlsDly=1.00s

1.00s

44 FwdFq=1.00Hz

1.00Hz

45 RevFq=1.00Hz

1.00Hz

46 BEngDly=1.00s

1.00s

47 BEngF=2.00Hz

2.00Hz

50 FLX MIN=NONE

NONE

51 FluxLVEL=0%

0%

60 XclCF=0.00Hz

0.00Hz

64 FAN=During Run

During Run

65 SaveMot Frq=N

N

66 SLCOM=None

None

67 ScON=90.00%

90.00%

68 SC OF=10.00%

10.00%

70 RunEMod=Always Enable 71 RunDStp=Free Run 72 QStpT=5.0s

Always Enable Free Run 5.0s

74 RegAvdSel=N

N

75 VlRegL=700V

700V

76 CpFrL=1.00Hz

1.00Hz

77 RegAvP=50.0%

50.0%

78 RgAvI=50.0ms

50.0ms

80 FireModSel=None FireModSel=None

None

81 FMdFr=60.00Hz

60.00Hz

82 FModD=Forward FModD=Forward

Forward

SETTING 1

SETTING 2

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

G4 (Cn): Control Functions 4 FREQ=2.0 / 3.0kHz

2.0 / 3.0kHz

5 PWM=Normal PWM

Normal PWM

9 PreExT=1.00s 10 PreExF=100.0% 11 PwofDl=0.00s

98

1.00s 100.0% 0.00s

SD300 SERIES


DEFAULT VALUE

20 SL2GaViSel=N

N

21 ASR P1=500%

___%

22 ASR I1=300ms

___ms

23 ASR P2=120.0%

___._%

24 ASR I2=30.0%

___._%

25 ASR I1=300ms

___ms

26 P Flux=50%

__%

27 I Flux=50%

__%

28 SpEsP1=100

___

29 SpEsI1=500

___

30 SpEsI2=2000

___

31 ACR P2=500

___

32 ACR I2=500

___

48 ACR P1=1200

1200

49 ACR I1=120

120

52 OuFVec=0ms

0ms

53 TqLimRef=LOCAL

LOCAL

54 TLpsFW=180.0%

180.0%

55 TLngFW=180.0% TLngFW=180.0%

180.0%

56 TLpsRV=180.0%

180.0%

57 TLngRV=180.0%

180.0%

62 SpLiRf=LOCAL

LOCAL

63 SpL(+)=50.00Hz

50.00Hz

64 SpL(-)=50.00Hz

50.00Hz

65 SpLGa=500% 70 SSMode=Flying Start1

500% Flying Start1

71 Srch Mod=0000

0000

72 Srch I=150%

150%

73 Kp Srch=100/600

100/600

74 Ki Srch=100/600

100/600

75 SrchDly=1.0s

1.0s

76 SpEsGa=100%

100%

77 KEB Sel=No 78 KEBStr=125.0%

No 125.0%

SETTING 1

SETTING 2

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______


99



79 KEBStp=130.0%

130.0%

80 KEBPGn=10000

10000

81 KEBIGn=500

500

85 FlxPrGa1=370

370

86 FlxPrGa2=0

0

87 FlxPrGa3=100

100

88 FlxInGa1=50

50

89 FlxInGa2=50

50

90 FlxInGa3=50 91 SLVoCmp1=20 92 SLVoCmp2=20

SETTING 1

SETTING 2

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

___ ___ ___

93 SLVoCmp3=20

20

94 FWFrS=100.0%

100.0%

95 FcFrS= 2.00Hz

2.00Hz

G5 (In): Inputs 1 MxFA=[G1.20]/dr.20Hz MxFA=[G1.20]/dr.20Hz

[G1.20]/dr.20Hz

2 MaxTrq=100.0%

100.0%

5 AnlgIN1=0.00V

0.00V

6 An1PT=0-10V

0-10V

7 Ain1LP=10ms

10ms

8 A1MnV=0.00V

0.00V

9 A1MnR=0.00%

0.00%

10 An1MxV=10.00V

10.00V

11 A1MxR=10.00%

10.00%

12 A1NMn=-10.00V

-10.00V

13 A1MnR=-10.00%

-10.00%

14 A1MxV=-10.00V

-10.00V

15 A1Mx=-10.00%

-10.00%

16 V1 Invert=N

N

17 A1DeLl=0.04%

0.04%

35 AngIN2=0.00V

0.00V

37 A2LPF=10ms

10ms

38 A2MnC=0.00V

0.00V

39 A2MnR=0.00%

0.00%

40 A2MxC=10.00V

10.00V

100

SD300 SERIES

POWER ELECTRONICS PARAMETER 41 A2MxR=100.00% 46 V2 Invert=N

DEFAULT VALUE 100.00% N

47 A2DeLl=0.04%

0.04%

50 AnI2=0.00mA

0.00mA

52 AI2LF=10ms

10ms

53 A3MnC=4.00mA

4.00mA

54 A3MnR=0.00%

0.00%

55 A2MxC=10.00mA

10.00mA

56 A2MxR=100.00%

100.00%

61 I2 Invert=N

N

62 A2DeLl=0.04%

0.04%

65 DI1=START(+)

1

66 DI2= START(-)

2

67 DI3=RESET

3

68 DI4=RESET

3

69 DI5=SPEED-L

7

70 DI6=SPEED-M

8

71 DI7=SPEED-H

9

85 DIOnF=10ms

10ms

86 DIOfF=3ms

3ms

87 DCTy=0000

0000

89 DiScan=1ms

1ms

90 StDI=0000

0000

91 TIPls=0.00kHz

0.00kHz

92 TIFlt=400ms

400ms

93 TIMn=0.00kHz

0.00kHz

94 TIMnR=0.00%

0.00%

95 TIMx=32.00kHz

32.00kHz

96 TIMxR=100.00%

100.00%

97 TI Invert=N 98 TIDeLl=0.04% 99 IOSWST=0.0Bit IOSWST=0.0Bit

N 0.04% 00

SETTING 1

SETTING 2

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

G6 (OU): Outputs 1 AO1=Frequency AO1=Frequency

Frequency

2 AO1Ga=100.0%

100.0%


101

SD300 SERIES

POWER ELECTRONICS

PARAMETER

DEFAULT VALUE

3 AO1Ofs=0.0%

0.0%

4 AO1Fil=5ms

5ms

5 AO1Con=0.0%

0.0%

6 ANOUT1=0.0%

0.0%

30 OP FLT RLY=010

010

31 RLY1=Trip

Trip

33 DOP1=Run

Run

41 DO Sts=00

00

50 TRLON=0.00s

0.00s

51 TRLOF=0.00s

0.00s

52 INV YES/NC=00

00

53 TOnDl=0.00s

0.00s

54 TOfDl=0.00s

0.00s

55 TiOnD=0.00s

0.00s

56 TOfDl=0.00s

0.00s

57 FDTLv=30.00Hz

30.00Hz

58 FDTBd=10.00Hz

10.00Hz

61 TOM=Frequency

Frequency

62 TOGa=100.0%

100.0%

63 TOOfs=0.0%

0.0%

64 TOFil=5ms

5ms

65 TOCon=0.0%

0.0%

66 TO=0.0%

0.0%

SETTING 1

SETTING 2

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

G7 (CM): Communications 1 Slave Addr=1

1

2 Prot=Modbus

Modbus

3 BaudR=9600bps

9600bps

4 Mode=D8/PN/S1

D8/PN/S1

5 RespDly=5ms

5ms

CM.6

0.00

CM.7

1

CM.8

12Mbps

CM.9

-

CM.30

3

CM.31

000A

102

______________ ___________________ _____

_____________ ___________________ ______

______________ ___________________ _____

_____________ ___________________ ______

______________ ___________________ _____

_____________ ___________________ ______

______________ ___________________ _____

_____________ ___________________ ______

______________ ___________________ _____

_____________ ___________________ ______

______________ ___________________ _____

_____________ ___________________ ______

SD300 SERIES


DEFAULT VALUE

CM.32

000E

CM.33

000F

CM.34

0000

CM.35

0000

CM.36

0000

CM.37

0000

CM.38

0000

CM.50

2

CM.51

0005

CM.52

0006

CM.53

0000

CM.54

0000

CM.55

0000

CM.56

0000

CM.57

0000

CM.58

0000

CM.68

0

CM.70

None

CM.71

None

CM.72

None

CM.73

None

CM.74

None

CM.75

None

CM.76

None

CM.77

None

CM.86

0

CM.90

0

CM.91

0

CM.92

0

CM.93

0

94 ActualCom=N

NO

CM.95

Disable all

CM.96

0

SETTING 1

SETTING 2

______________ ___________________ _____

_____________ ___________________ ______

______________ ___________________ _____

_____________ ___________________ ______

______________ ___________________ _____

_____________ ___________________ ______

______________ ___________________ _____

_____________ ___________________ ______

______________ ___________________ _____

_____________ ___________________ ______

______________ ___________________ _____

_____________ ___________________ ______

______________ ___________________ _____

_____________ ___________________ ______

______________ ___________________ _____

_____________ ___________________ ______

______________ ___________________ _____

_____________ ___________________ ______

______________ ___________________ _____

_____________ ___________________ ______

______________ ___________________ _____

_____________ ___________________ ______

______________ ___________________ _____

_____________ ___________________ ______

______________ ___________________ _____

_____________ ___________________ ______

______________ ___________________ _____

_____________ ___________________ ______

______________ ___________________ _____

_____________ ___________________ ______

______________ ___________________ _____

_____________ ___________________ ______

______________ ___________________ _____

_____________ ___________________ ______

______________ ___________________ _____

_____________ ___________________ ______

______________ ___________________ _____

_____________ ___________________ ______

______________ ___________________ _____

_____________ ___________________ ______

______________ ___________________ _____

_____________ ___________________ ______

______________ ___________________ _____

_____________ ___________________ ______

______________ ___________________ _____

_____________ ___________________ ______

______________ ___________________ _____

_____________ ___________________ ______

______________ ___________________ _____

_____________ ___________________ ______

______________ ___________________ _____

_____________ ___________________ ______

______________ ___________________ _____

_____________ ___________________ ______

______________ ___________________ _____

_____________ ___________________ ______

______________ ___________________ _____

_____________ ___________________ ______

______________ ___________________ _____

_____________ ___________________ ______

______________ ___________________ _____

_____________ ___________________ ______

______________ ___________________ _____

_____________ ___________________ ______

______________ ___________________ _____

_____________ ___________________ ______

G8 (AP): PID 1 ApMod=Proc PID

Proc PID

_____________ ___________________ ______

____________ ___________________ _______


103

SD300 SERIES

POWER ELECTRONICS

PARAMETER

DEFAULT VALUE

2 UsSeqEn=N

N

16 PIDOut=+0.0%

+0.0%

17 PIDRef=+50.00%

+50.00%

18 PIDFdb=+0.00%

+0.00%

19 PIDLo=+50.00%

+50.00%

20 SELREF=MREF SELREF=MREF

MREF

21 SELFBK=V1

V1

22 GANKp=+50.00%

+50.00%

23 INTEGRL=10.0ms INTEGRL=10.0ms

10.0ms

24 DIFFE=0ms

0ms

25 GAINF=+0.0%

+0.0%

26 PGaSca=100.0%

100.0%

27 PIDFl=0ms

0ms

28 PIDMd=Process

Process

29 MxSL=+60.00Hz

+60.00Hz

30 MnSL=-60.00Hz

-60.00Hz

31 INVERT PID=N

N

32 OutSc=+100.00% 34 PPIDR=0.00Hz

+100.00% 0.00Hz

35 PPIDE=0.0%

0.0%

36 PPIDTim=600s

600s

37 LPTSlp=60.0s

60.0s

38 SlpSp=0.00Hz

0.00Hz

39 LPPon=+35%

+35%

40 WkUPID=Below

Below

42 PIDUn=% 43 PIDuG=100.00% 44 PIDUnSc=x1 45 GaKp2=100.0%

% 100.00% x1 100.0%

SETTING 1

SETTING 2

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

___________ ___________________ ________

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

G9 (Pr): Protections 4 Load Duty=Hevy

Hevy

5 LSS PH=NONE

NONE

6 Ripple V=15V

15V

7 FlDecT=3.0s

3.0s

8 Str Aft Rst=N

N

104

SD300 SERIES


DEFAULT VALUE

9 Retry Num=0

0

10 RetryDly=1.0s

1.0s

12 RIRLs=None

None

13 RfLsDl=1.0s

1.0s

14 RfLRf=0.00Hz

0.00Hz

15 AILL=Half

Half

17 OlWarnSel=YES

YES

18 OLWrnL=+150% OLWrnL=+150%

+150%

19 OLWrnT=10.0s OLWrnT=10.0s

10.0s

20 OLTS=Freerun OLTS=Freerun

Freerun

21 OLLevel=180%

180%

22 OLTrpT=60.0s OLTrpT=60.0s

60.0s

25 EnableUL=YES

YES

26 ULWnDl=10.0s

10.0s

27 ULFM=None

None

28 ULFlDl=30.0

30.0

29 UlMnL=+30%

+30%

30 ULMxL=+30%

+30%

31 NoMD=None

None

32 NoMtrLv=+5%

+5%

33 NoMtrDl=3.0s

3.0s

40 ThMM=None

None

41 MTCOOL=SELF

SELF

42 ETH1min=150%

150%

43 ETHcont=+120%

+120%

45 BSMod=FreeRun

FreeRun

50 StallPR=00

00

51 StFr1=60Hz

60Hz

52 StlLev1=180%

180%

53 StFr2=60Hz

60Hz

54 StlLev2=180%

180%

55 StFr3=60Hz

60Hz

56 StlLev3=180%

180%

57 StFr4=60Hz

60Hz

SETTING 1

SETTING 2

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

___________ ___________________ ________

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______


105

SD300 SERIES PARAMETER 58 StlLev4=180%

POWER ELECTRONICS DEFAULT VALUE 180%

59 FB Kp=0%

0%

60 CAPDgLV=0%

0%

61 CAPDg=+0%

+0%

62 CAPExLv=0%

0%

63 CAPDgL=0.0%

0.0%

66 DBWarnED=+0% DB WarnED=+0%

+0%

73 SpdDev=N

N

74 SpdDevLv=50

50

75 SpdDevTi=60

60

79 FANTrip=Warn

Warn

80 TrpMd=FreeRun TrpMd=FreeRun

FreeRun

81 LVT Dly=0.0s

0.0s

82 LV2 On=YES

YES

86 FanTi=0%

0%

87 FanELv=90.0%

90.0%

88 FanTiRst=N

N

89 CAP FAN St=0

0

SETTING 1

SETTING 2

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

G10 (M2): Second Motor 4 AccTi=20.0s

20.0s

5 DECEL=30.0s

30.0s

6 MTR2PWR=4.0kW

4.0kW

7 MTRFRQ=60.00Hz

60.00Hz

8 Ctr. T=V/Hz

V/Hz

10 POLE Numbr=4

__

11 RtSlp=64rpm

__rpm

12 MTRCUR=8.6A

_._A

13 NOLODC=3.1A

_._A

14 MTR VOLT=0V

__V

15 EFFICIEN=+84%

___%

16 InertiaRate=0

__

17 Rs=138.8mΩ

___mΩ

18 LSigma=1.244m

_.___m

19 Ls=16.45mH 20 Tr=228ms

106

__.__mH ___ms

SD300 SERIES


DEFAULT VALUE

25 V/FPn=Linear

Linear

26 FWBoost=+2.0%

+2.0%

27 RVBoost=+2.0%

+2.0%

28 StlLev1=150%

150%

29 ETH1min=+150%

+150%

30 ETHcont=+100%

+100%

SETTING 1

SETTING 2

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

G11 (US): PLC Sequence 1 OpComm=Stop OpComm=Stop

Stop

2 LoopTime=0.02s LoopTime=0.02s

0.02s

11 LkOut1=0

0

12 LkOut2=0

0

13 LkOut3=0

0

14 LkOut4=0

0

15 LkOut5=0

0

16 LkOut6=0

0

17 LkOut7=0

0

18 LkOut8=0

0

19 LkOut9=0

0

20 LkOut10=0

0

21 LkOut11=0

0

22 LkOut12=0

0

23 LkOut13=0

0

24 LkOut14=0

0

25 LkOut15=0

0

26 LkOut16=0

0

27 LkOut17=0

0

28 LkOut18=0

0

31 UFInp1=0

0

32 UFInp2=0

0

33 UFInp3=0

0

34 UFInp4=0 35 UFInp5=0 36 UFInp6=0 37 UFInp7=0 38 UFInp8=0

0 0 0 0 0


107

SD300 SERIES PARAMETER 39 UFInp9=0 40 UFInp10=0 41 UFInp11=0 42 UFInp12=0


44 UFInp14=0

48 UFInp18=0 49 UFInp19=0 50 UFInp20=0 51 UFInp21=0 52 UFInp22=0 53 UFInp23=0 54 UFInp24=0

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

___________ ___________________ ________

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

0 0 0 0 0 0 0 0

56 UFInp26=0

0

59 UFInp29=0

____________ ___________________ _______

0

55 UFInp25=0

58 UFInp28=0

_____________ ___________________ ______

0

0

57 UFInp27=0

____________ ___________________ _______

0

0

47 UFInp17=0

_____________ ___________________ ______ 0

43 UFInp13=0

46 UFInp16=0

SETTING 2

0

0

45 UFInp15=0

SETTING 1

0

0 0 0

60 UFInp30=0

0

80 InV1=0.000

0.000

81 InI1=+0.000

+0.000

82 DIValue=0

0

85 AOVal=

-

88 DOValue=0

0

G12 (UF): PLC Function 1 Func1=NOP

NOP

2 Inpt1A=0

0

3 Inpt1B=0

0

4 Inpt1C=0

0

5 Outp1=+0

+0

6 Func2=NOP 7 Inpt2A=0

108

NOP 0

SD300 SERIES


DEFAULT VALUE

8 Inpt2B=0

0

9 Inpt2C=0

0

10 Outp2=+0

+0

11 Func3=NOP

NOP

12 Inpt3A=0

0

13 Inpt3B=0

0

14 Inpt3C=0

0

15 Outp3=+0

+0

16 Func4=NOP

NOP

17 Inpt4A=0

0

18 Inpt4B=0

0

19 Inpt4C=0

0

20 Outp4=+0

+0

21 Func5=NOP

NOP

22 Inpt5A=0

0

23 Inpt5B=0

0

24 Inpt5C=0

0

25 Outp5=+0

+0

26 Func6=NOP

NOP

27 Inpt6A=0

0

28 Inpt6B=0

0

29 Inpt6C=0

0

30 Outp6=+0

+0

31 Func7=NOP

NOP

32 Inpt7A=0

0

33 Inpt7B=0

0

34 Inpt7C=0

0

35 Outp7=+0

+0

36 Func8=NOP

NOP

37 Inpt8A=0

0

38 Inpt8B=0

0

39 Inpt8C=0

0

40 Outp8=+0

+0

41 Func9=NOP

NOP

SETTING 1

SETTING 2

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

___________ ___________________ ________

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______


109



42 Inpt9A=0

0

43 Inpt9B=0

0

44 Inpt9C=0

0

45 Outp9=+0

+0

46 Func10=NOP

NOP

47 Inpt10A=0

0

48 Inpt10B=0

0

49 Inpt10C=0

0

50 Outp10=+0

+0

51 Func11=NOP

NOP

52 Inpt11A=0

0

53 Inpt11B=0

0

54 Inpt11C=0

0

55 Outp11=+0

+0

56 Func12=NOP

NOP

57 Inpt12A=0

0

58 Inpt12B=0

0

59 Inpt12C=0

0

60 Outp12=+0

+0

61 Func13=NOP

NOP

62 Inpt13A=0

0

63 Inpt13B=0

0

64 Inpt13C=0

0

65 Outp13=+0

+0

66 Func14=NOP

NOP

67 Inpt14A=0

0

68 Inpt14B=0

0

69 Inpt14C=0

0

70 Outp14=+0

+0

71 Func15=NOP

NOP

72 Inpt15A=0

0

73 Inpt15B=0

0

74 Inpt15C=0

0

75 Outp15=+0

+0

110

SETTING 1

SETTING 2

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

SD300 SERIES


DEFAULT VALUE

76 Func16=NOP

NOP

77 Inpt16A=0

0

78 Inpt16B=0

0

79 Inpt16C=0

0

80 Outp16=+0

+0

81 Func17=NOP

NOP

82 Inpt17A=0

0

83 Inpt17B=0

0

84 Inpt17C=0

0

85 Outp17=+0

+0

86 Func18=NOP

NOP

87 Inpt18A=0

0

88 Inpt18B=0

0

89 Inpt18C=0

0

90 Outp18=+0

+0

SETTING 1

SETTING 2

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______

_____________ ___________________ ______

____________ ___________________ _______


111

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C/ Leonardo da Vinci, 24 – 26 • Parque Tecnológico • 46980 – PATERNA • VALENCIA • ESPAÑA Tel. 902 40 20 70 (Spain) • Tel. (+34) (+34) 96 136 65 57 • Fax (+34) 96 131 131 82 01 BRANCHES BARCELONA • Avda. de la Ferrería, 86-88 • 08110 • MONTCADA I REIXAC Tel. (+34) 96 136 65 57 • Fax (+34) 93 564 47 52 CATALONIA LLEIDA • C/ Terrasa, 13 · Bajo • 25005 • LLEIDA Tel. (+34) 97 372 59 52 • Fax (+34) 97 372 59 52 CANARY LAS PALMAS • C/ Juan de la Cierva, 4 • 35200 • TELDE ISLANDS Tel. (+34) 928 68 26 47 • Fax (+34) 928 68 26 47 CASTEL L N • C/ Juan Bautista Poeta • 2º Piso · Puerta 4 • 12006 • CASTELLÓN LEVANTE NORTH CENTRE SOUTH

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Tel. (+34) 96 136 65 57 MURCIA • Pol. Residencial Santa Ana • Avda. Venecia, 17 • 30319 • CARTAGENA Tel. (+34) 96 853 51 94 • Fax (+34) 96 812 66 23 VIZCAYA • Parque de Actividades Empresariales Asuarán • Edificio Asúa, 1º B • Ctra. Bilbao – Plencia • 48950 • ERANDIO • Tel. (+34) 96 136 65 57 • Fax (+34) 94 431 79 08 MADRID • Avda. Rey Juan Carlos I, 98, 4º C • 28916 • LEGANÉS Tel. (+34) 96 136 65 57 • Fax (+34) 91 687 53 84 SEVILLA • C/Arquitectura, Bloque 6 • Planta 5ª • Módulo 2 • Parque Empresarial Nuevo Torneo • 41015 • SEVILLA • Tel. (+34) 95 451 57 73 • Fax (+34) 95 451 57 73 INTERNATIONAL SUBSIDIARIES Power Electroni Electroni cs Australia Pty Ltd • U6, 30-34 Octal St, Yatala, - Brisbane, Q ueensland 4207 • P.O. Box 3166, Browns Plains, Queensland 4118 Tel. (+61) 7 3386 1993 • Fax (+61) 7 3386 1993 Email: [email protected] Power Electronics Brazil Ltda • Domo Business - Rua José Versolato, 111 Conjunto 1509 –

Torre B - Centro São Bernardo do Campo - SP - Brasil CEP 09750-730 - Tel. (+55) 11 5891 9612 • Tel. (+55) 11 5891 9762 •Email: [email protected] Alonso de Córdova nº 5870, Oficina 210-211 • Las Condes - Santiago de Chile Tel. (+56) 2 3223 8916 • Email: [email protected] [email protected].. Technical assistance: Tel. (+56) 9 9096 9466 • Email: [email protected] Power Electronics Beijing • No 28 East Road Beisanhuan • 100013, Chaoyang District • Beijing

• R.P. CHINA • Tel. (+86 10) 6437 9197 • Fax (+86 10) 6437 9181 Power Electroni Electroni cs Asia Ltd • 20/F Winbase Centre • 208 Queen’s Road Central • HONG KONG • R.P. CHINA • Email: [email protected] Terminal Terrestre de Carga, Autopista vía Medellín KM 3.5 Costado Sur, Bodega 60, Sector Cota, COLOMBIA Bogotá • Tel. (+57) 322 3464855 • Email: [email protected] Bibiliotèque Nationale 2 104 Avenue de France 75013 Paris, France Telf. +33(0)1 46 46 10 34 FRANCE Ext. 1034. Email: [email protected] Power Electronics Deutschland GmbH • Neuseser Strasse 15 - 90455 Nürnberg GERMANY Tel: (+49) 911 99 43 99 0 • Fax: (+49) 911 99 43 99 8 • Email: [email protected] Power Electronics Asia HQ Co Co • 953-1 •Dokok-dong, Gangnam-gu - 135-270 - Seoul • KOREA Email: [email protected] Power Electronics India • Nº5, Cunningham Crescent, 1st floor. Bangalore- 560052 INDIA Tel: +91 80 6569 0489• Email: [email protected] Power Electronics Italia Srl • Via Paracelso 16, Palazzo Andromeda 1, Centro Direzionale ITALY Colleoni - 20864 Agrate Brianza – Monza Brianza • Tel. +39. 039.9050 899 • Email: [email protected] Power Electronics Japan KK • Japan, 2-7-5, Toranomon, Minato-ku, Tokyo, Japan, 105-0001 JAPAN Burex Toranomon Building 3rd • Tel. 03-6206-1145 • Fax 03 -6206-1175 P.E. Internacional Mexico S de RL • Calz. Jinetes #197 - Las Arboledas - Atizapan de Zaragoza • 52950, Estado de México • Tel. (+52) 55 5390 8818 • Tel. (+52) 55 5390 8363 • MEXICO Email: [email protected] Power Electronics – Ekoakua • Geea sarl N°184 Blo c Hay EL.Massira Aït Melloul • 80150 • Agadir • Morocco • Tel: +212 528 24 04 57 • Mob: (+34) 628 11 11 76 72 MOROCCO Email: [email protected] Power Electronics New Zealand Zealand Ltd • 12A Opawa Road, Waltham • Christchurch 8023 • P.O. NEW Box 1269 Christchurch 8140 • Tel. (+64 3) 379 98 26 • Fax. (+64 3) 379 98 27 • ZEALAND Email: [email protected] Power Electronics South Africa Pty Ltd • Central Office Park Unit 5 • 257 Jean Avenue • SOUTH Centurion 0157 • Tel. (+34) 96 136 65 57 • Fax (+34) 96 131 82 01: AFRICA Email: [email protected] Stora Varvsgatan 13a, 211 75 Malmö • Tel. 040-35 86 00 • Fax 040-93 23 01 • SWEDEN Email: [email protected] PERPA Ticaret Merkezi A Blok Kat:2 No:9/0034 34384 Okmeydani Sisli • Istanbul • Tel. 0 212 221 TURKEY 48 48 (124) • Fax.0 212 221 17 00 • Email: [email protected] UNITED ARAB P.O. Box 487282, 33rd Floor, HDS Business Centre, Plot M1 Jumeirah Lakes Tower, Dubai, EMIRATES U.A.E. Email: [email protected] UNITED Power Electroni Electroni cs Corp UK Ltd • Unit 2, Madingley Court, Chippenham Drive, Kingston, Milton Keynes, MK10 0BZ Tel. (+44) 149 437 0029 • Email: [email protected] KINGDOM UNITED Power Electronics USA Inc. • 4777 N 44th Ave • Phoenix• AZ 85031 • USA • STATES Tel: 602-354-4890 • Fax: (415) 874 -3001 • Email: [email protected]

CHINA

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