ATAE Cluster System V200R002C10
Hardware Quick Installation Guide Issue: 03 Date: 2015-03-20
About This Document This document provides guidelines for onsite installation of hardware devices and cables. This helps hardware installation engineers to search f or installation procedures quickly. quickly. This document describes how to install the components that are not installed before delivery, including the AT ATAE boards, disk arrays, ar rays, and primary power supply. supply. For details about how to install the components that are installed before delivery and optional components, see the AT ATAE Cluster System Hardware Hardware Installation Guide. Guide. After the installation is complete, power on the components in sequence by referring to Powering On the System in A in AT TAE Cluster System Product Product Documentation. Documentation.
Installation Tools
Measuring Measurin g Tape Tape
Socket wrench
Phillips Screwdriver
Flat-head Screwdriver
Torque wrench wren ch
Wire stripper
RJ45 crimping tool
Multimeter
Network cable tester
Crimping tool
Hydraulic pliers
Diagonal pliers
Wire clippers
Utility knife
1
Adjustable wrench wrench
ESD gloves
Copyright © Huawei Technologies Co., Ltd. 2015. All rights reserved.
Installation Process This document applies to the following scenario: Initial deployment: You deploy OSS products or components provided by Huawei after initially establishing the ATAE cluster system.
For details about how to install hardware for new deployment or capacity expansion, see AT A TAE Cluster System Hardware Hardware Installation Guide. No.
Installation Procedure
Reference
1
Installation Preparations
AT ATAE Cluster System System Hardware Installation Guide
2
Installing Cabinets
See the N68E Cabinet Installation Guide delivered with the cabinet.
3
Installing Power Cables and PGND Cables of a Cabinet
P3-P5
4
Installing Internal Components of a Cabinet
P6-P12
5
Installing Power Cables and PGND Cables of the Internal Components of a Cabinet
P13-P18
6
Installing Signal Cables Cables
P19-P42
7
Checking the Installation
P43-P45
8
Appendix
P46-P48
XY in label in following description is a random number generated at delivery. delivery. You You need to select the cabinet, subrack, board, disk array, and cables with the same random number for onsite installation. For example, in a cabinet having the label AB-MPR II-1, the labels of the main storage subrack (MSS), main processing subrack (MPS) and the board in slot 1 are ABMSS-1-2, AB-MPS-1-5 and AB-MPS-1-5-1. The following figures provide cable connections when devices are fully configured in the cabinet. If devices in the cabinet are not fully configured in actual situations, connect only the actually configured devices and ignore the connections for unconfigured devices. Check the locations of the actually configured devices and labels before connecting the cables. See the appendix (P46-P48) to learn the positions of the ports on the disk array and boards when you connect signal cables.
2
Installation Process This document applies to the following scenario: Initial deployment: You deploy OSS products or components provided by Huawei after initially establishing the ATAE cluster system.
For details about how to install hardware for new deployment or capacity expansion, see AT A TAE Cluster System Hardware Hardware Installation Guide. No.
Installation Procedure
Reference
1
Installation Preparations
AT ATAE Cluster System System Hardware Installation Guide
2
Installing Cabinets
See the N68E Cabinet Installation Guide delivered with the cabinet.
3
Installing Power Cables and PGND Cables of a Cabinet
P3-P5
4
Installing Internal Components of a Cabinet
P6-P12
5
Installing Power Cables and PGND Cables of the Internal Components of a Cabinet
P13-P18
6
Installing Signal Cables Cables
P19-P42
7
Checking the Installation
P43-P45
8
Appendix
P46-P48
XY in label in following description is a random number generated at delivery. delivery. You You need to select the cabinet, subrack, board, disk array, and cables with the same random number for onsite installation. For example, in a cabinet having the label AB-MPR II-1, the labels of the main storage subrack (MSS), main processing subrack (MPS) and the board in slot 1 are ABMSS-1-2, AB-MPS-1-5 and AB-MPS-1-5-1. The following figures provide cable connections when devices are fully configured in the cabinet. If devices in the cabinet are not fully configured in actual situations, connect only the actually configured devices and ignore the connections for unconfigured devices. Check the locations of the actually configured devices and labels before connecting the cables. See the appendix (P46-P48) to learn the positions of the ports on the disk array and boards when you connect signal cables.
2
Installing Power Cables and PGND Cables of a Cabinet 1 Overhead cabling
Attach temporary labels. labels.
Cable Cutter
Distribute the cables into the cabinet. Assemble the OT terminals. Install the power cables. Over plate must be cut.
Install the PGND cables.
•Do not expose any wire of the cable when preparing the OT terminal on the ATAE side. •Comply with the survey design when preparing the power cable terminal on the power distribution frame (PDF) side. Prepare the power terminals and connect them to the PDF.
PGND cable ( ×1)
-48 V power cable (×6)
Heat gun
RTN power cable (×6)
Wire stripper
3
Hydraulic pliers
2 Underfloor cabling Attach temporary labels. labels.
Cable Cutter
Distribute the cables into the cabinet.
Generally use a redundant thin coaxial cable or Ethernet cable as the rope.
Assemble the OT terminals. Install the power cables. Install the PGND cables. Over plate must be cut.
•Do not expose any wire of the cable when preparing the OT terminal on the ATAE side. •Comply with the survey design when creating the power cable terminal on the PDF side.
Prepare the power terminals and connect them to the PDF.
Heat gun
Wire stripper Hydraulic pliers
4
3 Connecting power cables of the PDB DPD100-6-20 DC PDB •Dual three inputs: -48V/63A for each input. •Maximum output power: 7560W. •Maximum input current: Maximum 100 A for each input. DPD100-2-20 DC PDB •Two inputs: -48V/63A for each input. •Maximum output power: 4000W. •Maximum input current: Maximum 100 A for each input. APD32-6-24 AC PDB •Dual two inputs: 220V/20A for each input. •Maximum output power: 8000W. •Maximum input current:
The APD32-6-24 AC PDB supports dual two AC inputs by installing a two-pin connector at the input terminal block on the back. The following figure shows the dual two-input terminals of the APD32-6-24 AC PDB. The four two-pin connectors are connected to the following posts respectively: L2 and L3 on the left side N2 and N3 on the left side L2 and L3 on the right side N2 and N3 on the right side
Maximum 32A for each input.
APD63-2-24 AC PDB •Two inputs: 220V/32A for each input. •Maximum output power: 6500W. •Maximum input current: Maximum 63A for each input. 5
Installing Internal Components of a Cabinet 1 Diagram of the components in the cabinet (DC) The main processing cabinet
The network device cabinet
Configure the network device cabinet when the ATAE cluster system adopts the Citrix client access scheme, full E1 networking scheme, or partial E1 networking scheme. Install the network device cabinet by referring to the ATAE Cluster System Hardware Installation Guide. 6
2 Diagram of the components in the cabinet (AC) The main processing cabinet
The network device cabinet
Configure the network device cabinet when the ATAE cluster system adopts the Citrix client access scheme, full E1 networking scheme, or part ial E1 networking scheme. Install the network device cabinet by referring to the ATAE Cluster System Hardware Installation Guide.
7
3 Board slot planning of a subrack
OSMU boards include the active OSMU board and standby OSMU board when the standby OSMU board is deployed. The active OSMU board is installed in slot 1 of the first subrack (XY-MPS-1-5-1). The standby OSMU board is installed in a subrack based on the service deployment. For example, the standby OSMU board can be installed in slot 14 in the first subrack (XY-MPS-1-5-14) or in the second subrack (XY-EPS-1-6-14). In the latter case, the OGPU board of the corresponding slot in above table is standby OSMU board.
Main processing subrack (XY-MPS-1-5) Slot ID
Board Label
Board Type
Board Function
1
XY-MPS-1-5-1
OSMU board
OSMU server.
2
XY-MPS-1-5-2
OGPU board
OSS server.
3
XY-MPS-1-5-3
4
XY-MPS-1-5-4
5
XY-MPS-1-5-5
6
XY-MPS-1-5-6
7
XY-MPS-1-5-7
Switching board
LAN switch in the ATAE subrack.
8
XY-MPS-1-5-8
9
XY-MPS-1-5-9
OGPU board
OSS server.
10
XY-MPS-1-5-10
11
XY-MPS-1-5-11
12
XY-MPS-1-5-12
13
XY-MPS-1-5-13
14
XY-MPS-1-5-14
8
3 Board slot planning of a subrack
Extended processing subrack (XY-EPS-1-6) Slot ID
Board Label
Board Type
Board Function
1
XY-EPS-1-6-1
OGPU board
OSS server.
2
XY-EPS-1-6-2
3
XY-EPS-1-6-3
4
XY-EPS-1-6-4
5
XY-EPS-1-6-5
6
XY-EPS-1-6-6
7
XY-EPS-1-6-7
Switching board
LAN switch in the ATAE subrack.
8
XY-EPS-1-6-8
9
XY-EPS-1-6-9
OGPU board
OSS server.
10
XY-EPS-1-6-10
11
XY-EPS-1-6-11
12
XY-EPS-1-6-12
13
XY-EPS-1-6-13
14
XY-EPS-1-6-14
9
4 Installing boards Install rear boards
Remove filler panels
Hold the lower edge of the board with one hand and hold the ejector level on the board with the other hand, and then slide the board along the guide rails at the rear of the subrack until the positioning pin on the board is properly seated in the positioning hole in the subrack. Pivot the ejector levers inward until the ejector levers are completely locked by the latches. Clockwise fasten the captive screws to fix the board in the subrack.
Use a screwdriver to loosen the two captive screws on the filler panel. Grasp the two captive screws to flatly pull the filler panel out of the slot. If a rear board is configured, install the mapping front board after the rear board is installed. Check labels before installing the front and rear boards. Ensure that the label on a front board is the same as that on the rear board that is installed in the same slot as the front board. Install front boards
Install filler panels
Hold the lower edge of the board with one hand and hold the ejector level on the board with the other hand, and then slide the board along the guide rails in the front of the subrack until the positioning pin on the board is properly seated in the positioning hole in the subrack. Pivot the ejector levers inward until the ejector levers are completely locked by the latches. Clockwise fasten the captive screws with a screwdriver to secure the board in the subrack clockwise.
Align the upper and lower edges of the filler panel with the guide rail (slot). Insert the filler panel into the subrack smoothly. Make sure that the positioning pin on the filler panel is inserted into the positioning hole on the subrack. Clockwise fasten the captive screws to fix the filler panel.
10
5 Installing disk arrays Install the controller enclosure for the disk array
Observe the mounting bars on the two sides at the installation position of the controller enclosure and make sure that the floating nuts are installed at the planned positions. Lift the controller enclosure slightly higher than the support guide rails of the cabinet, place the controller enclosure on the support guide rails, and then push it into the cabinet. Clockwise screw the M6 screws by using a screwdriver to fasten the controller enclosure. Insert the optical module into the optical module installation slot on the rear controller of the controller enclosure.
array controller enclosure. Install the disk array's front panel.
•The optical module is delivered with the disk array. •The optical module is an electrostaticsensitive component. Place it in an ESD and dustproof environment during transportation, storage, and usage. If an optical module is not used temporarily, do not remove the protective cover from the optical module.
Install the disk enclosure for the disk array
•The controller enclosure and disk enclosure are heavy upon full configuration. It is recommended that three people move them to avoid human injury. •The devices must be installed on the guide rails. Do not directly stack devices; otherwise, the devices may be damaged. Observe the mounting bars on the two sides at the installation position of the disk enclosure and make sure that the floating nuts are installed at the planned positions. Lift the disk enclosure slightly higher than the support guide rails of the cabinet, place the disk enclosure on the support guide rails, and then push it into the cabinet. Clockwise screw the M6 screws by using a screwdriver to fasten the disk enclosure. Install the disk array's front panel. 11
6 Installing the primary power supply Install the primary power supply subrack
•The ATAE subrack supports only the DC input. If the AC power is used to supply power for the ATAE subrack, you need to configure the primary power supply. The primary power supply converts the AC input provided by the PDB in the cabinet into the DC output and provides the DC output for the power module in the ATAE subrack. •If the power module of the primary power supply is installed in the primary power supply subrack, it is recommended that the primary power supply should be moved by two persons to prevent an injury because the device is heavy. Observe the mounting bars on the two sides of the installation position of the primary power supply and ensure that the f loating nuts of the cabinet are installed in the planned positions. Raise the subrack to the position slightly higher than the support guide rail of the cabinet, place the primary power supply to the support guide rail, and then push it into the cabinet until the rack-mounting ears are firmly close to the mounting bars in front of the cabinet. Clockwise fasten the M6 screws with a screwdriver to fix the primary power supply subrack. Install the power module of the primary power supply
Skip this step if the power module has already been installed in the primary power supply subrack. Push the clip at the lower left corner of the power module to the left. Open the panel of the power module. Push the power module gently along the power subrack, and then close the panel of the power module when the power module cannot be pushed forward. In this manner, the power module is fixed in the power subrack.
12
Installing Power Cables and PGND Cables of the Internal Components of a Cabinet 1 Diagram of power distribution inside the cabinet (DC) Main Processing Cabinet (XY-MPR II-1, DC)
13
2 Diagram of power distribution inside the cabinet (AC) Main Processing Cabinet (XY-MPR II-1, AC)
14
3 Mapping between devices and switches Main Processing Cabinet (XY-MPR II-1, DC) Device
Device Label
Control Switch
Circuit Breaker Specification/Quantity/Label
GE LAN switch
LSW-1
A1, B1
5A/2PCS/LSW-1
GE LAN switch
LSW-0
A2, B2
5A/2PCS/LSW-0
ATAE subrack
XY-EPS-1-6
A9, A10, B9, B10
32A/4PCS/SUBRACK-1
ATAE subrack
XY-MPS-1-5
A7, A8, B7, B8
32A/4PCS/SUBRACK-0
Disk array disk enclosure
XY-ESS-1-4
A3, B3
15A/2PCS/ARRAY-3
Disk array disk enclosure
XY-ESS-1-3
A4, B4
15A/2PCS/ARRAY-2
Disk array controller enclosure
XY-MSS-1-2
A5, B5
15A/2PCS/ARRAY-1
Disk array controller enclosure
XY-BSS-1-1
A6, B6
15A/2PCS/ARRAY-0
Main Processing Cabinet (XY-MPR II-1, AC) Device
Device Label
Control Switch
Circuit Breaker Specification/Quantity
GE LAN switch
LSW-1
A4, B4
10A/2PCS
GE LAN switch
LSW-0
A6, B6
10A/2PCS
Primary power supply
-
A2, A3, A5, B2, B3, B5
16A/6PCS
Disk array disk enclosure
XY-ESS-1-4
A7, B7
6A/2PCS
Disk array disk enclosure
XY-ESS-1-3
A8, B8
6A/2PCS
Disk array controller enclosure
XY-MSS-1-2
A11, B11
6A/2PCS
Disk array controller enclosure
XY-BSS-1-1
A12, B12
6A/2PCS
The power cables (2.1 and 2.2) between the ATAE subrack (XY-EPS-1-6) and the primary power supply and the power cables (1.1 and 1.2) between the ATAE subrack (XY-EPS-1-6) and the primary power supply are bound to the cabinet before delivery. They need to be installed on site. The power cables (3.1 and 3.2) between the ATAE subrack (XY-EPS-1-6) and the primary power supply and the power cables (4.1 and 4.2) between the ATAE subrack (XY-EPS-1-6) and the primary power supply are delivered with the primary power supply. They need to be installed on site. Configure the network device cabinet when the ATAE cluster system adopts the Citrix client access scheme, full E1 networking scheme, or partial E1 networking scheme. For detailed installation guidelines, see the ATAE Cluster System Hardware Installation Guide.
15
3 Installing the power cables and PGND cables of a subrack Connect the DC power cables
Connect the PGND cables
Use the Phillips screwdriver to screw off the screw on the protecting hood of the power entry module in the subrack and remove the plastic washer. Use the Phillips screwdriver to screw off the M6 screw assemblies on the NEG(-) and RTN(+) wiring terminals of the power entry module in the subrack and remove the screws. Connect the OT terminal of the blue DC power cable to the NEG wiring terminal on the power entry module in the subrack and fasten the screw. Connect the OT terminal of the black DC power cable to the RTN wiring terminal on the power entry module in the subrack and fasten the screw. Install the plastic washer on the protecting hood of the power entry module in the subrack and fasten the screw.
There is a ground terminal at the upper left corner and a ground terminal at the upper right corner of the rear of the subrack. You need to connect only the ground terminal at the upper right corner. Connect the AC power cables
The ATAE subrack supports only the DC input. If the AC power is used to supply power for the ATAE subrack, you need to configure the primary power supply. The primary power supply converts the AC input provided by the PDB in the cabinet into the DC output and provides the DC output for the power module in the ATAE subrack. To learn the mapping between the output ports on the power entry module in the subrack and the output ports on the primary power supply, see "Diagram of power distribution inside the cabinet (AC)."
Use the Phillips screwdriver to screw off the M6 screw assemblies on the NEG(-) and RTN(+) wiring terminals of the primary power supply and remove the screws. 16
3 Installing the Power Cables and PGND Cables of a Subrack Connect the AC power cables Connect the OT terminal of the blue DC power cable to the NEG wiring terminal on the primary power supply and fasten the screw. Connect the OT t erminal of the black DC power cable to the RTN wiring terminal on the primary power supply and fasten the screw.
Use the Phillips screwdriver to screw off the screw on the protecting hood of the power entry module in the subrack and remove the plastic washer. Use the Phillips screwdriver to screw off the M6 screw assemblies on the NEG(-) and RTN(+) wiring terminals of the power entry module in the subrack and remove the screws. Connect the OT terminal of the blue DC power cable to the NEG wiring terminal on the power entry module in the subrack and fasten the screw. Connect the OT terminal of the black DC power cable to the RTN wiring terminal on the power entry m odule in the subrack and fasten the screw. Install the plastic washer on the protecting hood of the power entry module in the subrack and fasten the screw.
4 Installing the Power Cables and PGND Cables of the Primary Power Supply Supply Connect the power cables Connect the PGND cables
There is a ground terminal at the upper left corner and a ground terminal at the upper right corner of the rear of the primary power supply. You need to connect only the ground terminal at the upper right corner. The 3-core lines of the AC power cables include a protective earth (PE) line; therefore, no separate PGND cable is required for the devices in the cabinet.
Plug the power connector into the power socket of the primary power. supply
17
5 Installing the Power Cables and PGND Cables of a Disk Array Connect the DC power cables
Connect the PGND cables
On the mounting bars at the rear of the cabinet, select a PGND cable according to the proximity principle. Place the OT terminal at the other end of the PGND cable to the ground screw hole at the controller enclosure of the disk array and use a ground screw to fix the OT terminal to the controller enclosure.
Remove the protecting hood from the DC power module in the controller enclosure of the disk array. Use the Phillips screwdriver to screw off the nuts for fixing the DC power cables of the controller enclosure, place the shock absorption pad, pad, and round hole of the OT terminal on the wire posts, connect the OT terminal of the cable in back to the RTN(+) wring end, connect the OT terminal of the cable in blue to the NEG(-) wring end, and fasten the nuts. Install the protecting hood for the DC power module in the controller enclosure.
Connect the AC power cables •The controller enclosure and the hard disk enclosure of the disk array can use the AC power module or DC power module. You can select the required power module based on the actual power supply environment. •The methods for installing the power cables and PGND cables of the disk arrays at different types are similar. •The 3-core lines of the AC power cables include a protective earth (PE) line; therefore, no separate PGND cable is required for the devices in the cabinet.
Insert the power connector into the power socket of the controller enclosure or disk enclosure of the disk array.
18
Installing Signal Cables 1 Connecting the MPS and the EPS Use network cables to connect the main processing subrack (MPS) and extended processing subrack (EPS) by scenario based on the labels and port information. Application scenarios: An ATAE cluster system is newly deployed and the MPS and EPS are configured simultaneously, the model of the switching board’s RTM is AXCRA1. Board Slot
Port on the
Cable
Board Slot
Port on the
Cable
(XY-MPS-1-6)
Board
Label
(XY-EPS-1-5)
Board
Label
7
BASE LAN3
7.4
7
BASE LAN3
7.4
8
BASE LAN3
8.4
8
BASE LAN3
8.4
Connections between the MPS and the EPS:
19
Installing Signal Cables 1 Connecting the MPS and the EPS Use network cables to connect the main processing subrack (MPS) and extended processing subrack (EPS) by scenario based on the labels and port information. Application scenarios: An ATAE cluster system is newly deployed and the MPS and EPS are configured simultaneously, the model of the switching board’s RTM is AXCRM. Board Slot
Port on the
Cable
Board Slot
Port on the
Cable
(XY-MPS-1-6)
Board
Label
(XY-EPS-1-5)
Board
Label
7
BASE LAN3
7.4
7
BASE LAN3
7.4
8
BASE LAN3
8.4
8
BASE LAN3
8.4
Connections between the MPS and the EPS:
20
2 Connecting the Controller Enclosure and the Disk Enclosure
Only the main storage subrack (MSS) in the ATAE cluster system needs to cascade with the disk enclosure. Cascade two disk enclosures with the controller enclosure, as shown in the following figure.
mini SAS cable
Connect EXP0 port of controller B in the disk array controller enclosure (XY-MSS-1-2) to the PRI port of cascading module B in the first disk enclosure (XY-ESS-1-3). Connect the PRI port of cascading module A in the first disk enclosure (XY-ESS-1-3) to EXP0 cascading port of controller A in the disk array controller enclosure (XY-MSS-1-2). Connect EXP1 port of controller B in the disk array controller enclosure (XY-MSS-1-2) to the PRI port of cascading module B in the second disk enclosure (XY-ESS-1-4). Connect the PRI port of cascading module A in the second disk enclosure (XY-ESS-1-4) to EXP1 port of controller A in the disk array controller enclosure (XY-MSS-1-2). In this manner, a loop is formed, which avoids SPOF of the disk enclosure.
21
2 Connecting the Controller Enclosure and the Disk Enclosure Cascade one disk enclosure with the controller enclosure, as shown in the following figure.
Connect the EXP0 port on controller B of the controller enclosure (XY-MSS-1-2) to the PRI port on cascading module B of the disk enclosure (XY-ESS-1-3). Connect the PRI port on cascading module A of the disk enclosure (XY-ESS-1-3) to the EXP0 port on controller A of the controller enclosure (XY-MSS-1-2). Then, a ring is formed to avoid SPOF on disk enclosures.
22
3 Connecting the Controller Enclosure and the Subrack You can check the information about the disk array model and disk size on the labels shown as below.
23
3 Connecting the Controller Enclosure and the Subrack Use network cables to connect the controller enclosure and the subrack by scenario based on the labels and port information. Application scenarios: The model of the switching board’s RTM is AXCRA1. CAUTION
The network cables for connecting the MPS and controller enclosure have been laid out upon delivery, and you only need to insert the two ends of a cable into the required ports of the devices based on the cable labels. The connections between the subrack and the S3900 -M300 disk array controller enclosure are the same as those between the subrack and the S3900-M200 disk array controller enclosure. Figure bellow uses the scenario where both the MSS and the BSS are deployed and the disk array controller enclosure model is S3900 -M300 as an example. If the BSS is not configured, ignore the connections between the BSS and t he disk array controller enclosure.
Controller
Port on the Controller
Enclosure Label
Enclosure
7.1
XY-MSS-1-2
Ethernet port (UP)
BASE LAN1
7.2
XY-BSS-1-1
Ethernet port (UP)
BASE LAN0
8.1
XY-MSS-1-2
Ethernet port (DOWN)
BASE LAN1
8.2
XY-BSS-1-1
Ethernet port (DOWN)
Board Label
Board Port
Cable Label
XY-MPS-1-5-7
BASE LAN0
XY-MPS-1-5-8
Connections between the controller enclosure and the subrack using network cables:
24
3 Connecting the Controller Enclosure and the Subrack Use network cables to connect the controller enclosure and the subrack by scenario based on the labels and port information. Application scenarios: The model of the switching board’s RTM is AXCRM. CAUTION
The network cables for connecting the MPS and controller enclosure have been laid out upon delivery, and you only need to insert the two ends of a cable into the required ports of the devices based on the cable labels. The connections between the subrack and the S3900 -M300 disk array controller enclosure are the same as those between the subrack and the S3900-M200 disk array controller enclosure. Figure bellow uses the scenario where both the MSS and the BSS are deployed and the disk array controller enclosure model is S3900 -M300 as an example. If the BSS is not configured, ignore the connections between the BSS and t he disk array controller enclosure.
Controller
Port on the Controller
Enclosure Label
Enclosure
7.1
XY-MSS-1-2
Ethernet port (UP)
BASE LAN1
7.2
XY-BSS-1-1
Ethernet port (UP)
BASE LAN0
8.1
XY-MSS-1-2
Ethernet port (DOWN)
BASE LAN1
8.2
XY-BSS-1-1
Ethernet port (DOWN)
Board Label
Board Port
Cable Label
XY-MPS-1-5-7
BASE LAN0
XY-MPS-1-5-8
Connections between the controller enclosure and the subrack using network cables:
25
3 Connecting the Controller Enclosure and the Subrack Use optical fibers to connect the controller enclosure and the subrack by scenario based on the labels and port information. Application scenarios: The model of MSS is S3900-M300 and the model of the switching board’s RTM is AXCRA1.
The following figures provide cable connections when devices are fully configured in the cabinet. If devices in the cabinet are not fully configured in actual situations, connect only the actually configured devices and ignore the connections for unconfigured devices. Check the locations of the actually configured devices and labels before connecting the cables.
Board Label
XY-MPS-1-5-7
XY-MPS-1-5-8
XY-EPS-1-6-7
XY-EPS-1-6-8
Cable Label
Port on the Board
Controller
Port on the
Enclosure
Controller
Label
Enclosure
XY-MPS-1-5 7.SFP0
SFP0
XY-MSS-1-2
FC P1 (UP)
XY-MPS-1-5 7.SFP1
SFP1
XY-MSS-1-2
FC P1 (DOWN)
XY-MPS-1-5 7.SFP2
SFP2
XY-BSS-1-1
FC H0 (DOWN)
XY-MPS-1-5 8.SFP0
SFP0
XY-MSS-1-2
FC P0 (UP)
XY-MPS-1-5 8.SFP1
SFP1
XY-MSS-1-2
FC P0 (DOWN)
XY-MPS-1-5 8.SFP2
SFP2
XY-BSS-1-1
FC H0 (UP)
XY-EPS-1-6 7.SFP0
SFP0
XY-MSS-1-2
FC H1 (UP)
XY-EPS-1-6 7.SFP1
SFP1
XY-MSS-1-2
FC H1 (DOWN)
XY-EPS-1-6 8.SFP0
SFP0
XY-MSS-1-2
FC H3 (UP)
XY-EPS-1-6 8.SFP1
SFP1
XY-MSS-1-2
FC H3 (DOWN)
26
3 Connecting the Controller Enclosure and the Subrack Connections between the controller enclosure and the subrack using optical fibers:
27
3 Connecting the Controller Enclosure and the Subrack Use optical fibers to connect the controller enclosure and the subrack by scenario based on the labels and port information. Application scenarios: The model of MSS is S3900-M300 and the model of the switching board’s RTM is AXCRM.
The following figures provide cable connections when devices are fully configured in the cabinet. If devices in the cabinet are not fully configured in actual situations, connect only the actually configured devices and ignore the connections for unconfigured devices. Check the locations of the actually configured devices and labels before connecting the cables.
Board Label
XY-MPS-1-5-7
XY-MPS-1-5-8
XY-EPS-1-6-7
XY-EPS-1-6-8
Cable Label
Port on the Board
Controller
Port on the
Enclosure
Controller
Label
Enclosure
XY-MPS-1-5 7.SFP0
SFP0
XY-MSS-1-2
FC P1 (UP)
XY-MPS-1-5 7.SFP1
SFP1
XY-MSS-1-2
FC P1 (DOWN)
XY-MPS-1-5 7.SFP2
SFP2
XY-BSS-1-1
FC H0 (DOWN)
XY-MPS-1-5 8.SFP0
SFP0
XY-MSS-1-2
FC P0 (UP)
XY-MPS-1-5 8.SFP1
SFP1
XY-MSS-1-2
FC P0 (DOWN)
XY-MPS-1-5 8.SFP2
SFP2
XY-BSS-1-1
FC H0 (UP)
XY-EPS-1-6 7.SFP0
SFP0
XY-MSS-1-2
FC H1 (UP)
XY-EPS-1-6 7.SFP1
SFP1
XY-MSS-1-2
FC H1 (DOWN)
XY-EPS-1-6 8.SFP0
SFP0
XY-MSS-1-2
FC H3 (UP)
XY-EPS-1-6 8.SFP1
SFP1
XY-MSS-1-2
FC H3 (DOWN)
28
3 Connecting the Controller Enclosure and the Subrack Connections between the controller enclosure and the subrack using optical fibers:
29
3 Connecting the Controller Enclosure and the Subrack Use optical fibers to connect the controller enclosure and the subrack by scenario based on the labels and port information. Application scenario Only the MSS is configured and its model is S3900-M200,and the model of the switching board’s RTM is AXCRA1.
The following figures provide cable connections when devices are f ully configured in the cabinet. If devices in the cabinet are not fully configured in actual situations, connect only the actually configured devices and ignore the connections for unconf igured devices. Check the locations of the actually configured devices and labels before connecting the cables.
Board Label
XY-MPS-1-5-7
XY-MPS-1-5-8
Port on
Controller
Port on the
the
Enclosure
Controller
Board
Label
Enclosure
XY-MPS-1-5 7.SFP0
SFP0
XY-MSS-1-2
FC H2 (UP)
XY-MPS-1-5 7.SFP1
SFP1
XY-MSS-1-2
FC H2 (DOWN)
XY-MPS-1-5 8.SFP0
SFP0
XY-MSS-1-2
FC H0 (UP)
XY-MPS-1-5 8.SFP1
SFP1
XY-MSS-1-2
FC H0 (DOWN)
Cable Label
Connections between the controller enclosure and the subrack using optical fibers:
30
3 Connecting the Controller Enclosure and the Subrack Use optical fibers to connect the controller enclosure and the subrack by scenario based on the labels and port information. Application scenario Only the MSS is configured and its model is S3900-M200,and the model of the switching board’s RTM is AXCRM.
The following figures provide cable connections when devices are f ully configured in the cabinet. If devices in the cabinet are not fully configured in actual situations, connect only the actually configured devices and ignore the connections for unconf igured devices. Check the locations of the actually configured devices and labels before connecting the cables.
Board Label
XY-MPS-1-5-7
XY-MPS-1-5-8
Port on
Controller
Port on the
the
Enclosure
Controller
Board
Label
Enclosure
XY-MPS-1-5 7.SFP0
SFP0
XY-MSS-1-2
FC H2 (UP)
XY-MPS-1-5 7.SFP1
SFP1
XY-MSS-1-2
FC H2 (DOWN)
XY-MPS-1-5 8.SFP0
SFP0
XY-MSS-1-2
FC H0 (UP)
XY-MPS-1-5 8.SFP1
SFP1
XY-MSS-1-2
FC H0 (DOWN)
Cable Label
Connections between the controller enclosure and the subrack using optical fibers:
31
3 Connecting the Controller Enclosure and the Subrack Use optical fibers to connect the controller enclosure and the subrack by scenario based on the labels and port information. Application scenario Only when the standby OSMU board is deployed in the EPS, and The model of the switching board’s RTM is AXCRA1.
Board Label
Cable Label
Port on the Board
Controller
Port on the
Enclosure
Controller
Label
Enclosure
XY-EPS-1-6-7
XY-EPS-1-6 7.SFP2
SFP2
XY-BSS-1-1
FC H2 (DOWN)
XY-EPS-1-6-8
XY-EPS-1-6 8.SFP2
SFP2
XY-BSS-1-1
FC H2 (UP)
Connections between the controller enclosure and the subrack using optical fibers:
32
3 Connecting the Controller Enclosure and the Subrack Use optical fibers to connect the controller enclosure and the subrack by scenario based on the labels and port information. Application scenario Only when the standby OSMU board is deployed in the EPS, and The model of the switching board’s RTM is AXCRM.
Board Label
Cable Label
Port on the Board
Controller
Port on the
Enclosure
Controller
Label
Enclosure
XY-EPS-1-6-7
XY-EPS-1-6 7.SFP2
SFP2
XY-BSS-1-1
FC H2 (DOWN)
XY-EPS-1-6-8
XY-EPS-1-6 8.SFP2
SFP2
XY-BSS-1-1
FC H2 (UP)
Connections between the controller enclosure and the subrack using optical fibers:
33
4 Connecting the Subracks (MPS/EPS) and the Switches Application scenario The ATAE cluster system is newly deployed and the model of the switching board’s RTM is AXCRA1. Connect the local end of the cables to the corresponding ports on the RTM of the switching board based on the label information. One end of the cables has been connected to the ports on the switch before delivery. Therefore, you only need to connect the other end of the cables to t he corresponding ports on the RTM of the switching board on site. Subrack Label
Slot
Port on the Switching Board
Cable Label
Port on the Switch
XY-MPS-1-5
7
FABRIC GE LAN0
7.5
LSW-0 LAN01
8
FABRIC GE LAN0
8.5
LSW-1 LAN01
7
FABRIC GE LAN0
21.5
LSW-0 LAN03
8
FABRIC GE LAN0
22.5
LSW-1 LAN03
XY-EPS-1-6
Connections between subracks and switches:
34
4 Connecting the Subracks (MPS/EPS) and the Switches Application scenario The ATAE cluster system is newly deployed and the model of the switching board’s RTM is AXCRM. Connect the RTM of the switching boards and the switches with optical fibers based on the label information. Subrack Label
Slot
Port on the Switching Board
Cable Label
Port on the Switch
XY-MPS-1-5
7
FABRIC 10GE LAN6
7.5
LSW-0 10GE LAN1
8
FABRIC 10GE LAN6
8.5
LSW-1 10GE LAN1
7
FABRIC 10GE LAN6
21.5
LSW-0 10GE LAN2
8
FABRIC 10GE LAN6
22.5
LSW-1 10GE LAN2
XY-EPS-1-6
Connections between subracks and switches:
35
5 Connecting the Switches and the Operator's Network Application scenario Connections when the model of the Ethernet switches is S5352C-EI, and you must connect the switches to the telecom operator's network using network cables.
If you need to...
Then...
Connect the switches to the same VLAN of the same switch in the telecom operator's network Connect the switches to different switches or routers in the telecom operator's network, and the switches or routers in the telecom operator's network are in the same VLAN
Route network cables from port LAN48 on LSW-0 and LSW-1 to the desired network plane, as shown in Figure 1.
Connect the switches to different switches or routers in the telecom operator's network, and the switches or routers in the telecom operator's network are not in the same VLAN
a. Connect port LAN46 on LSW-0 and port LAN46 on LSW-1 using a network cable, as shown in Figure 2. CAUTION
Do not perform this operation if the switches or routes in the operator's network are in the same VLAN. Otherwise, network loop will occur. b. Route network cables from port LAN48 on LSW-0 and LSW-1 of VLAN2 to the desired network plane, as shown in Figure 2.
Not connect the switches to the telecom operator's network
Connect ports LAN46 on LSW-0 and LSW-1 using a network cable, as shown in Figure 3.
CAUTION
When the switches need to be connected to the telecom operator's in future, perform operations described for the preceding scenarios. If the switches do not need to be cascaded, disconnect the network cable that connects ports LAN46 on LSW-0 and on LSW-1, and then connect the switches to the telecom operator's network.
36
5 Connecting the Switches and the Operator's Network Figure 1 Connecting the switches to the telecom operator's network using network cables (connect to the same VLAN of the telecom operator's network)
Figure 2 Connecting the switches to the telecom operator's network using network cables (connect to the different VLAN of the telecom operator's network )
Figure Connecting the switches to the telecom operator‘s network using network cables (not connect to the telecom operator’s network )
37
5 Connecting the Switches and the Operator's Network Application scenario Connections when the model of the Ethernet switches is S5310-52C-EI, the telecom operator's network is an optical Ethernet, and you want to connect the switches to the telecom operator's network using network cables. If you need to...
Then...
Connect the switches to the same VLAN of the same switch in the telecom operator's network Connect the switches to different switches or routers in the telecom operator's network, and the switches or routers in the telecom operator's network are in the same VLAN
Route network cables from port LAN48 on LSW-0 and LSW-1 to the desired network plane, as shown in Figure 1.
Connect the switches to different switches or routers in the telecom operator's network, and the switches or routers in the telecom operator's network are not in the same VLAN
a. Connect port LAN46 on LSW-0 and port LAN46 on LSW-1 using a network cable, as shown in Figure 2. CAUTION
Do not perform this operation if the switches or routes in the operator's network are in the same VLAN. Otherwise, network loop will occur. b. Route network cables from port LAN48 on LSW-0 and LSW-1 of VLAN2 to the desired network plane, as shown in Figure 2.
Not connect the switches to the telecom operator's network
Connect ports LAN46 on LSW-0 and LSW-1 using a network cable, as shown in Figure 3.
CAUTION
When the switches need to be connected to the telecom operator's in future, perform operations described for the preceding scenarios. If the switches do not need to be cascaded, disconnect the network cable that connects ports LAN46 on LSW-0 and on LSW-1, and then connect the switches to the telecom operator's network.
38
5 Connecting the Switches and the Operator's Network Figure 1 Connecting the switches to the telecom operator's network using network cables (connect to the same VLAN of the telecom operator's network)
Figure 2 Connecting the switches to the telecom operator's network using network cables (connect to the different VLAN of the telecom operator's network )
Figure Connecting the switches to the telecom operator‘s network using network cables (not connect to the telecom operator’s network )
39
5 Connecting the Switches and the Operator's Network Application scenario Connections when the model of the Ethernet switches is S5310-52C-EI, the telecom operator's network is an optical Ethernet, and you want to connect the switches to the telecom operator's network using optical fibers.
If you need to...
Then...
Connect the switches to the same VLAN of the same switch in the telecom operator's network Connect the switches to different switches or routers in the telecom operator's network, and the switches or routers in the telecom operator's network are in the same VLAN
Route optical fibers from Ethernet optical ports LAN3 on LSW-0 and LSW-1 to the desired network plane, as shown in Figure 1.
Connect the switches to different switches or routers in the telecom operator's network, and the switches or routers in the telecom operator's network are not in the same VLAN
a. Connect Ethernet optical ports LAN4 on LSW0 and LSW-1 using an optical fiber, as shown in Figure 2. CAUTION
Do not perform this operation if the switches or routes in the operator's network are in the same VLAN. Otherwise, network loop will occur. b. Route optical fibers from Ethernet optical ports LAN3 on LSW-0 and LSW-1 to the desired network plane, as shown in Figure 2.
Not connect the switches to the telecom operator's network
Connect Ethernet optical ports LAN4 on LSW-0 and LSW-1 using an optical fiber, as shown in Figure 3. CAUTION
When the switches need to be connected to the telecom operator's in future, perform operations described for the preceding scenarios. If the switches do not need to be cascaded, disconnect the optical fiberthat connects Ethernet optical ports LAN4 on LSW-0 and on LSW-1, and then connect the switches to the telecom operator's network.
40
5 Connecting the Switches and the Operator's Network Figure 1 Connecting the switches to the telecom operator's network using optical fibers (connect to the same VLAN of the telecom operator's network)
Figure 2 Connecting the switches to the telecom operator's network using optical fibers (connect to the different VLAN of the telecom operator‘s network )
Figure 3 Connecting the switches to the telecom operator‘s network using optical fibers (not connect to the telecom operator’s network )
41
6 Connecting the DC PDB and SDM board You need to use a cable to connect the DC PDB and SDM board of the main processing subrack (MPS) only when the DC PDB and SMME are configured. Figure 1 Connecting the DC PDB and SDM board of the MPS
42
Checking the Installation 1 Checking the Installation of Cabinets No.
Item
1
Check that the cabinets are placed according to the engineering design documents.
2
Check that the racks are secured firmly. The installation of the racks must comply with the shockproof requirements, and the vertical deviation must be less than 3 mm (0.12 in.). Perform the check using the level and the plumb line.
3
If a cabinet is installed on the ESD floor, check that the feet of the supports are fastened by the expansion bolts secured to the floor. The insulating plate, plain washer, spring washer, nut (bolt) must be installed in correct sequence. The expansion bolts are properly secured to the installation holes. The supports are insulated from the floor, and the floor holders are insulated from the guide rails. W hen measured by a multimeter in megohms, the resistance of all the insulation points between the supports and the cabinets must exceed 5 megaohm.
4
Check that all the screws are fastened tightly. Every screw has a plain washer and a spring washer, and the two washers are installed correctly.
5
Check that the cabinets are lined up along the walkway to form a cabinet row in which the vertical deviation between two neighboring cabinets is less than 5 mm (0.20 in.). Each row of the cabinets is neatly aligned.
6
When multiple cabinets are combined, check that all the connected plates for attaching the cabinets are installed correctly.
7
Check that the side panel, front door, and rear door are installed correctly. The front door, rear door and their locks can be opened and closed smoothly.
8
Check that the front door, rear door, and side panel are tidy, free of stains, and handprints.
9
Check that the cable holes of the cabinet are covered. The cable holes of the cabinet can be covered by a plate, a cloth bag, or other insulating material that is tidy and fireproof. If a cover plate is used, the width of the plate must be larger than that of the hole. If a cloth bag is used, the mouth of the cloth bag must be tightened. If a plastic cover is used, the leading-out hole must be cut of adequate width.
10
Check that there are no surplus tie wraps, stubs, or other sundries in the cabinets.
11
Check that all the front panels and filler panels delivered are installed.
12
Check that the ESD wrist strap is inserted into the ESD socket on the cabinet.
13
Check that the cabinet labels are affixed in a tidy manner.
43
2 Checking the Installation of Components in the Cabinets No.
Item
1
Check whether the installation positions of the internal components comply with the specifications according to the actual engineering documents.
2
Check whether all panel screws of the components are installed and fastened.
3
Check whether the panels and exterior of the components are in good conditions.
4
Check whether the component labels (subrack protection film, board name plate, transportation label, and product nameplate) are flaked off.
5
Check whether the bar codes of the components are flaked off.
6
Check whether the ejector levers of the boards are secure.
7
Check whether the captive screws of the boards are fastened.
8
Check whether there are vacant slots in the subrack and whether filler panels are installed in the vacant slots.
9
Check whether the protective cover is installed for the power module (This check item is only available for the devices equipped with power modules and protective covers).
3 Checking the Installation of PGND Cables and Power Cables No.
Item
1
All the power cables and PGND cables are copper-core cables.
2
There are no solder joints or connectors in the power cables and the PGND cables.
3
The extra length of power cables or PGND cables are truncated and are not coiled.
4
There are no breaking equipment such as switches and fuses in the electrical connection of the grounding system.
5
The ground bars and PGND bars are connected to one ground conductor.
6
The OT terminals at both ends of the power cables or PGND cables are soldered or crimped securely.
7
The bare wires and OT terminals at the wiring terminals are tightly wrapped up with the PVC insulation tape or heat shrink tubing.
8
The power cables and PGND cables connecting the PDB with the functional modules, and the PGND cables connecting the modules with the ground bar are al l correctly installed and have satisfactory contact.
9
The front and rear doors are connected to the ground bolts on the lower enclosure of the cabinet using 6 mm2 greenish yellow cables. Two such cables are used for each door.
10
The power cables and PGND cables are bound separately from other cables.
11
Labels are attached at both ends of the power cables and the PGND cables.
12
The plastic cover plate on the top of the terminals of the PDB is installed correctly. 44
4 Checking the Installation of Signal Cables No.
Item
1
There are no solder joints or connectors in the signal cables. The signal cables are not scratched or broken.
2
The connectors of the signal cables are tight and secure.
3
Proper length of the cable is reserved at the connectors.
4
Proper length is reserved for the signal cables at turning points. The turning radius meets the requirement.
5
The optical cables must be sheathed using corrugated pipes at outsides of cabinets. Both ends of the pipes must be fastened. The edges are smooth or be processed for cutting prevention.
6
No other cables are laid on the optical cables.
7
The extra optical cables are coiled on the fiber management tray at the rear side of the cabinet.
8
The signal cables connected to the left part of the subrack are led out of the subrack from the left. Similarly, the signal cables connected to the right part of the subrack are led out of the subrack from the right.
9
The signal cables are bound separately from the power cables. The signal cables are bound and arranged neatly and closely. The cable ties ar e spaced evenly. The tips of the cable ties point to the same direction.
10
The extra length of the cable ties must be cut and the cut surface must be smooth.
11
The cables whose connectors are far away from the cable entrance are arranged at the external side of the cable bundle, while those near the entrance are arranged at the internal side of the cable bundle. The trunk cables are laid out smoothly without any tangling.
45
Appendix Port on the controller enclosure
1.1 EXP 0 (UP)
1.2 Ethernet port (UP)
1.3 Maintenance network
1.4 RS-232 serial port
port 1.5 EXP 1 (UP)
1.6 FC P0 (UP)
1.7 FC P1 (UP)
1.8 FC P2 (UP)
1.9 FC P3 (UP)
1.10 FC H2 (UP)
1.11 FC H0 (UP)
1.12 FC H1 (UP)
2.2 Ethernet port (DOWN)
2.3 Maintenance network
2.4 RS-232 serial port
2.5 EXP 1 (DOWN)
2.6 FC P0 (DOWN)
2.7 FC P1 (DOWN)
2.8 FC P2 (DOWN)
2.9 FC P3 (DOWN)
2.10 FC H2 (DOWN)
2.11 FC H0 (DOWN)
2.12 FC H1 (DOWN)
1.13 FC H3 (UP) 2.1 EXP 0 (DOWN)
port
2.13 FC H3 (DOWN)
46
Appendix
Port on the RTM of the OSMU/OGPU board
47
Appendix Port on the RTM of the switching board(AXCRA1)
48
Port on the RTM of the switching board(AXCRM)