ACE_5000[1].pdf

ACTA ACTARIS RIS

CONFIDENTIAL CONFIDENTIAL

ACE 5000 type 5.1 Technical Document Three Phase Time Switch Static Meter

D0216713 – Technical Guide ACE 5000 Type 5.1 – Release B – 03/07/25

Page 1 of 43

ACTA ACTARIS RIS

1


G E N E R A L___________________________ L_____________________________________ ____________________ ____________________ ____________________ ____________ __4 4 1.1 1.1

Scop cope ______________ _______________ _______________ _______________ ___________ 5

1.2 1.2

Life Lifeti tim me _______________ _______________ _______________ _______________ ________ 6

1.3 1.3

Meter Meter overvie overview w_______________ _______________ _______________ _______________ ___ 6

1.3.1 1.3.2 1.3.3 1.3.4 1.3.5 1.3.6 1.3.7 1.3.8 1.3.9

1.4 1.4

Enclo En closur suree protec protectio tion n & Clim Climat atee _________ ____ _____ _____ _____ _____ _____ _____ _____ _____ _____ 10

1.4.1 1.4.2 1.4.3

1.5 1.5

2.1 2.1

Powe Powerr Supp Supply ly Unit Unit ______________ _______________ _______________ _______________ 12

2.2 2.2

LV/DC LV/DC Curren Currentt ranges ranges____ _________ _____ _____ _____ _____ _____ _____ _____ _____ _____ _____ __ 12

2.3 2.3

LV/C LV/CT T Curr Curren entt rang ranges es______________ ______________ _______________ _______________ ____________ 12

2.4 2.4

Real Time Time clock clock (acc. (acc. to IEC 61038) 61038) _____ _____ _____ _____ _____ _____ _____ _____ _____ 12

2.5 2.5

LCD overview_____ ________ _________ ________ ________ ________ _________ ________ _______ 14 LCD LCD modes modes _________ ________ ________ ________ _________ ________ ________ ________ ______ 17 Metrolog Metrology y LED ________ _________ ________ ________ ________ _________ ________ ________ ___ 22

M E TR OLOG OL OGY___ Y______ ______ ______ ______ _____ _____ _____ _____ _____ _____ _____ _____ _____ _____ _____ _____ _____ _____ _____ _____ _____ _____ _____ _____23 ___23 3.1 3.1

Metr Metrol olog ogy y Indi Indica cati tion onss ___________ _______________ _______________ _______________ 23

3.1.1 3.1.2 3.1.3 3.1.4 3.1.5

3.2 3.2

Metrolo Metrology gy princi principle ple ________ ________ _________ ________ ________ ________ _________ ________ 23 Metrolog Metrology y modes__ ________ ________ _________ ________ ________ ________ _________ ________ 23 Metrology Metrology LED constant constant and duration duration ________ ________ ________ _________ ________ ________ ___ 25 Pulse Output ________ ________ ________ ________ _________ ________ ________ ________ ______ 25 Instantaneou Instantaneouss values values ________ _________ ________ ________ ________ _________ ________ _______ 25

Expl Exploi oita tati tion on data data _______________ _______________ _______________ _______________ 26

3.2.1 3.2.2 3.2.3

Energy Energy Regist Registers ers _________ ________ ________ ________ _________ ________ ________ ________ __ 26 Maximum Maximum Demand Demand Register Registerss ________ ________ ________ _________ ________ ________ ________ __ 28 Maximum Maximum Registe Registers rs ________ ________ _________ ________ ________ ________ _________ ________ 29

T A R I F F S____________________ S______________________________ ____________________ ____________________ ____________________ ___________________ _________30 30 4.1 4.1

Defini Definitio tion n & ACE 5.1 5.1 Time Time Switc Switch: h: _________ ____ _____ _____ _____ _____ _____ _____ _____ _____ __ 30

4.1.1 4.1.2 4.1.3

5

Battery____________________________________________________________________________13 Super Super Capacito Capacitorr ________ _________ ________ ________ ________ _________ ________ ________ ___ 13

Huma Hu man n Mach Machin inee Inter Interfa face ce ________ ____ _________ _____ _____ _____ _____ _____ _____ _____ _____ _____ 14

2.5.1 2.5.2 2.5.3

4

Variants___________________________________________________________________________11

H A R D WAR WA R E F UNCT UN CTII ONA L SPE CI F I CA TI ONS _____ _______ _____ _____ _____ _____ _____ _____ _____ _____ _____ _____ _____12 ___12

2.4.1 2.4.2

3

Protect Protection ion ________ ________ _________ ________ ________ ________ _________ ________ _______ 10 Tempera Temperature ture range range ________ ________ ________ ________ _________ ________ ________ ________ __ 10 Humidity Humidity range ________ _________ ________ ________ ________ _________ ________ ________ ___ 11

Stan Standa dard rdss ______________ _______________ _______________ _______________ _______ 11

1.5.1

2

Main Assembli Assemblies es Identific Identificatio ation n _________ ________ ________ ________ _________ ________ ________ 6 Main Dimensi Dimensions ons & Fixing Fixing Triangl Trianglee __________ ________ _________ ________ ________ ________ ___7 Direct Direct Connected Connected Terminal Terminal & Connecti Connections ons ________ ________ ________ _________ ________ ________ 8 Current Current Transfor Transformer mer connecte connected d Terminal Terminal & Connectio Connections ns ____________ ________ _________ ________ _8 Envelope Envelope Material Material ________ ________ ________ ________ _________ ________ ________ ________ ___8 Functions Functions on Cover ________ ________ _________ ________ ________ ________ _________ ________ _9 External External / Internal Internal IP Link _________ ________ ________ ________ _________ ________ ________ ___ 10 Auxili Auxiliary ary termin terminals als ________ ________ _________ ________ ________ ________ _________ ________ 10 Opening Opening Cover Detector Detector________ ________ ________ ________ _________ ________ ________ ________ ______ 10

PowerPower-Up Up ________ ________ _________ ________ ________ ________ _________ ________ _______ 30 PowerPower-Do Down wn ________ ________ ________ ________ _________ ________ ________ ________ ______ 30 Precisio Precision n on RTC setting setting ________ ________ _________ ________ ________ ________ _________ ____ 30

4.2 4.2

Cont Contra ract ct chan change ge ______________ _______________ _______________ _______________ __ 30

4.3 4.3

End En d of Billi Billing ng (E.O (E.O.B .B.)_ .)_ _______________ _______________ _______________ __________ 31

4.4 4.4

Load Load Manag Manageme ement nt ______________ _______________ _______________ _______________ 31

D iagnost iagnostic ic and Survey Survey _____ ________ _____ _____ _____ _____ _____ _____ _____ _____ _____ _____ _____ _____ _____ _____ _____ _____ _____ _____ _____ _____33 ___33 5.1.1 5.1.2

Parameter ParameterSetC SetChecksu hecksum m ________ ________ ________ _________ ________ ________ ________ ______ 33 ProgrammingCounter_________________________________________________________________33


Page 2 of 43

ACTA ACTARIS RIS

1


G E N E R A L___________________________ L_____________________________________ ____________________ ____________________ ____________________ ____________ __4 4 1.1 1.1

Scop cope ______________ _______________ _______________ _______________ ___________ 5

1.2 1.2

Life Lifeti tim me _______________ _______________ _______________ _______________ ________ 6

1.3 1.3

Meter Meter overvie overview w_______________ _______________ _______________ _______________ ___ 6

1.3.1 1.3.2 1.3.3 1.3.4 1.3.5 1.3.6 1.3.7 1.3.8 1.3.9

1.4 1.4

Enclo En closur suree protec protectio tion n & Clim Climat atee _________ ____ _____ _____ _____ _____ _____ _____ _____ _____ _____ 10

1.4.1 1.4.2 1.4.3

1.5 1.5

2.1 2.1

Powe Powerr Supp Supply ly Unit Unit ______________ _______________ _______________ _______________ 12

2.2 2.2

LV/DC LV/DC Curren Currentt ranges ranges____ _________ _____ _____ _____ _____ _____ _____ _____ _____ _____ _____ __ 12

2.3 2.3

LV/C LV/CT T Curr Curren entt rang ranges es______________ ______________ _______________ _______________ ____________ 12

2.4 2.4

Real Time Time clock clock (acc. (acc. to IEC 61038) 61038) _____ _____ _____ _____ _____ _____ _____ _____ _____ 12

2.5 2.5

LCD overview_____ ________ _________ ________ ________ ________ _________ ________ _______ 14 LCD LCD modes modes _________ ________ ________ ________ _________ ________ ________ ________ ______ 17 Metrolog Metrology y LED ________ _________ ________ ________ ________ _________ ________ ________ ___ 22

M E TR OLOG OL OGY___ Y______ ______ ______ ______ _____ _____ _____ _____ _____ _____ _____ _____ _____ _____ _____ _____ _____ _____ _____ _____ _____ _____ _____ _____23 ___23 3.1 3.1

Metr Metrol olog ogy y Indi Indica cati tion onss ___________ _______________ _______________ _______________ 23

3.1.1 3.1.2 3.1.3 3.1.4 3.1.5

3.2 3.2

Metrolo Metrology gy princi principle ple ________ ________ _________ ________ ________ ________ _________ ________ 23 Metrolog Metrology y modes__ ________ ________ _________ ________ ________ ________ _________ ________ 23 Metrology Metrology LED constant constant and duration duration ________ ________ ________ _________ ________ ________ ___ 25 Pulse Output ________ ________ ________ ________ _________ ________ ________ ________ ______ 25 Instantaneou Instantaneouss values values ________ _________ ________ ________ ________ _________ ________ _______ 25

Expl Exploi oita tati tion on data data _______________ _______________ _______________ _______________ 26

3.2.1 3.2.2 3.2.3

Energy Energy Regist Registers ers _________ ________ ________ ________ _________ ________ ________ ________ __ 26 Maximum Maximum Demand Demand Register Registerss ________ ________ ________ _________ ________ ________ ________ __ 28 Maximum Maximum Registe Registers rs ________ ________ _________ ________ ________ ________ _________ ________ 29

T A R I F F S____________________ S______________________________ ____________________ ____________________ ____________________ ___________________ _________30 30 4.1 4.1

Defini Definitio tion n & ACE 5.1 5.1 Time Time Switc Switch: h: _________ ____ _____ _____ _____ _____ _____ _____ _____ _____ __ 30

4.1.1 4.1.2 4.1.3

5

Battery____________________________________________________________________________13 Super Super Capacito Capacitorr ________ _________ ________ ________ ________ _________ ________ ________ ___ 13

Huma Hu man n Mach Machin inee Inter Interfa face ce ________ ____ _________ _____ _____ _____ _____ _____ _____ _____ _____ _____ 14

2.5.1 2.5.2 2.5.3

4

Variants___________________________________________________________________________11

H A R D WAR WA R E F UNCT UN CTII ONA L SPE CI F I CA TI ONS _____ _______ _____ _____ _____ _____ _____ _____ _____ _____ _____ _____ _____12 ___12

2.4.1 2.4.2

3

Protect Protection ion ________ ________ _________ ________ ________ ________ _________ ________ _______ 10 Tempera Temperature ture range range ________ ________ ________ ________ _________ ________ ________ ________ __ 10 Humidity Humidity range ________ _________ ________ ________ ________ _________ ________ ________ ___ 11

Stan Standa dard rdss ______________ _______________ _______________ _______________ _______ 11

1.5.1

2

Main Assembli Assemblies es Identific Identificatio ation n _________ ________ ________ ________ _________ ________ ________ 6 Main Dimensi Dimensions ons & Fixing Fixing Triangl Trianglee __________ ________ _________ ________ ________ ________ ___7 Direct Direct Connected Connected Terminal Terminal & Connecti Connections ons ________ ________ ________ _________ ________ ________ 8 Current Current Transfor Transformer mer connecte connected d Terminal Terminal & Connectio Connections ns ____________ ________ _________ ________ _8 Envelope Envelope Material Material ________ ________ ________ ________ _________ ________ ________ ________ ___8 Functions Functions on Cover ________ ________ _________ ________ ________ ________ _________ ________ _9 External External / Internal Internal IP Link _________ ________ ________ ________ _________ ________ ________ ___ 10 Auxili Auxiliary ary termin terminals als ________ ________ _________ ________ ________ ________ _________ ________ 10 Opening Opening Cover Detector Detector________ ________ ________ ________ _________ ________ ________ ________ ______ 10

PowerPower-Up Up ________ ________ _________ ________ ________ ________ _________ ________ _______ 30 PowerPower-Do Down wn ________ ________ ________ ________ _________ ________ ________ ________ ______ 30 Precisio Precision n on RTC setting setting ________ ________ _________ ________ ________ ________ _________ ____ 30

4.2 4.2

Cont Contra ract ct chan change ge ______________ _______________ _______________ _______________ __ 30

4.3 4.3

End En d of Billi Billing ng (E.O (E.O.B .B.)_ .)_ _______________ _______________ _______________ __________ 31

4.4 4.4

Load Load Manag Manageme ement nt ______________ _______________ _______________ _______________ 31

D iagnost iagnostic ic and Survey Survey _____ ________ _____ _____ _____ _____ _____ _____ _____ _____ _____ _____ _____ _____ _____ _____ _____ _____ _____ _____ _____ _____33 ___33 5.1.1 5.1.2

Parameter ParameterSetC SetChecksu hecksum m ________ ________ ________ _________ ________ ________ ________ ______ 33 ProgrammingCounter_________________________________________________________________33


Page 2 of 43

ACTA ACTARIS RIS


5.1.3 5.1.4 5.1.5 5.1.6 5.1.7 5.1.8

6

ReverseFlo ReverseFlowCoun wCounter ter ________ _________ ________ ________ ________ _________ ________ _______ 33 BillingPeriodCounter_________________________________________________________________33 Terminal Terminal Cover Cover Opening Opening Counter Counter________ ________ ________ ________ ________ _________ ________ _______ 33 CutOffCounter______________________________________________________________________33 StatusWor StatusWord d _________ ________ ________ ________ _________ ________ ________ ________ ______ 33 Check Check Reading Reading register register ________ ________ ________ _________ ________ ________ ________ ______ 33

COM C OMM M UNI UN I C A TI ONs ON s________ ____________ ________ ________ ________ ________ ________ ________ ________ ________ ________ ________ ________ _______ ___34 34 6.1 6.1

IR comm commun unica icati tion on port port : ______________ _______________ _______________ __________ 34

6.1.1 6.1.2 6.1.3

6.2 6.2

Flag Flag (IEC (IEC 61107) 61107) ReadRead-out out ________ ________ ________ ________ _________ ________ ________ ___ 34 COSEM COSEM Reading Reading and Programm Programming ing _______ _________ ________ ________ ________ _________ ____ 34 DATA DATA BUS OUTPUT OUTPUT _______ _________ ________ ________ ________ _________ ________ _______ 35

Loca Locall Read Readin ing g _______________ _______________ _______________ _______________ __ 35

6.2.1 6.2.2 6.2.3

Prin Princi ciple ple ________ ________ ________ _________ ________ ________ ________ _________ ________ 35 Data Data Format Format _________ ________ ________ ________ _________ ________ ________ ________ ______ 36 Remote Remote Reading_______________ Reading_______________ ________ _________ ________ ________ ________ _________ ____ 36

IMPO IMPORT RTAN ANT:_______________ T:_______________ _______________ _______________ _______________ _______ 36

7

8

9

I nsta nstallati llati on ___________________ _____________________________ ____________________ ____________________ ____________________ __________________ ________37 37 7.1

Prelimin Preliminary ary verificati verifications ons before before the meter meter is powered powered up ________ _____ ______ ______ ___ ______ ___ ______ ______ ______ ___ 37

7.2 7.2

Batter Battery y connect connection ion [optio [optional nal]] _________ ____ _____ _____ _____ _____ _____ _____ _____ _____ _____ __ 37

7.3 7.3

LCD LCD testi testing ng and Date Date and Time Time Set Settin ting g ________ ____ _________ _____ _____ _____ _____ _____ _____ _____ 37

7.4 7.4

Batter Battery y rep replac laceme ement nt [Op [Optio tional nal]] _________ ____ _____ _____ _____ _____ _____ _____ _____ _____ _____ 37

R eadi ng and and confi configur gura ation tool / " AI M S 5000" 5000" ________________________ __________________________________ ______________ ____38 38 8.1 8.1

Inst Install allati ation_____________ on_____________ _______________ _______________ _______________ _______ 38

8.2 8.2

Setup Set up ______________ _______________ _______________ _______________ __________ 38

8.3 8.3

User User and per permis missio sions ns manage managemen mentt _________ ____ _____ _____ _____ _____ _____ _____ _____ _____ __ 38

8.4 8.4

Mete Meterr mana manage geme ment nt _____________ _______________ _______________ _______________ 38

8.5 8.5

Conf Config igura urati tion on_____________ _____________ _______________ _______________ _______________ _____ 38

8.6 8.6

Cosem Cosem Conne Connecti ction on ______________ _______________ _______________ _______________ 38

8.7 8.7

Conf Configu igurat ration ion progra programm mming ing _________ ____ _____ _____ _____ _____ _____ _____ _____ _____ _____ __ 39

8.8 8.8

Data Data read readin ing______________________ g______________________ _______________ _______________ ____________ 39

8.9 8.9

Spec Specif ific ic acti action onss _______________ _______________ _______________ _______________ __ 39

A nnexe nnexess _____________________ _______________________________ ____________________ ____________________ ____________________ ___________________ _________40 40 9.1 9.1

Norms ______________ _______________ _______________ _______________ __________ 40

9.2 9.2

Config Configura uratio tion n and Exploi Exploitat tation ion data data _____ _____ _____ _____ _____ _____ _____ _____ _____ 41


Page 3 of 43

ACTA ACTARIS RIS

1


GENERAL

Meter Type

ACE 5000 type 5.1 3ph TSW

LifeTime

15 years (<0.5% drop-out rate/year)

Enclosure Protection Degree

Overall Terminal Block

IP 54 IP xxB

Temperature Range

Specified Operating Range Limit Range of Operation Storage & Transport

-25°C to 60°C -40°C to 70°C -40°C to 80°C

Humidity Range

Specified Operating+C22 Range Limit Range of Operation Storage & Transport

45% to 90%RH < 95% RH over 95% RH non condensing

Connection Type

3phases 3 wires or 4 wires

Internal or External

Metrology Accuracy

Active Energy Energy Reactive Energy

Class 1 IEC 61036 Class 2 IEC 61268

LED Constant

1000 pulses / kWh

In Test mode 5000 pulses available per kWh or kvarh

Terminal Connection

DIN 46 857 part2

(asymmetric connection)

Voltage Operating Range

Vn (Un) = 3x230 (400)V / 3x400V or Vn (Un) = 3x127 (220)V / 3x220V 3x220V Fully Redundant Power Supply

From -30% up to +25% ( Operation without loss of accuracy with only two wires connected )

Limit Voltage Ranges

(Un) 0V to 500 V

(Withstands neutral rupture)

LV/DC Nominal Current (Ib)

5A

(Other Ib currents available for commercial purposes)

LV/DC Maximum Current (Imax)

80A, 120A

LV/CTNominal Current (Ib)

1A

LV/CT Maximum Current (Imax)

10A

Limit Current Ranges

IP Link

(Other Ib currents available for commercial purposes)

Ib/250 1.2 Imax 30.Imax for ½ cycle nominal frequency

Starting current Limit max current Withstands :

Frequency

50, 60 Hz + 10%

Metrology Start Up

< 2.5s

Continue Operation on V drops

0.5s @ [ 0.7 Vn .. 1.25 Vn ]

0.2s

Back-Up Power Supply Unit

Lithium Battery Super-Capacitor

3 years / 23°C ; Rated shelf life of 10years 7 days capacity; recharge less than 12hours 12hours

Overall Consumption

2W and 4VA capacitive at Vn

Real Time Clock

+ 0.5s/day @ 23°C with Main Power and + 0.1s/day/°C for Specified Operating Range + 1s/day @ 23°C with Back-Up Power Power Clock accuracy

Time Switch & Registers Energy Registers NR = non resetable [1..n] registers registers per per Rate n = 8 for TSW only 3 energies possible, either P+, Q+, Por P+, Q+, Q-

Maximum Demand Registers

MDI. P+ or

S+

MDI. P+ or

S+ [1..n]

Max.I 1/2/3

Maximum Registers

Ma x.I1/2/3 [1..n] Max. P+ Max U 1/2/3

Instantaneous Values

if only two wires [ 0.9 Vn .. 1.25 Vn ]

According to IEC 61038 typically < 9s/month and < 3min/year for Specified Operating Range Range

4 Seasons with 4 Day Profiles & up to 8 Rates 12 End of Billing dates 72 Special Days P+ [1..n] (NR) P+Total (NR) Q+ [1..n] (NR) Q+Total (NR) P- or Q- [1..n] (NR) P- or Q-Total Q-Total (NR)

-

Leap year and Day-light Saving Time management One historical Billing data Bill.P+ Bill.P+ [1..n] [1..n] Bill.P+Total Bill.Q+ Bill.Q+ [1..n] Bill.Q+Total Bill.PBill.P- or or Q-[1..n] Q-[1..n] Bill.PBill.P- or Q-Total Q-Total

( W or VA ) ( W or VA)

( A ) filtered ( A ) filtered ( W ) filtered ( V ) not filtered

RMS Current per phase RMS Voltage per phase

(A) (V)

Hist.MDI.P+

or S+

Hist.MDI.P+

S+ [1..n] or S+

Hist.Bill.P+ Hist.Bill.P+ [1..n] Hist.Bill.P+ Hist.Bill.P+Total Total Hist.Bill.Q+ [1..n] Hist.Bill.Q+ Hist.Bill.Q+Total Total Hist.Bill.P- or Q-[1..n] Hist.Bill.PHist.Bill.P- or or Q-Total Q-Total ( W or VA) ( W or VA)

( kWh ) ( kvarh ) ( kWh or kvarh )

Number of Sub-interval s N = 1 to 5, 10 and 15 Sub-Interval Duration in minutes ∆ T = 1, 3, 5, 10, 15, 20, 30, 60 Block or sliding operation

Filter Time Constant = 20s, 5 or 10 minutes

Active Power Apparent Power Power Factor

(W) ( VA )

Displaying Information : 2 Push Buttons : Normal and Autoscrolling mode A: Scrolling button Special Function mode B: Reset button - sealable Test mode Readout (all data) according to IEC 61107 Read/Write (single data values) according to DLMS/COSEM (IEC 62056)

Display

Energy Resolution : 6+0 , 6+1 , 5+2 Digit size : 6mm x 8mm LCD display

Optical Port

IEC 61107 sealable optical port

Communication Communication Speed

Communication : 9600 bps

Data Bus Output or Pulse Output

Serial unidirectional unidirectional Data Bus Ouput with information information of Readout Readout @ 1200 bps (set by default) default) Pulse Output S0 (DIN 43 864 & IEC 62053-31 type A) Programmable constant for 500, 1000 and 2000 pulses / kWh or kvarh and programmable pulse length from 10ms up to 150ms

Load Management

0, 1 or 2 Relay out-puts 5 A 250 V

Insulation Strength

4 kV 50Hz for 1 min

Impulse Voltage Insulation Strength

Mains connections Output connections

Immunity to HF Fields

30 V/m < 2 GHz

Size ( W x H x D )

21 8 x 17 179 x 1 06 06 ( wi wi th th ou ou t T er er mi mi na na l C ov ov er er )

Weight

1.7 kg

Anti-fraud devices

Optical port password protection Number of times in programming mode Number of reverse energy detections Check read index

Configuration Tool

(MDI and EOB are reset automatically or manually through the push buttons)

Relays can be controlled directly, by rate change or by current threshold.

10 kV 12 kV

272 x 1 79 79 x 10 6 ( wi wi th th Te Te rm rm in ina l C ov ov er er )

Number of power outages Working time (total & by rate) Detection Terminal Cover Opening

AIMS+ 5000 with with Cripkey protection protection


Page 4 of 43

ACTARIS

1.1

CONFIDENTIAL

Scope

The meter is designed within the ACE 5000 family and is identified as 5.1 type.

The ACE 5.1 is an asymmetrical direct connected 3 phase 4 wire static meter for low voltage applications. The meter covers current ranges from 5A up to 120A providing active and reactive energy measurements according to class 1 IEC 61036 and class 2 IEC 61268 respectively and showing either one or the other through the calibration LED. The meter measures active and reactive energies, maximum consumed energies, power, currents and voltages. The meter integrates a Maximum Demand Regist er as well as an internal Real Time Clock managing a Time Switch up to 8 rates for 3 different energy types over 4 seasons with 4 different Day Profiles through 72 special days, plus the capability of automatically changing between Summer and Winter time. The ACE 5.1 carries Load Management features through up to two relay outputs, has permanent electrical readout output feature or the traditional DIN S0 pulse-output facility. It is designed with a back-up power supply carrying a super capacitor or a replaceable lithium battery. Automatic or manual End Of Billing holding one or more historical billing data. All meter data is stored in an Electrically Erasable Programmable Read Only Memory (EEPROM), which remains intact even in the event of long total power losses (over 10 years). The meter carries a LCD where the information displayed obeys to DLMS/COSEM identification code table or to codes set by the customer. An optical port communicating at 9600bps with the capability of being sealed is available allowing IEC61107 readout and DLMS/COSEM read/write. The meters are fully programmable through a dedicated Windows software application.


Page 5 of 43

ACTARIS

1.2

CONFIDENTIAL

Lifetime

The meter is designed to cope with a 15 years life-time with a maximum drop-out rate of 0.5% / year

1.3

Meter overview

1.3.1

Main Assemblies Identification

ACE 5.1 is made of: •

1 base

•

1 LCD and its holder

•

1 cover with Output terminals

•

1 Optical port and 1 metrology LED

•

1 replaceable battery and 2 push buttons (variant dependent)

•

1 top PCB with microcontroler & all metrology components

•

1 bottom PCB with power supply, I/O components & relays

•

1 terminal cover that protects the connection terminals against fraud.

•

1 terminal block with all associated connections and 1 retainer Metrological LED

Push Buttons D (Display)

Push Buttons S (Sealable)

Infrared Optica l port

Battery Holder

Cover

LCD

Top PCB Bottom PCB

1 Pulse output or Data Bu s Outpu t

2 Relays

Opcode

Terminal Cover

Base

ITerminal Block + current sensors


Page 6 of 43

ACTARIS

1.3.2

CONFIDENTIAL

Main Dimensions & Fixing Triangle

External Dimensions

•

Meter Fixing

The meter is designed to be mounted vertically, directly hooked on a metering board using a DIN three triangular arrangement points. The meter is removable from its mounting board only after breaking the terminal cover seal(s). Fixation Triangle

Tv

Th Meter

Th (mm)

Tv (mm)

ACE 5.1

150

186, 201 and 230


Page 7 of 43

ACTARIS

1.3.3 •

CONFIDENTIAL

Direct Connected Terminal & Connections

Terminals

ACE 5.1’s carries a VDE connection arrangement (asymmetrical terminals) of 120A or 80A of maximum current, with an internal or external IP link (common-point).

3 Phase 4 Wire meter connections

The main terminals accept wiring of 16mm², 35mm² and use 2 screws.

Note : This 120A VDE DC meter variant is not fully compliant with DIN 43-857 specification (non compliance stands for the neutral terminals pitch of 10 mm instead of 9 mm and terminal bore’s is greater than 6.5 mm). The reason comes from the DIN standard itself, specified for a 60A meter.

Cables The meter can withstand a permanent maximum current of :

TERMINALS

Copper

Aluminium

Cables

Cables

120 A (Copper)

ü

80 A (tinned)

ü

ü

1.3.4

Current Transformer connected Terminal & Connections

1.3.5

Envelope Material

Meter case has been designed and arranged so that any non-permanent deformation cannot prevent satisfactory meter operation. All plastic components are able to be recycled as expressed by their recycling markings. Parts color •

Standard colour: light grey RAL 7035

•

Push buttons: blue PANTONE 300.

•

Terminal Cover is grey or transparent


Page 8 of 43

ACTARIS

CONFIDENTIAL

The overall range of meters has been designed and constructed in order to avoid introducing any danger in normal use and under normal conditions ensuring: •

personal safety against electric shock

•

personal safety against effects of excessive temperature

•

protection against spread of fire

•

protection against penetration of solid objects, dust and water

•

protection against projecting particles in case of internal default.

All parts, which are subjected to corrosion under normal working conditions, are effectively protected. The material of which the meter is made passes the Glow Wire test given by IEC 695-2-1 :

1.3.6

•

Base and Terminal Block

- 960°C ± 15°C @ 30s ± 1s

•

Terminal cover and Cover - 650°C ± 10°C @ 30s ± 1s

Functions on Cover

Without having to remove the meter cover, it is possible to carry out the following operations: •

visually read the display unit and operate the buttons

•

visually read the nameplate or scan the serial number bar-code

•

read and program the meter through the optical port with a PC

reset max current, status word using the push buttons on the front of the meter cover or through the optical port •

•

start EOB, test relays, test LCD

•

test active or reactive energy meter accuracy by picking up LED pulse signals

•

replace battery

•

set date & time

Meter is marked by the following information •

Type of meter

•

The constructor’s identification

• •

Utility’s name and logo Legal approval identification

•

Meter accuracy class and Metrology Modes (See 3.1.2)

•

Distribution system : kind of current, number of wires

•

Meter constant

•

Reference voltage

•

Basic and maximum current

•

Reference frequency

• •

for double insulation Serial number

•

Bar-code

•

Outputs identification


Page 9 of 43

ACTARIS

1.3.7

CONFIDENTIAL

External / Inte rnal IP Link

According to the following pictures it is possible to select either external or internal IP Link which is provided by a transparent plastic part maintained by the sealed cover and allows or does not allows access to the common point screws.

External IP Link

1.3.8

Internal IP Link

Auxiliary terminals

Access to ACE 5.1 output terminals will only be possible after removing the terminal cover : Function

Reference

Bore size

Screw

Characteristics

Relay 1: Load management

20/21

4.4x4.2

M3

5A 250V

Relay 2: Load management

22/23

4.4x4.2

M3

5 A 250V

-

30/31

-

-

Blank

PO/DBO (Data Bus Output)

32 / 33

4.4x4.2

M3

I=10mA 240V

-

34/35

-

-

Blank

1.3.9

Opening Cover Detector

As an extended antifraud feature, the OPCODE (OPening COver DEtector) detects the opening of the sealed terminal cover at any time, i.e., even if the meter is completely powered down. When the mains are powered after a tamper event, while it was not powered, the meter will detect the tamper and increase the internal counter with 1 opening cover event. While powered, the device detects the number of times the terminal cover has been opened keeping a 1 second reset gap between two frauds. The OPCODE device is checked every 200ms and in case of fraud detection it is confirmed 200ms later. The "OPCODE tamper index" is increased and the device is reset. The "OPCODE tamper index" registers up to 255 events setting an overflow bit in the status word if the index rolls over to 0. This bit can be reset using the push buttons or the IR communication port.

1.4

Enclosure protection & Climate

1.4.1

Protection

ACE 5.1 has been designed to be an indoor meter carrying the following protection degrees: •

IP51 and IP54

1.4.2

Temperature range

ACE 5.1 has been designed to withstand the most severe climate conditions •

Operating Temperature Range:

-25°C to +60°C


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•

Limit Range of Operation:

-40°C to +70°C

•

Storage & Transport:

-40°C to +80°C

1.4.3

Humidity range

•

Operating Humidity Range:

45% to 90% relative humidity

•

Limit Range of Operation: Storage & Transport:

≤ 95%

•

1.5

relative humidity withstands over 95% relative humidity non condensing

Standards

ACE 5.1 complies with the following standards: •

Active energy, class 1.0 according to IEC 61036

•

Reactive energy, class 2.0 according to IEC 61268

•

Real Time Clock accuracy, according to IEC 61038

All versions of the meter comply with IEC 61107 Metering Communication Standard optical port. Data available through IEC 61107 for complete data readout and read and write according to DLMS/COSEM (IEC 62056). Please refer to Annexes section for complete norm list.

1.5.1

Variants

Based on the following options several variants are available •

CT 10A or DC 80A or DC120A

• •

Removable battery or Super Capacitor External or Internal IP LINK

•

With or Without Opcode

•

No, one or two Relays

•

Active Energy Class 1 or Clas s 2

•

Metrology Modes (See 3.1.2)

•

No or One or Two Pulse Output

•

Standard or Specific Marking

•

Default or Specific Configuration


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ACTARIS

2

CONFIDENTIAL

HARDWARE FUNCTIONAL SPECIFICATIONS

2.1

Power Supply Unit

The ACE 5.1 meter is designed with a fully redundant 3 phase 4 wire power supply, for 50, 60Hz frequency with nominal voltage of 127V up to 230V in 3 or 4 wires connection types. •

Withstands the inversion of one phase and neutral.

•

2 wires from the 4 possible are mandatory for product operation.

±10%

network

Design Note : The meter has 3 different qualified network voltages (220, 230 and 240V), however the reference network voltage used in all calculations dimensioning the meter is 230 V (Vn). Power consumption: The maximum overall consumption per ph ase of the apparatus under the reference conditions is : •

2 W and 4 VA inductive.

Typical per phase power consumption are: Current circuit DC(Ib=10A, Un=230V) 50mVA CT(Ib=5A, Un=230V) 250mVA

2.2

Voltage circuit 0.5W_0.8VA 0.5W_0.8VA

LV/DC Current ranges

Nominal Operating Current Range •

Basic Current (Ib): 5A

•

Max Currents: 80A for 80A variant or 120A for 120A variant

Limit Current Operating Range •

Starting Current : 20mA

•

Maximum current: 1.2 Imax , i.e, 96 A for Imax 1 and 144 A for Imax 2

The meter withstands 30 times Imax for ½ cycle at nominal frequency range

2.3

Meter Variants

30 times Imax

80 A

2 400 A

120 A

3 600 A

LV/CT Current ranges

Nominal Operating Current Range •

Basic Current (Ib): 1A

•

Max Currents: 10A

2.4

Real Time clock (acc. to IEC 61038)

All real timing functions within the meter, like rate changes or special day management, among others, are derived from the integrated real time clock (RTC). Its source is internal and based on a 32.768 kHz crystal. This meter is equipped with a small back-up power supply, and optionally either a lithium battery or a supercapacitor. Without the extra energy sources the auxiliary power circuit holds the RTC working for at least 15 minutes. In case of the super-capacitor, the RTC is maintained at least 7days of continuous total supply outage. If the lithium battery is chosen, it will maintain the RTC up to 3 years. Characteristics of Time accuracy: •

± 0,5s

per day at 23°C when meter is powered by main


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•

±1s

per day when RTC is powered by backup power

•

± 0.1s

per day per °C: temperature deviation for operating scope = -25°C to 60°C in accordance with Operating range

As the crystal drift is not linear over the temperature range and time, the internal clock source accuracy is better than 15 seconds per month at 23°C, and 6 minutes per year over the full temperature range. Time is possible to be set (re-synchronised) with 1 second accuracy [hh,mm,ss], by a programming operation using the IR port or directly using the sealed push-button on the meter cover. The meter verifies the consistency of Date & Time programmed in the meter and rejects not valid ones.

2.4.1

Battery

The meter may be equipped with a replaceable lithium battery, which is accessed by a battery holder placed on the front of the meter. This battery holder can be sealed and therefore its access possible only after breaking it. The battery carries the following characteristics : •

Standard size Lithium battery CR2450,

•

Rated shelf life of 10 years (20 years typically),

The battery is modified into an assembly to fit meter’s battery holder. The battery holder provides a space to put a sticker to indicate battery date of change. also indicates a printed forecasted date for its replacement. A battery failure indication is shown in the display when the battery capacity decreased by about 10% or when it is absent.

2.4.2

Super Capacitor

The Super capacitor is placed on the meter’s bottom board and not replaceable. It assures a minimum capacity of 7 days in case of continuous total supply outage with a recharging time no more than 12 hours.


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ACTARIS

2.5

CONFIDENTIAL

Human Machine Interface

The Human Machine Interface is the communication mean between the end user and the meter without interposed devices. The User Interface is made of two push buttons and one LCD Display.

2.5.1

LCD overview

As described earlier the meter carries a Liquid Crystal Display, which is organised in 3 different areas with a total of 60x20mm viewing surface. •

Area 1 – Main digits Area 2 – Code digits

•

Area 3 – Units informatio n (the 5 bottom icons are printed on the meter nameplate)

•

R1

R2

The information displayed is shown on an auto-scrolling mode, which can be interrupted at any time by the use of the push buttons shifting to a manual scrolling. The display can be read at a 3 m distance of and its contrast value is greater than 0.90. 2.5.1.1

Main Digits

Decimal dot position is configurable (no, one or two decimal points, i.e. format "6.0" "6.1" or " 5.2"). 2.5.1.2

Code Digits area

NB: The code is blinking when the value correspond to an active tariff. For each parameter, the following letters can be displayed in the Code Digits area when the OBIS codes are not used.

Letter

LCD Code

Letter

A, a

N, n

B, b

O, o

C, c

P, p

D, d

Q, q

E, e

R, r


LCD Code

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ACTARIS

CONFIDENTIAL

F, f

S, s

G, g

T, t

H, h

U, u

I, i

V, v

J, j

Y, y

L, l

Z, z

M, m

-, _

K,k v W,w X,x

All stay blank

ATTENTION: Several letters must be used with care due to possible misunderstandings. They are : Capital "i"

Can be 1, capital "i" or small "L"

Small "L"

Can be 1, capital "i" or small "L"

Capital "O"

Can be number 0

Capital and Small "Q"

Can be number 9

Capital and Small "S"

Can be Number 5

Capital "V"

Equal to capital letter "U"

Capital "Z"

Can be number 2

Should also pay attention the space left by the symbols "1", capital "I" and small "L". Although two letters ensue each other, by optical effect the user may read a space. Examples: MDI6 (Max Demand Register) th

We can either read Max Demand value for 16 rate !… th

or we can read Max Demand Register for 6 rate !… Ul1 (Voltage Phase 1) HIST (Historical)


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ACTARIS

2.5.1.3

CONFIDENTIAL

Units and Icons area

Cursors: when lightened above the following ideograms, means •

Communication in progress

•

Excess Demand above a treshold

• •

R1

Relay 1 closed

R2

Relay 2 closed Battery failure

•

Arrows icons: •

P+ Import Aggregate Active Energy flowing

•

P- Export Aggregate Active Energy flowing

•

Q+ Import Aggregate Reactive Energy flowing

Q- Export Aggregate Reactive Energy flowing When there is no energy flowing through the meter (meter blocked) the arrows are unlightened. •

Units: Depending on the value, the following units are displayable kWh, kW, A , V, VA, kVarh, Var Phase icons: Lx: continuously lightened when voltage on Lx Lx: unlightened when no voltage on Lx L1 & L2 & L3: blinking at 2Hz in case of wrong connection (order, inversion) or overvoltage Lx : blinking at 2Hz in case of overvoltage on Lx


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ACTARIS

2.5.2

CONFIDENTIAL

LCD modes

There are two push buttons (A and B) situated on the top right hand corner of the meter cover. Their role consists on giving user access to 3 main different LCD modes which allows the user either to read the data "Reading mode", or to perform specific actions "Special Function Mode" or to configure Energy retransmitted on the metrological Led "Test Mode". The following state chart present the procedure to switch between each mode.

Alar m mo de No overvoltage during 10 s.

Overvoltage

Reading Mode

Short Pressure on B AND current diplay different than Metrol ogical pulses

Display mode

Long Pressure on A OR Short Pressure on A 5 min. time out

Special Function Mode Short Press on A and B Long Pressure on B

Test Mode Short Pressure on A

Auto scrol ling mode

Long Pressure on A

60 min. time out (if authorized)

Long Pressure on B or Time Out

Blank mode

2.5.2.1 2.5.2.1.1

Reading Mode / Available data Sub mode Display

In normal mode, most of the exploitation data are configurable with AIMS, the list of these data is given in annex 9.2. The data itself and the associated parameter code (by default OBIS codes Ref[8]) are configurable with AIMS. Used Push buttons: A only to go from one parameter to the next one. 2.5.2.1.2

Sub mode Auto Scrolling

Each parameter is displayed every 5 seconds.


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ACTARIS

2.5.2.2

CONFIDENTIAL

Special function mode / Available data and action

IMPORTANT: This mode is not accessible when there is a communication in progress Special Function Main State Chart

Actions sub-State Chart Principle

Normal Mode

Value n

Short Press B

XXX.n

Special Function Mode

A pressed

Value n+1 Sequence 1 A&B

XXX.n+1

pressed A pressed

A pressed

A pressed (Action canceled)

Sequence 2 Value m A&B pressed

XXX.m A pressed

Sequence n

A and B pressed

Values are one of these: billing energy registers per tariff; status word; maximum currents per phase and per tariff.

Proposed Action

B pressed (Action confirmed)

Execution Report

Ÿ Ÿ Ÿ

Proposed Action can be one of these: bill , to generate End Of Billing; rESEt , to erase Status Word. rESEt , to erase Max Currents. Ÿ Ÿ Ÿ

At these step, user can either: execute proposed action by pushing S button; cancel action and restart the sequence by pushing D button. Ÿ Ÿ

Execution Report can be one of these: Eob , to indicate End Of Billing is done; St = 0 , to indicate Status Word is erased; MC = 0 , to indicate Max Current is erased. Ÿ Ÿ Ÿ


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Once entered in Special Function Mode the following sequences could be used (Hypothesis: all the possible actions chose by the customer) Sequence 1: LCD Test : All segments displayed (Good repair to check the Special Function Mode enter because of the limited Human Interface Ergonomy) Sequence 2: Reset Maximum current per tariff and per phase (depending on the contract) Sequence 3: Reset Status Words Sequence 4: Test of output relays. Sequence 5: End Of Billing Sequence 6: Set the date and time Because Sequence 4 and 6 does not strictly follow the State-Chart above, the two next State-Chart describes the procedure to follow.

Relays test sub-State Chart

tESt relay(s) icon()s

D pressed

tESt 1 NOTE 1: this sequence is accessible if the meter has at least 1 relay. Otherwise, it will be bypassed by the meter.

1 or 2 relays opened A pressed (only 1 relay)

D pressed

tESt 2

NOTE 2: if there is only 1 relay, the 2 last states are bypassed.

1 or 2 relays closed

D pressed (2 relays)

A pressed

tESt 3 left relays opened - right relay closed

D pressed

tESt 4 left relays closed - right relay opened

A & B pressed


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ACTARIS

CONFIDENTIAL

Date and time setting sub-State Chart

A & B pressed

DD:MM:YY

A & B pressed

Date setting code

HH:MM:SS Time setting code

A or B pressed

A pressed increase Year

DD:MM: YY Date setting code

A or B pressed

B pressed decrease Year

A pressed increase Hour

HH :MM:SS Time setting code

A & B pressed

A pressed increase Month

DD: MM:YY Date setting code

DD:MM:YY Date setting code

B pressed decrease Hour

A & B pressed

B pressed decrease Month

A pressed increase Minute

HH: MM:SS Time setting code

A & B pressed

A pressed increase Day

A & B pressed

B pressed decrease Minute

A & B pressed

B pressed decrease Day

A pressed increase Second

HH:MM: S S Time setting code

B pressed decrease Second

NOTE 1: if the time format is AM/ PM, a dot is used to indicate AM/PM information. Dot lightened means PM. This dot is located just after SS field. NOTE 2: even if the date format is MM:DD:YY, day setting comes after month setting.

A & B pressed


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ACTARIS

2.5.2.3

CONFIDENTIAL

Test Mode / Available data and actions

This mode allows to change the energy type retransmitted on the metrological Led (Active or Reactive), to increase the Led constant Pulse / kwh or kvarh and to read the active or reactive energy register in 5.2 format (2 decimals). Note: In order to allow a customer to stay in test mode in their Laboratory for example, the Exit Time Out of this mode is configurable in days and independent from power down/up.

Test Mode Reminder: Long Press on B to enter in test mode fromReading Mode 2 Exit Conditions, either Long Press on B or continuous x days test mode time-out (configurable). In case of power down in test mode, test mode is recovered at Power up. P is the Led pulse constant (configurable) IR communication (COSEM or 1107) are authorised in this mode. Ÿ Ÿ Ÿ Ÿ Ÿ

Reading Mode

Metrological Led

LCD Ph1

LED Active P pulses / kWh

123456

kWh

Ph2 Ph3

LONG press B

Ph1


LEd

P

Short press A

kWh

23456.78

kWh

Short PressA

Ph2 Ph3

Current active (or reactive) index. Phase icons are lighting if blocked or unlighting if started.

Short Press B

Ph1

LED Active 5000 pulses / kWh

Short press A

kWh

LEd 5

23456.78

kWh

Short PressA

Ph2 Ph3

Short Press B and Reactive Register visible

Ph1

LED Réactive P pulses / kvarh

LEd

P

Short press A

kvarh

06875.42

kvarh

Short press A

Ph2 Ph3

Short Press B and Reactive Register visible

Ph1

LED Réactive 5000 pulses / kvarh

LEd 5

Short press A

kvarh

Short Press B AND Reactive Registers NOT visible

Short press A

06875.42

kvarh

Ph2 Ph3

Test Mode Metrological LED

Long Press B or Time Out

Ph1


123456

kWh

Ph2 Ph3

Reading mode


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CONFIDENTIAL

2.5.2.4

Alarm Mode

If an overvoltage is detected on RMS Voltages per phase (overvoltage threshold configurable), the message "ALArM V" is displayed. 10 second after the overvoltage disappears, the LCD comes back to the previous state in Display mode.

2.5.3

Metrology LED

The LED designed to emit the metrology pulses is visible from outside, with the meter in operating position. The nominal characteristics of this LED are as follows: •

luminance (10 mCd)

•

red colour

• •

Angle of vision ± 15°. Convergence is obtained for a distance between 0 and 5 mm from the front panel.

A metallic part on the meter case is used to hold a reading cell by magnetic attraction. Pre-centering exists on the meter.


Page 22 of 43

ACTARIS

3

CONFIDENTIAL

METROLOGY

3.1

Metrology Indications

The ACE 5.1 is a Class1 Active energy meter according to IEC61036 and a Class2 Reactive energy meter according to IEC61268.

3.1.1

Metrology principle

The apparatus is equipped with 3 special design current transformers, internally called MCT (Mutual Current Transformer), providing the AD converter with an analogue current ratio. Samples read on the meter elements, which are not modified by calculation, are (V1, V2, V3, I1, I2, I3) and permit, among others, the calculation of active, reactive and apparent energy quantities, as well as the power factor and RMS values. Voltage and current signals are sampled and processed to be compensated, equalised, calibrated and phase corrected in order to give final filtered voltage and current values.

3.1.2

Metrology modes

Two different energy measurement modes are available in the meter. •

Bi-directional Mode - concerns (P+, P-, Q+) and is represented by the symbol

Unidirectional Mode - concerns (P+, Q+, Q-) and is represented by the symbol Note: These 2 energy measurement modes are factory programmable only •

Within each mode there are three available agg reg ate energ y c alculation mode: •

Ferraris,

•

Static,

•

Anti-fraud .

Note: These 3 aggregate energy calculation modes are customer programmable Description of Bi-directional Mode: (P+, P-, Q+) "n" is the phase number

Metrology LED

LED

Active

LED Reactive

Static |Σ

Pn |

|Σ

Qn | +

Anti-fraud

PO Active

Σ Pn if Σ Pn > 0

PO Reactive

Σ Qn if Σ Q n > 0

P+ Register

Σ Pn if Σ Pn > 0

P- Register

Σ Pn if Σ Pn < 0

|Σ Pn-|

Q+ Register

Σ Qn if Σ Q n > 0

Σ Qn

Pulse Output

Energy Registers

Ferraris

Σ Pn

Σ Pn Σ Qn

Σ Pn


+

+

+ |Σ

Pn- |

+

+ |Σ

Pn- |

+

Σ Pn

+

Page 23 of 43

ACTARIS

CONFIDENTIAL

Description of Unidirectional Mode: (P+, Q+, Q-)

Ferraris

"n" is the phase number

Metrology LED

LED

Active

LED Reactive

|Σ

Pn |

|Σ

Qn |

Σ Pn

Anti-fraud

+

PO Active

Σ Pn if Σ Pn > 0

PO Reactive

Σ Qn if Σ Q n > 0

P+ Register

Σ Pn if Σ Pn > 0

Q+ Register

Σ Qn if Σ Q n > 0

Σ Qn

Q- Register

Σ Qn if Σ Q n < 0

| Σ Qn-|

Pulse Output

Energy Registers

Static

Σ Pn Σ Qn

Σ Pn

+

+

+ |Σ

Pn- |

+

+ |Σ

Pn- |

+

Σ Pn +

Example depending on the measurement mode chosen above, after 1 second of measurement period Meas ur ed A cti ve Energy (wh)

S tatus o f A cti ve Energy

Meas ur ed R eacti ve Energy (varh)

II

+2 -5

Import Export

+7 -5

III

+1

Import

+1

Phase

I

The metrology outputs and the different registers will then be distributed the way described below :

Ferraris

S tatic

Metrology pulses Active

|2-5+1|=2

Metrology pulses Reactive

|7-5+1|=3

Pulses in PO Active

2 - 5 + 1 = -2 => 0

Pulses in PO Reactive

2+1=3

A nti -F raud

2+5+1=8

7+1=8

Energy register P+

2 - 5 + 1 = -2 => 0

2+1=3

2+5+1=8

Energy register

P-

2 - 5 + 1 = -2 => 2

5

5

Energy register

Q+

7+1=8

Ferraris

S tatic

Metrology pulses Active

|2-5+1|=2

Metrology pulses Reactive

|7-5+1|=3

Pulses in PO Active

2 - 5 + 1 = -2 => 0

Pulses in PO Reactive

Energy register P+

2+1=3

A nti -F raud

2+5+1=8

7-5+1=3

2 - 5 + 1 = -2 => 0

2+1=3

Energy register

Q+

7-5+1=3

Energy register

Q-

7 - 5 + 1 = 3 => 0


2+5+1=8

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ACTARIS

CONFIDENTIAL

IMPORTANT : As shown above, although the export reactive energy is selected, leaving only one active energy register, the meter still measures the export active energy but this value is saved only when in anti-fraud mode.

3.1.3

Metrology LED constant and duration

The metrology LED has been designed to display metrology luminous pulses (blinks) for active or reactive energy, visible from outside, with the meter in operating position. The LED transmits active or reactive energy pulses depending on configuration. The led is mainly used for meter calibration. And its nominal pulse length is 10 ms for ON state and 10 ms for OFF. Meter constant corresponds to the electrical energy measured between two consecutive pulses. No problem of saturation exists with the pulses, even in case of heavy consumption. ( Over 3ph @ 1.2 Imax (144A) & 1.25x240V ) 3.1.3.1

LV/DC Metrological Led constant

Standard pulse rates: 500 - 1000 – 2000 pulses/kWh (Configur able with AIMS) In LCD Test mode the pulse rate could be increased to 5000 pulses/kWh 3.1.3.2

LV/CT Metrological Led constant

Standard pulse rates: 50 - 100 – 200 pulses/kWh (Configu rable with AIMS) In LCD Test mode the pulse rate could be increased to 500 pulses/kWh

3.1.4

Pulse Output

During a cut -off, a saving into the EEPROM of pulses which have to be emitted is done, in order to retransmit it just after power-up. In case of saturation, the LED pulses and the pulse of the pulse output device will no longer be synchronised. The Pulse emitter device can be active or inactive. The selection of pulse transmission (active or not) is carried out via IR communication. The pulse output device is exclusive with the Data Output (see 6.1.3). (Recall of definition under DIN 43-864 and IEC 62053-31 type A) max voltage : U = 27 V DC max current : I = 27 mA DC max wire length : l = 0.5 m (for a standard DIN S0 pulse emitter connection) 3.1.4.1

LV/DC Metrological Led constant

Standard pulse rates: 500 - 1000 – 2000 pulses/kWh (Configurable with AIMS) 3.1.4.2

LV/CT Metrological Led constant

Standard pulse rates: 50 * CT ratio - 100 * CT ratio – 200 * CT ratio pulses/kWh (Configurable with AIMS)

3.1.5 •

Instantaneous values

Rms currents and voltages

Rms Current per phase and Rms Voltage per phase are calculated from an accumulation of squared Current and Voltage samples between 1 second tops, being «square-rooted» during the same time period. •

Active Power

The meter calculates every second the instantaneous Active Power quantity W. The Active Energy calculated at the sampling frequency (USAMPLE * ISAMPLE) is accumulated in the Active Power register every second providing an average «instantaneous» Active Power every second once divided by the number of samples over


Page 25 of 43

ACTARIS

CONFIDENTIAL

the period. Its sign is used to determine the active energy direction (import or export) and its absolute value is used to determine if the energy status is BLOCKED or STARTED. •

Average Apparent Power

Measurement of the RMS Apparent Power is carried out every second using the RMS arithmetic method : the Apparent Power VA comes from the multiplication between Urms and Irms. •

Power Factor

The power factor is calculated every second per phase and aggregate. Pf agg = kWagg / kVAagg

(P / S )

The resolution of the calculation is 0,01. The calculation uses active power signed and apparent power unsigned. The sign of the Power Factor is the sign of Active Power. •

Phase sequence (V 1/V 2, V 1/V3, V2/V 3)

This function returns the voltage to voltage angle according to the different connection types. From these angles are deduce the phase sequence. When the phase sequence is wrong, a bit is raised in the status word. As soon as the right connection is restored, the bit is reset .

3.2

Exploitation data

Design Note : all energy registers are calculated and saved with the 0 precision of one unit ( 1x10 ).

3.2.1

Energy Registers

Nota: Internal energy register resolution is Wh and Varh respectively for Active and Reactive energy. P+ [1..n] P+Total

*1 *1

(NR)

Active Energy Import, data registered per tariff. No reset possible.

(NR)

Active Energy Import Total, sum-up of all Active Energy Import tariff registers. No reset possible. This register is tariff independent.

Bill.P+ [1..n]

Billing Active Energy Import, data registered per tariff during a billing period. Registers reset to zero at End Of Billing (EOB)

Bill.P+Total

Billing Active Energy Import Total, sum-up of all Active Energy Import tariff registers during a billing period. Register reset to zero at End Of Billing (EOB). This register is tariff independent.

Hist.Bill.P+ [1..n]

Historical Billing Active Energy Import, data registered per tariff during the previous billing period. Registers reset with respective tariff Billing Active Energy Import register’s value at End Of Billing (EOB)

Hist.Bill.P+Total

Billing Active Energy Import Total, sum-up of all Active Energy Import tariff registers during a billing period. Register refreshed at End Of Billing (EOB). This register is tariff independent.

*1

P- [1..n] P-Total

*2 *2

Bill.P- [1..n]

These are described as Import registers but they cumulate Export energy as well as when Absolute Value Mode is selected

(NR)

Active Energy Export, data registered per tariff. No reset possible.

(NR)

Active Energy Export Total, sum-up of all Active Energy Export tariff registers. No reset possible. This register is tariff independent. Billing Active Energy Export, data registered per tariff during a billing period. Registers reset to zero at End Of Billing (EOB)


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Bill.P-Total

Billing Active Energy Export Total, sum-up of all Active Energy Export tariff registers during a billing period. Register reset to zero at End Of Billing (EOB). This register is tariff independent.

Hist.Bill.P- [1..n]

Historical Billing Active Energy Export, data registered per tariff during the previous billing period. Registers reset with respective tariff Billing Active Energy Export register’s value at End Of Billing (EOB)

Hist.Bill.P-Total

Billing Active Energy Export Total, sum-up of all Active Energy Export tariff registers during a billing period. Register refreshed at End Of Billing (EOB). This register is tariff independent.

*2

These are described as Export registers but they cumulate export energy only when this energy is selected

Q+ [1..n]

(NR)

Import Reactive Energy, data registered per tariff. No reset possible.

Q+Total

(NR)

Import Reactive Energy Total, sum-up of all import Reactive Energy tariff registers. No reset possible. This register is tariff independent.

Bill.Q+ [1..n]

Import Billing Reactive Energy, data registered per tariff during a billing period. Registers reset to zero at End Of Billing (EOB)

Bill.Q+Total

Import Billing Reactive Energy Total, sum-up of all import Reactive Energy tariff registers during a billing period. Register reset to zero at End Of Billing (EOB). This register is tariff independent.

Hist.Bill.Q+ [1..n]

Historical Import Billing Reactive Energy, data registered per tariff during the previous billing period. Registers reset with respective tariff import Billing Reactive Energy register’s value at End Of Billing (EOB)

Hist.Bill.Q+Total

Import Historical Billing Reactive Energy Total, sum-up of all import historical Reactive Energy tariff registers during a billing period. Register refreshed at End Of Billing (EOB). This register is tariff independent.

Q- [1..n]

(NR)

Export Reactive Energy, data registered per tariff. No reset possible.

Q-Total

(NR)

Export Reactive Energy Total, sum-up of all export Reactive Energy tariff registers. No reset possible. This register is tariff independent.

Bill.Q- [1..n]

Export Billing Reactive Energy, data registered per tariff during a billing period. Registers reset to zero at End Of Billing (EOB)

Bill.Q-Total

Export Billing Reactive Energy Total, sum-up of all export Reactive Energy tariff registers during a billing period. Register reset to zero at End Of Billing (EOB). This register is tariff independent.

Hist.Bill.Q- [1..n]

Historical Export Billing Reactive Energy, data registered per tariff during the previous billing period. Registers reset with respective tariff export Billing Reactive Energy register’s value at End Of Billing (EOB)

Hist.Bill.Q-Total

Export Historical Billing Reactive Energy Total, sum-up of all export historical Reactive Energy tariff registers during a billing period. Register refreshed at End Of Billing (EOB). This register is tariff independent.

*3

These are export reactive energy registers, used only when this energy is selected.


Page 27 of 43

ACTARIS

3.2.2

CONFIDENTIAL

Maximum Demand Registers

The values measured by the Maximum Demand Registers are power averages determined over a chosen number of Sub-Intervals with a selected time duration: Number of Sub-intervals: N = 1 to 5, 10 and 15. Sub-Interval Duration in minutes: DT = 1, 3, 5, 10, 15, 20, 30, 60.

The calculation of the MDR is synchronised on the RTC, i.e. the time of an end of integration period is a multiple of the programmed sub-interval duration.

Sub intervals duration (min.)

Time of end of integration period

1

Minutes 0, 1, 2, 3, 4, 5, 6, 7, ….., 58, 59 of an hour.

3

Minutes 0, 3, 6, 9, 12, 15, 18, 21, 24, 27, 30, …., 54, 57 of an hour.

5

Minutes 0, 5, 10, 15, 20, 25, 30, 35, 40, 45, 50, 55 of an hour.

10

Minutes 0, 10, 20, 30, 40, 50 of an hour.

15

Minutes 0, 15, 30, 45 of an hour.

20

Minutes 0, 20, 40 of an hour.

30

Minutes 0, 30 of an hour.

60

Minute 0 of an hour.

In case of exceptional events (tariff change, end of billing, contract change, power down or clock setting (except DST event)), the ongoing integration period is stopped. Depending on a choice made by a programmed parameter through the IR communication port, the calculation of the last integration period can be neglected or computed theoretically as if the integration period was complete. After these events (power up instead of power down), a new integration period begins: the time between the event and the end of the integration period synchronised on the RTC is considered as a complete integration period.

One of two maximum energy types could be managed depending of the customer order (once the type defined, it is not possible to change afterwards either with Push buttons or with AIMS). The possible types are Active Import (P+) or Apparent Import (S+).

MDI.P+ [1..n] (respectively S+)

W (resp. VA) - Maximum Demand Register of Active Power Import per tariff. Average maximum power per tariff over the predefined number and duration of Sub-intervals. Reset to zero at End Of Billing (EOB). (respectively Apparent Import)

MDI.P+ (respectively S+)

W (resp. VA) - Maximum Demand Register of Active Power Import. This register is tariff independent and represent the maximum of the MDI.P+ [1..n]. Reset to zero at End Of Billing (EOB). (respectively Apparent Import)

Hist.MDI.P+ [1..n] (respectively S+) W (resp. VA) - Historical Maximum Demand Register of Active Power Import per tariff. Registers refreshed with respective Maximum Demand Indicator of Active Power Import per tariff register’s value at End Of Billing (EOB). (respectively Apparent Import)


Page 28 of 43

ACTARIS

CONFIDENTIAL

Hist.MDI.P+ (respectively S+)

3.2.3

W (resp. VA) - Historical Maximum Demand Register of Active Power Import. Register refreshed with Maximum Demand Indicator of Active Power Import register’s value at End Of Billing (EOB). (respectively Apparent Import)

Maximum Registers

The maximum registers report the maximum values over an averaged sliding period of time, this period of time is called “Filter Time Constant” and can take the following values: 20 seconds, 5 or 10 minutes. The averaged Current values per tariff are used for Load Management ( see 4.4). The aim of this sliding window is to simulate the thermal behaviour of a circuit-breaker allowing the detection of fraud to the subscribed currents. These values are reset to zero via the IR communication port or using the push buttons. The meter is also equipped with a special memory case where the maximum voltage values per phase are saved.. Max.I1/2/3

A - Maximum current per phase measured selected time window.

Max.I1/2/3 [1..n]

A - Maximum current per phase and per tariff measured the selected time window.

Max.P+

W - Maximum Active Power Import measured for the selected time window

In addition maximum voltages are not filtered in order to detect over-voltage events. Max U1/2/3

V - Maximum voltage per phase (non resettable)


Page 29 of 43

ACTARIS

4

CONFIDENTIAL

TARIFFS

4.1

Definition & ACE 5.1 Time Switch:

A tariff, or rate, is a well-determined period of time during which a set of registers is enabled and used for billing purposes. The meter carries only one living tariff at a time, applicable to all billing registers, being able to change it 8 times every 24-hour period. The ACE 5.1 is equipped with 8 tariffs that can be used to set 4 different day profiles. Each day profile will then be used to define the meter's behaviour through 7- week days, defining a week profile. There are 4-week profiles available, one for each season (therefore 4 seasons). 72 special days are available which are defined through the set of generic dates. These dates are defined either by a year less fixed date (ex: 01_MAY) or by a generic sliding date (ex: First Sunday of November). The group of Timse Switch options is defined as a calendar. Able to support a calendar from 01_JAN_2000 to 31_DEC_2099, the apparatus carries the following functions: •

Leap year – every year that can be divided by 4 is a leap year. When internal time of the meter i s 31_DEC_2099 at 23h59mn59sec, then Date & Time restart from 01_JAN_2000 at 0h0mn0sec and corresponding bit in the RTC Status word is set. Leap year Management is not configurable.

•

Day Light Saving Time – a total of 16 years could be handled with 32 programmed dates. It is also possible to define generic dates. 2 DST adjustments can be defined each year; one advance & one reverse in any order. In the same configuration, for each year, advance & reverse DST adjustment shall be always in the same order and contains therefore a total of 32 DST adjustments.

•

Current and Latent calendar – the future calendar allows a change of time switch behaviour after a configurable date. (This feature is particularly useful when an utility wants to programme a simultaneous calendar change over a wide meter population)

Each tariff can have a different subscribed current. These subscribed current per tariff can be used by the utilities for billing purposes as it establishes a current threshold. This threshold is responsible for the Load Management, i.e., the control of up two relay outputs (see § 4.4 Load Management). Besides the control by current threshold, the relays could also be controlled by the daily tariff changes (maximum 8 per day).

4.1.1 Power-Up In case of a mains failure the meter re-synchronises the calendar at power-up with the current Date & Time and sets the state of the meter (Tariff rate, Relays & Excess Demand Flag) according to the current Date & Time. At power-up, if Date & Time is lost, the RTC restart 01 January 2000, in addition a flag is set, allowing blinking of time displayed on LCD.

4.1.2

Power-Down

While power is down the meter continues to count Date & Time, within its auxiliary power supply limits. No other actions are performed. (See §2.3 for definition on Real Time Clock)

4.1.3

Precision on RTC setting

Depending on the configuration, the format of the available RTC information on the Display, will be either on a 24h or 12h format (plus AM/PM).

4.2

Contract change

A contract is the name given to the set of up to 8 tariffs, or rates, agreed between the utility and the final client. A contract change can only be performed through the IR communication port using AIMS 5000. It allows for a given pre-programmed Time Switch to limit or extend the tariffs used. When the contract change is processed, an automatic EOB is performed.


Page 30 of 43

ACTARIS

4.3

CONFIDENTIAL

End of Billing (E.O.B.)

The End Of Billing orders are given either by the IR communication port, using the push button or through the pre-programmed internal calendar. Two types of EOB could be performed (configurable by the customer with AIMS 5000) •

"Cumulative" mode: Copy of the billing registers per tariff and total into the corresponding registers

•

"Hybrid " mode: Copy of the billing registers per tariff and total into the corresponding registers and reset of the billing registers per tariff.

The internal calendar carries up to 12 year-less End Of Billing dates (day / month) permitting yearly roll-over and it occurs by default at 00:00:00 hours. Note: If a power-off masks more than one End of Billing event, only one End of Billing will be generated at power-up. Note: For a matter of security, specially thinking on manual meter reading events, the meter prevents two End Of Billing orders within the same half-hour (30 minutes). If by any chance two successive EOB orders were given too close, and no energy had been registered, the data of at least one historical set of registers would have been lost.

4.4

Load Management

Load Management (dynamic load management or load shedding) is a functionality that generates actions directly on the output circuits (relays). As soon as averaged RMS current (see 3.2.3) of one of the 3 phases is above the subscribed current in use (the current threshold chosen per tariff - §4.1), an excess of consumption is detected. The relays are then switched to a pre-defined position (configurable with AIMS). The meter has two output circuits delivered as options. The output circuits are equipped with single direction, single-pole electric-control cut-off equipment. These controls lead to stable states able to support currents up to 5A and 250V. The actions over the relays are made through the tariff change and through the control of the consumed current by the load connected to the meter As well as to the hy steresis control values, explained below. The hysteresis avoids the relays to switch on & off too many times when the averaged current value is around the subscribed current. The management of the load through the evaluation of its current threshold is prior to the tariff. An icon is set and erased on the display depending of the status of the over-current. The hysteresis values are defined in the Configuration programme and loaded into the meter through the optical port. The example below represents the averaged current of a phase and the state of a relay when the hysteresis values are crossed.


Page 31 of 43

ACTARIS

CONFIDENTIAL

Hysteresis High Value

Subscribed current

Hysteresis Low Value

Relay ON

Relay OFF

Relay ON

Electrical requirement: •

Breaking power of the enclosed output circuits Each output circuit is able to carry out 60 000 operations (30 000 closings and 30 000 openings) under the following conditions: * Imax under 250 V, 50 Hz on a resistive circuit with constant value, * Imax/2 under 250 V, 50 Hz, on an inductive circuit with a power factor equal to 0.4.

•

Undervoltage The output circuits do not cause faulty operation under the sole effect of the disappearance of the network voltage, or upon its re-establishment.


Page 32 of 43

ACTARIS

5

CONFIDENTIAL

DIAGNOSTIC AND SURVEY

The following exploitation data are intended to provide information to ease ACE 5000 maintenance and exploitation and failure diagnostic.

5.1.1

ParameterSetChecksum

This register contains a 16bit checksum of all the customer configuration data set. It avoids reading the whole configuration set to check if it is the correct one programmed in the meter.

5.1.2

ProgrammingCounter

This register counts the number of programming attempts from IR port and from the user interface. The maximum capacity of the register is 65500. When it reaches this limit, it stays at this value even if another programming action happens. This register cannot be reset.

5.1.3 ReverseFlowCounter The number of export transits is registered in a register with a maximum capacity of 65500. This register cannot be reset and when it reaches its maximum value, it stays there even if a new reverse flow occurs.

5.1.4

BillingPeriodCounter

The number of billing periods is registered with a maximum capacity of 255. This register cannot be reset and when it reaches its maximum value, it stays there even if new billing period occurs.

5.1.5

Terminal Cover Opening Counter

This register counts the opening number of the sealed terminal cover. The maximum capacity of the register is 255 (1 byte), After it reaches this values, the next opening cover event brings this register back to 0, and a fraud register overflow bit (erasable) is indicated on the status word. This register cannot be reset.

5.1.6 CutOffCounter This register counts the cut off numbers. The maximum capacity of the register is 255 (1 byte), After it reaches this values, the next cut off brings this register back to 0, and a fraud register overflow bit (erasable) is indicated on the status word. This register cannot be reset.

5.1.7

StatusWord

The standard status word provides the following information •

Incorrect Phase sequence

•

Cut off overflow flag

• •

Frauds overflow flag.. Overvoltage flag. .

•

Phase loss flag per phase

•

Memory test flag

5.1.8

Check Reading register

This data available on LCD is a signature of the active import energy register used in the current contract, which allows the utility to prevent billing tampering in case or "manual" reading.


Page 33 of 43

ACTARIS

6

CONFIDENTIAL

COMMUNICATIONS

6.1

IR communication port :

The communication is the mean, which gives access both to the meter’s exploitation data and to its configuration data. The meter carries one full communication protocol, DLMS/COSEM (IEC 62056) with connection mode E of IEC61107, and a Flag (IEC 61107) data read-out capacity. The remote access to the meter is made through an infrared optical port based on the flag protocol IEC 61107. This port is situated beneath the liquid crystal display on the left hand side. It is equipped with a metallic part to hold a reading cell by magnetic attraction (pre-centering exists). All of the technical and functional characteristics of the local communication link are according to [6]. COSEM is a multi layered protocol, including physical, data-link, application layer. COSEM by a formal definition of data type (COSEM objects) and a non-ambiguous data identification (OBIS Code) guarantee interoperability on a lot of metering data.

Flag- Connection Mode C and E Client / ? Device address ! CR LF HHU

Server Tariff Device

300 bd. 7E1

/ XXXZ \W Ident CR LF Data Readout

Mode E-HDLC

ACK 0 Z 0 CR LF

STX Data ! CR LF ETX BCC

ACK 2 Z 2 CR LF

NACK

ACK 2 Z 2 CR LF

Z bd. 7E1 End

METERING HDLC protocol

6.1.1

Z bd. 8N1

Flag (IEC 61107) Read-out

Communication speed: After connection at 300bauds, ACE 5000 proposes 9600 bauds The data readout content is configurable in the same manner than Data Bus Output (see 6.2).

6.1.2

COSEM Reading and Programming

Communication speed: After connection at 300bauds, ACE 5000 proposes 9600 bauds Authentification mechanism: Password (no encryption) Client type: one client type (Utility) allowed to read, program, execute some scripts depending on access rights given by configuration in factory according to the utility needs.

NOTA: For the exhaustive list of Configuration and Exploitation data please refer to Annex 9.2.


Page 34 of 43

ACTARIS

6.1.3

CONFIDENTIAL

DATA BUS OUTPUT

The Data Bus Output is situated on the right hand side of the meter cover and is exclusively set by the programming software (AIMS 5000) as a Pulse Output or a Serial Data Output. This feature allows to read locally or remotely a configurable set of data (Via AIMS). Indeed once configured in D.B.O. mode the meter send always the data refreshed as soon as their content changed without any costly system.

6.2

Local Reading

Meter ACE 5000

PC

PC DBO Interface

6.2.1

Principle

The Data Bus Output allows to get meter data from the RS232 port of a PC. The connection is done through a simple interface (PC DBO Interface) using a twisted pair, screwed in terminals on the meter side, and ended by a SubD9 connector including hardware adaptor. The data can be simply read using Hyperterminal, such as shown below or by a specific application for post processing .

Frame format: According to the configuration, the data readout set is composed by x lines, each line contents the data identifier on 4 ASCII characters followed by the data value between brackets; the data value includes the numerical value and the corresponding unit if significant). Speed:

1200 bps


Page 35 of 43

ACTARIS

CONFIDENTIAL

Data:

7

Parity:

Even

Stop bit:

1

Average Time out inter line:

25ms

Average Time out inter frame (set of lines):

25ms

NOTA: For the exhaustive list of the data available and configurable on DBO and Readout please refer to Annex 9.2.

6.2.2

Data Format

One data per line: "Data ID" ("Value" [*] "Unit") [YY-MM-DD HH:MM:SS] •

Field Data ID: OBIS Code

•

Field * optional separator in case of unit

•

Field Unit: V, A …

IMPORTANT: The Data Identification (OBIS Code) string is not configurable.

6.2.3

Remote Reading

PC

Modem

PSTN Modem

Meter A C E 5 0 0 0

IMPORTANT: A specific Interface cable must be used to connect the meter to the Modem. The Modem connected to the meter must be powered independently. All the other characteristics remains the same than for local reading (Format, Data).


Page 36 of 43

ACTARIS

7

CONFIDENTIAL

INSTALLATION

The following procedure is recommended in case of a first installation of ACE 5000.

7.1

Preliminary verifications before the meter is powered up

Warning : the ACE 5000 measurement circuit wiring diagram is non-symetrical VDE. It is important to verify that the measurement circuits are correctly wired to the meter’s terminal block. NON-SYMETRICAL

1

2

3

+I1

U1

-I1

4 +I2

5

6

U2

-I2

7 +I3

8 U3

9

11

-I3

UN

The pulse outputs is a "low level" type and so it is important to verify that no voltage greater than 30 Volts is connected to these terminals.

7.2

Battery connection [optional]

The battery has an equivalent life time of three years accumulated power interruptions. The battery is disconnected in all new meters. The battery must be connected just before the first power up sequence but not prematurely since this will unnecessarily reduce the battery’s life time.

7.3

LCD testing and Date and Time Setting

According to 2.5.2.2

7.4

Battery replacement [Optional]

The battery has an equivalent life time of three years accumulated power interruptions and a natural life time of 10 years. Th e non-fatal battery error is displayed when 80 % of the equivalent life time has been used or when the natural life time end date has been exceeded or when the terminal voltage falls below 2V. •

It is possible to change the battery without altering the meter data.

•

Once the battery has been changed then the battery natural life time end date must updated under the battery gate.


Page 37 of 43

ACTARIS

8

CONFIDENTIAL

READING AND CONFIGURATION TOOL / "AIMS 5000"

Note 1: The purpose of this section is not to describe in details AIMS+ which is self "documented" (Help on line) but to present the main features. Note 2: Two main type of access are provided: Administrator (able to manage the others users permissions) and the others.

8.1 Installation Follow the installation procedure provided in the CD ROM.

8.2

Setup

This menu allows to configure general items on the PC (Com port, …)

8.3

User and permissions management

In order to facilitate the management of the users . The administrator could create and modify 4 differents user profiles group which gives access to specific functions sub-sets.

8.4

Meter management

AIMS 5000+ is able to manage meter database which contains a few data such as •

Serial number

•

Utility passwords

•

Customer Field

8.5 Configuration This main function provides creation, modification and storage of the configurations. A configuration is a set of configuration parameters (See 0). In addition it is possible to export or import configuration files to exchange between different users on different PC.

8.6

Cosem Connection

This specific item allow to establish a COSEM connexion with the ACE 5000 with an optical head.


Page 38 of 43

ACTARIS

8.7

CONFIDENTIAL

Configuration programming

Once configuration defined and Cosem connection established with a meter, it is possible to program (write) whole or part of configuration.

8.8

Data reading

As per programming, it is possible to read whole or part of exploitation data (see ¡Error! No se encuentra el origen de la referencia.) stored in the meter. Once read the data are stored in directory organised by meter serial number. The data could be also exported in exel file format for further processing.

8.9

Specific actions

This item group specific actions such as •

Clock setting

•

Relay testing

•

Metrological Led testing …


Page 39 of 43

ACTARIS

9

CONFIDENTIAL

ANNEXES

9.1

Norms

General applicable Standards: 1.

IEC 61036

Second Edition:1996 -09 + Amendment 1

Electronic a.c. watt-hour meters; (Accuracy class 1 and 2)

2.

IEC 61268

First Edition: 1995-09

Electronic a.c. reactive volt-ampere-hour meters (Accuracy classes 2 and 3)

3.

IEC 61038

Edition 1.2: 1998 -11

Time switches for tariff control

4.

DIN 43857

Part 2: 1978-09

Electricity meters housed in insulation material for direct connection up to 60 A limit current;

Part 4: 1974-12 5.

DIN 43859

1977-06 Draft Standard: 1990-03

Electricity meters for instrument transformer connection; main dimensions for three-phase meters

Nota: NMI approval tests were also passed agains the new version of the general standards •

IEC 62052-11 : Electricity metering equipment (a.c) - General Requirements, Tests and test Conditions Part 11 : Metering equipment

•

IEC 62053-21 : Electricity metering equipment (a.c) - Particular Requirements - Part 21 : Static meters for active energy (classes 1 and 2)

•

IEC 62053-22 : Electricity metering equipment (a.c) - Particular Requirements - Part 21 : Static meters for active energy (classes 0.2 S and 0.5 S)

•

IEC 62053-23 : Electricity metering equipment (a.c) - Particular Requirements - Part 21 : Static meters for reactive energy (classes 2 and 3)

Communication Standards:

6.

IEC 62056-21

Edition 1.0: 2002 -05

Direct Local Data Exchange (3rd edition of IEC 61107)

7.

IEC 62056-42

Edition 1.0: 2002 -02

Physical layer services and procedures for connection oriented asynchronous data exchange

8.

IEC 62056-46

Edition 1.0: 2002 -02

Data Link Layer using HDLC-Protocol

9.

IEC 62056-53

Edition 1.0: 2002 -02

COSEM Application Layer

10. IEC 62056-61

Edition 1.0: 2002 -02

OBIS Object Identification System

11. IEC 62056-62

Edition 1.0: 2002 -02

Interface Objects


Page 40 of 43

ACTARIS

9.2

1

CONFIDENTIAL

Configuration and Exploitation data A

B

Column

Meaning

Cust. Mod. 3

Configurable access 4

DB O (Y/N)

Indicates which accesses are allowed when the meter is in customer mode. -> Get: reading -> Set: programming -> Get/Set: reading and programming Some Customer mode access rights are programmable. A star ( * ) indicates that Get (resp. Set) can be allowed or not. If there is no star, then the corresponding access right is fixed. Indicates if corresponding data can be available on DBO and Readout. -> Y: available -> N: never available TS

-> Y* : available and Time Stamped, depending on Readout And DBO Configuration object.

5

Display (Y/N)

Indicates if corresponding data can be di splayed depending on Display Configuration -> Y: available -> N: never available

6


Page 41 of 43

ACTARIS

CONFIDENTIAL

Configuration data

A 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 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60 61 62 63 64

B

C

D E Logical Name B C D

A

F

G H

I

J

K L

Configurable

E

F

Cust. Mode

Access

M N O DBO Display Y/N

Get Set

A light green background indicates which codes are showed when the object is displayed 96, 97, 98 and 99 can be displayed as C, F, L and P (respectively), as allowed by IEC 62056-61

Metrology Metrol reading parameters Metrol output control 1 Metrol output control 2 Constants LED Active Constant LED Reactive Constant PULSE Active Constant PULSE Reactive Constant Metrol calibration date and time Measurement parameters Measurement modes (Aggregate energy calculation mode) Current transformers ratio numerator Current transformers ratio denominator Response times Maximum current response time Maximum power response time Maximum demand parameters Real Time Clock Clock Daylight saving time Time switch Activity calendar Special day table Logical device Current Association Logical Device Name Utility association Public client association Utility access rights Billing Period End of Billing parameters Status Meter Status Register and contract parameters Demand management parameters Readout And DBO Configuration Subscribed currents Subscribed current Auxiliary Output config uration Config contract parameters Contract number Meter identification Firmware identification Customer serial number Customer serial number, left part Customer serial number, right part Factory data Diagnostic Standard diagnostic Status word Display Display configuration parameters Customer field Customer field, left part Customer field, right part Script tables User script (US)

1

1

160

4

0

255

1

1

160

2

0

255

1

1

160

5

0

255

1

1

0

3

0

255

1

1

0

3

1

255

1

1

0

3

3

255

1

1

0

3

4

255

0

0

96

2

5

255

1

1

160

3

0

255

1

1

0

4

2

255

1

1

0

4

5

255

1

1

167

1

0

255

1

1

0

8

1

255

1

1

0

8

0

255

0

0

1

0

0

255

0

0

161

1

0

255

0

0

13

0

0

255

0

0

11

0

0

255

0

0

40

0

0

255

0

0

42

0

0

255

0

0

40

0

1

255

0

0

40

0

2

255

0

0

164

1

0

0

0

15

0

0

0

162

1

1

0

0

1 0 1

Get Get/Set Get/Set Get Get Get/Set Get/Set Get

*

N N N

N N N

N N N N N

N N N N N

* *

* *

Get/Set Get/Set Get/Set

*

*

N Y* Y*

N Y Y


* * *

* * *

N N N

N N N

Get/Set Get/Set

Y N

N N

Get/Set Get/Set

N N

N N

255

Get Get Get/Set Get Get

N N N N N

N N N N N

0

255

Get/Set

N

N

1

0

255

Get

N

N

163

1

0

255

96

50

0

255

Get/Set Get/Set

N N

N N

1

11

35

n

255

0

168

1

0

255

1

96

50

1

255


96

50

2

Y* N N Y

Y N N Y

Get Get

Y* Y

Y Y

*

*

0

0

169

1

0

255

0

0

96

1

0

255

0

0

96

1

0

128

0

0

96

1

0

129

0

0

169

1

1

255

Get

N

N

1

1

140

0

1

255

Get

0

0

96

5

0

255

N Y

N Y

0

0

165

1

0

255

0

0

96

1

1

255

Get/Set Get/Set

N Y*

Y

0

0

96

1

1

128

0

0

96

1

1

129

0

0

10

1

101

255

Execute

N

N


Page 42 of 43

ACE_5000[1].pdf

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