Remote monitoring and control unit REC 523...ventional radio • Management via network control...

1MRS 750431-MBGIssued: April 1999
Status: UpdatedVersion: B/21.11.2001Data subject to change without notice
REC 523
Remote monitoring and control unit
1

Features • Remote control and monitoring unit for the control of medium voltage disconnectors, switches, ring-main units and other substa-tion secondary equipment

• Current and voltage measurement by means of conventional transformers or cur-rent and voltage sensors

• Extended functionality for protection and fault indication, control, measurement, con-dition monitoring, power quality and com-munication

• Protection functions including e.g. non-directional and directional overcurrent and earth-fault protection, undervoltage protec-tion and auto-reclosing

• Control functions including local and remote control of switching objects, status indication of the switching objects and interlockings on bay and station level

• Measurement of phase currents, phase-to-phase and phase-to-neutral voltages, residual current and voltage, frequency, power factor, active and reactive power and energy, etc.

• Condition monitoring including circuit-breaker condition monitoring and internal self-supervision of the unit

• Additional functions including capacitor bank control and measurement of current and voltage harmonics

• Extensive, bidirectional information exchange between the power system pro-cess and the network control centre via several remote communication protocols

• Communication via radio telephone, radio link, fixed lines, leased lines, public tele-phone lines, mobile phones (NMT/GSM), DLC and radio modems

• Operation, communication and reporting secured during power outages by means of maintenance-free batteries

• Power supply unit including integrated tem-perature compensated battery charger

• Automatic heating control in low tempera-ture and humid environments

• Outlet for communication device, e.g. con-ventional radio

• Management via network control system, e.g. MicroSCADA

• Continuous self-supervision of hardware and software

• Part of the ABB Substation Automation system

Application The remote monitoring and control unit REC 523 is designed to be used for remote and local control, protection and fault indica-tion, condition monitoring, supervision and automation of secondary substations in medium voltage networks. It can be used with various ring main units (RMUs), air-insulated

and SF6-insulated disconnectors, switches and other remote-controlled substation sec-ondary equipment.

The remote monitoring and control unit REC 523 can be connected to conventional current and voltage transformers or to the new ABB current and voltage sensors.

Remote monitoring and control unit REC 5231MRS 750431-MBG

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The freely programmable LED display facili-tates status indication of local I/Os and thus also of the RMU, disconnectors or switches.

Increased performance is achieved by using the benefits of the multi-processor environ-ment.

Digital signal processing, together with a powerful CPU and distributed I/O handling, enables flexible and modular constructions, parallel operation and, in addition, improves response times and accuracy. The modern technology applied in the unit extends the flexibility of the system.

Design The REC 523 remote monitoring and control unit incorporates a wide range of functions:

• Protection functions

• Measurement functions

• Power quality functions

• Control functions

• Condition monitoring functions

• General functions

• Communication functions

• Standard functions

The function blocks are documented on the CD-ROM “Technical Descriptions of Func-tions” (1MRS 750889-MCD).

Protection and fault indication functionsREC 523 provides a set of protection func-tions which also can be used for fault indica-tion. The protection function blocks (e.g. NOC3Low) supported by REC 523 are inde-pendent of each other and have their own set-ting groups, data recording, etc. For example, the non-directional overcurrent protection includes two different stages, NOC3Low and NOC3High, both with independent protection functions.

By means of the fault indication functions the network control system can obtain informa-tion about measured and set values. The information can be used, for instance, to locate faults in a medium voltage distribution network. The wide energizing input ranges of transformers and sensors facilitate monitoring and fault indication in different types of sub-station.

Measurement functionsMeasurement functions include three phase currents, neutral current, three-phase volt-ages, residual voltage, frequency, active and reactive power and power factor. In addition, other measurement functions are available.

Disturbance recorderThe transient disturbance recorder is able torecord 16 current or voltage waveforms and16 logic digital signals. The sampling fre-quency of the analogue inputs is 2 kHz at thrated frequency of 50 Hz and 2.4 kHz at therated frequency of 60 Hz.

The user can set the length of a recording within a range determined by the number ofanalogue inputs used. The number of recordings depends on the sampling frequency, length of recordings and number of analoguinputs.

The recordings can be uploaded with a DR-Collector Tool which converts the data to a COMTRADE format. The DR-Collector Tool is supported in CAP501 and CAP505 relay tools.

Power quality functionsPower quality functions enable measuremenof total harmonic distortion (THD) of voltage and current, and total demand distortion (TDD) of current. Individual harmonics are measured up to the 13th.

The power quality functions produce statisti-cal data about harmonic distortion for long term evaluation. Short time average and maimum values for THD and individual har-monics are also supported.

LIB 510 supports graphical presentation of harmonics in the PQ Monitoring Tool.

Control functionsThe unit includes binary inputs and relay ouputs for the control of up to four disconnec-tors, switches or other objects. The objects can be controlled remotely over the networkcontrol system or locally via push-buttons, which normally are placed in a separate enclosure. Disconnector and switch status indication is obtained via the binary inputs. One of the outputs can be used for the controf an external heater and one output is usedfor internal fault (IRF) indication.


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Power factor controller (option)The function is designed to be used for con-trolling the switching of capacitor banks based on the reactive power requirements of the load in the network. The power factor controller of REC 523 controls a maximum of 4 capacitor banks.

Condition monitoring functionsThe condition of the batteries is secured by periodic condition monitoring tests. The unit measures the battery voltage continuously, also during the condition monitoring test. The minimum voltage value will be recorded in the memory. The condition and lifetime of the batteries can be estimated on the basis of the minimum values recorded.

Regular reinitialization is used for monitoring the condition of the optional plug-in modem or an external modem. The monitoring and control unit reinitializes the modem when there has not been any successful communi-cation within a certain period of time.

Condition monitoring function blocks like supervision of the energizing current and voltage input circuit, operation time counter, scheduled maintenance and breaker travel time are available for the REC 523 units

General functionsAdditional functions are available for differ-ent general purposes to be used in logics such as activation of MMI backlight, switch-groups, and resetting of operation indications, latched output signals, registers and distur-bance recorder.

Standard functionsStandard functions are used for logics such as interlocking, alarming and control sequenc-ing. The use of logic functions is not limited and the functions can be interconnected to fault indication, control, measurement, condi-tion monitoring and other standard functions. In addition, binary inputs, outputs, LON inputs and outputs can be connected to stan-dard functions by using the relay configura-tion tool (CAP 505).

Battery backupThe battery backup of the station can be arranged by using two 12 V, 17 Ah or 38 Ah, sealed lead acid batteries in the monitoring and control unit. The integrated temperature-compensated switched-mode battery charger

charges the batteries under normal conditions and supplies the power needed by the unit during power outages. Thus the operation of the unit and the communication between the substation and the network control centre are always secured.

Optional modemThe optional plug-in modem incorporates a public/leased line modem for telephone line interfaces with pulse and tone dialling and a radio interface with radio keying and for the two- or four-wire fixed cable connection. The communication transfer rate is up to 14400 bps (V.32bis). The modem is specially designed for harsh conditions, such as in most unheated secondary substations. The wide application range of the modem covers the common communication ways, thus facilitat-ing system engineering.

More information can be found in Operator’sManual for “1MRS119000 Plug-in Modem” (1MRS750577-MUM).

Data communicationFor remote communication purposes the unis provided with an RS232 serial port, and thoptional plug-in modem with an RJ12 tele-phone connector and a screw connector.

The RS232 serial port with SPA protocol andLON protocol are used for local communication with a PC to be used e.g. for parameterization with the CAP 505 tool.

Supported field bus protocols are the LON bus and the SPA bus. Network managemenprotocols supported are IEC 60870-5-101, MODBUS or DNP3.0. Other protocols can bedeveloped on request.

Other functions

Low auxiliary voltage indicationThe REC 523 unit includes indication of a low auxiliary voltage. The power supply module issues an internal alarm signal whendrop in the power supply voltage is detected(AC fail, active low). The alarm signal will be activated if the power supply voltage is about 10% below the lowest rated DC input voltage of the power supply module.

Indication of a low auxiliary voltage is avail-able in relay configuration and can be configured to activate an alarm.


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Overtemperature indicationThe REC 523 unit includes indication of an internal relay temperature. The power supply module gives an internal alarm signal when overtemperature has been detected inside the unit enclosure. The alarm signal will be acti-vated if the temperature inside the relay enclosure increases to +78°C (+75°C… +83°C). Overtemperature indication is avail-able in the relay configuration and can con-figured to activate an alarm.

Analogue channelsThe number of channels used depends on the selected unit type and the kind of matching transformers or sensor inputs used. A REC 523 remote monitoring and control unit can have a maximum of 9 external analogue measurements. Furthermore, the unit has two internal analogue channels, channels 11 and 12, for the residual current and voltage calcu-lated from phase currents and voltages.

The REC 523 measures the analogue signals needed for fault indication, measuring, etc. by using current and voltage sensors developed by ABB or galvanically separated matching transformers.

A current sensor (Rogowski coil) or a voltage sensor can be connected to each sensor input. The REC 523 allows the user to configure each sensor input for the type of sensor to be used.

Each analogue channel of the unit is sepa-rately configured by using the relay configu-ration tool (CAP 505).

A separate scaling factor can be set for each analogue channel. The factors enable differ-ences between the ratings of the protected unit and those of the measuring device (CTs, VTs etc.). The setting value 1.00 means that the rated value of the protected unit is exactly the same as that of the measuring device.

Calculated analogue channelsThe REC 523 unit includes two virtual chan-nels to obtain the residual current and voltage when sensors are used. Current and voltage sensors are connected directly to the unit via coaxial cables and therefore residual connec-tion of the phase currents or open-delta con-nection of the phase voltages cannot be made. Both amplitude and phase angle are calcu-lated for the virtual channels.

Though primarily meant to be used with sensors, the calculated analogue channels can also be used with conventional current and voltage transformers.

Channel 11 is used to numerically derive theresidual current I0 from the three phase cur-rents (I0 = ).

Note! When sensitive earth-fault protection isneeded, it is not, however, recommended toreplace core balance transformers with the numerically derived sum of the phase cur-rents. Normally, an earth-fault setting below10% of the rated value requires a core balantransformer.

Channel 12 is used to derive the residual voage U0 from the three phase voltages (U0 = ). This channel is used instead of the open-delta connection when voltage sensors are used to measure the phvoltages.

Binary inputsThe binary inputs of the units are voltage controlled and optically isolated. The func-tion of a binary input can be inverted. Pro-grammable filter time removes debounces and short disturbances on a binary input. Thfilter time is set for each binary input of the unit.

Some specific digital inputs can be pro-grammed to operate as pulse counters. Whea digital input is programmed to operate as pulse counter, pulse counting frequency canbe up to100 Hz.

Oscillation suppressionThe REC 523 units have two global parameters for the suppression of binary input oscillation. The settings of these parameters determine the oscillation level and hysteresifor all binary inputs. Oscillation suppressionis used to reduce the load from the system when a binary input starts oscillating. A binary input is regarded as oscillating if the number of valid status changes after filteringis more than the set number of changes per1 s. During oscillation, the binary input is blocked (status is invalid) and an event is generated.

Attributes of a binary input for relay con-figurationFor each binary input the status of the input (value), the time tag for the status change (time) and the validity of the binary input (invalidity) can be issued by the attributes.

I1 I2 I3+ +

U1 U2 U3+ +


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These attributes are available in the relay con-figuration and can be used for different pur-poses, e.g. by using PLC logic functions.

OutputsThe outputs of the unit are categorized as fol-lows:

• HSPO: High speed power output, double-pole contact, e.g. for tripping purposes (e.g. circuit breaker)

• SO: Signal output, either NO (Normal Open) or NO/NC (Normal Open/Normal Closed) contact. The output contact is nor-mal duty and thus it cannot be used for controlling a heavy load like a circuit breaker

LED displayThe LED panel consists of power-on, IRF, STO and 21 freely programmable LEDs through the CAP 505 tool. Each LED has four states: ON, OFF, fast blinking, and slow blinking. The STO LED indicates when the unit is saving information into nonvolatile memory.

External serial communicationsThe REC 523 has one RS485 and two RS232 serial communication ports. The 9-pole RS485 connection X5.3 connects the REC 523 units to the distribution automation sys-tem via a SPA bus or a LON bus. The RS232 port (X5.2) is used for the parameterization purposes. The second RS232 port (X5.1) is used for the remote communication protocol.

The fibre-optic interface module type RER 103 is used for connecting the REC unit to the fibre-optic communication bus. This module supports both SPA bus and LON bus communication. An optional modem uses port X5.1.

Self supervisionThe REC 523 unit is provided with an exten-sive self-supervision system. The self-super-vision system handles run-time fault situa-tions and informs the user about existing faults over remote communication and LON/SPA communication.

After a fault has been detected the red IRF indicator lights up. At the same time the unit delivers a fault signal to the self-supervision output relay and blocks the protection trip outputs.

The fault code is stored in the memory and can be read from the unit.

Relay configurationThe Relay Configuration Tool, which is included in the CAP 505 Relay Product Engneering Tools, is used for configuring the REC 523 unit, protection and logic function blocks, control and measurement functions,timers and other functional elements includein the logic functions category.

The Relay Configuration Tool is based on thstandard IEC 61131-3. The programmable system of REC 523 unit allows the output contacts to be operated in accordance with thstate of the logic inputs and the outputs of protection and fault indication, control, mea-surement and condition monitoring functionsThe PLC logics (e.g. interlocking and alarm logic) are programmed with Boolean func-tions, timers, counters, comparators and flipflops. The program is written in the function block diagram language by using the configuration software.

Lon network configuration with LNT 505The Lon network configuration tool is used for binding network variables between the units. Typically, LON is used for transferringstatus data between units.

Relay parameterizationThe parameters of the units can be set via thserial communication using the Relay SettinTool CAP 501.

External parameterizationThe Relay Setting tool CAP 501 is used for parameterizing the units. The parameters cabe set off-line in a PC and downloaded to thunit over a communication port. The setting parameters can be chosen from the hierarchcal menu structure.

Terminal connectionsAll external circuits are connected to the ter-minal blocks on the rear panel. The terminalblock for the measuring transformers consisof fixed screw terminals.

ABB’s sensors (Rogowski coils or voltage sensors) are connected to the unit with spe-cial-type shielded twin BNC connectors. Thistype of connectors is used to improve reliabiity and protection against disturbances. Un-used sensor inputs must be short-circuited with a special connector 1MRS 1200515.


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The binary input and output contacts of the units are connected to the multi-pole connec-tors.

Protective earth is connected to the screw, marked with the earth symbol.

Connector descriptions:

Fig. 1 Terminal diagram of REC 523 with sensors (REC523D 060_AC/REC523D 065_AC)

X7.1

1

2

ACFail

TempAlarm

LED PANELX7.2

12

X3.2

BIO1_3_BI12

123

456

789

101112

131415161718

X3.1

BIO1_3_BI1

BIO1_3_BI2

BIO1_3_BI3

BIO1_3_BI4

BIO1_3_BI5

BIO1_3_BI6

BIO1_3_BI7

BIO1_3_BI8

BIO1_3_BI9

BIO1_3_BI10

BIO1_3_BI11

5

6

79

8

1012

11

1315

14

1618

17

X3.23

4BIO1_3_SO1

BIO1_3_SO2

BIO1_3_SO3

BIO1_3_SO4

BIO1_3_SO5

BIO1_3_SO6

8

1718

9

121314

15

16

11

X7.3

PSC_7_SO1orHeater Output

12

34

56

X7.3

PSC_7_BI1

PSC_7_BI2

PSC_7_BI3

10

98

BATTERY

-

IRF

5

34

SERIAL BUSX5.1

SERIAL BUSX5.2

SERIAL BUSX5.3

PSC_7_HSPO1

PSC_7_HSPO2

termd2_5

X2.6

X2.7

X2.8

X2.9

Ch 4, sensor

Ch 3, sensor

Ch 2, sensor

Ch 1, sensor

DIFF

DIFF

DIFF

X2.4 Ch 7, sensorDIFF

X7.1

6

7RADIO 12V

REC 523 Remote Monitoring and Control Unit(060 _AC / 065 _AC)

Mains

+

-

+

-

+

Ch 9, sensor

X2.1 Ch 10, sensor

X2.2

X2.3 Ch 8, sensor

DIFF

DIFF

DIFF

DIFF

X2.5 Ch 5, sensorDIFF


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Fig. 2 Terminal diagram of REC 523 with three current transformers (REC523D 032_AA/REC523D 037_AA)

12

34

56

X7.3

123

456

789

101112

131415161718

X3.1

12

X3.2

X7.1

1

2

Ch 2, CT1

Ch 3, CT2

Ch 4, CT31A5A

1A5A

1A5A

X1.1

87654321

9

BIO1_3_BI1

BIO1_3_BI2

BIO1_3_BI3

BIO1_3_BI4

BIO1_3_BI5

BIO1_3_BI6

BIO1_3_BI7

BIO1_3_BI8

BIO1_3_BI9

BIO1_3_BI10

BIO1_3_BI11

BIO1_3_BI12

PSC_7_BI1

PSC_7_BI2

PSC_7_BI3

5

6

79

8

1012

11

1315

14

1618

17

X3.23

4BIO1_3_SO1

BIO1_3_SO2

BIO1_3_SO3

BIO1_3_SO4

BIO1_3_SO5

BIO1_3_SO6

LED PANELX7.2

IRF

5

34

X7.1

6

7

10

98

RADIO 12V

BATTERY

+

-

+

-

SERIAL BUSX5.1

SERIAL BUSX5.2

SERIAL BUSX5.3

ACFail

8

1718

9

121314

15

16

11

X7.3


P S C _ 7 _ H S P O 1

P S C _ 7 _ H S P O 2

termd2_6

Mains

+

-TempAlarm

REC 523 Remote Monitoring and Control Unit(032 _AA / 037 _AA)


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Fig. 3 Terminal diagram of REC 523 with three current and three voltage transformers (REC523D 033_AA/REC523D 038_AA)

12

34

56

X7.3

123

456

789

101112

131415161718

X3.1

12

X3.2

8

1718

X7.1

1

2

BIO1_3_BI1

BIO1_3_BI2

BIO1_3_BI3

BIO1_3_BI4

BIO1_3_BI5

BIO1_3_BI6

BIO1_3_BI7

BIO1_3_BI8

BIO1_3_BI9

BIO1_3_BI10

BIO1_3_BI11

BIO1_3_BI12

PSC_7_BI1

PSC_7_BI2

PSC_7_BI3

5

6

79

8

1012

11

1315

14

1618

17

X3.23

4BIO1_3_SO1

BIO1_3_SO2

BIO1_3_SO3

BIO1_3_SO4

BIO1_3_SO5

BIO1_3_SO6

LED PANELX7.2

10

98

BATTERY

-

IRF

5

34


SERIAL BUSX5.1

SERIAL BUSX5.2

SERIAL BUSX5.3

ACFail

TempAlarm

P S C _ 7 _ H S P O 1

P S C _ 7 _ H S P O 2

termd2_7

X7.1

6

7

9

121314

15

16

11

X7.3

RADIO 12V


Mains

+

-

+

-

+

Ch 2, CT1

Ch 3, CT2

Ch 4, CT3

100V

100V

100V

1A5A

1A5A

1A5A

X1.1

Ch 8, VT1

Ch 9, VT2

Ch 10, VT3

161514131211

87654321

109

1918

2221

27

2524


9

Fig. 4 Terminal diagram of REC 523 with four current and three voltage transformers (REC523D 034_AA/REC523D 039_AA)

12

34

56

X7.3

123

456

789

101112

131415161718

X3.1

12

X3.2

8

1718

9

121314

15

16

11

X7.3

X7.1

1

2

BIO1_3_BI1

BIO1_3_BI2

BIO1_3_BI3

BIO1_3_BI4

BIO1_3_BI5

BIO1_3_BI6

BIO1_3_BI7

BIO1_3_BI8

BIO1_3_BI9

BIO1_3_BI10

BIO1_3_BI11

BIO1_3_BI12

PSC_7_BI1

PSC_7_BI2

PSC_7_BI3

5

6

79

8

1012

11

1315

14

1618

17

X3.23

4BIO1_3_SO1

BIO1_3_SO2

BIO1_3_SO3

BIO1_3_SO4

BIO1_3_SO5

BIO1_3_SO6

LED PANELX7.2


IRF

5

34

X7.1

6

7

10

98

RADIO 12V

BATTERY

+

-

+

-

SERIAL BUSX5.1

SERIAL BUSX5.2

SERIAL BUSX5.3

ACFail

TempAlarm

PSC_7_HSPO1

PSC_7_HSPO2

termd2_8


Mains

+

-

Ch 2, CT1

Ch 3, CT2

Ch 4, CT3

Ch 5, CT41A5A

230V

230V

230V

1A5A

1A5A

1A5A

X1.1

Ch 8, VT1

Ch 9, VT2

Ch 10, VT3

161514131211

87654321

109

1918

2221

27

2524


10

Fig. 5 Terminal diagram of REC 523 with six current and three voltage transformers (REC523D 061_AA/REC523D 066_AA)

12

34

56

X7.3

123

456

789

101112

131415161718

X3.1

12

X3.2

8

1718

X7.1

1

2

BIO1_3_BI1

BIO1_3_BI2

BIO1_3_BI3

BIO1_3_BI4

BIO1_3_BI5

BIO1_3_BI6

BIO1_3_BI7

BIO1_3_BI8

BIO1_3_BI9

BIO1_3_BI10

BIO1_3_BI11

BIO1_3_BI12

PSC_7_BI1

PSC_7_BI2

PSC_7_BI3

5

6

79

8

1012

11

1315

14

1618

17

X3.23

4BIO1_3_SO1

BIO1_3_SO2

BIO1_3_SO3

BIO1_3_SO4

BIO1_3_SO5

BIO1_3_SO6

LED PANELX7.2

10

98

BATTERY

-

IRF

5

34


SERIAL BUSX5.1

SERIAL BUSX5.2

SERIAL BUSX5.3

ACFail

TempAlarm

P S C _ 7 _ H S P O 1

P S C _ 7 _ H S P O 2

termdCT6

1A5A

1A5A

1A5A

100V

1A5A

1A5A

100V

1A5A

87654321

9

X7.1

6

7

9

121314

15

16

11

X7.3

RADIO 12V


Mains

+

-

+

-

+

Ch 2, CT1

Ch 3, CT2

Ch 4, CT3

Ch 5, VT1

100V

X1.1

Ch 6, VT2

Ch 7, CT4

Ch 8, CT5

Ch 9, CT6

Ch 10, VT3

1615

1312

191817

232221

27

2524

10

20


11

Fig. 6 Terminal diagram of REC 523 with three current and six voltage transformers (REC523A 062_AA/REC523D 067_AA)

12

34

56

X7.3

123

456

789

101112

131415161718

X3.1

12

X3.2

8

1718

X7.1

1

2

BIO1_3_BI1

BIO1_3_BI2

BIO1_3_BI3

BIO1_3_BI4

BIO1_3_BI5

BIO1_3_BI6

BIO1_3_BI7

BIO1_3_BI8

BIO1_3_BI9

BIO1_3_BI10

BIO1_3_BI11

BIO1_3_BI12

PSC_7_BI1

PSC_7_BI2

PSC_7_BI3

5

6

79

8

1012

11

1315

14

1618

17

X3.23

4BIO1_3_SO1

BIO1_3_SO2

BIO1_3_SO3

BIO1_3_SO4

BIO1_3_SO5

BIO1_3_SO6

LED PANELX7.2

10

98

BATTERY

-

IRF

5

34


SERIAL BUSX5.1

SERIAL BUSX5.2

SERIAL BUSX5.3

ACFail

TempAlarm

P S C _ 7 _ H S P O 1

P S C _ 7 _ H S P O 2

termdVT6

1A5A

1A5A

1A5A

100V

100V

100V

100V

100V

100VX7.1

6

7

9

121314

15

16

11

X7.3

RADIO 12V


Mains

+

-

+

-

+

Ch 2, CT1

Ch 3, CT2

Ch 4, CT3

Ch 5, VT1

X1.1

Ch 6, VT2

Ch 7, VT3

Ch 8, VT4

Ch 9, VT5

Ch 10, VT6

1615

13

12

87654321

109

1918

2221

27

2524


y

.

f

12

Auxiliary voltageFor its operation the REC 523 unit requires a auxiliary voltage supply. The unit’s internal power supply module forms the secured volt-ages required by the relay electronics. The power supply module is a galvanically iso-lated (fly-back type) dc/dc converter. A LED indicator “ON” on the front panel is lit when the power supply module is in operation.

Power supplyThere are two basic versions of power supplmodules available for the REC 523: type PSC1 and type PSC2. The module PSC1 isused for the voltage range 80…265 V ac/dcand module PSC2 for the range 18…80 V dcThe power supply version is specified by a letter combination in the hardware number othe REC 523.

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)XQFWLRQV 'HVFULSWLRQABSACOSADDANDASINATANBITGETBITSETBOOL_TO_*

BOOL2INTBYTE_TO_*COMHCOSCTDCTUCTUDDATE_TO_UDINTDINT_TO_*DIVDWORD_TO_*EQEXPEXPTF_TRIGGEGTINT_TO_*INT2BOOLLELIMITLNLOGLTMAXMINMODMOVEMULMUX

Absolute valuePrincipal arc cosineExtensible adderExtensible AND connectionArc sineArc tangentGet one bitSet one bitType conversion from BOOL to WORD/ USINT/ UINT/ UDINT/ SINT/ REAL/ DWORD/ DINT/ BYTEType conversion from BOOL inputs to INT outputType conversion from BYTE to WORD/ DWORDHysteresis comparatorCosine in radiansDown-counterUp-counterUp-down counterType conversion from DATE to UDINTType conversion from DINT to SINT/ REAL/ INTDividerType conversion from DWORD to WORD/ BYTEExtensible comparison to equalNatural exponentialExponentiationFalling edge detectorExtensible comparison to greater or equalExtensible comparison to greaterType conversion from INT to REAL/ DINTType conversion from INT input to BOOL outputsExtensible comparison to less or equalLimitationNatural logarithmLogarithm base 10Extensible comparison to lessExtensible maximumExtensible minimumModuloMoveExtensible multiplierExtensible multiplexer


13

NENOTORR_TRIGREAL_TO_*

ROLRORRSRS_D

SELSHLSHRSINSINT_TO_*SUBSQRTSRXORTANTIME_TO_*TOD_TO_*TOFTONTPTRUNC_*UDINT_TO_*

UINT_TO_*

USINT_TO_*

WORD_TO_*

Comparison to greater or lessComplementExtensible OR connectionRising edge detectorType conversion from REAL to USINT/ UINT/ UDINT/ SINT/ INT/ DINTRotate to leftRotate to rightReset dominant bistable function blockReset dominant bistable function block with data inputBinary selectionBit-shift to leftBit-shift to rightSine in radiansType conversion from SINT to REAL/ INT/ DINTSubtractorSquare rootSet dominant bistable function blockExtensible exclusive OR connectionTangent in radiansType conversion from TIME to UDINT/ TOD/ REALType conversion from TOD to UDINT/ TIME/ REALOff-delay timerOn-delay timerPulseTruncation toward zeroType conversion from UDINT to USINT/ UINT/ REALType conversion from UINT to USINT/ UDINT/ REAL/ BOOLType conversion from USINT to UINT/ UDINT/ REALType conversion from WORD to DWORD/ BYTE

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Functions Description

CMBWEAR1CMBWEAR2CMCU3CMGAS1CMGAS3CMSCHEDCMSPRC1CMTIME1CMTIME2CMTRAV1CMVO3

Circuit-breaker electric wear 1Circuit-breaker electric wear 2Supervision function of the energizing current input circuitGas pressure monitoringThree-pole gas pressure monitoringScheduled maintenanceSpring charging control 1Operate time counter 1 for the operate time used (motors)Operate time counter 2 for the operate time used (motors)Breaker travel time 1Supervision function of the energizing voltage input circuit

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Functions Description

COCB1COCB2CO3DC1CO3DC2CODC1…COCD5COIND1…COIND8COLOCAT

Circuit breaker 1 control with indicationCircuit breaker 2 control with indicationThree-state disconnector 1 with indicationThree-state disconnector 2 with indicationDisconnector 1…5 control with indicationSwitching device 1…8 indicationLogic-controlled control position selector


14

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The number of capacitor banks to be controlledThe relational step sizes and the type of the switching sequence

Size of the first capacitor bank (should be the smallest)Target value for daytime cos ϕDay unitTarget value for night-time cos ϕ Night unitSetting the reconnection inhibit time (discharge time)Sensitivity in the inductive sideSensitivity in the capacitive sideAlarm limit for the maximum reactive powerAlarm limit for the minimum reactive powerOvervoltage limit when the switching in is inhibitedOperation mode

Starting the automatic testing sequenceCalculation methodControl principleDuration demandDay&night switch

Manual command

1...41:1:1:1 linear; 1:1:1:1 circul.; 1:1:2:2 circul.; 1:2:2:2 linear; 1:2:2:2 circul.; 1:2:4:4 linear; 1:2:4:4 circul.; 1:2:4:8 10.0...50000.0 kvar0.70...1.00Inductive; Capacitive0.70...1.00Inductive; Capacitive0.5...6000.0 s60.0...200.0%0.0...100.0%0.1...100.0 Mvar-100.0...0.0 Mvar0.80...1.60 x UnNot in use; Automatic mode; Manual mode; Testing modeNot activated; StartNormal; IntegralProgressive; Direct0.5...6000.0 sNot in use; Digital input; Internal clock; By settingNot activated; Remove one step; Add one step: Disconnect all

Recorded dataNumber of switching operations per dayNumber of switching operations per week

0...655350...65535

Operation accuraciesAccuracy class of operation

±2.0% of set value or ±0.02 x rated value2.0

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The general measurement function blocks can be used to measure general purpose dc or ac voltage signals with a sensor input. They also include a REAL type input which can be used to monitor any internal REAL type IEC 61131-3 based signal.

GE1…3 (V dc/ac)General REAL type input

-10000.00000...10000.00000-10000.00000...10000.00000

1HXWUDOFXUUHQWPHDVXUHPHQW0(&8$DQG0(&8%

Io (A)Io (%)Operation accuracy

0.0…20000.0 A0.0…80.0% of Inf/fn = 0.95…1.05: ±1.0% of set value or ±0.01 x In

7KUHHSKDVHFXUUHQWPHDVXUHPHQW0(&8$0(&8%

IL1 (A)IL2 (A)IL3 (A)IL1 (%)IL2 (%)IL3 (%)IL1 demand (A)IL2 demand (A)IL3 demand (A)IL1 demand (%)IL2 demand (%)IL3 demand (%)Operation accuracy

0.0…20000.0 A0.0…20000.0 A0.0…20000.0 A0.0…1000.0% of In0.0…1000.0% of In0.0…1000.0% of In0.0…20000.0 A0.0…20000.0 A0.0…20000.0 A0.0…1000.0% of In0.0…1000.0% of In0.0…1000.0% of Inf/fn = 0.95…1.05: ±1.0% of set value or ±0.01 x In


15

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P3 (kW)Q3 (kvar)Power factor DPFPower factor PFP3 demand (kW)Q3 demand (kvar)Energy kWhReverse kWhEnergy kvarhReverse kvarhOperation accuracy

-999999…999999 kW-999999…999999 kvar-1.00…1.00-1.00…1.00-999999…999999 kW-999999…999999 kvar0…999999 kWh0…999999 kWh0…999999 kvarh0…999999 kvarh±2.0% of set value or ±0.02 x rated value

6\VWHPIUHTXHQF\PHDVXUHPHQW0()5

FrequencyAverage Freq.Voltage UOperation accuracy

10.00…75.00 Hz10.00…75.00 Hz0.0…2.0 x Un±0.1 Hz

5HVLGXDOYROWDJHPHDVXUHPHQW0(92$0(92%

Uo (V)Uo (%)Operation accuracy

0…150000 V0.0…120.0% of Unf/fn = 0.95…1.05: ±1.0% of set value or ±0.01 x Un

7KUHHSKDVHYROWDJHPHDVXUHPHQW0(92$0(92%

U1_12 (V)U2_23 (V)U3_31 (V)U1_12 (pu)U2_23 (pu)U3_31 (pu)U1_12 Aver (V)U2_23 Aver (V)U3_31 Aver (V)U1_12 Aver (pu)U2_23 Aver (pu)U3_31 Aver (pu)Operation accuracy

0.00…999.99 kV0.00…999.99 kV0.00…999.99 kV0.00…2.00 x Un0.00…2.00 x Un0.00…2.00 x Un0.00…999.99 kV0.00…999.99 kV0.00…999.99 kV0.00…2.00 x Un0.00…2.00 x Un0.00…2.00 x Unf/fn = 0.95…1.05: ±1.0% of set value or ±0.01 x Un


16

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The transient disturbance recorder MEDREC16 is used for monitoring the current and voltage waveforms as well as the status data of internal IEC 1131-3 based logic signals and binary inputs connected to the relay terminals. The maximum number of analogue channels as well as that of logic signals is 16. One fundamental cycle contains 40 samples.

Operation mode

Pre-trg timeOver limit ILxOver limit IoOver limit IobOver limit UoOver limit UxOver limit UxyOver limit U12bOver limit ILxbUnder limit UxUnder limit UxyAI filter time

SaturationOverwriteExtension0…100%0.00…40.00 x In0.00…40.00 x In0.00…40.00 x In0.00…2.00 x Un0.00…2.00 x Un0.00…2.00 x Un0.00…2.00 x Un0.00…40.00 x In0.00…2.00 x Un0.00…2.00 x Un0.000…60.000 s

The recording can be triggered by one or several of the alternatives listed below:• triggering by rising or falling edge of any (or several) of the binary inputs

• triggering by overcurrent, overvoltage or undervoltage

• manual triggering via MMI

• triggering via serial communication or a parameter

• periodic triggering

The recording length depends on the number of records and channels used. For example, the following combination of recording length, number of records and number of channels is available at 50 Hz:

# records \ # channels 1 3 10

1 1066 cyc.21.3 s

399 cyc.7.9 s

125 cyc.2.5 s

5 212 cyc.4.2 s

79 cyc.1.5 s

25 cyc.0.5 s

10 106 cyc.2.1 s

39 cyc.0.7 s

12 cyc.0.24 s

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7KUHHSKDVHQRQGLUHFWLRQDORYHUFXUUHQWSURWHFWLRQORZVHWVWDJH12&/RZ,!Start currentOperate time at DT modeTime multiplier at IDMT modeOperation mode

Measuring mode

Drop-off time of the operate time counter

0.10…5.00 x In0.05…300.00 s0.05…1.00Not in useDefinite timeExtremely inverseVery inverseNormal inverseLong time inverseRI-type inverseRD-type inversePeak-to-peakFundamental frequency0...1000 ms


17

Operation accuracyStart time

Reset time

Reset ratio, typicallyRetardation timeOperate time accuracy at DT modeAccuracy class index E at IDMT mode

Note! The values below apply when f/fn = 0.95...1.05±2.5% of set value or ±0.01 x InInjected currents > 2.0 x start current:internal time < 32 ms total time < 40 ms40...1000 ms (depends on the minimum pulse width set for the trip output)0.95< 45 ms±2% of set value or ±20 msClass index E = 5.0 or ±20 ms

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Start currentOperate timeOperation mode

Measuring mode


0.10…40.00 x In0.05…300.00 sNot in useDefinite time

Peak-to-peakFundamental frequency0...1000 ms

Operation accuracy

Start time

Reset time

Reset ratio, typicallyRetardation timeOperate time accuracy at DT mode

Note! The values below apply when f/fn = 0.95...1.050.1...10 x In: ±2.5% of set value or ±0.01 x In10...40 x In: ±5.0% of set valueInjected currents > 2.0 x start current:internal time < 32 mstotal time < 40 ms40...1000 ms (depends on the minimum pulse width set for the trip output)0.95< 45 ms±2% of set value or ±20 ms

7KUHHSKDVHGLUHFWLRQDO2&IXQFWLRQORZVHWVWDJH'2&/RZ,!→Operation mode

Start currentOperate timeTime multiplierBasic angle ϕbOperation direction

Earth-fault protection

Measuring mode


Not in use;Definite timeExtremely inv.;Very inverseNormal inverseLong-time inv.;RI-type inverseRD-type inverse0.05…40.00 x In0.05…300.00 s0.05…1.000…90°ForwardReverseDisabledEnabledPhase-to-phase voltages, peak-to-peak measurementPhase-to-phase voltages, fundamental freq. measurementPhase-to-earth voltages, peak-to-peak measurementPhase-to-earth voltages, fundamental freq. measurement0...1000 ms


18

Operation accuracy

Start time

Reset time


Note! The values below apply when f/fn = 0.95...1.050.1...10 x In: ±2.5% of set value or ±0.01 x In10...40 x In: ±5.0% of set value±2.5% of measured voltage or ±0.01 x Un±2°Injected currents > 2.0 x start current:internal time < 42 ms total time < 50 ms40...1000 ms (depends on the minimum pulse width set for the trip output)0.95< 45 ms±2% of set value or ±20 msClass index E = 5.0 or ±20 ms

7KUHHSKDVHGLUHFWLRQDO2&IXQFWLRQKLJKVHWVWDJH, '2&+LJK,!!→Operation mode

Start currentOperate timeBasic angle ϕbOperation direction

Earth-fault protection

Non-directional operation (when the direction cannot be determined)Measuring mode


Not in useDefinite time0.05…40.00 x In0.05…300.00 s0…90°ForwardReverseDisabledEnabledDisabledEnabledPhase-to-phase voltages, peak-to-peak measurementPhase-to-phase voltages, fundamental freq. measurementPhase-to-earth voltages, peak-to-peak measurementPhase-to-earth voltages, fundamental freq. measurement0...1000 ms

Operation accuracy

Start time

Reset time


Note! The values below apply when f/fn = 0.95...1.050.1...10 x In: ±2.5% of set value or ±0.01 x In10...40 x In: ±5.0% of set value±2.5% of measured voltage or ±0.01 x Un±2°Injected currents > 2.0 x start current:internal time < 42 ms total time < 50 ms40...1000 ms (depends on the minimum pulse width set for the trip output)0.95< 45 ms±2% of set value or ±20 ms


19

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Start currentOperate time at DT modeTime multiplier at IDMT modeOperation mode

Measuring mode


1.0…100.0% of In0.05…300.00 s0.05…1.00Not in useDefinite timeExtremely inverseVery inverseNormal inverseLong time inverseRI-type inverseRD-type inversePeak-to-peakFundamental frequency0...1000 ms


Reset time


Note! The values below apply when f/fn = 0.95...1.05±2.5% of set value + 0.0005 x InInjected currents > 2.0 x start current:internal time < 32 mstotal time < 40 ms40...1000 ms (depends on the minimum pulse width set for the trip output)0.95< 45 ms±2% of set value or ±20 msClass index E = 5.0 or ±20 ms

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Start currentOperate timeOperation mode

Measuring mode


0.10…12.00 x In0.05…300.00 sNot in useDefinite timePeak-to-peakFundamental frequency0...1000 ms


Reset time


Note! The values below apply when f/fn = 0.95...1.05±2.5% of set value or + 0.01 x InInjected currents > 2.0 x start current:internal time < 32 mstotal time < 40 ms40...1000 ms (depends on the minimum pulse width set for the trip output)0.95< 45 ms±2% of set value or ±20 ms


20

'LUHFWLRQDOHDUWKIDXOWSURWHFWLRQORZVHWVWDJH'()/RZ,R!→Start currentStart voltageOperate time at DT modeTime multiplier at IDMT modeOperation mode

Operation criteria

Operation direction

Basic angle ϕb

Operation characteristic

Intermittent E/F

Measuring mode


1.0…25.0% of In2.0…100.0% of Un0.1…300.0 s0.05…1.00Not in useDefinite timeExtremely inverseVery inverseNormal inverseLong time inverseBasic angle & UoBasic angleIoSin/Cos & UoIoSin/CosNon-directional IoNon-directional UoForwardReverse-90°-60°-30°0°IoSin(ϕ)IoCos(ϕ)Not activeActivePeak-to-peakFundamental frequency0...1000 ms

Operation accuracy

Start time

Reset time


Note! The values below apply when f/fn = 0.95...1.05±2.5% of set value + 0.0005 x In±2.5% of set value or + 0.01 x UnPhase angle ±2°Injected neutral current > 2.0 x start current andresidual voltage > 2.0 x start voltage:internal time < 72 mstotal time < 80 ms40...1000 ms (depends on the minimum pulse width set for the trip output)0.95< 50 ms±2% of set value or ±20 msClass index E = 5.0 or ±20 ms


21

'LUHFWLRQDOHDUWKIDXOWSURWHFWLRQKLJKVHWVWDJH'()+LJK,R!!→Start currentStart voltageOperate timeOperation mode

Operation criteria

Operation direction

Basic angle ϕb

Operation characteristic

Intermittent E/F

Measuring mode


1.0…200.0% of In2.0…100.0% of Un0.1…300.0 sNot in useDefinite timeBasic angle & UoBasic angleIoSin/Cos & UoIoSin/CosNon-directional IoNon-directional UoForwardReverse-90°-60°-30°0°IoSin(ϕ)IoCos(ϕ)Not activeActivePeak-to-peakFundamental frequency0...1000 ms

Operation accuracy

Start time

Reset time


Note! The values below apply when f/fn = 0.95...1.05±2.5% of set value + 0.0005 x In±2.5% of set value or + 0.01 x UnPhase angle ±2°Injected neutral current > 2.0 x start currentand residual voltage > 2.0 x start voltage:internal time < 72 mstotal time < 80 ms40...1000 ms (depends on the minimum pulse width set for the trip output)0.95< 50 ms±2% of set value or ±20 ms

3KDVHGLVFRQWLQXLW\SURWHFWLRQ&8%/RZ∆,!Start unbalanceOperate timeOperation mode

10.0…95.0%1.0…300.0 sNot in useDefinite time


Reset time

Reset ratio, typicallyRetardation time

Operate time accuracy at DT mode

Note! The values below apply when f/fn = 0.95...1.05±2.5% of set value or ±1% unitinternal time < 95 mstotal time < 100 ms40...1000 ms (depends on the minimum pulse width set for the trip output)0.95Total time for blocking: < 25 msTotal time when current drops below start value: < 50 ms±2% of set value or ±50 ms


22

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Start voltageOperate timeTime multiplierOperation mode

Measuring mode

Operation hysteresis

0.10…1.20 x Un0.1…300.0 s0.1…1.0Not in useDefinite timeC curvePhase-to-phase voltages; peak-to-peak measurementPhase-to-phase voltages; fundamental freq. measurementPhase-to-earth voltages; fundamental freq. measurement1.0...5.0%


Reset time

Reset ratioRetardation timeOperate time accuracy at DT modeAccuracy class index E at IDMT mode, typically

Note! The values below apply when f/fn = 0.95...1.05±2.5% of set value or ±0.01 x UnInjected voltages < 0.5 x start voltage:internal time < 32 mstotal time < 40 ms40...1000 ms (depends on the minimum pulse width set for the trip output)1.04 (range 1.005...1.05)< 60 ms±2.5% of set value±35 ms

7KUHHSKDVHXQGHUYROWDJHSURWHFWLRQKLJKVHWVWDJH89+LJK8

Start voltageOperate timeOperation mode

Measuring mode

Operation hysteresis

0.10…1.20 x Un0.1…300.0 sNot in useDefinite timePhase-to-phase voltages; peak-to-peak measurementPhase-to-phase voltages; fundamental freq. measurementPhase-to-earth voltages; fundamental freq. measurement1.0...5.0%


Reset time

Reset ratioRetardation timeOperate time accuracy at DT mode

Note! The values below apply when f/fn = 0.95...1.05±2.5% of set value or ±0.01 x UnInjected voltages < 0.5 x start voltage:internal time < 32 mstotal time < 40 ms40...1000 ms (depends on the minimum pulse width set for the trip output)1.04 (range 1.005...1.05)< 60 ms±2.5% of set value

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Ratio I2f/I1f>Start currentOperation mode

5…50%0.10…5.00 x InNot in useInrush modeStart-up mode

Operation accuracy

Start time

Note! The values below apply when f/fn = 0.95...1.05Current meas.: ±2.5% of set value or ±0.01 x InRatio I2f/I1f measurement: ±5.0% of set valueInternal time < 32 msTotal time < 40 ms


23

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Number of reclosuresInitiation mode

AR1, AR2, AR3, AR4 starting line operation mode

AR1 AR2, AR3, AR4 start delayDead timeSynchro-checkDiscriminating time td

0…5TripStartNo operationAR shot initiatedInitiation of AR shot blocked0…10.00 s0.20…300.00 sNot in use; ARSYNC in use0…30.00 s

Operation accuracy ±1% of setting value or ±30 ms

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The current waveform distortion measurement PQCU3H is used for measurement and statistical analysis of current waveform distortion. The standards concerning voltage distortion measurement are applied to current distortion measurement in PQCU3H. Data collection and analysis is done according to EN 50160. Measuring principles for individual harmonics and THD are adapted from the International standard IEC 61000-4-7. The American standard IEEE Std 1159 is also partly supported. Analysis can be done for one selected phase current or most distorted phase current can be tracked.

Measuring modesMeasurement activationTriggering modeDistortion factor

Not in use; L1; L2; L3; Worst phaseTriggering by: setting parameter, binary input, date & time settingSingle; Continuous; PeriodicTHD; TDD

Monitored valuesTHD (3 sec and 10 min mean values)Harmonic components from 1st to 13th (3 sec mean values)Harmonic components from 2nd to 13th (10 min mean values)

0.0 ... 1000.0%

0.0 ... 1000.0% In

0.0 ... 1000.0% In

StatisticsObservation times for statistics

Percentile settingPercentiles for each harmonic and THDFive fixed percentiles (1,5,50,95,99) for one selectable harmonic or THDMaximum values for each harmonic and THDRecorded data

1 hour; 12 hours; 1 day; 2 days; 3 days; 4 days; 5 days; 6 days; 1 week90.0 ... 99.5%

0.0 ... 1000.0% In

0.0 ... 1000.0% In

0.0 ... 1000.0% InOne data set for updating; One data set from the previous observation period

Harmonic limit supervisionLimit for THDLimits for each harmonicRecorded data

0.0 ... 60.0%0.0 ... 40.0% InIf any limit should be exceeded, the whole harmonic set will be recorded during the maximum THD (3 sec values)

Operation criteriaFundamental frequencyFrequency deviation

Amplitude of the fundamental wave

0.9 ... 1.1 Fn≤ 0.5 Hz (difference between max and min values within one second)≥ 1% In

Measurement accuracyMeasured harmonic Im = 1st, ... , 10thMeasured harmonic Im = 11th, ... , 13th

In accordance with IEC 61000-4-7

± 1.0% In, if Im < 10% In; ± 10% Im, if Im ≥ 10% In


24

9ROWDJHZDYHIRUPGLVWRUWLRQPHDVXUHPHQW3492+

The voltage waveform distortion measurement PQVO3H is used for measurement and statistical analysis of voltage waveform distortion. Data collection and analysis is done according to EN 50160. Measuring principles for individual harmonics and THD are adapted from the International standard IEC 61000-4-7. The American standard IEEE Std 1159 is also partly supported. Analysis can be done for one selected phase or phase-to-phase voltage or most distorted phase or phase-to-phase voltage can be tracked.

Measuring modesMeasurement activationTriggering mode

Not in use; L1; L2; L3; Worst phase; L1-L2; L2-L3; L3-L1; Worst mainTriggering by: setting parameter, binary input, date & time settingSingle; Continuous; Periodic

Monitored valuesTHD (3 sec and 10 min mean values)Harmonic components from 1st to 13th (3 sec mean values)Harmonic components from 2nd to 13th (10 min mean values)

0.0 ... 120.0%

0.0 ... 120.0% Un

0.0 ... 120.0% Un

StatisticsObservation times for statistics

Percentile settingPercentiles for each harmonic and THDFive fixed percentiles (1,5,50,95,99) for one selectable harmonic or THDMaximum values for each harmonic and THDRecorded data

1 hour; 12 hours; 1 day; 2 days; 3 days; 4 days; 5 days; 6 days; 1 week90.0 ... 99.5%

0.0 ... 120.0% Un

0.0 ... 120.0% Un

0.0 ... 120.0% UnOne data set for updating; One data set from the previous observation period

Harmonic limit supervisionLimit for THDLimits for each harmonicRecorded data

0.0 ... 30.0%0.0 ... 20.0% UnIf any limit should be exceeded, the whole harmonic set will be recorded during the maximum THD (3 sec values)

Operation criteriaFundamental frequencyFrequency deviation

Amplitude of the fundamental wave

0.9 ... 1.1 Fn≤ 0.5 Hz (difference between max and min values within one second)≥ 0.7 Un

Measurement accuracyMeasured harmonic Um = 1st, ... , 10thMeasured harmonic Um = 11th, ... , 13th

In accordance with IEC 61000-4-7

± 0.3% Un, if Um < 3% Un; ± 10% Um, if Um ≥ 3% Un


25

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Rated frequency 50.0/60.0 Hz

Frequency range 13th harmonic

Current inputs rated current 1 A/5 A

Thermal withstand capability

continuously 4 A/20 A

for 1 s 100 A/500 A

dynamic current withstand, half-wave value 250 A/1250 A

input impedance <100mΩ/<20 mΩ

Voltage inputs rated voltage 100 V/110 V/115 V/120 V / 230 V (parameterization)

voltage withstand, continuous 2 x Un (240 V)

burden at rated voltage <0.5 VA

Sensor inputs, max 8 voltage range RMS ±9.4 V

voltage range peak ±12 V

input impedance >4.7 MΩinput capacitance < 1 nF

7DEOH*HQHUDOWHFKQLFDOGDWD

Size REC 523: 261 mm (w), 265 mm (h), 250 mm (d) weight 5...7.2 kg

Aux. power supplies PSC1 (1MRS118022-xxA):- rated ac voltage- rated dc voltage - operating voltage range- fusePSC2 (1MRS118023-xxC):- rated dc voltage- operating range- fuse Normal power consumptionBurden of auxiliary supply at different operating conditionsRipple in dc aux. voltage

110 / 120 / 220 / 240 / Vac110 / 125 / 220 Vdc80... 265 Vac / dc2 A slow

24 / 36 / 48 / 60 Vdc18... 80 Vdc8 A slow20...30 W

10 W /100 WMax. 12% of the DC value

Battery(recommended)

YUA NP 17-12:- rated voltage- capacity- weight- sizeYUA NPL 24-12:- rated voltage- capacity- weight- size

12 V17 Ah5.6 kg181x76x167 cm (L x W x H)

12 V24 Ah, long life9.0 kg197x165x170 cm (L x W x H)

Supply for radios With batteriesWithout batteries

12 Vdc, 7 A peak, 1 A continuously12 Vdc, 1 A peak

Temperature- compensated charger for batteries:

Rated charging voltageOutput power Fuse (F2)Temperature compensation

27.6 Vdc, at 20°C15 W6 A- 0.04 V / °C


26

Binary inputs Number of inputsOperating range

Current drainPower consumption/input Pulse counting (specific binary inputs), frequency range

1518...265 V dc (24 V, 48 V, 60 V, 110 V, 220 V dc)~2...25 mA< 0.8 W

0...100 Hz

Power outputs Number of outputsRated voltage- continuous carry - make and carry for 0.5 s - make and carry for 3 s - breaking capacity when the control circuit time constant L/R<40 ms at 48 V, 110 V, 220 V dcContact material

2250 V ac/dc5 A30 A15 A

1 A, 0.25 A, 0.15 AAgCdO2

Signalling outputs

Number of outputsRated voltage- continuous carry- make and carry for 0.5 s - make and carry for 3 s Breaking capacity, when the control circuit time constant L/R <40 ms, for 48 V, 110 V, 220 V dcContact material

7250 V ac/dc5 A10 A8 A

1 A, 0.25 A, 0.15 AAgCdO2

Environmental tests Specified service temperature range- with heated enclosureTransport and storage temperature rangeDegree of protection, IEC 529: - wall-, flush- and rack-mounted - with UEMC-xx enclosure Tests:- dry heat test- dry cold test - damp heat test, cyclic- storage temperature test

-10...+55°C-40...+55°C

-40...+70°C

IP 20IP 55

IEC 60068-2-2IEC 60068-2-1IEC 60068-2-30r.h = 95%, T = 25°C...55°CIEC 60068-2-48

Insulation tests Dielectric test, test voltageIEC 60255-5

2kV, 50 Hz, 1 min.

Impulse voltage test, test voltageIEC 60255-5

5 kV, unipolar impulses, waweform 1.2/50 µs, source energy 0.5 J

Insulation resistance measurements, insulation resistanceIEC 60255-5

>100 MΩ, 500 V dc

Mechanical tests Vibration tests (sinusoidal) IEC 60255-21-1, class I

Shock and bump test IEC 60255-21-2, class I

Electromagnetic compatibility tests

The EMC immunity test level fulfills the requirements specified below

1 MHz burst disturbance test, class III, IEC 60255-22-1

common mode 2.5 kV

differential mode 1.0 kV



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Electrostatic discharge test, class III, IEC 61000-4-2 and IEC60255-22-2

for contact discharge 6 kV

for air discharge 8 kV

Radio frequency interference test

conducted, common modeIEC 61000-4-6

10 V (rms),f = 150 kHz…80 MHz

radiated, amplitude-modulatedIEC 61000-4-3

10 V/m (rms),f = 80…1000 MHz

radiated, pulse-modulatedENV 50204

10 V/m, f = 900 MHz

radiated, test with a portable transmitterIEC 60255-22-3, method C

f = 77.2 MHz, P = 6 W;f = 172.25 MHz, P = 5 W

Fast transient disturbance testIEC 60255-22-4 andIEC 61000-4-4

power supply 4 kV

I/O ports 2 kV

Surge immunity testIEC 61000-4-5

power supply 4 kV, common mode2 kV, differential mode

I/O ports 2 kV, common mode1 kV, differential mode

Power frequency (50 Hz)magnetic fieldIEC 61000-4-8

100 A/m

Voltage dips and short interruptionsIEC 61000-4-11

30%, 10 ms>90%, 5000 ms

Electromagnetic emission testsEN 55011

conducted RF emission (mains terminal)

EN 55011, class A

radiated RF emission EN 55011, class A

CE approval Complies with the EMC directive 89/336/EEC and the LV directive 73/23/EEC

Data communication Communication interface connector X5.1

- Serial interface RS232 on the real panel for connecting the unit to the remote control system via the remote communication protocol

Communication interface connector X5.2

- Serial interface RS232 on the real panel for parameterization the unit via a parameterization cable

Communication interface connector X5.3:

- Serial interface RS-485 on the real panel for:

- LON bus or SPA bus, selectable- the fibre-optic interface module RER 103 is

needed for galvanic isolation- data transfer rate for the SPA bus is 4800/

9600 bps- data transfer rate for the LON bus is

78 kbps / 1.25 Mbps

Connectors with optional plug-in modem module:- data transfer rate for remote communication protocol

- parameterization

300/600/1200/4800/9600/14400 bpsvia parameterization cable 1MRS120520

Interface connector X4.1 RJ-12 connector for public telephone line

Interface connector X4.2 - RS-232 connection- configuration via PC and any terminal

software by using AT-Hayes commands



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Interface connector X4.3 - screw terminal connector for radio and leased lines

- radio’s transmitter keying

Communication protocols SPA bus protocolLON bus acc. to ABB LON Application Guideline V1.2IEC 60870-5-101 acc. to Protocol Description 1MRS750956MODBUS acc. to Protocol Description 1MRS750957DNP 3.0 acc. to Protocol Description 1MRS750958

Programming tools CAP 501CAP 505

Event recording All events are recorded in higher- level syntax: reason, time, date

The 500 latest events are recorded

Data recording Records operate values

Control functions Refer to Technical Description of functions, manual 1MRS750528-MUM

Condition monitoring functions Refer to Technical Description of functions, manual 1MRS750528-MUM

Measurements Refer to Technical Description of functions, manual 1MRS750528-MUM:- temperature of enclosure- battery voltage

-40°...+60°C, ±3°C15...35 Vdc, ±3%

Self-supervision All analogue reference voltagesAutomatic test sequences:- I/Os- Batteries- Flash memory


Plug-in modems for relays / units based on REC 501...REC 533 and RED 500 platform Types

1MRS119000-Axx1MRS119000-Bxx (Extended temperature range)

Manufacturer Westermo Teleindustri AB, Sweden

Telephone line interface Modes; Dial-up, 2- or 4-wire leased or fixed lineITU-T recommendations:- ITU-T V.21 300 bps- ITU-T V.22 1 200 bps- ITU-T V.22 bis 2 400 bps- ITU-T V.23 1 200/75 bps- ITU-T V.32 9 600 bps- ITU-T V.32 bis 14 400 bps

Input sensitivityOutput level Modem configuration

-43 to -6 dBmsoftware adjustable, -2 to -17 dBm AT Commands and S registers, Jumper settings

Radio interface ModesInput sensitivityOutput levelSubcarrier detector TX/RX switch (PTT)TX/RX delayModem configuration

2- or 4-wire private line-43 to -6 dBmsoftware or automatically adjusted, -2 to -17 dBm 12 - 60 V forward voltage, (0.3 - 1.8 mA)relay operated (5A, 30 Vdc, 250 Vac)adj. between 30 and 2000 msAT Commands and S registers


29

DTE InterfaceData speed Data format

2 x RS232 in parallel auto-detection between 300 - 38400 bit/sauto-detection between 7 or 8 bits; odd, even or no parity; 1 stop bit

Power consumption 5 V, typical 165 mA, max 250 mA24 V, passive typical 26 mA, active typical 45 mA, max. 60 mA.

Environmental conditions Ambient temp. range:- 1MRS119000-Axx- 1MRS119000-BxxStorage temperatureRelative humidity

+5...+50°C-20...+60°C-40...+125°C15...90%, non-condensing

Mechanical dimensions W x Lheight (components)

160 x 233.4 mm (E2)max. 16 mm

Applicable manuals Operator’s manualEngineering manual

1MRS750577-MUM EN1MRS750720-MUM EN


o -

-

s

be

30

Ordering Order numberThe following data should be specified in the order:

• Order number

• Software number of protocol options (refer to section “Software configuration and software number” below)

• Software number of function options (refer to section “Software configuration and software number” below)

• Quantity of REC 523 units

• Other options, e.g. modem module (refer tsection “Optional peripherials” in the Technical Reference Manual.

Each REC 523 unit has a specific order number that identifies the unit type as well as thehardware and the software revision as described in the figure below.

The REC 523 units differ from each other as to the number and type of measuring inputs.

All the REC 523 hardware versions include the same number of digital inputs and outputs, whereas the number of matching transformers and sensor inputs as well as the auxiliary volt-age range vary between the different hardware versions.

Software configuration and software numberEach REC 523 allows different software con-figurations based on separate functions that can be activated from comprehensive libraries

within the scope of the processing capacity awell as the I/O connections and analogue channels available, and considering the totalCPU load of the selected functions

There are two separate software numbers to specified in the order, one for the protocol options as described in the table 10 and the other for the function options as described inthe table 11.

REC523D 033AAA

TypedRec

Analogue interface typeA: Only matching transformers included (MIM)B: Sensor inputs and transformers included (MIM and SIM)C: Only sensor inputs included (SIM)

Digital input voltage rangeA: Ur = 24/48/60/110/220 VdcAuxiliary voltage range of a power supply moduleA: Ur = 110/120/220/240 V ac; 110/125/220 V dc (PSC1)C: Ur = 24/48/60 V dc (PSC2)

Software revisionControl unit type

Hardware number

7DEOH3URWRFRORSWLRQV

Software No Protocol options included

1MRS110006-001 SPA, LON and IEC 60870-5-101 (unbalanced mode)

1MRS110011-001 SPA, LON and DNP 3.0

1MRS110012-001 SPA, LON and Modbus (both the RTU and ASCII modes)

7DEOH)XQFWLRQRSWLRQVIRU5(&

Software No Function options for REC 523

1MRS100512 Current waveform distortion measurement

1MRS100513 Voltage waveform distortion measurement

1MRS100143 Power factor controller


31

Optional peripherals

1) Includes the cable (1MRS 120525) between the plug-in modem module and the REC 523 unit

2) xx marks the country code Note! Local approval required for switched lines.

3) XX receiver / transmitterB = plastic fibre cableM = Glass fibre cable

The REC 523 versions have the following analogue channels:

The REC 523 Remote Monitoring and Control unit always includes:

• A CPU module

• A Power supply and charger module:

• frequency 50/60 Hz

• 2 power outputs, double-pole

• 1 signal output or heater output

• +12 V output for communication devices

• 3 digital inputs

• 1 IRF output

• An I/O module BIO1:

• 12 digital inputs

• 2 signal outputs (NO)

• 4 signal outputs (NO/NC)

Modem module1):

- normal temperature range 1MRS 119000-Axx 2)

- wide temperature range 1MRS 119000-Bxx 2)

Parameterization cable 1MRS 120520

Cable between REC 523 and a commercial modem 1MRS 120528

Cable between MicroSCADA and REC 523 1MRS 120523

Bus connection module RER 103 1MRS 090701-XX 3)

Semi-flush mounting kit 1MRS 050239

Rack mounting kit 1MRS 050242

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5(&'&$$ZDOOPRXQWHG5(&'&$$IOXVKPRXQWHG

3 current transformersUaux = 80-265 V AC/DC

3 current transformersUaux = 18-80 V DC



3 current transformers 1/5 A3 voltage transformers 100 VUaux = 80-265 V AC/DC

3 current transformers 1/5 A3 voltage transformers 100 VUaux = 18-80 V DC





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5(&'&$&ZDOOPRXQWHG5(&'&$&IOXVKPRXQWHG

9 sensor channels(current sensor or voltage divider)Uaux = 80-265 V AC/DC

9 sensor channels(current sensor or voltage divider)Uaux = 18-80 V DC










32

The last number of the hardware version num-ber specifies whether the measuring and con-trol unit is flush-mounted or wall-mounted.

Each analogue channel is separately config-ured by using the Relay Configuration Tool.

The hardware number and a combined soft-ware nymber is labelled on the marking strip on the front panel of the device delivered. The software number is for factory use only.

Application examples

Fig. 7 Basic functions of the REC 523 provided with an NPS-type air-insulated disconnector and KOHU/KOKU current sensors

REC 523 +12V Radio

+24V

O

C

MV

1

2

9

1

2

15

1

2

9

IRF

M

523SEC

Heating

Modem(Optional)

Open

Close

Enclosure UEMC A2

Remote

offon

aux


33

References

Fig. 8 Basic functions of the REC 523 provided with a CCF-type ring main unit (RMU)

REC 523+12V

Radio

+24V

1

2

9

1

2

15

1

2

9

IRF

M M

O

C

Remoteoffon

O

C

3

4

1

2

LV

MV

523RMU

Modem(Optional)

Open

Close

Enclosure UEMC A2

aux

Open

Close

$GGLWLRQDOLQIRUPDWLRQ

Technical Reference Manual 1MRS 750881-MUM

REF54_, REM543, REC523 Descriptions of Functions

1MRS 750889-MCD (CD-ROM only)

Installation and Commissioning Manual 1MRS 750879-MUM

Operator’s Manual for “1MRS119000 plug-in modem”

1MRS 750577-MUM

Technical Reference Manual RER 103 1MRS 750532-MUM

IEC 60870-5-101 Protocol Manual 1MRS 750956-MUM

Modbus Protocol Manual 1MRS 752015-MUM

DNP 3.0 Protocol Manual 1MRS 750958-MUM

Echelon, LON and LonTalk are registered trademarks of Echelon Corporation.All other product names are trademarks, registered trademarks, or service marks of their respective owners.

ABB Oy

P.O. Box 699FIN-65101 Vaasa, FinlandTel +358 10 224 000Fax +358 10 224 1094www.abb.com/substationautomation

Remote monitoring and control unit REC 523...ventional radio • Management via network control...

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