csc-150 busbar protection ied product guide_v1.10

CSC-150Busbar Protection IED

Product Guide

Version V1.10Doc. Code: 0SF.492.056(E)Issued Date 2012.8Copyright owner: Beijing Sifang Automation Co., Ltd.

Note: The company keeps the right to perfect the instruction. If equipments do not agree with the instruction at anywhere, please contact our company in time. We will provide you with corresponding service.

® is registered trademark of Beijing Sifang Automation Co., Ltd.

We reserve all rights to this document, even in the event that a patent is issued and a different commercial proprietary right is registered. Improper use, in particular reproduction and dissemination to third parties, is not permitted.

This document has been carefully checked. If the user nevertheless detects any errors, he is asked to notify us as soon as possible.

The data contained in this manual is intended solely for the IED description and is not to be deemed to be a statement of guaranteed properties. In the interests of our customers, we constantly seek to ensure that our products are developed to the latest technological standards as a result; it is possible that there may be some differences between the hardware/software product and this information product.

Manufacturer:Beijing Sifang Automation Co., Ltd.

Overview

1

CSC-150 is selective, reliable and high

speed busbar protection IED (Intelligent

Electronic Device), with powerful capa-

-bilities to cover following applications:

For various busbar arrangements,

including those listed below:

Single Busbar

Two Single Busbars connected

with bus coupler

Two Separate Busbars in 1

CB

arrangement

Double Busbar

Main and Transfer Busbar

Double Main and one Transfer

Busbar

Main and Main/Transfer Busbar

For solidly earthed, low impedance

earthed or isolated power system

Used in a wide range of voltage levels,

up to 750kV

Communication with station automation

system

The IED provides reliable busbar

differential protection with integrated check

zone, short saturation-free time and fast

tripping time as well as circuit breaker

failure protection and dead zone

protection.

The wide application flexibility makes the

IED an excellent choice for both new

installations and retrofitting of the existing

installations.

.

Feature

2

Protection and monitoring IED with

extensive functional library, user

configuration possibility and expand-

-able hardware design to meet with

user’s special requirements

Inter-lock between two CPU modules,

avoiding maloperation due to internal

severe fault of one module

Busbar differential protection (87BB)

Low-impedance centralized differ-

-ential protection

Selective zone tripping

Extreme stability against exteral

fault, short CT saturation-free time

Phase-segraegated measuring

system

Integrated check zone

Bus couplers/disconnetor is defin-

-able in busbar scheme

A complete protection functions library,

include:

Busbar differential protection

(87BB)

Circuit breaker failure protection

(50BF)

Dead zone protection (50DZ)

Voltage transformer secondary

circuit supervision (97FF)

Current transformer secondary

circuit supervision

Self-supervision to all modules in the

IED

Complete IED information recording:

tripping reports, alarm reports, startup

reports and general operation reports.

Any kinds of reports can be stored up

to 2000 and be memorized in case of

power disconnection

Up to three electric /optical Ethernet

ports can be selected to communicate

with substation automation system by

IEC61850 or IEC60870-5-103 proto-

-cols

Up to two electric RS-485 ports can be

selected to communicate with

substation automation system by

IEC60870-5-103 protocol

Time synchronization via network

(SNTP), pulse and IRIG-B mode

Configurable LEDs (Light Emitting

Diodes) and output relays satisfied

users’ requirement

Versatile human-machine interface

Multifunctional software tool for setting,

monitoring, fault recording analysis,

configuration, etc.

Function

3

Protection functions

Description ANSI Code

IEC 61850

Logical Node

Name

IEC 60617

graphical

symbol

Differential protection

Busbar differential protection 87BB PDIF

Breaker control function

Breaker failure protection 50BF RBRF

3I> BF

I0>BF

I2>BF

Dead zone protection 50DZ

Secondary system supervision

CT secondary circuit supervision

VT secondary circuit supervision 97FF

Position of circuit breaker, disconnector

and other switching devices monitoring

Monitoring functions

Description

Auxiliary contacts of circuit breaker supervision

Self-supervision

Fault recorder

Station communication

Description

Front communication port

Isolated RS232 port for maintaining

Rear communication port

0-2 isolated electrical RS485 communication ports, support IEC 60870-5-103 protocol

Function

4

0-3 Ethernet electrical/optical communication ports, support IEC 61850 protocol or IEC 60870-5-103

protocol

Time synchronization port, support GPS pulse or IRIG-B code

IED software tools

Functions

Reading measuring value, IED report

Setting

IED testing

Disturbance recording analysis

IED configuration

Printing

Function

5

Application for busbar

50BF

RBRF

3I>BF

87BB

PDIF

50BF 3I>BF

RBRF

50BF 3I>BF

RBRF

50DZ

50BF 3I>BF

RBRF

50BF 3I>BF

RBRF

MONITORING

STATION

COMMUNICATION

MEASUREMENT

- RS232/485

- RJ45/FO

- IEC61850

- IEC60870-5-103

Fault recording

50DZ 50DZ

50DZ 50DZ

Protection

6

Busbar differential protection (87BB)

Busbar differential protection represents

the main protection function of the IED. It is

characterized by a high measurement

accuracy as well as flexible matching to

most of busbar configurations. The

operation is based on the percentage

restraint principle with an extreme stability

feature against heavy CT saturation

caused by external fault.

Operating characteristic

Figure 1 illustrates the characteristic of busbar differential protection function.

iDiff

iRes

I_BDiff

K=1

K=K_Diff

Operating zone

Figure 1 Characteristic of busbar differential

protection

where:

iDiff: Busbar differential current

iRes: Busbar restraint current

I_BDiff: The sensitive threshold of pickup current of busbar differential protection

K_Diff: Slope_BDiff, the settable slope of the characteristic

If a short circuit occurs on the busbars

whereby the same phase relation applies

to all infeeding currents, then the fault

characteristic is a straight line inclined at

45°. Any difference in phase relation of the

fault currents leads to a lowering of the

fault characteristic. The settable slope,

Slope_BDiff is represented as a straight

line with corresponding gradient and forms

the operating characteristic.

The differential current iDiff and the

restraining current iRes are calculated in the

IED according to following formula. The

following definitions are applied for each

phase.

where:

n1, n2,… nn: CT transformation ratios of various feeders connected to the busbar. The IED is informed about these values by user-defined settings

The IED evaluates the differential current

and the restraining current at consecutive

sampling intervals. The busbar protection

would issue a trip command if there are

more than (N-2) samples fulfilling following

condition in the program observation

window:

The above mentioned calculation is

performed in relevant bus zones as well as

in check zone, respectively. The trip

command can be issued only when both

the faulty bus zone and the check zone are

in operating area.

Automatic ratio compensation

CT ratios of in a busbar system may be

different in various feeders, because the

load conditions may be different in the

feeders. The IED adjusts CT ratio of all

Protection

7

feeders automatically, making the

secondary currents fulfilling Krichhoff’s

current law (KCL). In order to insure the

accuracy, the difference of CT ratios

among various feeders should not be more

than 4 times.

Disconnector replica

The IED confirms the disconnector status

by monitoring the disconnector status

contacts. For each disconnector, both the

normally open status contact (NO) and

normally close status contact (NC) are

required. Based on the status of these two

contacts, the IED can discriminate error of

the contacts and then alarm or/and block

the relevant bus zone of differential

protection depending on the setting. If

blocking protection is selected, the IED

would issue an alarm signal and would

block the protection. If no blocking is

selected, only alarm signal would be

issued and the protection would continue

to its operation according to the previous

healthy state of the disconnector before

the contacts error.

Circuit breaker status

The feeder or coupler circuit breaker status

contacts together with disconnector status

contacts are used to determine the actual

bus connection state for differential current

calculation and indication of busbar

connection

Both normally open status contact and

normally close status contact of circuit

breakers of all feeders including bus

coupler are connected to the IED. Based

on the status of these two contacts, the

IED can discriminate error of the contacts

and then alarm until the error is cleared,

and the protection would continue to its

operation according the previous healthy

state of the breaker before the contacts

error.

Current transformer open circuit supervision

When an open circuit occurs in secondary

circuit of current transformers, differential

current appears in bus-section selective

zones. Further, if the faulty current

transformer corresponds to a feeder,

differential current would further appear in

check zone. The IED detects such a

condition and issues respective alarm

report. Moreover, it is possible to block

busbar differential protection when a CT

open circuit is detected.

Differential current saturation supervision

When an external fault occurs near the

busbar, it may lead to current transformer

saturation on the faulty feeder. The

resulting differential current may cause the

protection to maloperate if no measure is

taken to detect saturation condition. To

cope with the problem, the IED provides a

sensitive element to detect current trans-

-former saturation according to the wave-

-form characteristics of differential and

restraining current.

In fact, secondary current can be

transformed accurately, even by a

saturated current transformer, when the

current is near zero or at the initial instants

of fault. At these instants, the differential

current is zero. The IED adopts this

characteristic to detect current transformer

saturation. The CT saturation free time is

only 2 ms.

Protection

8

Sequence trip

In case of bus coupler with only one CT,

when a fault occurs between the CT and

bus coupler circuit breaker while the circuit

breaker is closed, the IED will trip the bus

section near bus coupler circuit breaker

instantaneously, and after a fixed time

delay, if the bus coupler circuit breaker is

opened, the IED will trip the other bus

section. The tripping logic is illustrated in

Figure 2.

Bus A

IFAULT

Instantaneous trip

Line

A1

Line

B1

Line

BmLine

An

Delay trip

Bus B

Closed CB

Legend:

Figure 2 Trip logic to clear fault between coupler

breaker and its CT

Breaker failure protection (50BF)

The circuit breaker failure protection is able

to detect a failure of the circuit breaker

during a fault clearance. It ensures fast

back-up tripping of surrounding breakers

by tripping relevant bus sections.

The protection operates separately for

each feeder and coupler with dedicated

settings.

Once a circuit breaker operating failure

occurs on a feeder/transformer, the bus

section which the feeder/transformer is

connected with can be selectively isolated

by the protection. In addition a transfer trip

signal is issued to trip the remote end

circuit breaker of the feeder or other

transformer windings.

In the event of a circuit breaker failure with

a busbar fault, a transfer trip signal is

issued to trip the remote end circuit

breaker of the feeder.

The current criteria are in combination with

three phase current, zero and negative

sequence current to achieve a higher

security.

2 trip stages (local and surrounding

breaker tripping)

Related bus zone tripping in second

stage

Transfer trip command to the remote

line end in second stage

Internal/ external initiation

Single/three phase CBF initiation

Current criteria checking (including

phase current, zero and negative

sequence current)

Dead zone protection (50DZ)

The IED provides dead zone protection to

protect the area, between circuit breaker

and CT in the case that CB is open.

Protection

9

Therefore, by occurrence of a fault in dead

zone, the short circuit current is measured

by protection relay while CB auxiliary

contacts indicate the CB is open.

Self-adaptive for bus side CT or line

side CT

When one bus side CT of feeder is applied,

once a fault occurs in the dead zone, the

IED trips the relevant busbar zone.

Tripping logic is illustrated in Figure 3

Bus

IFAULT

Trip

Line1 Line2 LineN

Opened CB

Closed CB

Legend:

Figure 3 Tripping logic when applying bus side

CT

When one line side CT is applied, when a

fault occurs in the dead zone, protection

relay sends a transfer trip to remote end

relay to isolate the fault. Tripping logic is

illustrated in Figure 4

Bus

IFAULT

Relay

Inter trip

Line1 Line2 LineN

Trip

Opened CB

Closed CB

Legend:

Figure 4 Tripping logic when applying line side

CT

In case of bus coupler with only one CT,

when a fault occurs between the CT and

bus coupler circuit breaker while the circuit

breaker is opened, the IED will trip the bus

section near the bus coupler CT

instantaneously. Tripping logic is illustrated

in Figure 5.

Protection

10

Bus A

IFAULT

Instantaneous trip

Line

A1

Line

B1

Line

BmLine

An

Bus B

Opened CB

Closed CB

Legend:

Figure 5 Tripping logic for fault between coupler

breaker and its CT

Secondary system supervision

Current transformer secondary circuit supervision Open circuited CT cores can cause

unwanted operation of differential protec-

-tion function.

The interruption on CT secondary circuit

can be detected by the IED. The IED

provides following features:

One stage for alarm

One stage for block busbar differential

protection

Each stage can be selected and set

separately

Voltage transformer secondary

circuit supervision

A measured voltage failure, due to a

broken conductor or a short circuit fault in

the secondary circuit of voltage

transformer is detected in the IED. The

features of the function are as follows:

Symmetrical/asymmetrical VT failure

detection

3-phase AC voltage MCB monitoring

1-phase AC voltage MCB monitoring

Zero and negative sequence current

monitoring

Applicable in solid grounded,

compensated or isolated networks

Auxiliary contacts of circuit breaker and disconnector supervision

The IED is connected with normally open

contacts and normally close contacts of

circuit breakers and disconnectors. It

performs monitoring on the received

information to detect any implausible

status.

If such a wrong status is detected for a

disconnector, the IED will announce it after

a settable time delay, and continue to

operate according to previous healthy state

of disconnector contacts. If the blocking

function is enabled, the relevant bus zone

of the busbar differential protection would

be blocked until the wrong status changing

to normal. Otherwise, the relevant bus

zone of the busbar differential protection

would not be blocked.

If such a wrong status is detected for a

circuit breaker, the device announces it

after a settable time delay, and the

protection will continue to operate

according to previous healthy state of

Protection

11

disconnector contacts.

Monitoring

12

Self-supervision

All modules can perform self-

-supervision to its key hardware

components and program, as soon as

energizing. Parts of the modules are

self-supervised in real time. All internal

faults or abnormal conditions will

initiate an alarm. The fatal faults among

them will result in the whole IED

blocked

CPU module and communication

module perform real time inter-

-supervision. Therefore communication

interruption between them is detected

and related alarm will be given

CRC checks for the setting, program

and configuration, etc.

Communication

13

Station communication

Overview

The IED is able to connect to one or

more substation level systems or

equipments simultaneously, through the

communication ports with

communication protocols supported.

(Shown in Figure 6)

Gateway

or

converter

Work Station 3

Server or

Work Station 1

Server or

Work Station 2

Work Station 4

Net 2: IEC61850/IEC103,Ethernet Port B

Net 3: IEC103, RS485 Port A

Net 4: IEC103, RS485 Port B

Net 1: IEC61850/IEC103,Ethernet Port A

Gateway

or

converter

SwitchSwitch Switch

Switch

Switch

Switch

Figure 6 Connection example for multi-networks of station automation system

Note: All four ports can work in parallel


There is a serial RS232 port on the front

plate of all the IEDs. Through this port,

the IED can be connected to the

personal computer for setting, testing,

and configuration using the dedicated

Sifang software tool.

RS485 communication ports

Up to 2 isolated electrical RS485

communication ports are provided to

connect with substation automation

system. These two ports can work in

parallel for IEC60870-5-103.

Ethernet communication ports

Up to 3 electrical or optical Ethernet

communication ports are provided to

connect with substation automation system.

These two out of three ports can work in

parallel for one protocol, IEC61850 or

IEC60870-5-103.

Communication protocol

The IED supports station communication

with IEC 61850-8 and IED60870-5-103

protocols.

By means of IEC61850, GOOSE peer- to

peer communication make it possible that

bay IEDs can exchange information to

each other directly, and a simple

master-less system can be set up for bay

and system interlocking and other

interactive function.

Time synchronization port

All IEDs feature a permanently integrated

electrical time synchronization port. It can

be used to feed timing telegrams in IRIG-B

Communication

14

or pulse format into the IEDs via time

synchronization receivers. The IED can

adapt the second or minute pulse in the

pulse mode automatically.

Meanwhile, SNTP network time

synchronization can be applied.

The Figure 7 illustrates the optional time

synchronization modes.

SNTP IRIG-B Pulse

Ethernet port IRIG-B port Binary input

Figure 7 Time synchronizing modes

Software Tools

15

A user-friendly software tool is offered for

engineering, setting, disturbance analysis

and monitoring. It provides versatile

functionalities required throughout the life

cycle of protection IEDs. Its features are as

follows:

Device administration in projects with

freely configurable hierarchies for any

substation and electrical power station

topology

Modification, import and export of

parameter sets sorted by protection

functions, with setting logicality check

Precise fault analysis with visualization

of fault records in curves, circle

diagrams, vector diagrams, bar charts

and data sheet.

Intelligent plausibility checks rule out

incorrect input

Graphical visualization of charac-

-teristics and zone diagrams with direct

manipulation of the curves

Password-protected access for

different jobs such as parameter setting,

commissioning and controlling

(authorized staff only)

Testing and diagnostic functions

–decisive support in the commissioning

phase

Connection

16

Front plate The whole front plate is divided into

zones, each of them with a well-defined

functionality:

1

2

3

45

68 7

CSC-150

Figure 8 Front plate

1 Liquid crystal display (LCD)

2 LEDs

3 Shortcut function keys

4 Arrow keys

5 Reset key

6 Quit key

7 Set key

8 RS232 communication port

Rear terminals

17

Rear plate CAN

Test port

AIM

AIM

AIM

AIM

AIM

AIM

AIM

BO

M

CP

U2

CP

U1

BO

M

BO

M

PS

M

BO

M

BO

M

BIM

BO

M

PS

M

CO

M

X1X2X3X4X11X12X13X14

X5X6X7X8X15X16X17X18X19 X9X10X20

X21

Figure 9 Rear plate of the main case

BIM

BO

M

BO

M

BO

M

BIM

BIM

BIM

X1X3X5X7X9X11X13

CAN

X14

BIM

X2

BIM

X4

BIM

X6

BO

M

X8

BO

M

X10

PS

M

X12

Figure 10 Rear plate of the auxiliary case

.

Hardware

18

Modules

Analogue Input Module (AIM)

The analogue input module is used to

galvanically separate and transform the

secondary currents and voltages

generated by the measuring transformers.

CPU Module (CPU)

The CPU module handles all protection

functions and logic. There are two CPU

modules in the IED, CPU1 and CPU2, with

the same software and hardware. They

work in parallel and interlock each other to

prevent maloperation due to the internal

faults of one CPU modules.

Moreover, the redundant A/D sampling

channels are equipped. By comparing the

data from redundant sampling channels,

any sampling data errors and the channel

hardware faults can be detected

immediately and the proper alarm and

blocking is initiated in time.

Communication Module (COM)

The communication module performs

communication between the internal

protection system and external equipments

such as HMI, engineering workstation,

substation automation system, RTU, etc.,

to transmit remote metering, remote

signaling, SOE, event reports and record

data.

Up to 3 channels isolated electrical or

optical Ethernet ports and up to 2 channels

RS485 serial communication ports can be

provided in communication module to meet

the communication demands of different

substation automation system and RTU at

the same time.

The time synchronization port is equipped,

which can work in pulse mode or IRIG-B

mode. SNTP mode can be applied through

communication port.

In addition, a series printer port is also

reserved.

Binary Input Module (BIM)

The binary input module is used to connect

the input signals and alarm signals such as

the auxiliary contacts of the circuit breaker

(CB), etc.

Binary Output Module (BOM)

The binary output modules mainly provide

tripping output contacts, initiating output

contacts and signaling output contacts. All

the tripping output relays have contacts

with a high switching capacity and are

blocked by protection startup elements.

Each output relay can be configured to

satisfy the demands of users.

Power Supply Module (PSM)

The power supply module is used to

provide the correct internal voltages and

full isolation between the terminal and the

battery system.

Hardware

19

Dimension

A

B

C

D

E

Figure 11 8U, 1/1 x 19” main case with rear cover

Table 1 Dimension of the main case

Legend A B C D E

Dimension (mm) 354.8 482.8 267.7 320 450

Hardware

20

A

B

CD

E

F

G

Figure 12 Cut-out for the panel mounting of main case

Table 2 Dimension of the cut-out for main case panel mounting

Legend A B C D E F G

Dimension (mm) 450 465 101.6 76.2 101.6 355.6 6.5

Hardware

21

B

A

C

D

Figure 13 4U, 1/1 x 19” auxiliary case with rear cover

Table 3 Dimension of the auxiliary case

Legend A B C D E

Dimension (mm) 177 482.6 265 320 437.2

A

B

C D

E

Figure 14 Cut-out on the panel for auxiliary case

Table 4 Dimension of the cutout for auxiliary case panel mounting

Legend A B C D E

Dimension (mm) 450 465 101.6 178 6.5

Connection

22

A. Typical rear terminal diagram

X1 CSC-150

Main casea01I1

b01

a02I2

b02

a03I3

b03

a04I4

b04

a05I5

b05

a06I6

b06

a07I7

b07

a08I8

b08

a10

I9

b10

a09

b09

a11

b11

a12

b12

X2a01

I1b01

b12

X11a02

BI02 c02

BI03 a04

BI04 c04

BI05 a06

BI06 c06

BI07 a08

BI08 c08

BI09 a10

BI01

BI10 c10

BI11 a12

BI12 c12

BI13 a14

BI14 c14

BI15 a16

BI16 c16

BI17 a18

BI18 c18

BI19 a20

BI20 c20

BI21 a22

BI22 c22

BI23 a24

BI24 c24

BI25 a26

BI26 c26

BI27 a28

BI28 c28

BI29 a30

BI30 c30

a32

c32BI-COM1(-)

BI-COM2(-)

Note:

1) The module is same as X1

module.

I10

Null

Null

Null

Null

a12 Null

Null

1)

a01I1

b01

b12

a12 Null

Null

X8a01

I1b01

a02I2

b02

a03

b03

a04

b04

a05

b05

a06

b06

a07

b07

a08

b08

a10

b10

a09UB3b09UC3

UA3

a11

b11

a12

b12

UN3

UB1

UC1

UA1

UN1UB2

UC2

UA2

UN2

X3

a01I1

b01

b12

a12 Null

Null

X4

a01I1

b01

b12

a12 Null

Null

X5

a01I1

b01

b12

a12 Null

Null

X6

1)

1)

1)

1)

Null

Null

Null

Null

Null

Null

Null

Null

Connection

23

CSC-150 main case

Output relay 01

Output relay 02

Output relay 03

Output relay 04

Output relay 05

Output relay 06

Output relay 07

Output relay 08

Output relay 09

Output relay 10

Output relay 11

Output relay 12

Output relay 13

Output relay 14

Output relay 15

Output relay 16

X12a02

c02

a04

c04

a06

c06

a08

c08a10

c10

a12

c12

a14

c14

a16

c16

a18c18

a20

c20

a22

c22

a24

c24a26

c26

a28

c28

a30

c30

a32

c32

X131

2

3

4

5

6

7

89

10

11

12

13

14

15

16

Ethernet Port 1 - RJ45

Ethernet Port 2 - RJ45

Null

Null

Null

RS485 - 2B

RS485 - 2A

RS485 - 1B

RS485 - 1AGPS

Null

GPS - GND

Null

Null

Null

Null

Null

Null

1)

X14a02

c02

a04

c04

a06

c06

a08

c08a10

c10

a12

c12

a14

c14

a16

c16

a18c18

a20

c20

a22

c22

a24

c24a26

c26

a28

c28

a30

c30

a32

c32

DC 24V + output

Null

DC 24V - output

Power failure alarm relay 1

AUX DC + input


AUX DC - input

Null

Null

Null

Terminal for earthing


X15a02

c02

a04

c04

a06

c06

a08

c08a10

c10

a12

c12

a14

c14

a16

c16

a18c18

a20

c20

a22

c22

a24

c24a26

c26

a28

c28

a30

c30

a32

c32

DC 24V + output

Null

DC 24V - output


AUX DC + input


AUX DC - input

Null

Null

Null



Ethernet Port 1 - ST

Ethernet Port 2 - ST

Note:

1) Alternative Ethernet ports

are 2 ST optical fiber ports,

shown as following.

Null

Null

Null

Null

Null

Null

Null

Null

Connection

24

CSC-150 main case

X20a02

c02

a04

c04

a06

c06

a08

c08a10

c10

a12

c12

a14

c14

a16

c16

a18c18

a20

c20

a22

c22

a24

c24a26

c26

a28

c28

a30

c30

a32

c32

Output relay 01

Output relay 02

Output relay 03

Output relay 04

Output relay 05

Output relay 06

Output relay 07

Output relay 08

Output relay 09

Output relay 10

Output relay 11

Output relay 12

Output relay 13

Output relay 14

Output relay 15

Output relay 16

X16a02

c02

a04

c04

a06

c06

a08

c08a10

c10

a12

c12

a14

c14

a16

c16

a18c18

a20

c20

a22

c22

a24

c24a26

c26

a28

c28

a30

c30

a32

c32

Output relay 01

X17a02

c02

a32

c32

Output relay 01

Output relay 02

Output relay 03

Output relay 04

Output relay 05

Output relay 06

Output relay 07

Output relay 08

Output relay 09

Output relay 10

Output relay 11

Output relay 12

Output relay 13

Output relay 14

Output relay 15

Output relay 16

Note :

1) The 2 modules are

combined into 1 module.


module.

Output relay 16

1)

2)

1)

Output relay 01

X18a02

c02

a32

c32Output relay 16

2)

Output relay 01

X19a02

c02

a32

c32Output relay 16

2)

X21

CAN bus cable connector

Connection

25

CSC-150

auxiliary case X7a02

c02

a04

c04

a06

c06

a08

c08a10

c10

a12

c12

a14

c14

a16

c16

a18c18

a20

c20

a22

c22

a24

c24a26

c26

a28

c28

a30

c30

a32

c32

X1a02

c02

a04

c04

a06

c06

a08

c08a10

c10

a12

c12

a14

c14

a16

c16

a18c18

a20

c20

a22

c22

a24

c24a26

c26

a28

c28

a30

c30

a32

c32

Output relay 01

Output relay 02

Output relay 03

Output relay 04

Output relay 05

Output relay 06

Output relay 07

Output relay 08

Output relay 09

Output relay 10

Output relay 11

Output relay 12

Output relay 13

Output relay 14

Output relay 15

Output relay 16

Note :


module.

2) The 2 modules are

combined into 1 module.


module.

1)

2)

X9a02

c02

a04

c04

a06

c06

a08

c08a10

c10

a12

c12

a14

c14

a16

c16

a18c18

a20

c20

a22

c22

a24

c24a26

c26

a28

c28

a30

c30

a32

c32

Output relay 01

Output relay 02

Output relay 03

Output relay 04

Output relay 05

Output relay 06

Output relay 07

Output relay 08

Output relay 09

Output relay 10

Output relay 11

Output relay 12

Output relay 13

Output relay 14

Output relay 15

Output relay 16

BI02

BI03

BI04

BI05

BI06

BI07

BI08BI09

BI01

BI10

BI11

BI12

BI13

BI14

BI15

BI16

BI17BI18

BI19

BI20

BI21

BI22

BI23

BI24BI25

BI26

BI27

BI28

BI29

BI30BI-COM1(-)

BI-COM2(-)

X2a02

c02

a32

c32

BI01

BI02

BI-COM1(-)

BI-COM2(-)

1)

X3a02

c02

a32

c32

BI01

BI02

BI-COM1(-)

BI-COM2(-)

1)

X4a02

c02

a32

c32

BI01

BI02

BI-COM1(-)

BI-COM2(-)

1)

X5a02

c02

a32

c32

BI01

BI02

BI-COM1(-)

BI-COM2(-)

1)

X6a02

c02

a32

c32

BI01

BI02

BI-COM1(-)

BI-COM2(-)

X10a02

c02

a32

c32

X8a02

c02

a32

c32

Output relay 16

Output relay 01

Output relay 16

Output relay 01

2)

3)

3)

Connection

26

CSC-150

auxiliary case

Output relay 01

Output relay 02

Output relay 03

Output relay 04

Output relay 05

Output relay 06

Output relay 07

X11a02

c02

a04

c04

a06

c06

a08

c08a10

c10

a12

c12

a14

c14a16

c16

a18c18

a20

c20

a22

c22

a24

c24a26

c26

a28

c28

a30

c30

a32

c32

Output relay 08

Output relay 09

Output relay 10

Output relay 11

Output relay 12

Output relay 13

Output relay 14

Output relay 15

Output relay 16

X12a02

c02

a04

c04

a06

c06

a08

c08a10

c10

a12

c12

a14

c14

a16

c16

a18c18

a20

c20

a22

c22

a24

c24a26

c26

a28

c28

a30

c30

a32

c32

DC 24V + output

Null

DC 24V - output


AUX DC + input


AUX DC - input

Null

Null

Null



Null

Null

Null

Null

X14

CAN bus cable connector

X13a02

BI02 c02

BI03 a04

BI04 c04

BI05 a06

BI06 c06

BI07 a08

BI08 c08

BI09 a10

BI01

BI10 c10

BI11 a12

BI12 c12

BI13 a14

BI14 c14

BI15 a16

BI16 c16

BI17 a18

BI18 c18

BI19 a20

BI20 c20

BI21 a22

BI22 c22

BI23 a24

BI24 c24

BI25 a26

BI26 c26

BI27 a28

BI28 c28

BI29 a30

BI30 c30

a32

c32BI-COM1(-)

BI-COM2(-)

Connection

27

B. Typical analogue inputs connection for single busbar with line side CTs arrangement

Busbar-A

CSC-

150

C. Typical analogue inputs connection for single busbar with bus side CTs arrangement

Busbar-A

CSC-

150

Connection

28

D. Typical analogue inputs connection for single busbar with tie disconnector (line side CTs) arrangement

Busbar-A

CSC-

150

Busbar-B

E. Typical analogue inputs connection for single busbar with tie disconnector (bus side CTs) arrangement

Busbar-A

CSC-

150

Busbar-B

Connection

29

F. Typical analogue inputs connection for single busbar with tie disconnector and one CT (line side CTs) arrangement

Busbar-A

CSC-

150

Busbar-B

G. Typical analogue inputs connection for two single busbars connected with bus coupler and one CT (line side CTs) arrangement

Busbar-A

CSC-

150

Busbar-B

Connection

30

H. Typical analogue inputs connection for two single busbars connected with bus coupler and one CT (bus side CTs) arrangement

Busbar-A

CSC-

150

Busbar-B

I. Typical analogue inputs connection for two single busbars connected with bus coupler and two CTs (line side CTs) arrangement

Busbar-A

CSC-

150

Busbar-B

Connection

31

J. Typical analogue inputs connection for two single busbars connected with bus coupler and two CTs (bus side CTs) arrangement

Busbar-A

CSC-

150

Busbar-B

K. Typical analogue inputs connection for one and half breaker arrangement

Busbar-B

Busbar-A

CSC-

150

Connection

32

L. Typical analogue inputs connection for double busbar with one coupler CT arrangement

Busbar-A

Busbar-B

CSC-

150

M. Typical analogue inputs connection for double busbar with two coupler CTs arrangement

Busbar-A

Busbar-B

CSC-

150

Connection

33

N. Typical analogue inputs connection for main and transfer busbar with two coupler CTs (inside CTs) arrangement

Busbar-A

Busbar-B

CSC-

150

O. Typical analogue inputs connection for main and transfer busbar with two coupler CTs (outside CTs) arrangement

Busbar-A

Busbar-B

CSC-

150

Connection

34

P. Typical analogue inputs connection for main and transfer busbar with one coupler CTs (inside CTs) arrangement

Busbar-A

Busbar-B

CSC-

150

Q. Typical analogue inputs connection for main and transfer busbar with one coupler CTs (outside CTs) arrangement

Busbar-A

Busbar-B

CSC-

150

Connection

35

R. Typical analogue inputs connection for main and transfer busbar without coupler CTs (outside CTs) arrangement

Busbar-A

Busbar-B

CSC-

150

S. Typical analogue inputs connection for main and main/transfer busbar with inside CTs arrangement

Busbar-A

Busbar-B

CSC-

150

Connection

36

T. Typical analogue inputs connection for main and main and/or transfer busbar with outside CTs arrangement

Busbar-A

Busbar-B

CSC-

150

U. Typical analogue inputs connection for double main and transfer busbar with inside CTs arrangement

Busbar-A

Busbar-B

Busbar-C

CSC-

150

Connection

37

V. Typical analogue inputs connection for double main and transfer busbar with outside CTs arrangement

Busbar-A

Busbar-B

Busbar-C

CSC-

150

Technical data

38

Frequency

Item Standard Data

Rated system frequency IEC 60255-1 50 Hz or 60Hz

Internal current transformer

Item Standard Data

Rated current Ir IEC 60255-1 1 or 5 A

Nominal current range 0.05 Ir to 30 Ir

Nominal current range of sensitive

CT

0.005 to 1 A

Power consumption (per phase) ≤ 0.1 VA at Ir = 1 A;

≤ 0.5 VA at Ir = 5 A

≤ 0.5 VA for sensitive CT

Thermal overload capability IEC 60255-1

IEC 60255-27

100 Ir for 1 s

4 Ir continuous

Internal voltage transformer

Item Standard Data

Rated voltage Vr (ph-ph) IEC 60255-1 100 V /110 V

Nominal range (ph-e) 0.4 V to 120 V

Power consumption at Vr = 110 V IEC 60255-27

DL/T 478-2001

≤ 0.1 VA per phase

Thermal overload capability

(phase-neutral voltage)

IEC 60255-27

DL/T 478-2001

2 Vr, for 10s

1.5 Vr, continuous

Auxiliary voltage

Item Standard Data

Rated auxiliary voltage Uaux IEC60255-1 110 to 250V DC

Permissible tolerance IEC60255-1 ±%20 Uaux

Power consumption at quiescent

state

IEC60255-1 ≤ 50 W per power supply module

Power consumption at maximum

load

IEC60255-1 ≤ 60 W per power supply module

Technical data

39

Inrush Current IEC60255-1 T ≤ 10 ms/I≤ 25 A per power supply

module,

Binary inputs

Item Standard Data

Input voltage range IEC60255-1 110/125 V DC

220/250 V DC

Threshold1: guarantee

operation

IEC60255-1 154V, for 220/250V DC

77V, for 110V/125V DC

Threshold2: uncertain operation IEC60255-1 132V, for 220/250V DC;

66V, for 110V/125V DC

Response time/reset time IEC60255-1 Software provides de-bounce

time

Power consumption, energized IEC60255-1 Max. 0.5 W/input, 110V DC

Max. 1 W/input, 220V DC

Binary outputs

Item Standard Data

Max. system voltage IEC60255-1 250V DC / AC

Current carrying capacity IEC60255-1 5 A continuous,

30A，200ms ON, 15s OFF

Making capacity IEC60255-1 1100 W(DC) at inductive load with

L/R>40 ms

1000 VA(AC)

Breaking capacity IEC60255-1 220V DC, 0.15A, at L/R≤40 ms

110V DC, 0.30A, at L/R≤40 ms

Mechanical endurance, Unloaded IEC60255-1 50,000,000 cycles (3 Hz switching

frequency)

Mechanical endurance, making IEC60255-1 ≥1000 cycles

Mechanical endurance, breaking IEC60255-1 ≥1000 cycles

Specification state verification IEC60255-1

IEC60255-23

IEC61810-1

UL/CSA、TŰV

Technical data

40

Contact circuit resistance

measurement

IEC60255-1

IEC60255-23

IEC61810-1

30mΩ

Open Contact insulation test (AC

Dielectric strength)

IEC60255-1

IEC60255-27

AC1000V 1min

Maximum temperature of parts and

materials

IEC60255-1 55℃


Item Data

Number 1

Connection Isolated, RS232; front panel,

9-pin subminiature connector, for software tools

Communication speed 9600 baud

Max. length of communication cable 15 m

RS485 communication port

Item Data

Number 0 to 2

Connection 2-wire connector

Rear port in communication module

Max. length of communication cable 1.0 km

Test voltage 500 V AC against earth

For IEC 60870-5-103 protocol

Communication speed Factory setting 9600 baud,

Min. 1200 baud, Max. 19200 baud

Ethernet communication port

Item Data

Electrical communication port

Number 0 to 3

Connection RJ45 connector


Max. length of communication cable 100m

For IEC 61850 protocol

Technical data

41

Communication speed 100 Mbit/s

For IEC 60870-5-103 protocol


Optical communication port ( optional )

Number 0 to 2

Connection SC connector


Optical cable type Multi-mode

Max. length of communication cable 2.0km

IEC 61850 protocol


IEC 60870-5-103 protocol


Time synchronization

Item Data

Mode Pulse mode

IRIG-B signal format IRIG-B000

Connection 2-wire connector


Voltage levels differential input

Environmental influence

Item Data

Recommended permanent operating temperature -10 °C to +55°C

(Legibility of display may be impaired above

+55 °C /+131 °F)

Storage and transport temperature limit -25°C to +70°C

Permissible humidity 95 % of relative humidity

IED design

Item Data

Case size 8U×19inch, Main case

4U×19inch, Auxiliary case

Weight ≤ 16kg, Main case

≤ 5kg,, Auxiliary case

Technical Data

42

Product safety-related Tests

Item Standard Data

Over voltage category IEC60255-27 Category III

Pollution degree IEC60255-27 Degree 2

Insulation IEC60255-27 Basic insulation

Degree of protection (IP) IEC60255-27

IEC 60529

Front plate: IP40

Rear, side, top and bottom: IP 30

Power frequency high voltage

withstand test

IEC 60255-5

EN 60255-5

ANSI C37.90

GB/T 15145-2001

DL/T 478-2001

2KV, 50Hz

2.8kV

between the following circuits:

auxiliary power supply

CT / VT inputs

binary inputs

binary outputs

case earth

500V, 50Hz

between the following circuits:

Communication ports to case

earth

time synchronization terminals

to case earth

Impulse voltage test IEC60255-5

IEC 60255-27

EN 60255-5

ANSI C37.90

GB/T 15145-2001

DL/T 478-2001

5kV (1.2/50μs, 0.5J)

If Ui≥63V

1kV if Ui<63V

Tested between the following

circuits:


CT / VT inputs

binary inputs

binary outputs

case earth

Note: Ui: Rated voltage

Insulation resistance IEC60255-5

IEC 60255-27

EN 60255-5

ANSI C37.90

GB/T 15145-2001

DL/T 478-2001

≥ 100 MΩ at 500 V

Technical Data

43

Protective bonding resistance IEC60255-27 ≤ 0.1Ω

Fire withstand/flammability IEC60255-27 Class V2

Electromagnetic immunity tests

Item Standard Data

1 MHz burst immunity test IEC60255-22-1

IEC60255-26

IEC61000-4-18

EN 60255-22-1

ANSI/IEEE C37.90.1

Class III

2.5 kV CM ; 1 kV DM

Tested on the following circuits:


CT / VT inputs

binary inputs

binary outputs

1 kV CM ; 0 kV DM


communication ports

Electrostatic discharge IEC 60255-22-2

IEC 61000-4-2

EN 60255-22-2

Level 4

8 kV contact discharge;

15 kV air gap discharge;

both polarities; 150 pF; Ri = 330 Ω

Radiated electromagnetic field

disturbance test

IEC 60255-22-3

EN 60255-22-3

Frequency sweep:

80 MHz – 1 GHz; 1.4 GHz – 2.7 GHz

spot frequencies:

80 MHz; 160 MHz; 380 MHz; 450

MHz; 900 MHz; 1850 MHz; 2150

MHz

10 V/m

AM, 80%, 1 kHz

Radiated electromagnetic field

disturbance test

IEC 60255-22-3

EN 60255-22-3

Pulse-modulated

10 V/m, 900 MHz; repetition rate

200 Hz, on duration 50 %

Electric fast transient/burst immunity

test

IEC 60255-22-4,

IEC 61000-4-4

EN 60255-22-4

ANSI/IEEE C37.90.1

Class A, 4KV



CT / VT inputs

binary inputs

binary outputs

Class A, 1KV


Technical Data

44

communication ports

Surge immunity test IEC 60255-22-5

IEC 61000-4-5

4.0kV L-E

2.0kV L-L



CT / VT inputs

binary inputs

binary outputs

500V L-E


communication ports

Conduct immunity test IEC 60255-22-6

IEC 61000-4-6

Frequency sweep: 150 kHz – 80

MHz

spot frequencies: 27 MHz and 68

MHz

10 V

AM, 80%, 1 kHz

Power frequency immunity test IEC60255-22-7 Class A

300 V CM

150 V DM

Power frequency magnetic field test IEC 61000-4-8 Level 4

30 A/m cont. / 300 A/m 1 s to 3 s

100 kHz burst immunity test IEC61000-4-18 2.5 kV CM ; 1 kV DM



CT / VT inputs

binary inputs

binary outputs

1 kV CM ; 0 kV DM


communication ports

DC voltage interruption test

Item Standard Data

DC voltage dips IEC 60255-11 100% reduction 20 ms

60% reduction 200 ms

30% reduction 500 ms

Technical Data

45

DC voltage interruptions IEC 60255-11 100% reduction 5 s

DC voltage ripple IEC 60255-11 15%, twice rated frequency

DC voltage gradual shut–down

/start-up

IEC 60255-11 60 s shut down ramp

5 min power off

60 s start-up ramp

DC voltage reverse polarity IEC 60255-11 1 min

Electromagnetic emission test

Item Standard Data

Radiated emission IEC60255-25

EN60255-25

CISPR22

30MHz to 1GHz ( IT device may up

to 5 GHz)

Conducted emission IEC60255-25

EN60255-25

CISPR22

0.15MHz to 30MHz

Mechanical tests

Item Standard Data

Sinusoidal Vibration response

test

IEC60255-21-1

EN 60255-21-1

Class 1

10 Hz to 60 Hz: 0.075 mm

60 Hz to 150 Hz: 1 g

1 sweep cycle in each axis

Relay energized

Sinusoidal Vibration endurance

test

IEC60255-21-1

EN 60255-21-1

Class 1

10 Hz to 150 Hz: 1 g

20 sweep cycle in each axis

Relay non-energized

Shock response test IEC60255-21-2

EN 60255-21-2

Class 1

5 g, 11 ms duration

3 shocks in both directions of 3 axes

Relay energized

Shock withstand test IEC60255-21-2

EN 60255-21-2

Class 1

15 g, 11 ms duration

3 shocks in both directions of 3 axes

Relay non-energized

Bump test IEC60255-21-2 Class 1

Technical Data

46

10 g, 16 ms duration

1000 shocks in both directions of 3

axes

Relay non-energized

Seismic test IEC60255-21-3 Class 1

X-axis 1 Hz to 8/9 Hz: 7.5 mm

X-axis 8/9 Hz to 35 Hz :2 g

Y-axis 1 Hz to 8/9 Hz: 3.75 mm

Y-axis 8/9 Hz to 35 Hz :1 g

1 sweep cycle in each axis,

Relay energized

Climatic tests

Item Standard Data

Cold test - Operation IEC60255-27

IEC60068-2-1

-10°C, 16 hours, rated load

Cold test – Storage IEC60255-27 IEC60068-2-1 -25°C, 16 hours

Dry heat test – Operation [IEC60255-27

IEC60068-2-2

+55°C, 16 hours, rated load

Dry heat test – Storage IEC60255-27

IEC60068-2-2

+70°C, 16 hours

Change of temperature IEC60255-27

IEC60068-2-14

Test Nb, figure 2, 5 cycles

-10°C / +55°C

Damp heat static test IEC60255-27

IEC60068-2-78

+40°C, 93% r.h. 10 days, rated load

Damp heat cyclic test IEC60255-27

IEC60068-2-30

+55°C, 93% r.h. 6 cycles, rated load

CE Certificate

Item Data

EMC Directive EN 61000-6-2 and EN61000-6-4 (EMC Council

Directive 2004/108/EC)

Low voltage directive EN 60255-27 (Low-voltage directive 2006/95 EC).

Technical Data

47

Functions

NOTE: Ir: CT rated secondary current, 1A or 5A;

Busbar differential protection (ANSI 87BB)

Item Rang or Value Tolerance

Differential Current 0.4 Ir to 20.00 Ir ≤ ±5% setting or ±0.02Ir

Stabilization factor 0.3 - 0.99

Differential current reset threshold 0.1 Ir

Operating time < 15ms typically at 200%

setting

Reset time < 50ms

Breaker failure protection (ANSI 50 BF)


phase current

Negative sequence current

zero sequence current

0.08 Ir to 20.00 Ir ≤ ±3% setting or ±0.02Ir

Time delay of stage 1 0.00s to 32.00 s, step 0.01s ≤ ±1% setting or +25 ms, at

200% operating setting Time delay of stage 2 0.00s to 32.00 s, step 0.01s

Reset time of stage 1 < 20ms

Dead zone protection (ANSI 50DZ)


Current 0.08 Ir to 20.00 Ir ≤ ±3% setting or ±0.02Ir

Time delay 0.00s to 32.00s, step 0.01s ≤ ±1% setting or +40 ms, at

200% operating setting

VT secondary circuit supervision (97FF)

Item Range or value Tolerances

Minimum current 0.08Ir to 0.20Ir, step 0.01A ≤ ±3% setting or ±0.02Ir

Minimum zero or negative

sequence current

0.08Ir to 0.20Ir, step 0.01A ≤ ±5% setting or ±0.02Ir

Maximum phase to earth voltage 7.0V to 20.0V, step 0.01V ≤ ±3% setting or ±1 V

Technical Data

48

Maximum phase to phase

voltage

10.0V to 30.0V, step 0.01V ≤ ±3% setting or ±1 V

Normal phase to earth voltage 40.0V to 65.0V, step 0.01V ≤ ±3% setting or ±1 V

Ordering

49

Pre-configure scheme

Table 5 Functions and hardware of the pre-configure schemes for transmission network

Pre-configure scheme M01 M02 M03 M04 M05 M06 M07 M08

Station arrangement (N1)

D or

E or

H

A or

B or

C

F G D or

E or

H

A or

B or

C

F G

Voltage level (kV) ≥

230

≥

230

≤

230

≥

230

≥

230

≥

230

≥

230

≥

230

Number of bay

8F+1

C or

1T

8F+1

C

8F+1

C+1

T

8F+1

C/1T

16F+

1C or

1T

16F

+1C

16F+

1C+1

T

16F+

1C/1

T

Busbar differential protection (87BB) 1 1 1 1 1 1 1 1

Breaker failure protection (50BF) 1 1 1 1 1 1 1 1

Dead-zone protection (50DZ) 1 1 1 1 1 1 1 1

CT secondary circuit supervision 1 1 1 1 1 1 1 1

VT secondary circuit supervision

(97FF) (1) (1) (1) (1) (1) (1) (1) (1)

Analogue input module (10I ) 3 3 3 3 6 6 6 6

Analogue input module (2I+ 9U) (1) (1) (1) (1) (1) (1) (1) (1)

CPU modules 2 2 2 2 2 2 2 2

Communication module(with Ethernet

interfaces, RS485 interfaces and time

synchronizing interface)

1 1 1 1 1 1 1 1

Binary input module (30 BI) 4 4 5 5 8 8 8 8

Binary output modules (16 relays for

tripping and initiation) 1 1 1 1 2 2 2 2


tripping and initiation) 2 2 2 2 4 4 4 4


signal) 1 1 1 1 1 1 1 1

Power supply module 3 3 1 3 3 3 3 3

Programmable LEDs 18 18 18 18 18 18 18 18

Case, 8U,19” 1 1 1 1 1 1 1 1

Case, 4U,19” 1 1 1 1 1 1 1 1

Ordering

50

NOTE:

n : Quantity of standard function or standard hardware, n= 1, 2, ….;

(n) : Quantity of optional function or optional hardware, n= 1, 2, ….;

N1: Station arrangement:

A – Single Busbar

B – Two Single Busbars connected with Coupler

C – Two Separate Busbars in 1

CB arrangement

D – Double Busbar

E – Main and Transfer Busbar

F – Double Main and one Transfer Busbar with line side CT

G – Main and Main/Transfer Busbar

H – Double Main and one Transfer Busbar with bus side CT

Ordering

51

Table 6 Functions and hardware of the pre-configure schemes for sub-transmission and distribution

network

Pre-configure scheme M09 M10

Station arrangement (N1)

A, B or C A, B or C

Voltage level (kV) ≤ 132 ≤ 132

Number of bay 8F+1C 16F+1C

Busbar differential protection (87BB) 1 1

Breaker failure protection (50BF) 1 1

Dead-zone protection (50DZ) 1 1

CT secondary circuit supervision 1 1

VT secondary circuit supervision (97FF) (1) (1)

Analogue input module (10I ) 3 6

Analogue input module (2I+ 9U) 1 1

CPU modules 2 2

Communication module(with Ethernet interfaces, RS485

interfaces and time synchronizing interface) 1 1

Binary input module (30 BI) 3 5

Binary output modules (16 relays for tripping and initiation) 1 2

Binary output modules (32 relays for tripping and initiation) 1 2

Binary output modules (16 relays for signal) 1 1

Power supply module 3 3

Programmable LEDs 18 18

Case, 8U,19” 1 1

Case, 4U,19” 1 1

Ordering

52

NOTE:

n : Quantity of standard function or standard hardware, n= 1, 2, ….;

(n) : Quantity of optional function or optional hardware, n= 1, 2, ….;

N1: Station arrangement:

A – Single Busbar

B – Two Single Busbars connected with Coupler

C – Two Separate Busbars in 1

CB arrangement

D – Double Busbar

E – Main and Transfer Busbar

F – Double Main and one Transfer Busbar with line side CT

G – Main and Main/Transfer Busbar

H – Double Main and one Transfer Busbar with bus side CT

Ordering

53

Ordering code

A. Main case

C

Pre-configure SchemeM;N

0~9

0~9

No.1~16 No.17~45

S 1 5 -C 0

Ethernet interface:IEC61850-8; RS485 interface: IEC60870-5-103

Station Communication Protocols (T)

HMI Language (L) note

English

French

Russian

Spanish

Portuguese

Rated Frequency (F)

1

2

3

4

5

50 Hz 5

660 Hz

Ethernet interface:IEC60870-5-103; RS485 interface: IEC60870-5-103

FL T

1

2

Note: Chinese is always offered as default HMI language.

Ordering

54

No.17~25

Analogue Input Module (A)

110I (1A)

10I (5A) 2

Null

No.26~45

10I (1A)

10I (5A)

C S 1 5C 0 -

Slot 1

Slot 2

No.1~16

A

1

2

x

Null

10I (1A)

10I (5A)

Slot 3

1

2

x

Null

10I (1A)

10I (5A)

Slot 41

2

x

Null

10I (1A)

10I (5A)

Slot 5 1

2

x

Null

10I (1A)

10I (5A)

Slot 6 1

2

x

Null

Slot 7x

Null

2I (1A)+9U

2I (5A)+9U

Slot 8

f

x

g

Ordering

55

No.26~37

Communication module (C)

No.1~25

2 electrical Ethernet ports, 2 RS485 ports, IRIG-B

1

2 electrical Ethernet ports, 2 RS485 ports, Pulse

2 optical Ethernet ports, 2 RS485 ports, IRIG-B

2 optical Ethernet ports, 2 RS485 ports, Pulse

3 electrical Ethernet ports, 1 RS485 ports, IRIG-B

3 electrical Ethernet ports, 1 RS485 ports, Pulse 2

3

4

5

6

Slot 13

No.38~45

C S 1 5 -C 0

CPU Module 1 (M)

1Dedicated to CSC-150

Slot 9

M

CPU Module 2 (M)

1Dedicated to CSC-150

Slot 10

C

Binary Output Module (O)16 relays for tripping

Binary Input Module (I)

130BI (220V DC), with startup blocking relay

30BI (110V DC), with startup blocking relay 2

Slot 11

Slot 12

1

100V - 250V DC

Power Supply Module (P)

1

Slot 14

100V - 250V DC


1

Slot 15

POI

Ordering

56

No.38~45No.1~37

C S 1 5 -C 0

Slot 16 & 17Binary Output Module (O)

32 relays for tripping 2

O

Slot 18 & 1932 relays for tripping 2

Slot 2016 relays for tripping 1

K

Null x

Case and Front Plate (K)

Case: 8U, 19';

Front plate: Medium size LCD; 20 LEDs 1

Accessories

Cable for communication between main case and auxiliary case 1

Null x

Z

Ordering

57

B. Auxiliary case

No.10~16No.1~9

C S 1 5 -C 0


130BI (220V DC), with startup blocking relay

30BI (110V DC), with startup blocking relay 2

Slot 1

I

330BI (220V DC)

30BI (110V DC) 4

Slot 2

330BI (220V DC)

30BI (110V DC) 4

Slot 3

Null x

30BI (220V DC)

30BI (110V DC)

Slot 4

Null

30BI (220V DC)

30BI (110V DC)

Slot 5

Null

30BI (220V DC)

30BI (110V DC)

Slot 6

Null

No.17~28

3

4

x

3

4

x

3

4

x

Q A

Ordering

58

No.17~28No.1~16

C S 1 5 -C 0

Slot 7 & 8

Binary Output Module (O)

32 relays for tripping 2

O

Slot 9 & 1032 relays for tripping 2

Slot 11


330BI (220V DC)

30BI (110V DC) 4

Slot 13

P

Null x

Null x

Case and Front Plate (K)

Case: 4U, 19';

Front plate: Without LCD and LED

100V - 250V DC


1

Slot 12

16 relays (with 19 contacts) for signalling 3

I K

2

Q A Z

Accessories (Z)

Null x

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