Smart Grid Instruction manual rev. November 2014
Transcript of Smart Grid Instruction manual rev. November 2014
SafeRing and SafePlus 12/24kV - Ring Main Unit and Compact Switchgear for Smart GridInstruction manual
1VDD006176 GB
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CONTENTS
I. Introduction 3II. Power supply 4III. Remote and local communication 4IV. Packages 6 A. Options description 1. Automation level 6 2. Feeder automation device 7 3. MV network fault types 7 4. Fault passage indicators 8 5. Fault passage indicators remote reset 9 6. Distribution transformer feeders’ common remote emergency trip 9 7. Supervision on the LV side of the distribution transformer 9V. Maintenance 9 1. Battery life 9 2. Environmental 9 3. End of life 9VI. Appendixes A. Appendix 1: Packages differentiations 10 B. Appendix 2: Installation instructions 12 C. Appendix 3: On site setting instructions of feeder automation devices 14 D. Appendix 4: IEC 60870-5-104 Signal addresses 15
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I. Introduction Safering and SafePlus for Smart Grid (SG) is a 12-24 kV Medium Voltage (MV) Ring Main Unit (RMU)/Switchgear (SWGR) equipped with advanced Feeder Automation (FA) device, which in cooperation with additional devices (e.g. Fault Passage Indicators (FPI)) provides various data to the remote control centers. Key functions of all packages are described in next chapters of this document. There are seven different selections which give the end users possibility to adjust the pack-age to fit their requirements.
The purpose of this document is to describe RMU/SWGR for SG product.
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II. Power supply To prevent any risk of harm, ensure the main supply is disconnected before carrying out any work on the RMU.
All secondary devices within the RMU (except LV multi- meters) are powered by a 24V DC battery. The battery is charged by its charger, which needs external power supply:
− 90...264 VAC 50/60 Hz or 85...200V DC in case of FA device REC603 (internal battery charger) is used
− 94...132V AC or 184...264 VAC 50/60 Hz in case of FA device RTU560CIG10 or REC615 (external battery charger) is used
Please contact us in case you need other main power supply option.
Ensure that the main supply is correctly wired before energi-sing the system. After connecting the main supply, the system can be energised by closing the MCBs located in the lower low voltage compartment. More details regarding power supply connection can be found in Appendix 2.
III. Remote and local communication A. Remote communication (communication to the remote control center): Default delivery (standard package solution) comes with IEC 60870-5-104 remote communication protocol implemen- tation. The communication media is either wired Ethernet and/or wireless (GSM/GPRS) communication.
Please contact us in case you need other remote communi-cation protocol option.
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B. M2M-based communication solutionThe core of the secure and reliable communication solution is the M2M gateway, which is an industrial quality server with pre-installed management software for secure communication between a central location and remote sites. There are mul-tiple encryption protocols supported, for example, open VPN and SSH for data security and system integration for central monitoring systems. For security reasons, there is also an internal firewall for monitoring IP traffic and blocking unwanted connections.
Operator-independent solutionThe M2M gateway provides a fixed IP address for all remo-te devices. This means that the IP address on the wireless controller, for example, REC601 or REC603, does not need to be fixed. With this solution, all remote devices have a fixed IP address at all times, even if the address provided by the mobi-le operator is dynamic. The great advantage with this set-up is that you can use the standard, inexpensive SIM cards, as the remote devices do not require that the specific and costly SIM cards, equipped with private APN functionality, are to be used. This also provides you with the flexibility to select the best operator for each remote site.
Viola Patrol to monitor and manage remote devicesViola Patrol is an application within the M2M gateway soluti-on, for those remote devices where the Viola Patrol client has been installed. Viola Patrol offers a graphical user interface for monitoring and controlling the remote devices. The Patrol can be used to quickly and easily see the connection quality or locate faults. Additionally, longer-term actions can be view-ed through the metrics gathered and presented in graphical tables and charts. In brief, it indicates quickly if all connections are working and are secure. No installation is required, as the Patrol is pre-installed in the M2M gateway and used with a web browser.
C. Local communication (communication between different automation devices within the RMU): The signals from the RMU switches, FPIs and LV multi-me-ters are brought to the FA device by two different ways:
− digital signals (e.g. switch positions indication and control) are hardwired
− analog signals (e.g. measurements from the FPIs and LV multi-meters) are obtained over local communication bus which can be serial Modbus RTU or serial IEC 60870-5-101 communication protocol. Modbus RTU is used within Measurement package for communication between RTU560CIG10 (via it’s CPA port) or REC603 (via it‘s RS2 port) and FPIs; IEC 60870-5-101 is used for communica-tion between LV multi-meters and REC603 FA device (via its RS1/RS2 ports).
Solution example with M2M Gateway and REC601/REC603 wireless controller
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IV. Packages All standard packages always include:
− Power supply backup source for automation devices (24V DC batteries and charger)
− Wire (Ethernet) and/or wireless (GSM/GPRS) communi-cation interfaces (SIM card is not part of delivery)
− IEC 60870-5-104 host (slave) communication protocol
Three levels of automation are defined. There are additional options which can be selected for each package.
Main selections and their options are: (*) default values)1. Automation level
− Remote Monitoring package − Remote Control package *)
− Remote Measurement package
2. Feeder automation device − REC603 *)
− RTU560CIG10 − GPRS communication/modem:
− None *)
− RER601 − 560MDD10
− REC615 − GPRS communication/modem:
− None *)
− RER601
3. MV network fault types − OC and EF directional − OC and EF non directional *)
− Fault
4. Fault passage indicators − Kries - IKI-50_1F (directional) − Horstmann - ComPass B (directional) − Kries - IKI-20U2 *)
− Horstmann - SIGMA F+E (AC/DC) − REC615 IED inbuilt − REC615 IED inbuilt + 1 RIO600 SIM8F − REC615 IED inbuilt + 2 RIO600 SIM8F
5. Fault passage indicators remote reset − No − Yes *)
6. Distribution transformer feeders common remote emergency trip
− No − Yes *)
7. Supervision of the LV side of the distribution transformer − None *)
− Vamp: WIMO 6CP10 − Circutor: CVM-MINI-ITF-RS485-C2
A. Options description 1. Automation level Three automation levels (packages) are defined. See also Appendix 1: Packages differentiations.
− Remote Monitoring This package provides remote monitoring of the:
− RMU’s / SWGR’s primary switching devices positions ( -> grid topology supervision)
− FPI fault signalization (-> fast fault localization, reduced outage time, efficient use of manpower)
− Faults in transformer feeders
− Remote Control This package includes the features from the Remote
Monitoring package and in addition provides: − Remote control of RMU’s / SWGR’s primary switching
devices (-> fast fault isolation, fast restoration of healthy part of the MV network , operator safety)
− Remote operation is enabled by turning the Local / Remo-te selector switch on the front of the RMU to the Remote mode. Remote operation is disabled and power to the motor drive circuit via controller is disconnected in Local mode
− Local manual operation is enabled in both modes using the operating handle supplied. Local motor operation is enabled in Local mode by close (“I”) / open (“O”) push buttons. Local operation can be disabled by use of pad-locks
− Remote Measurement This package includes the features from the Remote
Control package and in addition provides: − MV network analog data values such as: currents, volta-
ges, frequency, power, energy, load flow direction etc. (-> improved notification of overloaded equipment, better maintenance planning, improved power quality). See Appendix 4 for more details.
Note: There are spare inputs which can be used for addi-tional customer specific „digital/binary” signals such as: SF6 gas pressure low signal, LV fuses tripped signal, trans-former overheating signal etc. The number of spare inputs depends on the configuration of the RMU / SWGR and on the type of fault detection for the MV network. See Appendix 1 for more details.
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2. Feeder automation device Compact FA devices secure remote monitoring and control of the secondary substations in the distribution networks. It enables the network control centers to monitor and control the field devices over the different communication infra- structure.
− REC603 The Wireless Controller REC603 is a compact, solution
based device for the remote control and monitoring of secondary substations such as network disconnectors, load break switches and Ring Main Units (RMUs) in distribution networks. REC603 enables the network control system to monitor and control the field devices over the public communication infrastructure (GPRS). The Wireless Controller REC603 utilizes the built-in GPRS for reliable and secure end-to-end communication providing remote monitoring and control of up to three objects.
Link to abb.com
− RTU560CIG10 The RTU560 DIN rail provides advanced functionality and
makes it the perfect fit for current and future smart grid applications. The compact housing with the possibility to integrate hardwired information fulfills complex require-ments and space restrictions at the same time.
Algorithms, switching sequences and logics can be implemented as logic building blocks. Libraries are used to make these building blocks available throughout the product family. Another enabler for Smart Grid is seen in the use of open standard protocols.
Those standard protocols in combination with wireless communication and PLC capabilities are able to provide fault detection isolation and restoration functionality.
Maintenance and service costs are kept low since RTU560 DIN rail solution is remotely configurable and maintainable. The high product quality and user-friendly service capability reduces life cycle costs.
Note: RTU560CIG10 doesn’t provide by default GPRS communication availability, thus it is possible to select from two compatible modems (RER601 and 560MDD10) in RTU560CIG10 subselection.
Link to abb.com
− REC615 REC615 is a dedicated grid automation IED designed for remote control and monitoring, protection, fault indication, power quality analyzing and automation in medium-voltage secondary distribution systems, including networks with distributed power generation, with secondary equipment such as medium-voltage disconnectors, switches and ring-main units.
With REC615, grid reliability can be enhanced, ranging from basic, non-directional overload signalisation to exten-ded protection functionality with power quality analyses. Thus, REC615 meets today’s requirements for smart grids and supports the protection of overhead line and cable fee-ders in isolated neutral, resistance-earthed, compensated and solidly earthed networks.
REC615 is intended for applications where multiple objects are controlled, based on sensor technology. REC615 provides superior fault location, isolation and restoration (FLIR) to lower the frequency and shorten the duration of faults (SAIFI/SAIDI). REC615 is a member of ABB’s Relion® product family and a part of its 615 protection and control product series.
Note: REC615 doesn’t provide by default GPRS commu-nication availability, thus it is possible to select RER601 in REC615 subselection.
Link to abb.com
Note: The availability depends on selected Automation level and selected Feeder automation device.
3. MV network fault types Different signals from FPIs can be transmitted to the control centers. These are selected also based on type of the MV network (isolated neutral, compensated neutral, high resis-tance earthing, low resistance earthing or solidly earthing).
Available options are: − OC and EF directional
With this selection two different types of events can be transferred to the remote control centers:
− Fault in forward direction (does not differentiate over- current and earth fault)
− Fault in backward direction (does not differentiate over- current and earth fault)
− OC and EF non directional With this selection two different types of events can be
transferred to the remote control centers: − Over-current fault (does not differentiate fault direction) − Earth fault (does not differentiate fault direction)
− Fault With this selection one type of event can be transferred to
the remote control centers: − Fault (does not differentiate over-current and earth fault nor
fault direction)
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4. Fault passage indicators FPI are devices which detect faults in the MV network and some of them are also able to provide MV analog values measurements to the FA device which then further transfers these signals to the control centers.
Available options are: − Kries - IKI-50_1F
The Grid-Inspector IKI-50 offers a directed error detection (short-circuit and earth fault) and a directed power flow measurement of all important measurement values and their derived values for power grids with local feeding. The loading, overload and errors of power grids can be monitored hereby. The Grid-Inspector is also able to selective disconnect a faulted cable section and allows to reduce the reclosing time after an error. Modbus and/or digital in- and outputs can transmit the data to any remote control substation.
− Horstmann - ComPass B The ComPass B is used in medium-voltage distribution
networks and combines the functions of a directional short-circuit and earth fault indicator. It has been developed and designed
− to detect short-circuits and earth faults − to indicate and remotely signal the fault and load flow
direction (A or B) − to measure, indicate and remotely signal load current,
voltage, power, cos phi and frequency of medium-voltage networks
The ComPass B is designed for operation in radial, ring and mesh networks. It can be used in solidly earthed, low- impedance, resonant earthed or isolated neutral systems.
− Kries - IKI-20U2 The combined short-circuit/earth-fault indicator IKI-20
is used for over current detection, indication and remote monitoring in distribution networks 1-52 kV. By connecting a summation split core transformer it is also possible to detect earth faults. The IKI-20 is mainly powered through the split core transformers.
− Horstmann - SIGMA F+E (AC/DC)
The SIGMA F+E (AC/DC) device is a combined earth fault and short-circuit indicator. It is used as remote indicator and serves to detect and display earth faults and short-circuit currents in medium voltage distribution networks. It consists of a display unit accommodated in a plug-in housing for panel mounting and two current transformers for short-circuit and one current transformer for the earth fault sensing which are connected to the device by means of measuring leads. The SIGMA F+E (AC/DC) short-circuit and earth fault indicator is not only capable of being operated in radial or open ring networks, but it can also be used in double fed ring networks either with automatic or manual re-closure feature. Owing to its measuring principle, the earth fault indication is suitable for distri- bution networks with low-impedance or solidly earthed neutral.
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− REC615 IED inbuilt / REC615 IED inbuilt + 1 (2) RIO600 SIM8F REC615 comes pre-configured in a way that three setting groups are defined and different protection functions are used to
detect different types of the network faults. So it is enough to activate corresponding setting group via REC615 menu.
REC615 protection functions setting Network type and corresponding pre-configured Setting Group (SG)
Used for detection of Function block Insulated (SG1) (default group) Compensated (SG2) Solidly earthed (SG3)
Earth Fault (EF) EFIPTOC1 Blocked Blocked In use; 1,59 x In
EF in Forward direction DEFLPDEF1 In use; 0,016 x In;
Char. angle: -90 deg.
In use; 0,016 x In;
Char. angle: 0 deg.
Blocked
EF in Backward direction DEFLPDEF2 In use; 0,016 x In;
Char. angle: -90 deg.
In use; 0,016 x In;
Char. angle: 0 deg.
Blocked
Over Current (OC) PHIPTOC1 In use; 1,59 x In In use; 1,59 x In In use; 1,59 x In
OC in Forward direction DPHLPDOC1 In use; 1,59 x In In use; 1,59 x In In use; 1,59 x In
OC in Backward direction DPHLPDOC2 In use; 1,59 x In In use; 1,59 x In In use; 1,59 x In
Nevertheless application-specific parameters (fault current levels, detection times, etc.) must be adjusted at site.
REC615 uses for current detection bushing sensors, thus for protection functions these values are valid: Earth nominal current: 630 A (calculated from 3 phase current sensors)Phase nominal current: 630 A0,016 x In then means 10 A primary value1,59 x In then means 1000 A primary value
Note: None of these protection functions will trip load break switch within SafeRing RMU. Faults are only signalized by the local alarm LEDs and are also transferred via communication to the control room.
Note: The availability depends on selected Automation level and MV network fault types.
RIO600 offers Fault Passage Indication (FPI) functionality. RIO600 enables accurate current and voltage measurements from the medium-voltage network utilizing ABB‘s light weight sensor technology. Based on the measured values, RIO600 gives directional fault passage indication and reports it to the upper level system. RIO600 also enables power flow and power quality monitoring.
RIO600 SIM8F modules come also pre-configured, but only one setting group is available here. By default setting, directional protection functions (earth fault and overcurrent) are set to detect faults in the forward
direction (“Directional mode” setting is set to “Forward”) and directional earth fault is tuned for insulated network (“Characteristics angle” setting is set to -90°).
Should these be changed, then PCM600 software must be used and corresponding parameters adjusted.
RIO600_SIM8F protection functions setting Network type and corresponding pre-configured setting
Used for detection of Function block Insulated (default setting) Compensated Solidly earthed (SG3)
Earth Fault (EF) detection EFPTOC Not in use Not in use In use; 1000 A
EF direction detection * DEFPTOC In use; 10 A;
Char. angle: -90 deg.
In use; 10 A;
Char. angle: 0 deg.
Not in use
Over Current (OC) detection PHPTOC In use; 1000 A In use; 1000 A In use; 1000 A
OC direction detection ** DPHPTOC In use; 1000 A In use; 1000 A In use; 1000 A
* „Directional mode“ (Forward / Reverse) and “Characteristic angle” settings must be adjusted based on the direction and network type in which should the module detect earth faults** „Directional mode“ (Forward / Reverse) setting must be adjusted based on the direction in which should the module detect overcurrent faults
Note: None of these protection functions will trip load break switch within SafeRing RMU. Faults are only signalized by the local alarm LEDs and are also transferred via communication to the control room.
Note: The availability depends on selected Automation level and MV network fault types.
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V. Maintenance:RMU for Smart Grid has been designed to minimize service intervals when operated in normal service conditions as speci-fied in IEC 62271-1.
It is recommended that any maintenance on RMU for Smart Grid should be carried out in accordance with IEC 62271-1, Section 11. Following the maintenance requirements below will help ensure continued operation throughout the life ex-pectancy of the system.
1. Battery life: Life time of batteries installed in RMU is 12 years at 20°C ambient temperature.
2. Environmental: RMU for Smart Grid is designed to operate between -25°C and +40°C.
Exception: The lowest operating temperature for LV multi meter CVM-MINI is -10°C.
RMU for Smart Grid installed in abnormal conditions will require regular inspection and maintenance depending on the nature of the environment.
3. End of life ABB PPMV NO, Power Products Medium Voltage Division, is committed to the protection of the environment and adheres to ISO 14001 standards.
Disposing of the IED: Definitions and regulations of hazardous materials are country-specific and change when the knowledge of materials increases. The materials used in this product are typical for electric and electronic devices. All parts used in this product are recyclable. When disposing of an IED or its parts contact a local waste handler who is authorized and specialized in disposing electronic waste. These handlers can sort the material by using dedicated sorting processes and dispose of the product according to the local requirements.
5. Fault passage indicators remote reset − No
The FPI signalization will be reset according to its setting (e.g. manually, automatically after fixed set time).
− Yes This option gives possibility to reset (fault indication)
FPIs remotely from the control centers.
Note: There is 1 common reset command for all FPIs in case of REC603 FA device – all FPIs within the RMU / SWGR will be reset at the same time.
6. Distribution transformer feeders’ common remote emergency trip
− No No possibility to remotely trip distribution transformers mo-
dules.
− Yes This option gives possibility to remotely trip distribution
transformers modules (usually F and/or V modules) from the control centers.
Note: There is 1 common trip command for all distribution transformers modules in case SafeRing RMU or in case of SafePlus SWGR and REC603 FA device – all modules will be tripped at the same time.
7. Supervision of the LV side of the distribution transformer This option gives possibility to remotely supervise secondary (Low Voltage) side of the distribution transformer. Different multi-function monitoring devices with extensive measuring and calculation functions will be available in this selection. The unit measures currents, voltages and frequencies, and calculates power and energy values. Interconnection cable between FA device and LV multi-meters is not part of delivery if the LV multi-meter is mounted outside the RMU.
− None No possibility to remotely supervise LV network analog
data.
− Vamp: WIMO 6CP10 WIMO 6CP10 secondary substation measuring and monito-
ring unit is a compact multi-function monitoring device with extensive measuring and calculation functions. Setting and programming possibilities are comprehensive and versatile. WIMO 6CP10 is ideal for secondary substation measuring and monitoring management. The unit measures currents, voltages and frequencies, and calculates power and energy values.
− Circutor: CVM-MINI-ITF-RS485-C2 The CVM-MINI panel analyzer is a programmable
measuring instrument; it offers a series of options for using it, which may be selected from configuration menus on the instrument itself. The CVM-MINI measures, calculates and displays the main electrical parameters for three-phase, balanced or unbalanced industrial systems.
Measurements are taken in true effective value using the three alternating and neutral voltage inputs and three current inputs to measure In /1A or In /5A secondary from external measurement transformers. The CVM-MINI allows the display of all electrical parameters, using the backlit LCD display, showing three instant electrical parameters, maximum or minimum on each page jump.
Note: See Appendix 4 for more details.
Note: The availability depends on the selected Feeder Automation device and Ring Main Unit module configuration. These devices are by default mounted in top entry box or low voltage compartment.
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VI. Appendixes
A. Appendix 1: Packages differentiations for SafeRing RMUs
RMU type 12/24 kV SafeRing
Name of the package Monitoring Control Measurement notes
FA device used REC603 RTU560CIG10 REC615 REC615+RIO600
LOAD BREAK SWITCHES POSITION MONITORING x x x x x x C modules
CIRCUIT BREAKERS POSITION MONITORING N/A N/A N/A N/A N/A N/A V modules
SWITCH-FUSE DISCONNECTORS POSITION MONITORING N/A N/A N/A N/A N/A N/A F modules
DISCONNECTORS POSITION MONITORING N/A N/A N/A N/A N/A N/A V modules
EARTHING SWITCHES POSITION MONITORING N/A N/A N/A o N/A x C modules
DIRECTIONAL FAULTS MONITORING x x x x x x MV network
NON DIRECTIONAL FAULTS MONITORING x x x x x x MV network
FAULTS MONITORING x x x x x x MV network
TR FEEDER(S) FAULT MONITORING x* x* x* x* x* x* * - 1 common signal
AC POWER SUPPLY ERROR MONITORING x x x N/A N/A N/A loss of main (AC) power supply
BATTERY_LOW_SPI x x x N/A N/A N/A REC603 specific data
AC AND DC POWER SUPPLY ERROR MONITORING N/A N/A N/A X x x 1 common signal for AC and DC
HEATER CONTROL x x x x x x automatic by thermo/hygro-stat
LOCAL / REMOTE local SWITCH N/A x* x* x* x* x* * - 1 common L/R switch common
MOTOR OPERATION OF THE LOAD BREAK SWITCHES N/A x x x x x C modules
MOTOR OPERATION OF THE CIRCUIT BREAKERS N/A N/A N/A N/A N/A N/A V modules
MOTOR OPERATION OF THE SWITCH-FUSE DISCONNECTORS N/A N/A N/A N/A N/A N/A F modules
MV NETWORK ANALOG VALUES MEASUREMENT N/A N/A x x x x I, UL-N, UL-L, f, cos Phi, ...
FPI RESET COMMAND o* o* o* o o o * - 1 common command
TR FEEDER(S) EMERGENCY TRIP COMMAND o* o* o* o* o* o* * - 1 common command; V, F modules
LV NETWORK ANALOG VALUES SUPERVISION o o o o N/A N/A I, UL-N, UL-L, f, cos Phi, ...
DISCONNECTORS TRAVEL TIME N/A x x N/A N/A N/A REC603 specific data
DISCONNECTORS TRAVEL VOLTAGE N/A x x N/A N/A N/A REC603 specific data
MODEM_RELAY_STATUS_SPI x x x N/A N/A N/A REC603 specific data
BATTERY_RELAY_STATUS_SPI x x x N/A N/A N/A REC603 specific data
CHARGER_RELAY_STATUS_SPI x x x N/A N/A N/A REC603 specific data
BATTERY_PROTECT_SPI x x x N/A N/A N/A REC603 specific data
TEMPERATURE_LOW_SPI x x x N/A N/A N/A REC603 specific data
TEMPERATURE_HI_SPI x x x N/A N/A N/A REC603 specific data
HEATER_RELAY_STATUS_SPI x x x N/A N/A N/A REC603 specific data
BATTERY_CHARGEVOLTAGE_FPI x x x N/A N/A N/A REC603 specific data
BATTERY_CHARGECURRENT_FPI x x x N/A N/A N/A REC603 specific data
Number of spare customer free usage DI
Number of cable switch modules in RMU
Package FPI type 2 3 4
Monitoring, Control or DIRECTIONAL 3 1 N/A
Measurement package with NON DIR. (OC & EF) 3 1 N/A
REC603 NON DIR. (FAULT) 5 4 N/A
Measurement package with RTU560CIG10 DIRECTIONAL 7 / 3 7 / 1 5 / N/A
without / with earthing switches position NON DIR. (OC & EF) 7 / 3 7 / 1 5 / N/A
monitoring NON DIR. (FAULT) 7 / 3 7 / 1 5 / N/A
Measurement package with REC615 ANY 2 0 (1 for CCC) N/A
Measurement package with REC615+RIO600 ANY 5 1 N/A
x availableo optionN/A not applicable/available
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Appendix 1: Packages differentiations for SafePlus SWGRs
SWGR type 12/24 kV SafePlus
Name of the package Monitoring Control Measurement notes
FA device used REC603 RTU560CIG10
LOAD BREAK SWITCHES POSITION MONITORING x x x x C, Sl modules
CIRCUIT BREAKERS POSITION MONITORING x x x x V, Sv, CB modules
SWITCH-FUSE DISCONNECTORS POSITION MONITORING x x x x F modules
DISCONNECTORS POSITION MONITORING N/A N/A N/A x V, Sv, CB modules
EARTHING SWITCHES POSITION MONITORING N/A N/A x x C, Sl, F, V, Sv, CB, De, Be modules
DIRECTIONAL FAULTS MONITORING x x x x MV network
NON DIRECTIONAL FAULTS MONITORING x x x x MV network
FAULTS MONITORING x x x x MV network
TR FEEDER(S) FAULT MONITORING x* x* x* x * - 1 common signal
AC POWER SUPPLY ERROR MONITORING x x x x loss of main (AC) power supply
BATTERY_LOW_SPI x x x N/A REC603 specific data
DC POWER SUPPLY ERROR MONITORING N/A N/A N/A x DC power supply low / high
HEATER CONTROL x x x x automatic by thermo/hygro-stat
LOCAL / REMOTE local SWITCH N/A x* x* x* * - 1 common L/R switch common
MOTOR OPERATION OF THE LOAD BREAK SWITCHES N/A x x x C, Sl modules
MOTOR OPERATION OF THE CIRCUIT BREAKERS N/A x x x V, Sv, CB modules
MOTOR OPERATION OF THE SWITCH-FUSE DISCONNECTORS N/A x x x F modules
MV NETWORK ANALOG VALUES MEASUREMENT N/A N/A x x I, UL-N, UL-L, f, cos Phi, ...
FPI RESET COMMAND o* o* o* o * - 1 common command
TR FEEDER(S) EMERGENCY TRIP COMMAND o* o* o* o * - 1 common command
LV NETWORK ANALOG VALUES SUPERVISION o o o o I, UL-N, UL-L, f, cos Phi, ...
DISCONNECTORS TRAVEL TIME N/A x x N/A REC603 specific data
DISCONNECTORS TRAVEL VOLTAGE N/A x x N/A REC603 specific data
MODEM_RELAY_STATUS_SPI x x x N/A REC603 specific data
BATTERY_RELAY_STATUS_SPI x x x N/A REC603 specific data
CHARGER_RELAY_STATUS_SPI x x x N/A REC603 specific data
BATTERY_PROTECT_SPI x x x N/A REC603 specific data
TEMPERATURE_LOW_SPI x x x N/A REC603 specific data
TEMPERATURE_HI_SPI x x x N/A REC603 specific data
HEATER_RELAY_STATUS_SPI x x x N/A REC603 specific data
BATTERY_CHARGEVOLTAGE_FPI x x x N/A REC603 specific data
BATTERY_CHARGECURRENT_FPI x x x N/A REC603 specific data
Number of spare customer free usage DI
Number of cable switch modules in RMU
Package FPI type 2 3 4
Monitoring or Control DIRECTIONAL 3 1 N/A
package with NON DIR. (OC & EF) 3 1 N/A
REC603 NON DIR. (FAULT) 5 4 N/A
Measurement package with REC603 ANY 3 1 N/A
DIRECTIONAL
Measurement package with RTU560CIG10 NON DIR. (OC & EF) Depends on the SWGR configuration
NON DIR. (FAULT)
x availableo optionN/A not applicable/available
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B. Appendix 2: Installation instructions
All devices (exception are „Supervision of the LV side of the distribution transformer” devices) come already installed inside the RMU, it is anyway needed to do some installation work directly on site:
− Installation of the additional wires (power supply, Ethernet, sub device, GSM antenna cables)
There are basically two paths for installation of the additional cables/wires:
− REC603 - connection points:
− REC603 - SIM card installation (set correct PIN code before inserting the card – see Appendix 3):
Unscrew the GSM antenna (if already installed) and release REC603 from te DIN rail:
Incline the REC603 box and install the SIM card (small screw driver is needed for removing of the SIM card holder):
Return the REC603 box back to its original position by proceeding described steps other way round.
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− RTU560CIG10 - connection points:
− RTU560CIG10 external modem 560MDD10 - SIM card installation (set correct PIN code before inserting the SIM card – see Appendix 3):
SIM card is inserted into the front side of the GSM/GPRS modem 560MDD10:
− RTU560CIG10 or REC615 / external modem RER601 - SIM card installation (set correct PIN code before inserting the SIM card – see Appendix 3):
− Correct interconnection between LV multi-meters and FA devices
− Circutor CVM-MINI(s) and RTU560CIG10 − The same Modbus line to which FPIs are connec-
ted is used – port CPA on RTU560CIG10
− Vamp WIMO6CP10(s) and REC603 − Use RS1 port of REC603 for first connected WIMO
and RS2 for second one − “CONSOLE/RS1“ switch must be set to “RS1“
position and all 4 DIP switches on the REC603 must be in OFF position “Ø“ if also the second WIMO is connected.
− Use DB9 connectors cable (female - male); minimum what is needed to be interconnected are pin2 - pin2; pin3 - pin3:
15
C. Appendix 3: On site setting instructions of feeder automation devices The secondary equipments which come installed within the RMU are preconfigured accordingly from the factory. Their configurations are adjusted according to the Safe Pro 3 standard package specification. It is nevertheless needed to do some on site setting mainly of the feeder automation box, so the setting (IP addresses etc.) fits to the communication system used (GPRS, Ethernet communication).
If not otherwise specified, FA devices come with these default settings:
− REC603, RTU560CIG10, Rear ports of the REC615 and RER601: − IP Address: 10.10.10.10 (10.10.10.2 for RER601 external GPRS modem and 10.10.10.15 for RIO600 LECM module) − Subnet mask: 255.0.0.0 − Default Gateway IP: 0.0.0.0 (10.10.10.2 for RTU560CIG10 or REC615 if RER601 external GPRS modem is used)
Note: Front REC615 port: IP: 192.168.0.254
REC603 (RER601) on site setting instructions: − The instructions can be found in the REC603 Quick Start Guide and Technical Manual (RER601 Quick Start Guide and
Technical Manual) of the devices. − No special software is needed. The setting is done in web browser (i.e. Microsoft Internet Explorer) so the cross-over
Ethernet cable and PC with Ethernet port are the only needed devices. − The default login password for the root is empty, but should be changed before connecting the device to a public network.
Password is changed from the System/Password menu. − Advanced technical support for this device can be obtained via your local ABB partners, which can then directly
(via the customer help portal) contact ABB Finland – the manufacturer of the REC603 and RER601.
RTU560CIG10 on site setting instructions: − The special configuration software – RTUtil560 – is needed. − It is recommended that the changes are done by person who has experience with this software. − The settings might be adjusted in the factory before RMU shipment. These values must be then provided: − RTU560CIG10 Ethernet interface values: IP Address, Subnet mask and Default Gateway IP
− If used RER601: Ethernet/GPRS interface values (RER601 all settings on pages 22 - 30 ) − If used 560MDD10: SIM card PIN, APN, local and remote IP addresses, User name and Password; VPN feature will be
available later on – contact us for more details − Advanced technical support for this device can be obtained via your local ABB partners, which can then directly (via the
customer help email) contact ABB Germany – the manufacturer of the RTU560 products.
REC615 on site setting instructions:− All the parameters (including IPs) can be set via REC615 local HMI menu.− For changing of it‘s internal logic, the special configuration software – PCM600 – is needed.− It is recommended that the changes are done by person who has experience with this software.− The settings might be adjusted in the factory before RMU shipment. These values must be then provided:− REC603 Ethernet interface values: IP Address, Subnet mask and Default Gateway IP − If used RER601: Ethernet/GPRS interface values (RER601 all settings on pages 22 - 30 )− Advanced technical support for this device can be obtained via your local ABB partners, which can then directly(via the customer help portal) contact ABB Finland – the manufacturer of the REC615 and RER601.
RIO600 modules (mainly SIM8F) on site setting instructions:− All the parameters can be set only by the configuration software - PCM600.− It is recommended that the changes are done by person who has experience with this software.
FPIs on site setting instructions:
The FPIs comes preconfigured (binary input mode, signaling output relays, Modbus parameters) according to the SafePro 3 selections. But the setting related to the network parameters like fault pick up current, fault current pick up time etc. must be done on site. Also voltage calibration has to be done on site. Please check the FPI’s manuals to find more details.
16
D. Appendix 4: IEC 60870-5-104 signal addresses
x available o option N/A not applicable/available DPI double-point information SPI single-point information
IEC 60870-5-104
GI group
SafeRing
data point description L1 L2 L3 L3 L3 L3
information data value read (R) note / scada KRIES HORSTMANN ABB Mon. Contr. Meas. Meas. Meas. Meas.
REC615 +
object address type written (W) mult. unit glb 1 5 6 10 13 IKI-50 specific Compass B specific REC615 specific REC603 REC603 REC603 RTU540 REC615 RIO600
100, 200, 300 DPI 1 (R) x x - - - - LOAD BREAK SWITCH POSITION OPEN x (3) x (3) x (3) x (4) x (3) x (3)
100, 200, 300 DPI 2 (R) x x - - - - LOAD BREAK SWITCH POSITION CLOSED x (3) x (3) x (3) x (4) x (3) x (3)
- DPI 1 (R) x x - - - - VACUUM CIRCUIT BREAKER POS. OPENN/A
- DPI 2 (R) x x - - - - VACUUM CIRCUIT BREAKER POS.CLOSED
110, 210, 310 DPI 1 (R) x x - - - - EARTHING SWITCH POSITION OPENN/A
o (3)N/A
x (3)
110, 210, 310 DPI 2 (R) x x - - - - EARTHING SWITCH POSITION CLOSED o (3) x (3)
- DPI 1 (R) x x - - - - DISCONNECTOR POSITION OPENN/A
- DPI 2 (R) x x - - - - DISCONNECTOR POSITION CLOSED
111, 211, 311 SPI 1 (R) x - - - x - FPI FORWARD (B) FAULT x (3) x (3) x (3)
N/A
112, 212, 312 SPI 1 (R) x - - - x - FPI EARTH FAULT x (3) x (3) x (3)
113, 213, 313 SPI 1 (R) x - - - x - FPI FAULT x (3) x (3) x (3)
114, 214, 314 SPI 1 (R) x - - - x - FPI BACKWARD (A) FAULT x (3) x (3) x (3)
115, 215, 315 SPI 1 (R) x - - - x - FPI OVERCURRENT FAULT x (3) x (3) x (3)
112, 212, ..., 412 SPI 1 (R) x - - - x - Earth fault (IE>) Earth fault (IE>) N/A
N/A
x (4)
N/A
115, 215, ..., 415 SPI 1 (R) x - - - x - Short-circuit (I>>) Short-circuit (I>>) N/A x (4)
117, 217, ..., 417 SPI 1 (R) x - - - x - Short-circuit L1 Event in phase 1 N/A x (4)
118, 218, ..., 418 SPI 1 (R) x - - - x - Short-circuit L2 Event in phase 2 N/A x (4)
119, 219, ..., 419 SPI 1 (R) x - - - x - Short-circuit L3 Event in phase 3 N/A x (4)
120, 220, ..., 420 SPI 1 (R) x - - - x - Limit monitoring U> Overvoltage (U>) N/A x (4)
121, 221, ..., 421 SPI 1 (R) x - - - x - Limit monitoring U< Undervoltage (U<) N/A x (4)
122, 222, ..., 422 SPI 1 (R) x - - - x - I>> direction A I>> direction A N/A x (4)
123, 223, ..., 423 SPI 1 (R) x - - - x - I>> direction B I>> direction B N/A x (4)
124, 224, ..., 424 SPI 1 (R) x - - - x - IE> direction A IE> direction A N/A x (4)
125, 225, ..., 425 SPI 1 (R) x - - - x - IE> direction B IE> direction B> N/A x (4)
126, 226, ..., 426 16BIT 0 ... 65535 (R) x - - - x - Type of Event 1 Event class. (Latest e.) N/A x (4)
112, 212, 312 SPI 1 (R) x - x - x - N/A N/A Earth fault (IE>)
N/A
x (1) x (3)
115, 215, 315 SPI 1 (R) x - x - x - N/A N/A Short-circuit (I>>) x (1) x (3)
117, 217, 317 SPI 1 (R) x - x - x - N/A N/A Event in phase 1 x (1) x (3)
118, 218, 318 SPI 1 (R) x - x - x - N/A N/A Event in phase 2 x (1) x (3)
119, 219, 319 SPI 1 (R) x - x - x - N/A N/A Event in phase 3 x (1) x (3)
120 SPI 1 (R) x - x - x - N/A N/A LBS1 Overvoltage (U>) x (1) N/A
121 SPI 1 (R) x - x - x - N/A N/A LBS 1 Undervoltage (U<) x (1) N/A
122, 222, 322 SPI 1 (R) x - x - x - N/A N/A I>> direction A (backward) x (1) x (3)
123, 223, 323 SPI 1 (R) x - x - x - N/A N/A I>> direction B (forward) x (1) x (3)
124, 224, 324 SPI 1 (R) x - x - x - N/A N/A IE> direction A (backward) x (1) x (3)
125, 225, 325 SPI 1 (R) x - x - x - N/A N/A IE> direction B (forward) x (1) x (3)
701, 702, ..., 707 SPI 1 (R) x - - - x - SPARE INPUT x (1-5) x (1-5) x (1-5) x (1-7) x (0-2) x (1-5)
716 SPI 1 (R) x - - - x - TR FEEDER(S) FAULT x (1) x (1) x (1) x (1) x (1) x (1)
402 SPI 0 (R) x - - - - x UNIVERSAL (AC/DC) POWER SUPPLY ERROR N/A N/A N/A x (1) x (1) x (1)
902 SPI 0 (R) x - - - - x AC POWER SUPPLY ERROR x (1) x (1) x (1) N/A N/A N/A
911 SPI 1 (R) x - - - - x LOW GAS PRESSURE o (1) o (1) o (1) o (1) o (1) o (1)
921 SPI 1 (R) x - - - - x ARC SUPPRESSOR ACTIVATED o (1) o (1) o (1) o (1) o (1) o (1)
808 SCS 1 (W) dir cmd - - - - - - FPI RESET o (1) o (1) o (1) N/A N/A N/A
801, 802, ..., 804 DSO16 2 (W) dir cmd - - - - - - FPI RESET N/A N/A N/A o (4) N/A N/A
151, 251, 351 SCS 1 (R dir cmd - - - - - - FPI RESET I (Programmable LEDs) N/A N/A N/A N/A o (1) o (3)
152 SCS 1 (R dir cmd - - - - - - FPI RESET II (Indications and LEDs) N/A N/A N/A N/A o (1) o (1)
810 SCS 1 (W) dir cmd - - - - - - TR FEEDER(S) EMERGENCY TRIP o (1) o (1) o (1) o (1) o (1) o (1)
101, 201,301 SPI 1 (R) x x - - - - SWITCH / CB REMOTE OPERATION ON N/A x (3) x (3) N/A N/A N/A
901 SPI 1 (R) x x - - - - RMU / SWGR REMOTE OPERATION ON N/A N/A N/A x (1) x (1) x (1)
150, 250, ..., 450 DCS 2 (W) sel/exc - - - - - - CLOSE SWITCH / CB COMMAND N/A x (3) x (3) x (4) x (3) x (3)
150, 250, ..., 450 DCS 1 (W) sel/exc - - - - - - OPEN SWITCH / CB COMMAND N/A x (3) x (3) x (4) x (3) x (3)
103, 203, 303 FPI 0 ... 10 (R) 1 sec x - - - - x DISCONNECTOR TRAVELTIME N/A x (3) x (3) N/A N/A N/A
104, 204, 304 FPI 0 ... 30 (R) 1 V x - - - - x DISCONNECTOR TRAVELVOLT N/A x (3) x (3) N/A N/A N/A
410 SPI 1 (R) x - - - - x MODEM_RELAY_STATUS_SPI x (1) x (1) x (1)
N/A
440 SPI 1 (R) x - - - - x BATTERY_RELAY_STATUS_SPI x (1) x (1) x (1)
420 SPI 1 (R) x - - - - x CHARGER_RELAY_STATUS_SPI x (1) x (1) x (1)
441 SPI 1 (R) 22 VDC x - - - - x BATTERY_LOW_SPI x (1) x (1) x (1)
442 SPI 1 (R) 21 VDC x - - - - x BATTERY_PROTECT_SPI x (1) x (1) x (1)
460 SPI 1 (R) -5 oC x - - - - x TEMPERATURE_LOW_SPI x (1) x (1) x (1)
461 SPI 1 (R) 80 oC x - - - - x TEMPERATURE_HI_SPI x (1) x (1) x (1)
443 FPI 0 ... 30 (R) 1 V x - - - - x BATTERY_CHARGEVOLTAGE_SPI x (1) x (1) x (1)
444 FPI 0 ... 10 (R) 1 A x - - - - x BATTERY_CHARGECURRENT_SPI x (1) x (1) x (1)
FPI floating point information SCS single command DCS double command DSO16 digital set point command 16 bit _ (3) in hooks max number of supported items
17
x available o option N/A not applicable/available DPI double-point information SPI single-point information
FPI floating point information SCS single command DCS double command DSO16 digital set point command 16 bit _ (3) in hooks max number of supported items
IEC 60870-5-104
GI group
SafePlus
data point description L1 L2 L3 L3
information data value read (R) note / scada KRIES HORSTMANN Mon. Contr. Meas. Meas.
object address type written (W) mult. unit glb 1 5 6 10 13 IKI-50 specific Compass B specific REC603 REC603 REC603 RTU540
100, 200, ..., 600 DPI 1 (R) x x - - - - LOAD BREAK SWITCH POSITION OPEN x (3) x (3) x (3) x (6)
100, 200, ..., 600 DPI 2 (R) x x - - - - LOAD BREAK SWITCH POSITION CLOSED x (3) x (3) x (3) x (6)
100, 200, ..., 600 DPI 1 (R) x x - - - - VACUUM CIRCUIT BREAKER POS. OPEN x (3) x (3) x (3) x (6)
100, 200, ..., 600 DPI 2 (R) x x - - - - VACUUM CIRCUIT BREAKER POS.CLOSED x (3) x (3) x (3) x (6)
110, 210, ..., 610 DPI 1 (R) x x - - - - EARTHING SWITCH POSITION OPENN/A
x (3) x (6)
110, 210, ..., 610 DPI 2 (R) x x - - - - EARTHING SWITCH POSITION CLOSED x (3) x (6)
140, 240, ..., 640 DPI 1 (R) x x - - - - DISCONNECTOR POSITION OPENN/A
x (6)
140, 240, ..., 640 DPI 2 (R) x x - - - - DISCONNECTOR POSITION CLOSED x (6)
111, 211, 311 SPI 1 (R) x - - - x - FPI FORWARD (B) FAULT x (3) x (3)
N/A
112, 212, 312 SPI 1 (R) x - - - x - FPI EARTH FAULT x (3) x (3)
113, 213, 313 SPI 1 (R) x - - - x - FPI FAULT x (3) x (3)
114, 214, 314 SPI 1 (R) x - - - x - FPI BACKWARD (A) FAULT x (3) x (3)
115, 215, 315 SPI 1 (R) x - - - x - FPI OVERCURRENT FAULT x (3) x (3)
112, 212, ..., 412 SPI 1 (R) x - x - x - Earth fault (IE>) Earth fault (IE>)
N/A
x (4)
N/A
115, 215, ..., 415 SPI 1 (R) x - x - x - Short-circuit dir. unknown (I>>) Short-circuit (I>>) x (4)
117, 217, ..., 417 SPI 1 (R) x - x - x - Short-circuit L1 Event in phase 1 x (4)
118, 218, ..., 418 SPI 1 (R) x - x - x - Short-circuit L2 Event in phase 2 x (4)
119, 219, ..., 419 SPI 1 (R) x - x - x - Short-circuit L3 Event in phase 3 x (4)
120, 220, ..., 420 SPI 1 (R) x - x - x - Limit monitoring U> Overvoltage (U>) x (4)
121, 221, ..., 421 SPI 1 (R) x - x - x - Limit monitoring U< Undervoltage (U<) x (4)
122, 222, ..., 422 SPI 1 (R) x - x - x - I>> direction A I>> direction A x (4)
123, 223, ..., 423 SPI 1 (R) x - x - x - I>> direction B I>> direction B x (4)
124, 224, ..., 424 SPI 1 (R) x - x - x - IE> direction A IE> direction A x (4)
125, 225, ..., 425 SPI 1 (R) x - x - x - IE> direction B IE> direction B> x (4)
112, 212, ..., 612 SPI 1 (R) x - - - x - Earth fault (IE>) Earth fault (IE>)
N/A
x (6)
115, 215, ..., 615 SPI 1 (R) x - - - x - Short-circuit (I>>) Short-circuit (I>>) x (6)
117, 217, ..., 617 SPI 1 (R) x - - - x - Short-circuit L1 Event in phase 1 x (6)
118, 218, ..., 618 SPI 1 (R) x - - - x - Short-circuit L2 Event in phase 2 x (6)
119, 219, ..., 619 SPI 1 (R) x - - - x - Short-circuit L3 Event in phase 3 x (6)
120, 220, ..., 620 SPI 1 (R) x - - - x - Limit monitoring U> Overvoltage (U>) x (6)
121, 221, ..., 621 SPI 1 (R) x - - - x - Limit monitoring U< Undervoltage (U<) x (6)
122, 222, ..., 622 SPI 1 (R) x - - - x - I>> direction A I>> direction A x (6)
123, 223, ..., 623 SPI 1 (R) x - - - x - I>> direction B I>> direction B x (6)
124, 224, ..., 624 SPI 1 (R) x - - - x - IE> direction A IE> direction A x (6)
125, 225, ..., 625 SPI 1 (R) x - - - x - IE> direction B IE> direction B x (6)
126, 226, ..., 626 16BIT 0 ... 65535 (R) x - - - x - Type of Event 1 Event class. (Latest e.) x (6)
701, 702, ..., 710 SPI 1 (R) x - - - x - SPARE INPUT x (1-5) x (1-5) x (1-3) o (1-10)
716, 116, ..., 616 SPI 1 (R) x - - - x - TR FEEDER(S) FAULT x (1) x (1) x (1) x (6)
402 SPI 0 (R) x - - - - x UNIVERSAL (AC/DC) POWER SUPPLY ERROR N/A N/A N/A N/A)
902 SPI 0 (R) x - - - - x AC POWER SUPPLY ERROR x (1) x (1) x (1) N/A
903 SPI 0 (R) x - - - - x DC POWER SUPPLY ERROR N/A N/A N/A x (1)
911, 912, ..., 916 SPI 1 (R) x - - - - x LOW GAS PRESSURE o (1) o (1) o (1) x (6)
921, 922, ..., 926 SPI 1 (R) x - - - - x ARC SUPPRESSOR ACTIVATED o (1) o (1) o (1) o (6)
808 SCS 1 (W) dir cmd - - - - - - FPI RESET o (1) o (1) o (1) N/A
801, 802, ..., 806 DSO16 2 (W) dir cmd - - - - - - FPI RESET N/A N/A N/A x (6)
808 SCS 1 (R) dir cmd - - - - - - FPI RESET I (Programmable LEDs) N/A N/A N/A N/A
809 SCS 1 (R) dir cmd - - - - - - FPI RESET II (Indications and LEDs) N/A N/A N/A N/A
810, 811, ..., 816 SCS 1 (W) dir cmd - - - - - - TR FEEDER(S) EMERGENCY TRIP o (1) o (1) o (1) o (6)
101, 201,301 SPI 1 (R) x x - - - - SWITCH / CB REMOTE OPERATION ON N/A x (3) x (3) N/A
901 SPI 1 (R) x x - - - - RMU / SWGR REMOTE OPERATION ON N/A N/A N/A x (1)
150, 250, ...,650 DCS 2 (W) sel/exc - - - - - - CLOSE SWITCH / CB COMMAND N/A x (3) x (3) x (6)
150, 250, ..., 650 DCS 1 (W) sel/exc - - - - - - OPEN SWITCH / CB COMMAND N/A x (3) x (3) x (6)
103, 203, 303 FPI 0 ... 10 (R) 1 sec x - - - - x DISCONNECTOR TRAVELTIME N/A x (3) x (3) N/A
104, 204, 304 FPI 0 ... 30 (R) 1 V x - - - - x DISCONNECTOR TRAVELVOLT N/A x (3) x (3) N/A
410 SPI 1 (R) x - - - - x MODEM_RELAY_STATUS_SPI x (1) x (1) x (1)
N/A
440 SPI 1 (R) x - - - - x BATTERY_RELAY_STATUS_SPI x (1) x (1) x (1)
420 SPI 1 (R) x - - - - x CHARGER_RELAY_STATUS_SPI x (1) x (1) x (1)
441 SPI 1 (R) 22 VDC x - - - - x BATTERY_LOW_SPI x (1) x (1) x (1)
442 SPI 1 (R) 21 VDC x - - - - x BATTERY_PROTECT_SPI x (1) x (1) x (1)
460 SPI 1 (R) -5 oC x - - - - x TEMPERATURE_LOW_SPI x (1) x (1) x (1)
461 SPI 1 (R) 80 oC x - - - - x TEMPERATURE_HI_SPI x (1) x (1) x (1)
443 FPI 0 ... 30 (R) 1 V x - - - - x BATTERY_CHARGEVOLTAGE_SPI x (1) x (1) x (1)
444 FPI 0 ... 10 (R) 1 A x - - - - x BATTERY_CHARGECURRENT_SPI x (1) x (1) x (1)
18
Valid for Monitoring, Control or Measurement packages with only REC603. − LV network analog data values:
− Vamp WIMO 6CP10 specific:
IEC 60870-5-104 information object addresses (IOA): IOA are the same for both used WIMOs, the differentiation is done by different IP protocol port assignment. Data from the first WIMO has port 2406 and from the second WIMO 2408. Standard (and default) port for all the rest signals is 2404.
o option N/A not applicable/available AMI analog measurement information o (2) in hooks max number of supported items
IEC 60870-5-104 SafeRing SafePlus
L1 L2 L3 L1 L2 L3
information data value read (R) note / scada GI group data point description Mon. Contr. Meas. Mon. Contr. Meas.
object address type written (W) mult. unit glb 1 5 6 10 13 REC603 REC603 REC603 REC603 REC603 REC603
16385 port 2406,8 AMI 0 ... +1 (R) 10000 A x - - - - - IL1 - Phase current IL1
16386 port 2406,8 AMI 0 ... +1 (R) 10000 A x - - - - - IL2 - Phase current IL2
16387 port 2406,8 AMI 0 ... +1 (R) 10000 A x - - - - - IL3 - Phase current IL3
16396 port 2406,8 AMI 0 ... +1 (R) 10000 A x - - - - - IoCalc - Calculated Io
16404 port 2406,8 AMI 0 ... +1 (R) 10000 A x - - - - - IL1da - 15 min average for IL1
16405 port 2406,8 AMI 0 ... +1 (R) 10000 A x - - - - - IL2da - 15 min average for IL2
16406 port 2406,8 AMI 0 ... +1 (R) 10000 A x - - - - - IL3da - 15 min average for IL3
16413 port 2406,8 AMI 0 ... +1 (R) 10000 kW x - - - - - Pda - Active power demand value 15 min
16407 port 2406,8 AMI 0 ... +1 (R) 100 % x - - - - - THDIL1 - Total harmonic distortion of phase current IL1
16408 port 2406,8 AMI 0 ... +1 (R) 100 % x - - - - - THDIL2 - Total harmonic distortion of phase current IL2
16409 port 2406,8 AMI 0 ... +1 (R) 100 % x - - - - - THDIL3 - Total harmonic distortion of phase current IL3
16391 port 2406,8 AMI 0 ... +1 (R) 1000 V x - - - - - U12 - Phase-to-phase voltage U12
16392 port 2406,8 AMI 0 ... +1 (R) 1000 V x - - - - - U23 - Phase-to-phase voltage U23
16393 port 2406,8 AMI 0 ... +1 (R) 1000 V x - - - - - U31 - Phase-to-phase voltage U31 o (2) o (2) o (2) o (2) o (2) o (2)
16388 port 2406,8 AMI 0 ... +1 (R) 1000 V x - - - - - UL1 - Phase-to-earth voltage UL1
16389 port 2406,8 AMI 0 ... +1 (R) 1000 V x - - - - - UL2 - Phase-to-earth voltage UL2
16390 port 2406,8 AMI 0 ... +1 (R) 1000 V x - - - - - UL3 - Phase-to-earth voltage UL3
16410 port 2406,8 AMI 0 ... +1 (R) 100 % x - - - - - THDUa - Total harmonic distortion of the voltage input a
16411 port 2406,8 AMI 0 ... +1 (R) 100 % x - - - - - THDUb - Total harmonic distortion of the voltage input b
16412 port 2406,8 AMI 0 ... +1 (R) 100 % x - - - - - THDUc - Total harmonic distortion of the voltage input c
16400 port 2406,8 AMI 0 ... +1 (R) 10000 kVA x - - - - - S - Apparent power
16398 port 2406,8 AMI 0 ... +1 (R) 10000 kW x - - - - - P - Active power
16399 port 2406,8 AMI 0 ... +1 (R) 10000 kVAr x - - - - - Q-Reactive power
16402 port 2406,8 AMI 0 ... +1 (R) 1 - x - - - - - CosPhi - Active power angle
16401 port 2406,8 AMI 0 ... +1 (R) 1 - x - - - - - PF - Power factpr
16403 port 2406,8 AMI 0 ... +1 (R) 100 Hz x - - - - - f - Frequency
16415 port 2406,8 AMI 0 ... +1 (R) 100 oC x - - - - - Dsitribution transformer temperature
19
Valid for Measurement package with only RTU540 products (RTU560CIG10). − LV network analog data values:
− Circutor CVM-MINI specific:
IEC 60870-5-104 information object addresses (IOA): data from the first CVM-MINI has IOA 11xxx and from the second CVM-MINI 12xxx.o option N/A not applicable/available AMI analog measurement information o (2) in hooks max number of supported items
SafeRing SafePlus
IEC 60870-5-104 L3 L3
information data value read (R) note / scada GI group data point description Measurement Measurement
object address type written (W) mult. unit glb 1 5 6 10 13 RTU540 RTU540
11000/14000 AMI 0 ... +1 (R) 10000 A x - - x - - A L1 Inst - Current
11001/14001 AMI 0 ... +1 (R) 10000 A x - - x - - A L1 Max - Current
11002/14002 AMI 0 ... +1 (R) 10000 A x - - x - - A L2 Inst - Current
11003/14003 AMI 0 ... +1 (R) 10000 A x - - x - - A L2 Max - Current
11004/14004 AMI 0 ... +1 (R) 10000 A x - - x - - A L3 Inst - Current
11005/14005 AMI 0 ... +1 (R) 10000 A x - - x - - A L3 Max - Current
11006/14006 AMI 0 ... +1 (R) 10000 A x - - x - - In Inst - Neutral current
11007/14007 AMI 0 ... +1 (R) 10000 A x - - x - - In Max - Neutral current
11008/14008 AMI 0 ... +1 (R) 10000 A x - - x - - A_AVG Inst - Three-phase current (average)
11009/14009 AMI 0 ... +1 (R) 10000 A x - - x - - A_AVG Max - Three-phase current (average)
11010/14010 AMI 0 ... +1 (R) 10000 A x - - x - - Md (A) 15min Inst - Maximum demand
11011/14011 AMI 0 ... +1 (R) 10000 A x - - x - - Md (A) 15min Max - Maximum demand
11012/14012 AMI 0 ... +1 (R) 100 % x - - x - - %THD A L1 Inst - Total harmonic distortion in current
11013/14013 AMI 0 ... +1 (R) 100 % x - - x - - %THD A L1 Max - Total harmonic distortion in current
11014/14014 AMI 0 ... +1 (R) 100 % x - - x - - %THD A L2 Inst - Total harmonic distortion in current
11015/14015 AMI 0 ... +1 (R) 100 % x - - x - - %THD A L2 Max - Total harmonic distortion in current
11016/14016 AMI 0 ... +1 (R) 100 % x - - x - - %THD A L3 Inst - Total harmonic distortion in current
11017/14017 AMI 0 ... +1 (R) 100 % x - - x - - %THD A L3 Max - Total harmonic distortion in current
11018/14018 AMI 0 ... +1 (R) 1000 V x - - x - - V12 Inst - Voltage line L1-L2
11019/14019 AMI 0 ... +1 (R) 1000 V x - - x - - V12 Max - Voltage line L1-L2
11020/14020 AMI 0 ... +1 (R) 1000 V x - - x - - V12 Min - Voltage line L1-L2
11021/14021 AMI 0 ... +1 (R) 1000 V x - - x - - V23 Inst - Voltage line L2-L3
11022/14022 AMI 0 ... +1 (R) 1000 V x - - x - - V23 Max - Voltage line L2-L3
11023/14023 AMI 0 ... +1 (R) 1000 V x - - x - - V23 Min - Voltage line L2-L3
11024/14024 AMI 0 ... +1 (R) 1000 V x - - x - - V31 Inst - Voltage line L3-L1
11025/14025 AMI 0 ... +1 (R) 1000 V x - - x - - V31 Max - Voltage line L3-L1
11026/14026 AMI 0 ... +1 (R) 1000 V x - - x - - V31 Min - Voltage line L3-L1
11027/14027 AMI 0 ... +1 (R) 1000 V x - - x - - V L1 Inst - Voltage phase L1
11028/14028 AMI 0 ... +1 (R) 1000 V x - - x - - V L1 Max - Voltage phase L1
11029/14029 AMI 0 ... +1 (R) 1000 V x - - x - - V L1 Min - Voltage phase L1
11030/14030 AMI 0 ... +1 (R) 1000 V x - - x - - V L2 Inst - Voltage phase L2
11031/14031 AMI 0 ... +1 (R) 1000 V x - - x - - V L2 Max - Voltage phase L2
11032/14032 AMI 0 ... +1 (R) 1000 V x - - x - - V L2 Min - Voltage phase L2
11033/14033 AMI 0 ... +1 (R) 1000 V x - - x - - V L3 Inst - Voltage phase L3 o (2) o (4)
11034/14034 AMI 0 ... +1 (R) 1000 V x - - x - - V L3 Max - Voltage phase L3
11035/14035 AMI 0 ... +1 (R) 1000 V x - - x - - V L3 Min - Voltage phase L3
11036/14036 AMI 0 ... +1 (R) 100 % x - - x - - %THD V L1 Inst - Total harmonic distortion in voltage
11037/14037 AMI 0 ... +1 (R) 100 % x - - x - - %THD V L1 Max - Total harmonic distortion in voltage
11038/14038 AMI 0 ... +1 (R) 100 % x - - x - - %THD V L2 Inst - Total harmonic distortion in voltage
11039/14039 AMI 0 ... +1 (R) 100 % x - - x - - %THD V L2 Max - Total harmonic distortion in voltage
11040/14040 AMI 0 ... +1 (R) 100 % x - - x - - %THD V L3 Inst - Total harmonic distortion in voltage
11041/14041 AMI 0 ... +1 (R) 100 % x - - x - - %THD V L3 Inst - Total harmonic distortion in voltage
11042/14042 AMI -1 ... +1 (R) 10000 kVA x - - x - - kVA lll Inst - Apparent power
11043/14043 AMI -1 ... +1 (R) 10000 kVA x - - x - - kVA lll Max - Apparent power
11044/14044 AMI -1 ... +1 (R) 10000 kVA x - - x - - kVA lll Min - Apparent power
11045/14045 AMI -1 ... +1 (R) 10000 kW x - - x - - kW lll Inst - Active power
11046/14046 AMI -1 ... +1 (R) 10000 kW x - - x - - kW lll Max - Active power
11047/14047 AMI -1 ... +1 (R) 10000 kVArL x - - x - - kVArL lll Inst - Inductive power
11048/14048 AMI -1 ... +1 (R) 10000 kVArL x - - x - - kVArL lll Max - Inductive power
11049/14049 AMI -1 ... +1 (R) 10000 kVArC x - - x - - kVArC lll Inst - Capacitive power
11050/14050 AMI -1 ... +1 (R) 10000 kVArC x - - x - - kVArC lll Max - Capacitive power
11051/14051 AMI -1 ... +1 (R) 1 - x - - x - - Cos Phi lll Inst - CosPhi
11052/14052 AMI -1 ... +1 (R) 1 - x - - x - - Cos Phi lll Max - CosPhi
11053/14053 AMI -1 ... +1 (R) 1 - x - - x - - Cos Phi lll Min - CosPhi
11054/14054 AMI -1 ... +1 (R) 1 - x - - x - - PF lll Inst - Power factor
11055/14055 AMI -1 ... +1 (R) 1 - x - - x - - PF lll Max - Power factor
11056/14056 AMI -1 ... +1 (R) 1 - x - - x - - PF lll Min - Power factor
11057/14057 AMI 0 ... +1 (R) 100 Hz x - - x - - Hz Inst - Frequency
11058/14058 AMI 0 ... +1 (R) 100 Hz x - - x - - Hz Max - Frequency
11059/14059 AMI 0 ... +1 (R) 100 Hz x - - x - - Hz Min - Frequency
11060/14060 AMI 0 ... +1 (R) 1000000 kW*h x - - x - - kW*h lll Inst - Active energy
11061/14061 AMI 0 ... +1 (R) 1000000 kVArL*h x - - x - - kVArL*h lll Inst - Inductive reactive energy
11062/14062 AMI 0 ... +1 (R) 1000000 kVArC*h x - - x - - kVArC*h lll Inst - Capacitive reactive energy
11063/14063 AMI 0 ... +1 (R) 1000000 kVA*h x - - x - - kVA*h lll Inst - Apparent energy
11064/14064 AMI 0 ... +1 (R) 1000000 kW*h x - - x - - kW*h lll (-) Inst - Active energy generated
11065/14065 AMI 0 ... +1 (R) 1000000 kVArL*h x - - x - - kVArL*h lll (-) Inst - Inductive energy generated
11066/14066 AMI 0 ... +1 (R) 1000000 kVArC*h x - - x - - kVArC*h lll (-) Inst - Capacitive energy generated
11067/14067 AMI 0 ... +1 (R) 1000000 kVA*h x - - x - - kVA*h lll (-) Inst - Apparent energy generated
20
Valid only for Measurement package. − MV network analog data values:
− Kries IKI-50 specific:
IEC 60870-5-104 information object addresses (IOA): data from the first (most left one) cable switch has IOA 10xx, from the second cable switch 20xx etc… AMI analog measurement information N/A not applicable/availablex (4) available, in hooks max number of supported items* - overflow (1.0 value in IEC 60870-5-104) means no value recorded yet ** Sign of the 1021: POS = FORWARD (B) / NEG = BACKWARD (A)
SafeRing SafePlus
IEC 60870-5-104 L3 L3 L3 L3
information data value read (R) note / scada GI group Meas. Meas. Meas. Meas.
object address type written (W) mult. unit glb 1 5 6 10 13 data point description REC603 RTU540 REC603 RTU540
1000/6000 AMI 0 ... +1 (R) 1000 A x - x - - - Phase current I L1
N/A x (4) N/A x (6)
1001/6001 AMI 0 ... +1 (R) 1000 A x - x - - - Phase current I L2
1002/6002 AMI 0 ... +1 (R) 1000 A x - x - - - Phase current I L3
1003/6003 AMI 0 ... +1 (R) 1000 A x - x - - - Earth current I0∑
1014/6014 AMI 0 ... +1 (R) 100 kV x - x - - - Voltage U L12
1015/6015 AMI 0 ... +1 (R) 100 kV x - x - - - Voltage U L23
1016/6016 AMI 0 ... +1 (R) 100 kV x - x - - - Voltage U L31
1017/6017 AMI 0 ... +1 (R) 100 kV x - x - - - Voltage U L1-N
1018/6018 AMI 0 ... +1 (R) 100 kV x - x - - - Voltage U L2-N
1019/6019 AMI 0 ... +1 (R) 100 kV x - x - - - Voltage U L3-N
1020/6020 AMI 0 ... +1 (R) 100 kV x - x - - - Voltage U0∑
1021/6021 AMI -1 ... +1 (R) 10000 kVA x - x - - - Apparent power ∑ S
1022/6022 AMI -1 ... +1 (R) 10000 kW x - x - - - Active power ∑ P
1023/6023 AMI -1 ... +1 (R) 10000 kVAr x - x - - - Reactive power ∑ Q
1024/6024 AMI -1 ... +1 (R) 1 - x - x - - - Power factor Cos Phi L2
1025/6025 AMI -1 ... +1 (R)) 100 Hz x - x - - - Frequency f L2
- AMI POS/NEG (R) 1 - x - x - - - Load flow direction **
1035/6035 AMI 0 ... +1 (R) 1000 A x - x - - - Average of forward phase current I Ø [dt] I L1 *
1036/6036 AMI 0 ... +1 (R) 1000 A x - x - - - Average of backward phase current I Ø [dt] I L1 *
1037/6037 AMI 0 ... +1 (R) 1000 A x - x - - - Average of forward phase current I Ø [dt] I L2 *
1038/6038 AMI 0 ... +1 (R) 1000 A x - x - - - Average of backward phase current I Ø [dt] I L2 *
1039/6039 AMI 0 ... +1 (R) 1000 A x - x - - - Average of forward phase current I Ø [dt] I L3 *
1040/6040 AMI 0 ... +1 (R) 1000 A x - x - - - Average of backward phase current I Ø [dt] I L3 *
1041/6041 AMI 0 ... +1 (R) 1000 A x - x - - - Max. of forward phase current I Ø Max [dT] I L1 *
1042/6042 AMI 0 ... +1 (R) 1000 A x - x - - - Max. of backward phase current I Ø Max [dT] I L1 *
1043/6043 AMI 0 ... +1 (R) 1000 A x - x - - - Max. of forward phase current I Ø Max [dT] I L2 *
1044/6044 AMI 0 ... +1 (R) 1000 A x - x - - - Max. of backward phase current I Ø Max [dT] I L2 *
1045/6045 AMI 0 ... +1 (R) 1000 A x - x - - - Max. of forward phase current I Ø Max [dT] I L3 *
1046/6046 AMI 0 ... +1 (R) 1000 A x - x - - - Max. of backward phase current I Ø Max [dT] I L3 *
1047/6047 AMI 0 ... +1 (R) 1000 A x - x - - - Max. of forward phase current I Ø Max/Res I L1 *
1048/6048 AMI 0 ... +1 (R) 1000 A x - x - - - Max. of backward phase current I Ø Max/Res I L1 *
1049/6049 AMI 0 ... +1 (R) 1000 A x - x - - - Max. of forward phase current I Ø Max/Res I L2 *
1050/6050 AMI 0 ... +1 (R) 1000 A x - x - - - Max. of backward phase current I Ø Max/Res I L2 *
1051/6051 AMI 0 ... +1 (R) 1000 A x - x - - - Max. of forward phase current I Ø Max/Res I L3 *
1052/6052 AMI 0 ... +1 (R) 1000 A x - x - - - Max. of backward phase current I Ø Max/Res I L3 *
1053/6053 AMI 0 ... +1 (R) 1000 A x - x - - - Average of forward earth current I Ø [dt] I0S *
1054/6054 AMI 0 ... +1 (R) 1000 A x - x - - - Average of backward earth current I Ø [dt] I0S *
1000/4000 FPI 0 ... +1000 (R) 1 A x - x - - - Phase current I L1
x (4) N/A x (4) N/A
1001/4001 FPI 0 ... +1000 (R) 1 A x - x - - - Phase current I L2
1002/4002 FPI 0 ... +1000 (R) 1 A x - x - - - Phase current I L3
1003/4003 FPI 0 ... +1000 (R) 1 A x - x - - - Earth current I0∑
1014/4014 FPI 0 ... +100000 (R) 1 V x - x - - - Voltage U L12
1015/4015 FPI 0 ... +100000 (R) 1 V x - x - - - Voltage U L23
1016/4016 FPI 0 ... +100000 (R) 1 V x - x - - - Voltage U L31
1017/4017 FPI 0 ... +100000 (R) 1 V x - x - - - Voltage U L1-N
1018/4018 FPI 0 ... +100000 (R) 1 V x - x - - - Voltage U L2-N
1019/4019 FPI 0 ... +100000 (R) 1 V x - x - - - Voltage U L3-N
1020/4020 FPI 0 ... +100000 (R) 1 V x - x - - - Voltage U0∑
1021/4021 FPI 0 ... +10000 (R) 1 kVA x - x - - - Apparent power ∑ S
1022/4022 FPI -10000 ... +10000 (R) 1 kW x - x - - - Active power ∑ P
1023/4023 FPI -10000 ... +10000 (R) 1 kVAr x - x - - - Reactive power ∑ Q
1024/4024 FPI -1 ... +1 (R) 1 - x - x - - - Power factor Cos Phi (Cos Phi Sum U1-U3, I1-I3)
1025/4025 FPI 0 ... +100 (R) 1 Hz x - x - - - Frequency f L2
- FPI POS/NEG (R) 1 - x - x - - - Load flow direction **
1035/4035 FPI 0 ... +1000 (R) 1 A x - x - - - Average of forward phase current I Ø [dt] I L1 *
1036/4036 FPI 0 ... +1000 (R) 1 A x - x - - - Average of backward phase current I Ø [dt] I L1 *
1037/4037 FPI 0 ... +1000 (R) 1 A x - x - - - Average of forward phase current I Ø [dt] I L2 *
1038/4038 FPI 0 ... +1000 (R) 1 A x - x - - - Average of backward phase current I Ø [dt] I L2 *
1039/4039 FPI 0 ... +1000 (R) 1 A x - x - - - Average of forward phase current I Ø [dt] I L3 *
1040/4040 FPI 0 ... +1000 (R) 1 A x - x - - - Average of backward phase current I Ø [dt] I L3 *
1041/4041 FPI 0 ... +1000 (R) 1 A x - x - - - Max. of forward phase current I Ø Max [dT] I L1 *
1042/4042 FPI 0 ... +1000 (R) 1 A x - x - - - Max. of backward phase current I Ø Max [dT] I L1 *
1043/4043 FPI 0 ... +1000 (R) 1 A x - x - - - Max. of forward phase current I Ø Max [dT] I L2 *
1044/4044 FPI 0 ... +1000 (R) 1 A x - x - - - Max. of backward phase current I Ø Max [dT] I L2 *
4045/4045 FPI 0 ... +1000 (R) 1 A x - x - - - Max. of forward phase current I Ø Max [dT] I L3 *
1046/4046 FPI 0 ... +1000 (R) 1 A x - x - - - Max. of backward phase current I Ø Max [dT] I L13*
1053/4053 FPI 0 ... +1000 (R) 1 A x - x - - - Average of forward earth current I Ø [dt] I0S *
21
Valid only for Measurement package. − MV network analog data values:
− Horstmann Compass B specific:
IEC 60870-5-104 information object addresses (IOA): data from the first (most left one) cable switch has IOA 10xx, from the second cable switch 20xx etc… AMI analog measurement information SPI single-point information FPI floating point informationN/A not applicable/availablex (4) available, in hooks max number of supported items
Safering SafePlus
IEC 60870-5-104 L3 L3 L3 L3
information data value read (R) note / scada GI group Meas. Meas. Meas. Meas.
object address type written (W) mult. unit glb 1 5 6 10 13 data point description REC603 RTU540 REC603 RTU540
1000/6000 AMI 0 ... +1 (R) 1000 A x - x - - - Phase current I1
N/A x /(4) N/A x (6)
1001/6001 AMI 0 ... +1 (R) 1000 A x - x - - - Phase current I2
1002/6002 AMI 0 ... +1 (R) 1000 A x - x - - - Phase current I3
1003/6003 AMI 0 ... +1 (R) 1000 A x - x - - - Earth current IE
1004/6004 AMI 0 ... +1 (R) 1000 A x - x - - - Average of phase current I1 Ø 15min
1005/6005 AMI 0 ... +1 (R) 1000 A x - x - - - Average of phase current I2 Ø 15min
1006/6006 AMI 0 ... +1 (R) 1000 A x - x - - - Average of phase current I3 Ø 15min
1007/6007 AMI 0 ... +1 (R) 1000 A x - x - - - Average of earth current IE Ø 15min
1008/6008 AMI 0 ... +1 (R) 1000 a x - x - - - Max. of phase current I1 max24h
1009/6009 AMI 0 ... +1 (R) 1000 A x - x - - - Max. of phase current I2 max24h
1010/6010 AMI 0 ... +1 (R) 1000 A x - x - - - Max. of phase current I3 max24h
1011/6011 AMI 0 ... +1 (R) 1000 A x - x - - - Max. of phase current I1 max LR
1012/6012 AMI 0 ... +1 (R) 1000 A x - x - - - Max. of phase current I2 max LR
1013/6013 AMI 0 ... +1 (R) 1000 A x - x - - - Max. of phase current I3 max LR
1014/6014 AMI 0 ... +1 (R) 100 kV x - x - - - Voltage V12
1015/6015 AMI 0 ... +1 (R) 100 kV x - x - - - Voltage V23
1016/6016 AMI 0 ... +1 (R) 100 kV x - x - - - Voltage V31
1017/6017 AMI 0 ... +1 (R) 100 kV x - x - - - Voltage V1
1018/6018 AMI 0 ... +1 (R) 100 kV x - x - - - Voltage V2
1019/6019 AMI 0 ... +1 (R) 100 kV x - x - - - Voltage V3
1020/6020 AMI 0 ... +1 (R) 100 kV x - x - - - Voltage VNE
1021/6021 AMI -1 ... +1 (R) 10000 kVA x - x - - - Apparent power S
1022/6022 AMI -1 ... +1 (R) 10000 kW x - x - - - Active power P
1023/6023 AMI -1 ... +1 (R) 10000 kVAr x - x - - - Reactive power Q
1024/6024 AMI -1 ... +1 (R) 1 - x - x - - - Power factor Cos Phi
1025/6025 AMI -1 ... +1 (R)) 100 Hz x - x - - - Frequency
1027/6027 SPI 1 (R) x - x - - - Load flow direction A
1028/6028 SPI 1 (R) x - x - - - Load flow direction B
1029/6029 AMI 0 ... +1 (R) 1000 A x - x - - - Max. of phase current I1 max7D
1030/6030 AMI 0 ... +1 (R) 1000 A x - x - - - Max. of phase current I2 max7D
1031/6031 AMI 0 ... +1 (R) 1000 A x - x - - - Max. of phase current I3 max7D
1032/6032 AMI 0 ... +1 (R) 1000 A x - x - - - Max. of phase current I1 max365D
1033/6033 AMI 0 ... +1 (R) 1000 A x - x - - - Max. of phase current I2 max365D
1034/6034 AMI 0 ... +1 (R) 1000 A x - x - - - Max. of phase current I3 max365D
1000/4000 FPI 0 ... +1000 (R) 1 A x - x - - - Phase current I1
x (4) N/A x (4) N/A
1001/4001 FPI 0 ... +1000 (R) 1 A x - x - - - Phase current I2
1002/4002 FPI 0 ... +1000 (R) 1 A x - x - - - Phase current I3
1003/4003 FPI 0 ... +1000 (R) 1 A x - x - - - Earth current IE
1004/4004 FPI 0 ... +1000 (R) 1 A x - x - - - Average of phase current I1 Ø 15min
1005/4005 FPI 0 ... +1000 (R) 1 A x - x - - - Average of phase current I2 Ø 15min
1006/4006 FPI 0 ... +1000 (R) 1 A x - x - - - Average of phase current I3 Ø 15min
1007/4007 FPI 0 ... +1000 (R) 1 A x - x - - - Average of earth current IE Ø 15min
1008/4008 FPI 0 ... +1000 (R) 1 A x - x - - - Max. of phase current I1 max24h
1009/4009 FPI 0 ... +1000 (R) 1 A x - x - - - Max. of phase current I2 max24h
1010/4010 FPI 0 ... +1000 (R) 1 A x - x - - - Max. of phase current I3 max24h
1014/4014 FPI 0 ... +100000 (R) 1 V x - x - - - Voltage V12
1015/4015 FPI 0 ... +100000 (R) 1 V x - x - - - Voltage V23
1016/4016 FPI 0 ... +100000 (R) 1 V x - x - - - Voltage V31
1017/4017 FPI 0 ... +100000 (R) 1 V x - x - - - Voltage V1
1018/4018 FPI 0 ... +100000 (R) 1 V x - x - - - Voltage V2
1019/4019 FPI 0 ... +100000 (R) 1 V x - x - - - Voltage V3
1020/4020 FPI 0 ... +100000 (R) 1 V x - x - - - Voltage VNE
1021/4021 FPI 0 ... +10000 (R) 1 kVA x - x - - - Apparent power S
1022/4022 FPI -10000 ... +10000 (R) 1 kW x - x - - - Active power P
1023/4023 FPI -10000 ... +10000 (R) 1 kVAr x - x - - - Reactive power Q
1024/4024 FPI -1 ... +1 (R) 1 - x - x - - - Power factor Cos Phi
1025/4025 FPI 0 ... +100 (R) 1 Hz x - x - - - Frequency
1027/4027 SPI 1 (R) x - x - - - Load flow direction A
1028/4028 SPI 1 (R) x - x - - - Load flow direction B
1029/4029 FPI 0 ... +1000 (R) 1 A x - x - - - Max. of phase current I1 max7D
1030/4030 FPI 0 ... +1000 (R) 1 A x - x - - - Max. of phase current I2 max7D
1031/4031 FPI 0 ... +1000 (R) 1 A x - x - - - Max. of phase current I3 max7D
1032/4032 FPI 0 ... +1000 (R) 1 A x - x - - - Max. of phase current I1 max365D
1033/4033 FPI 0 ... +1000 (R) 1 A x - x - - - Max. of phase current I2 max365D
1034/4034 FPI 0 ... +1000 (R) 1 A x - x - - - Max. of phase current I3 max365D
22
Valid only for Measurement package. − MV network analog data values:
− ABB REC615 specific:
SafeRing
IEC 60870-5-104 L3 L3
information data value read (R) note / scada GI group Measurement Measurement
object address type written (W) mult. unit glb 1 5 6 10 13 data point description REC615 REC615+RIO600
1000/3000 FPI 0 ... +1000 (R) 1 A x - x - - - Phase current I1
x (1) x (3)1001/3001 FPI 0 ... +1000 (R) 1 A x - x - - - Phase current I2
1002/3002 FPI 0 ... +1000 (R) 1 A x - x - - - Phase current I3
1003/2003/3003 FPI 0 ... +1000 (R) 3/1/1 A x - x - - - Earth current IE
2005/3005 FPI 0 ... +1000 (R) 1 A x - x - - - Average of phase current I2 ø15minN/A x (2)
2009/3009 FPI 0 ... +1000 (R) 1 A x - x - - - Max. of phase current I2 max24h
1014 FPII 0 ... +100000 (R) 1 V x - x - - - Voltage V12 x (1)
1015/3015 FPI 0 ... +100000 (R) 1 V x - x - - - Voltage V23 x (3)
1016 FPI 0 ... +100000 (R) 1 V x - x - - - Voltage V31
x (1)1017 FPII 0 ... +100000 (R) 1 V x - x - - - Voltage V1
1018 FPI 0 ... +100000 (R) 1 V x - x - - - Voltage V2
1019 FPII 0 ... +100000 (R) 1 V x - x - - - Voltage V3
1020/2020/3020 FPI 0 ... +100000 (R) 3/1/1 V x - x - - - Voltage VNE x (1)
x (3)
1021/3021 FPI -1 ... +10000 (R) 1 kVA x - x - - - Apparent power S
1022/3022 FPI -10000 ... +10000 (R) 1 kW x - x - - - Active power P
1023/3023 FPI -10000 ... +10000 (R) 1 kVAr x - x - - - Reactive power Q
1024/3024 FPI -1 ... +1 (R) 1 - x - x - - - Power factor Cos Phi
1025 FPI 0 ... +100 (R)) 1 Hz x - x - - - Frequency x (1)
- FPII POS/NEG (R) 1 - x - x - - - Load flow direction **** x (3)
930 DMI 0 ... +16 (R) 1 - x x - - - - Active Setting Group
x (1)931 SCS 1 (W) dir cmd - - - - - - Active SG 1 (Insulated network)
932 SCS 1 (W) dir cmd - - - - - - Active SG 1 (Compensated network)
933 SCS 1 (W) dir cmd - - - - - - Active SG 3 (Solidly earthed network)
IEC 60870-5-104 information object addresses (IOA):„data from the first (most left one) cable switch has IOA 10xx,from the second cable switch 20xx etc...“FPI floating point informationDMI digital measured informationSCS single commandx (3) available, in hooks max number of supported itemsN/A not applicable/available**** Sign of the 1022: POS = FORWARD (B) / NEG = BACKWARD (A)
Description on how the data are obtained: - spontaneously – data are sent automatically when their values change for pre-defined value - periodically – REC603: Medium Voltage analog values are sent at least once per 10 minutes – RTU540: Medium Voltage analog values are sent at least once per 10 minutes and Low Voltage
analog values at least once per 5 minutes
- interrogation commands: GI group description 0 global group - all signals 1 MV switches position and local/remote status 5 MV network analog values 6 LV network analog values (not valid for WIMO – use group 20 and ports 2406 and 2408) 10 MV network, distr. tr faults and SPARE inputs 13 Secondary devices status and errors
23
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