EKOR ORMAZABAL Manual [PDF]

Zitiervorschau

IG-159-GB

General Instructions

version 07

ekorRP PROTECTION, METERING AND CONTROL UNITS LIB 20.09.2012

Transformer Substations

Secondary Distribution Switchgear

Primary Distribution Switchgear

Protection and Automation

Low Voltage Boards

Distribution Transformers

Legal Deposit: 1457/2012

CAUTION! When MV equipment is operating, certain components are live, other parts may be in movement and some may reach high temperatures. Therefore, the use of this equipment poses electrical, mechanical and thermal risks. In order to ensure an acceptable level of protection for people and property, and in compliance with applicable environmental recommendations, Ormazabal designs and manufactures its products according to the principle of integrated safety, based on the following criteria: 

Elimination of hazards wherever possible.



Where elimination of hazards is neither technically nor economically feasible, appropriate protection functions are incorporated in the equipment.



Communication about remaining risks to facilitate the design of operating procedures which prevent such risks, training for the personnel in charge of the equipment, and the use of suitable personal protection equipment.



Use of recyclable materials and establishment of procedures for the disposal of equipment and components so that once the end of their service lives is reached, they are duly processed in accordance, as far as possible, with the environmental restrictions established by the competent authorities.

Consequently, the equipment to which the present manual refers complies with the requirements of section 11.2 of the forthcoming IEC standard 62271-1. It must therefore only be operated by appropriately qualified and supervised personnel, in accordance with the requirements of standard EN 50110-1 on the safety of electrical installations and standard EN 50110-2 on activities in or near electrical installations. Personnel must be fully familiar with the instructions and warnings contained in this manual and in other recommendations of a more general nature which are applicable to the situation according to current legislation. The above must be carefully observed, as the correct and safe operation of this equipment depends not only on its design but also on general circumstances which are in general beyond the control and responsibility of the manufacturer. More specifically: 

The equipment must be handled and transported appropriately from the factory to the place of installation.



All intermediate storage should occur in conditions which do not alter or damage the characteristics of the equipment or its essential components.



Service conditions must be compatible with the equipment rating.



The equipment must be operated strictly in accordance with the instructions given in the manual, and the applicable operating and safety principles must be clearly understood.



Maintenance should be performed properly, taking into account the actual service and environmental conditions in the place of installation.

The manufacturer declines all liability for any significant indirect damages resulting from violation of the guarantee, under any jurisdiction, including loss of income, stoppages and costs resulting from repair or replacement of parts. Guarantee The manufacturer guarantees this product against any defect in materials and operation during the contractual period. In the event that defects are detected, the manufacturer may opt either to repair or replace the equipment. Improper handling of this equipment and its repair by the user shall constitute a violation of the guarantee. Registered Trademarks and Copyrights All registered trademarks cited in this document are the property of their respective owners. The intellectual property of this manual belongs to the manufacturer.

In view of the constant evolution in standards and design, the characteristics of the elements contained in this manual are subject to change without prior notification. The validity of these characteristics, as well as the availability of components, are subject to confirmation by Ormazabal’s Technical - Commercial Department.

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CONTENTS 1.

GENERAL DESCRIPTION ............................................................................................ 5 1.1. GENERAL FUNCTIONAL CHARACTERISTICS ......................................................... 6 1.2. PARTS OF THE UNIT.................................................................................................. 7 1.3. COMMUNICATIONS AND PROGRAMMING SOFTWARE ....................................... 11

2.

APPLICATIONS .......................................................................................................... 13 2.1. TRANSFORMER PROTECTION ............................................................................... 13 2.2. GENERAL PROTECTION ......................................................................................... 14 2.3. LINE PROTECTION................................................................................................... 15

3.

PROTECTION FUNCTIONS ....................................................................................... 16 3.1. OVERCURRENT ....................................................................................................... 16 3.2. THERMOMETER (EXTERNAL TRIP) ....................................................................... 19 3.3. EARTH ULTRASENSITIVE DEVICE ......................................................................... 19

4.

METERING FUNCTIONS ............................................................................................ 21 4.1. CURRENT.................................................................................................................. 21

5.

SENSORS ................................................................................................................... 21 5.1. CURRENT SENSORS ............................................................................................... 21

6.

TECHNICAL CHARACTERISTICS ............................................................................. 26 6.1. RATED VALUES ........................................................................................................ 26 6.2. MECHANICAL DESIGN ............................................................................................. 26 6.3. INSULATION TESTS ................................................................................................. 26 6.4. ELECTROMAGNETIC COMPATIBILITY ................................................................... 26 6.5. CLIMATIC TESTS ...................................................................................................... 27 6.6. MECHANICAL TESTS ............................................................................................... 27 6.7. POWER TESTS ......................................................................................................... 27 6.8. CE CONFORMITY ..................................................................................................... 27

7.

PROTECTION, METERING AND CONTROL MODELS ............................................ 28 7.1. DESCRIPTION OF MODELS vs. FUNCTIONS ......................................................... 28 7.2. RELAY CONFIGURATOR ......................................................................................... 30 7.3. ekorRPT UNITS ......................................................................................................... 31 7.4. ekorRPG UNITS......................................................................................................... 42

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8.

SETTING AND HANDLING MENUS ........................................................................... 51 8.1. KEYPAD AND ALPHANUMERIC DISPLAY .............................................................. 51 8.2. DISPLAY .................................................................................................................... 52 8.3. PARAMETER SETTING ............................................................................................ 54 8.4. TRIP RECOGNITION ................................................................................................. 59 8.5. ERROR CODES ......................................................................................................... 60 8.6. MENU MAP (QUICK ACCESS) ................................................................................. 61

9.

MODBUS PROTOCOL FOR ekorRP RANGE UNITS ................................................ 64 9.1. READ / WRITE FUNCTIONS ..................................................................................... 65 9.2. PASSWORD-PROTECTED REGISTER WRITING ................................................... 66 9.3. CRC GENERATION ................................................................................................... 66 9.4. REGISTER MAP ........................................................................................................ 67

10.

ANNEX A ..................................................................................................................... 71

11.

ANNEX B ..................................................................................................................... 77

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1. GENERAL DESCRIPTION The ekorRP range of protection, metering and control units brings together an entire family of different equipment, which depending on the model, may incorporate protection functions as well as other functions such as local control, remote control, electrical parameter metering, automation, etc., related to the current and future automation, control and protection needs of Transformer and Switching Substations. Its use in Ormazabal’s CGMCOSMOS, CGM-CGC and CGM.3 cubicle systems allows the configuration of customised products for meeting the diverse needs of the different installations. The ekorRP protection, metering and control units have been designed to meet the national and international standard requirements and recommendations that are applied to each of the parts that make up the unit: EN 60255, EN 61000, EN 62271-200, EN 60068, EN 60044, IEC 60255, IEC 61000, IEC 62271-200, IEC 60068, IEC 60044

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Designed to be integrated in a cubicle, the ekorRP units also provide the following advantages over conventional devices:  Reduction in handling of interconnections when installing the cubicle. The only connection required is limited to MV cables.  Minimisation of the need to install control boxes on the cubicles.  Avoidance of wiring and installation errors; minimisation of commissioning time.  All the units are factory installed, adjusted and checked; each piece of equipment (relay + control + sensors) also undergoes a comprehensive check before being installed. The final unit tests are carried out once the unit is incorporated in the cubicle before delivery.  They protect a broad power range with the same model (e.g.: ekorRPG from 160 kVA up to 15 MVA, in CGMCOSMOS system cubicles).

1.1. GENERAL FUNCTIONAL CHARACTERISTICS All the relays of the ekorRP units include a microprocessor for processing the signals from the metering sensors. They process current metering by eradicating the influence of transient phenomena and calculate the magnitudes needed for to carry out protection functions. In addition, the efficient electrical metering values, which provide the instantaneous value of these installation parameters, are determined. They are equipped with keypad for local display, setup and operation of the unit, as well as communication ports to handle these functions from a computer, whether locally or remotely. A user-friendly design has been employed, so that the use of the various menus is intuitive. The current is measured by means of several current sensors with a high transformation ratio, making it possible for the same equipment to detect a wide range of power levels. These transformers or current sensors maintain the accuracy class in all of their rated range.

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The unit contains an events log where all of the latest trips made by the protection functions are registered. In addition, the total number of operations is saved as well as the unit's settings parameters. The local interface uses menus to provide the instantaneous values of the current metering for each phase and zero-sequence current, as well as the setting parameters, trip motives, etc. They can also be accessed via the communication ports. From a maintenance perspective, the ekorRP units have a series of features that reduce the time and the possibility of errors in the test and service restoration tasks. The main features include some toroidal-core current transformers with larger diameters and test connections; accessible and disconnectable terminal blocks for tests using current injection; and built-in test contacts, even in the basic models.

1.2. PARTS OF THE UNIT The parts that form the ekorRP protection, metering and control unit include the electronic relay, current sensors, power supply and test board, selfpowered toruses (only for selfpowered models) and the bistable trigger.

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Figure 1.2: Example of ekorRPT unit installation in fused protection cubicles

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1.2.1. Electronic Relay The electronic relay has keys and a display to set and view the protection, metering and control parameters. It includes a seal on the SET key to ensure that once the settings have been made they cannot be changed unless the seal is broken. The protection trips are registered on the display with the following parameters: reason for tripping, fault current value, tripping time and the time and date the event occurred. Errors in the unit, such as a switch failure, incorrect thermometer connection, low battery, etc., are also shown permanently. The 'On' LED is activated when the equipment receives power from an external source or the self-powered transformers. In this situation, the unit is operational to perform the protection functions. If the 'On' LED is not activated, only the unit's parameters can be viewed and/or adjusted (function exclusively assigned to the relay's internal battery). The current analog signals are conditioned internally by small and very accurate transformers that isolate the electronic circuits from the rest of the installation. The equipment has two communication ports, one on the front used for local configuration (RS232), and another one on the rear used for remote control (RS485). The standard communication protocol for all models is MODBUS. Others may be used depending on the application.

1.2.2. Current Sensors The current sensors are toroidal-core current transformers with a 300/1 A or 1000/1 A ratio, depending on the models. Their range of action is the same as the switchgear where they are installed. They are factory-installed in the cubicle bushings, which significantly simplifies the on-site assembly and connection. This way, once the MV cables are connected to the cubicle, the installation protection is operational. There are no sensor installation errors, due to earthing grids, polarities, etc. since they are previously installed and tested at the factory.

Current sensors

Bushing

The inner diameter of the toroidal-core current transformers is 82 mm, which means they can be used in cables of up to 400 mm2 without any problems for performing maintenance testing afterwards. If the equipment is selfpowered, the toroidal transformers are equipped with some anchorage points to place them in the same area as the metering transformers, thus forming a single,

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compact block. These transformers supply 1 W when the primary current is ≥ 5 A. This power is enough to allow the units to function correctly. All the current sensors have an integrated protection against the opening of secondary circuits, which prevents overvoltages.

1.2.3. Power Supply and Test Board The selfpowered equipment's power supply board prepares the selfpowered transformers' signal and converts it into a DC signal to safely power the equipment. The transformers permanently feed power from 5 to 630 primary amps to the board. It also has a 230 Vac input with 10 kV level of insulation. This input is for direct connection to the Transformer Substation's LVB. The power supply board of models with auxiliary power supply has an input for connecting both the AC (24 to 110 Vac) and DC (24 to 125 Vdc) power supply. The board prepares the signal, converting it into a DC signal suitable for safely powering the equipment. Furthermore, both types of board have a built-in protection trip test circuit as well as connectors for carrying out current injection functional tests during maintenance and checking operations. The units also have a protection device for absorbing the excess energy produced by the transformers when there are short-circuits up to 20 kA.

1.2.4. Bistable trigger The bistable trigger is an electromechanical actuator that is integrated into the switch driving mechanism. This trigger acts upon the switch when there is a protection trip. It is characterised by the low actuation power it requires for tripping. This energy is received in the form of pulses lasting 50 ms and with an amplitude of 12 V. When there is a fault, these pulses are repeated every 400 ms to ensure that the switch opens.

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1.3. COMMUNICATIONS AND PROGRAMMING SOFTWARE All the ekorRP units have two serial communication ports. The standard RS232 front port is used to set the local parameters with the ekorSOFT program[1]. At the rear, there is an RS485 port which is used for remote control. The standard communication protocol implemented in all equipment is MODBUS-RTU (binary) transmission mode, although other specific protocols can be implemented depending on the application. This protocol has the advantage of greater information density than other modes, resulting in a higher transmission rate for the same communication speed. Each message must be transmitted as a continuous string and the silences are used to detect the end of the message.

[1]

For more information about the ekorSOFT program, consult Ormazabal’s IG-155 document.

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The ekorSOFT setup program has three main operating modes:  Display: indicates the unit status, including electrical measurements, current settings, date and time.  User Settings: protection parameter change is enabled.  Event Log: the parameters of the final and penultimate trip are shown as well as the total number of trips made by the protection unit. Minimum system requirements for installing and using the ekorSOFT software:  Processor: Pentium II  RAM: 32 Mb  Operating System: MS WINDOWS  CD-ROM / DVD  RS-232 serial port

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2. APPLICATIONS 2.1. TRANSFORMER PROTECTION The distribution transformers require various protection functions. Their selection depends primarily on the power and level of responsibility they have in the installation. As an example, the protection functions that must be implemented to protect distribution transformers with a power rating between 160 kVA and 2 MVA are the following:  50  Instantaneous phase overcurrent. Protects against shortcircuits between phases in the primary circuit, or high value short-circuit currents between phases on the secondary side. This function is performed by the fuses when the protection cubicle does not include a circuit-breaker.  51  Phase overload. Protects against excessive overloads, which can deteriorate the transformer, or against short-circuits in several turns of the primary windings.  50N  Instantaneous earth fault. Protects against phase to earth short-circuits or secondary winding short-circuits, from the primary interconnections and windings.  51N  Earth Leakage. Protects against highly resistive faults from the primary to earth or to the secondary.  49T  Thermometer. Protects excessive transformer temperature.

against

Protection units that include the above mentioned functions:

Unit ekorRPT ekorRPG

System CGMCOSMOS

Systems CGM-CGC / CGM.3

Type of cubicle Fuse-combination switch

Power ranges to protect

Power ranges to protect

50 kVA...2000 kVA

50 kVA...1250 kVA

Circuit-breaker

50 kVA...15 MVA

50 kVA...25 MVA

See tables § 7.3.2 and § 7.4.2

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2.2. GENERAL PROTECTION The client supply installations require general protection to ensure that an installation is disconnected from the rest of the network in the event of a fault. In this way, the Utility's supply line will remain energised and other clients will remain unaffected. It also protects the client's installation by disconnecting it from the power source in the event of a fault. In this type of protection, all the faults detected in the substation's main circuit breaker should be simultaneously detected in the transformer substations so that they can be cleared before the line trips (protection selectivity).  50  Instantaneous phase overcurrent. Protects against short-circuits between phases.  51  Phase overload. Protects against excessive overloads, which can deteriorate the installation. It is also used as a limiting device to control the supply's maximum power.  50N  Instantaneous earth fault. Protects against phase-to-earth short-circuits.  51N  Earth leakage. Protects against highly resistive faults between phase and earth. The following protection units provide the above-mentioned functions: System CGMCOSMOS

Systems CGM-CGC / CGM.3

Unit ekorRPT

Type of cubicle Fuse-combination switch

Power ranges to protect 50 kVA...2000 kVA

Power ranges to protect 50 kVA...1250 kVA

ekorRPG

Circuit-breaker

50 kVA...15 MVA

50 kVA...25 MVA

See tables § 7.3.2 and § 7.4.2

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2.3. LINE PROTECTION The purpose of the line protection is to isolate this part of the network in case of fault, without it affecting the rest of the lines. Generally, it covers any fault that originates between the Substation, or Switching Substation, and the consumption points. The types of fault that occur in these areas of the network primarily depend on the nature of the line, overhead line or cable and the neutral used. In networks with overhead lines, most faults are transitory. Hence, many line reclosings are effective. On the other hand, in case of phase-to-earth faults in overhead lines, when the ground resistance is very high, the zero-sequence fault currents have a very low value In these cases, an ‘ultrasensitive’ neutral current detection is required. The underground cables have earth coupling capacities, which causes the single phase faults to include capacitive currents. This phenomenon makes detection difficult in isolated or resonant earthed neutral networks and thus requires the use of the directional function. Line protection is mainly accomplished by the following functions:  50  Instantaneous phase overcurrent. Protects against short-circuits between phases.  51  Phase overload. Protects against excessive overloads, which can deteriorate the installation.  50N  Instantaneous earth fault. Protects against phase-to-earth short-circuits.  51N  Earth leakage. Protects against highly resistive faults between phase and earth.  50Ns  Ultrasensitive earth instantaneous overcurrent. Protects against phase to earth short-circuits of very low value.  51Ns  Ultrasensitive earth leakage protection. Protects against highly resistive faults between phase and earth of very low value. Unit that includes the above mentioned functions: CGMCOSMOS / CGM-CGC / CGM.3 systems Unit ekorRPG

Type of cubicle Circuit-breaker

Maximum rated current 630 A

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3. PROTECTION FUNCTIONS 3.1. OVERCURRENT The units have an overcurrent function for each one of the phases (3 x 50-51) and, depending on the model, they may have another one for earth (50N-51N). The implemented protection curves are the ones listed in standard IEC 60255. Overcurrent functions that can be performed depending on the model:  Overload multicurve protection for phases (51).  Protection of phase-to-earth multicurve faults (51N).  Short-circuit protection (instantaneous) at a defined time between phases (50).  Short-circuit protection (instantaneous) at a defined time between phase and earth (50N). Meaning of the curve parameters for phase settings: t(s) Theoretical tripping time for a fault which evolves with a constant current value. I Actual current flowing through the phase with the largest amplitude. In Rated setting current. I> Withstand overload increment. K Curve factor. I>> Short-circuit current factor (instantaneous). T>> Short-circuit delay time (instantaneous).  Pick-up current value of NI, VI, and EI curves = 1.1 x In x I>  Pick-up current value of DT curve = 1.0 x In x I>  Instantaneous pick-up current value = In x I> x I>> In the case of earth settings, the parameters are similar to the phase settings. Each of them is described below. to(s)  Theoretical tripping time for an earth fault which evolves with a constant current value I0. Io  Actual current flowing to earth. In  Rated phase setting current. Io>  Withstand earth leakage factor (phase). Ko  Curve factor. Io>>  Short-circuit current factor (instantaneous). To>>  Short-circuit delay time (instantaneous).  Pick-up current value of NI, VI, and EI curves = 1,1 x In x Io>  Pick-up current value of DT curve = 1,0 x In x Io>  Instantaneous pick-up current value = In x Io> x Io>>

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3.2. THERMOMETER (EXTERNAL TRIP) The equipment has an input for connecting volt-free contacts and tripping the switch. This input is protected against erroneous connections (e.g. 230 Vac) showing an error code on the display when this anomaly occurs. The switch trips when the volt-free contact is closed for at least 200 ms. This prevents untimely tripping due to external disturbances. External tripping protection is disabled when all of the overcurrent protection functions are disabled (for firmware version 18 or later). In this situation, the relay will not trip the switch but a flashing arrow will appear at the top of the display screen to show that the external trip contact is closed (see section §8.4). The purpose of this function is to protect the transformers' maximum temperature. The trip input is associated to contact of the thermometer which measures the oil's temperature and when the maximum set value is reached, its associated contact closes and the switch trips. Unlike conventional coils, it has the advantage of not having low-voltage network connections with the consequent overvoltages generated in the control circuits. This trip input can also be associated to output contacts of remote control terminals, alarms and auxiliary relays responsible for opening the switch.

3.3. EARTH ULTRASENSITIVE DEVICE This protection corresponds to a particular type of overcurrent protections. It is primarily used in networks with isolated or resonant earthed neutral, where the phase-to-earth fault current value depends on the system cable capacity value and on the point in which the fault occurs. Generally, in Medium Voltage private installations with short cable stretches, simply determine a minimum zerosequence current threshold at which the protection must trip.

0-sequence toroidal transformer

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The current flowing to earth is detected using a toroidal-core current transformer which covers the three phases. In this way, the metering is independent from the phase current, thus avoiding errors in the phase metering transformers. In general, this type of protection must be used when the set earth current is less than 10% of the rated phase current (for example: for a rated phase current of 400 A with earth faults below 40 A). On the other hand, in the lines, whose cable stretches are usually long, it is necessary to identify the fault direction. Otherwise, trips can occur due to capacitive currents from other lines, when there is not any fault in the line. The available curves are: normally inverse (NI), very inverse (VI), extremely inverse (EI) and defined time (DT). The setting parameters are the same as in the earth faults of the overcurrent functions (section §3.1 Overcurrent), with the exception that factor Io> is replaced with the value directly in amps Ig. This way, this parameter can be set to very low earth current values, regardless of the phase setting current.  Pick-up current value of NI, VI, and EI curves = 1.1x Ig  Pick-up current value of DT curve = Ig  Instantaneous pick-up current value = Ig x Io>>

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4. METERING FUNCTIONS 4.1. CURRENT The current values measured by the ekorRP units correspond to the efficient values of each of the phases I1, I2 and I3. Eight samples from a halfperiod are used and the mean of five consecutive values is calculated. This measurement is updated every second. It offers Class 1 meter accuracy, from 5 A up to 120% of the current sensor’s maximum rated range. The zero-sequence current measurement Io is performed in the same way as the phase currents.  Current meters: I1, I2, I3 and Io

5. SENSORS 5.1. CURRENT SENSORS The electronic current transformers are designed for optimal adaptation to digital equipment technology, with a slight modification of the secondary interface. Therefore, the protection, metering and control equipment for these sensors operate with the same algorithms and with the same consistency as conventional devices. The low power outputs from the sensors can be adapted to standard values using external amplifiers. In this way, you can use conventional equipment or electronic relays.

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Main advantages derived from the use of sensor based systems:  Small volume.The decreased power consumption of these transformers allows their volume to be drastically reduced.  Improved accuracy. Signal acquisition is much more accurate due to high transformation ratios.  Wide range. When there are power increases in the installation, the sensors do not have to be replaced with ones having a greater ratio.  Greater safety. The open-air live parts disappear, increasing personnel safety.  Greater reliability. The full insulation of the whole installation provides greater levels of protection against external agents.  Easy maintenance. The sensors do not need to be disconnected when the cable or cubicle is being tested.

5.1.1. Functional Characteristics of Current Sensors The current sensors are toroidal-core current transformers with a high transformation ratio and low rated burden. These sensors are encapsulated in self-extinguishing polyurethane resin. Phase toroidal current transformers Ratio Metering range Protection Metering Burden Thermal current Dynamic current Saturation current Frequency Insulation Outer diameter Inner diameter Height Weight Polarity Encapsulation Thermal class Reference standard

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Range 5-100 A 300 / 1 A 5 A to 100 A Extd. 130% 5P20 Class 1 0,18 VA 20 kA 50 kA 7,800 A 50-60 Hz 0,72 / 3 kV 139 mm 82 mm 38 mm 1.350 kg S1 – blue, S2 – brown Self-extinguishing polyurethane B (130 ºC) IEC 60044-1

Range 15-630 A 1000 / 1 A 15 A to 630 A Extd. 130% 5P20 Class 1 0.2 VA 20 kA 50 kA 26,000 A 50-60 Hz 0,72 / 3 kV 139 mm 82 mm 38 mm 1.650 kg S1 – blue, S2 – brown Self-extinguishing polyurethane B (130 ºC) IEC 60044-1

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Toroidal power transformers Ratio Power supply range Thermal current Dynamic current Power Frequency Insulation Outer dimensions Inner dimensions Height Weight Polarity Encapsulation Thermal class Phase toroidal transformer

ekorRPT / ekorRPG 200/1 A with centre tap (100 + 100 A) 5 A to 630 A 20 kA 50 kA 0.4 VA to 5 A 50-60 Hz 0,72 / 3 kV 139 mm 82 mm 38 mm 1.240 kg S1 – blue, S2 – brown Self-extinguishing polyurethane B (130ºC) 0-sequence toroidal transformer

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5.1.2. Vector Sum/Zero-SequenceWiring The wiring of the aforementioned transformers is performed in two different ways, depending on whether they have a zero-sequence toroidal current transformer installed or not. As a general rule, the zero-sequence toroidal transformer is used when the earth fault current is a below 10% of the phase current rating. R

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S

T

DETECTION OF EARTH CURRENT BY VECTOR SUM

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Zero-sequence Toroidal Current Transformers

Ratio Metering range Protection Metering Burden Thermal current Dynamic current Saturation current Frequency Insulation Outer dimensions Inner dimensions Height Weight Polarity Encapsulation Thermal class Reference standard

Range 5-100 A

Range 15-630 A

300 / 1 A 0.5 A to 50 A Extd. 130% 5P10 Class 3 0.2 VA 20 kA 50 kA 780 A 50-60 Hz 0,72 / 3 kV 330 x 105 mm 272 x 50 mm 41 mm 0.98 kg S1 – blue, S2 – brown Self-extinguishing polyurethane B (130 ºC) IEC 60044-1

1000 / 1 A 0.5 A to 50 A Extd. 130% 5P10 Class 3 0.2 VA 20 kA 50 kA 780 A 50-60 Hz 0,72 / 3 kV 330 x 105 mm 272 x 50 mm 41 mm 0.98 kg S1 – blue, S2 – brown Self-extinguishing polyurethane B (130 ºC) IEC 60044-1

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6. TECHNICAL CHARACTERISTICS 6.1. RATED VALUES Power supply

Current inputs

Accuracy Frequency Output contacts Temperature Communications

AC DC Selfpowered Consumption Primary phase Earth

Voltage Current Switching power Operating Storage Front port

24 Vac...110 Vac+/-30% 24 Vdc...125 Vdc +/-30% >5 A, 230 Vac +/-30% < 1 VA 5 A...630 A (depending on model) 0.5 A..0.50 A (depending on model) 20 kA / 50 kA 0.1 Ω 5% (minimum 20 ms) Class 1 / 5P20 50 Hz; 60 Hz +/-1% 250 Vac 10 A (AC) 500 VA (resistive load) - 40 ºC to + 70 ºC - 40 ºC to + 70 ºC DB9 RS232

Rear port Protocol

RS485 (5 kV) – RJ45 MODBUS (RTU)

I thermal/dynamic Impedance Time delay Metering / Protection

6.2. MECHANICAL DESIGN IP rating

Dimensions (h x w x d): Weight Wiring

Terminals In cubicle

IP2X IP3X IP4X (according to IEC 60255-27) IK06 (according to EN 50102) 146 x 47 x 165 mm 0.3 kg 0.5...2.5 mm2

Cable/Termination

6.3. INSULATION TESTS IEC 60255-5

Insulation resistance Electric strength Voltage impulses:

standard differential

500 VDC: > 10 G 2 kVac; 50 Hz; 1 min 5 kV; 1.2/50 s; 0.5 J 1 kV; 1.2/50 s; 0.5 J

6.4. ELECTROMAGNETIC COMPATIBILITY IEC 60255-11 IEC 60255-22-1 IEC 60255-22-2 IEC 60255-22-3 IEC 60255-22-4 IEC 60255-22-5

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Voltage dips Ripple Damped wave 1 MHz Electrostatic discharges (IEC 61000-4-2, class IV) Radiated fields (IEC 61000-4-3, class III) Bursts - Fast transients (IEC 61000-4-4) Overvoltage pulses (IEC 61000-4-5)

200 ms 12 % 2.5 kV; 1 kV 8 kV air 6 kV contact 10 V/m ± 4 kV 4 kV; 2 kV

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IEC 60255-22-6

Induced radio frequency signals (IEC 61000-4-6) Magnetic fields

IEC 61000-4-8 IEC 61000-4-12 IEC 60255-25

Sinusoidal damped wave Electromagnetic emissions (EN61000-6-4)

150 kHz..0.80 MHz 100 A/m; 50 Hz constant 1000 A/m; 50 Hz short- time (2 s) 2.5 kV; 1 kV 150 kHz to 30 MHz (conducted) 30 MHz to 1 GHz (radiated)

6.5. CLIMATIC TESTS IEC 60068-2-1

Slow changes. Cold

IEC 60068-2-2

Slow changes. Heat

IEC 60068-2-78 IEC 60068-2-30

Damp heat, continuous test Damp heat cycles

- 40 ºC; 16 hrs. - 40 ºC; 16 hrs. + 60 ºC; 16 hrs. + 70 ºC; 16 hrs. + 40 ºC; 93%; 10 days + 55 ºC; 6 cycles

6.6. MECHANICAL TESTS IEC 60255-21-1 IEC 60255-21-2 IEC 60255-21-3

Sinusoidal vibration. Response Sinusoidal vibration. Endurance Impacts. Response Impact. Endurance Shock. Endurance Seismic tests

10 - 150 Hz; 1 g 10 - 150 Hz; 2 g 11 ms; 5 g 11 ms; 15 g 16 ms; 10 g 1 - 38 MHz, 1g vertical, 0.5 g horizontal

6.7. POWER TESTS IEC 60265 IEC 60265 IEC 60265 IEC 60056

No-load cable making and breaking Mainly active load making and breaking Earth faults No-load transformer making and breaking Short-circuit making and breaking

24 kV/50 A/ cosφ = 0.1 24 kV/630 A/ cosφ = 0,7 24 kV/200 A/50 A 13.2 kV /250 A/1250 kVA 20 kA / 1s

6.8. CE CONFORMITY This product complies with the European Union directive 2004/108/EC on electromagnetic compatibility, and with the IEC 60255 international regulations. The ekorRP unit has been designed and manufactured for use in industrial areas, in accordance with EMC standards. This compliance results from a test performed according to article 10 of the directive, and included in protocol CE26/08-43-EE-1.

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GENERAL INSTRUCTIONS FOR ekorRP PROTECTION, METERING AND CONTROL UNITS

7. PROTECTION, METERING AND CONTROL MODELS 7.1. DESCRIPTION OF MODELS vs. FUNCTIONS ekorRPT Distribution transformer protection unit installed in fuse-combination switch cubicles. The electronic unit performs all the protection functions except for the high value polyphase short-circuits that occur in the transformer’s primary. It has inputs and outputs for switch monitoring and control. The unit can protect a power range from 50 kVA up to 2000 kVA in CGMCOSMOS system cubicles and from 50 kVA up to 1250 kVA in CGM-CGC and CGM.3 system cubicles.

ekorRPG Distribution general protection unit installed in circuit-breaker cubicles. The main usage applications are: general protection of lines, private installations, transformers, capacitor stacks, etc. They can protect a power range from 50 kVA up to 400 kVA (630 kVA for CGM-CGC and CGM.3 system cubicles), when they include toroidal-core current transformers from 5 A to 100 A. With 15 A to 630 A toroidal-core current transformers, they offer a power range between 160 kVA and 15 MVA (25 MVA for CGM-CGC and CGM.3 system cubicles).

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IG-159-GB version 07 20.09.2012

Protection, Metering and Control Units ekorRP General Phase current sensors Earth (zero-sequence) current sensor Voltage sensors Digital Inputs Digital outputs Power supply 24 Vdc to 125 Vdc / 24 Vac to 110 Vac Self powered (> 5 A, + 230 Vac +/- 30%) Protection Phase overcurrent (50-51) Earth leakage overcurrent (50N-51N) Ultrasensitive earth leakage protection (50Ns-51Ns) Thermometer (49T) Communications MODBUS-RTU PROCOME RS-232 configuration port RS-485 port for remote control ekorSOFT setup and monitoring program Indications Tripping cause indication Error display Test Test blocks for current injection Output contact for test Measurements Current Presence / Absence of voltage

ekorRPG

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ekorRPT

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3 Op No 2 2 Op Op

3 Op No 2 2 Op Op

Yes Op Op Yes

Yes Op Op Yes

Yes No Yes Yes Op

Yes No Yes Yes Op

Yes Yes

Yes Yes

Yes Yes

Yes Yes

Yes No

Yes No

Op - Optional

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GENERAL INSTRUCTIONS FOR ekorRP PROTECTION, METERING AND CONTROL UNITS

7.2. RELAY CONFIGURATOR NOTE Not all combinations resulting from this configurator are possible. For the availability of other models, please consult Ormazabal's Technical Commercial Department. To select the ekorRP unit on the basis of the installation characteristics, the following configurator will be used: ekorRP

Type: G – For protection cubicle with circuit-breaker T – For fuse protection cubicle Protection functions: 10 – Three phases (3 x 50/51) 20 – Three phases and neutral (3 x 50/51 + 50N/51N) 30 – Three phases and sensitive neutral (3 x 50/51 + 50Ns/51Ns) Toroidal-core current transformers: 0 – Without toruses 1 – Range 5-100 A 2 – Range 15-630 A Power supply: A – Self powered B – Auxiliary power supply (Battery, UPS, etc.) Example: In the case of a selfpowered relay for a protection cubicle with a circuit-breaker, with functions 3 x 50/51 + 50Ns/51Ns and toroidal-core current transformers with a range of 5-100 A, the corresponding configurator would be ekorRPG-301A.

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7.3. ekorRPT UNITS 7.3.1. Functional description The ekorRPT protection, metering and control unit is used for the protection of distribution transformers. It is installed in fuse-combination switch cubicles so the electronic system performs all the protection functions, except high polyphase short-circuit values, which are cleared by the fuses. When an overcurrent that is within the values that the load break switch can open is detected, the relay acts upon a low power bistable trigger that opens the switch. If the fault current is greater than the breaking capacity of the load break switch[2], the switch trip is blocked so that the fuses will blow. On the other hand, the equipment is disconnected and the fuses do not remain energised.

 TRANSFORMER PROTECTION

 GENERAL PROTECTION (MV client supply)

[2 ]

1200 A for CGMCOSMOS-P, 480 A for CGM-CMP-F, 36 kV range, and CGM.3 and 300 A for CGM-CMP-F, 24 kV range.

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7.3.2. Technical Characteristics The ekorRPT unit is used to protect the following transformer power ratings. CGMCOSMOS System Line voltage

( )

[kV] 6,6 10 13,8 15 20

Fuse Rated Voltage [kV] 3/7,2 6/12 10/24 10/24 10/24

MINIMUM Transformer Power Fuse Rating [A] 16 10 16 16 16

[kVA]

MAXIMUM Transformer Power Fuse Rating [A] ( )

50 100 100 125 160

160 ¹ 160 (¹) 100 125 (²) 125

[kVA] 1250 1250 1250 1600 2000

¹ 442 mm cartridge, ² 125 A SIBA SSK Fuse

( )

CGM-CGC / CGM.3 System Line voltage

( )

[kV] 6,6 10 13,8 15 20 25 30

Fuse Rated Voltage [kV] 3/7,2 6/12 10/24 10/24 10/24 24/36 24/36

MINIMUM Transformer Power Fuse Rating [A] 16 16 10 16 16 25 25

[kVA] 50 100 100 125 160 200 250

MAXIMUM Transformer Power Fuse Rating [A] ( )

160 ¹ 125 63 63 63 80 (2) 80 (2)

[kVA] 1000 1250 800 1000 1250 2000 2500

¹ 442 mm cartridge SIBA SSK fuse (check)

(2)

Selection process for the ekorRPT unit protection parameters in CGMCOSMOS-P cubicles: 1. Determine the required fuse rating to protect the transformer in accordance with the fuse table in Ormazabal’s document IG-078. The maximum ratings that can be used are 160 A for voltages up to and including 12 kV, and 125 A for voltages up to and including 24 kV. 2. Calculate the transformer rated current In = S/3xUn. 3. Define the continuous overload level I>. Normal values in transformers of up to 2000 kVA are 20% for distribution installations and 5% for power generation installations. 4. Select the transitory overload curve. Coordination between relay curves and LV fuses is performed with the EI type curve. 5. Define the delay time in transitory overload K. This parameter is defined by the transformer’s thermal constant. This way, the greater the constant, the longer it takes for the transformer’s temperature to increase under an overload condition; and therefore, the protection trigger can be delayed longer. The usual value for distribution transformers is K = 0.2, which means that it trips in 2 s if the overload is 300% in the EI curve. 6. Short-circuit level I>>. The maximum value of the transformer’s magnetisation current must be determined. The current peak produced when a no-load transformer is connected, due to the effect of a magnetised nucleus, is several times greater than the rated current. This peak value, up to 12 times the rated value (10 times for more than

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1000 kVA) has a very high harmonic content, so its fundamental 50 Hz component is much less. Therefore, a usual setting value for this parameter is between 7 and 10. 7. Instantaneous time delay T>>. This value corresponds with the protection trip time in the event a short-circuit occurs. It depends on the coordination with other protections and the usual values are between 0.1 and 0.5 s. If the short-circuit value is high, the fuses will act in the time determined by their characteristic curve. 8. Determine the current value in case of secondary three-phase short-circuit. This fault must be cleared by the fuses, and it corresponds with the intersection point’s maximum value between the relay and the fuse curves. If the intersection point is greater than the secondary short-circuit value, the settings must be adjusted to meet this requirement. To select the ekorRPT unit protection parameters in CGM-CMP-F and CGM.3-P cubicles, the steps to follow are similar to those proposed in the paragraphs above, except for the first step. The fuse rating required to protect the transformer is determined according to the fuse table of Ormazabal’s documents IG-034 and IG-136 respectively. Please take into consideration that the minimum protection powers are listed in the table above. In case of protecting a transformer with following characteristics in CGMCOSMOS cubicle system: S = 1250 kVA, Un =15 kV and Uk = 5% Follow the procedure below for proper coordination between the fuses and the protection relay:  Fuse selection according to IG-078. 10/24 kV 125 A fuse  Rated current. In = S/3 x Un = 1250 kVA/3 x 15 kV  48 A  Continuous withstand overload 20%. In x I> = 48 A x 1.2  58 A  Extremely Inverse Curve type. E.I.  Transitory overload factor. K =0.2  Short-circuit level. In x I> x I>> = 48 A x 1.2 x 7  404 A  Instantaneous time delay T>> = 0,4 s  Secondary short-circuit. Ics = In x 100/ Uk = 48 A x 100 / 5  960 A

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GENERAL INSTRUCTIONS FOR ekorRP PROTECTION, METERING AND CONTROL UNITS

Figure 7.1: Example for SIBA SSK fuse

The earth unit setting depends on the characteristics of the line where the unit is installed. In general, the earth fault values are high enough to be detected as overcurrent. Even in isolated or resonant earthed neutral networks, the fault value in transformer protection installations is clearly different from the capacitive currents of the lines. This way, the transformer protection ekorRPT units are used in isolated neutral networks that do not require the directional function. The values of the setting parameters must guarantee selectivity with the main switch protections. Given the variety of protection criteria and types of neutral used in the networks, it does not exist a single parameterisation; each case requires a specific parameterisation. For transformers up to 2000 kVA, the settings below are given as a general example. It must be ensured that they properly apply to the protections upstream (general, line or main switch protections, among others.)

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Phase setting Setting of Earth ( )

Rated Current

Time delayed

Instantaneou s

I>

K

I>>

T>>

In=S/3xUn = 48 A

EI

DT

1,2

0,2

7

0,4

Type of Neutral

Time delayed

Instantaneou s

Io>

Ko

Solid or impedant

NI

DT

0,2

0,2

5

0,4

Isolated or resonant

NI

DT

0.1/Ig=2 A(*)

0,2

5

0,4

Io>> To>>

* In case a zero-sequence toroidal transformer is used

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7.3.3. Installation in a Cubicle The integral parts of the ekorRPT units are the electronic relay, the power supply and test board, the bistable trigger and the current sensors.

The electronic relay is fixed to the cubicle driving mechanism using anchors. The front of the equipment, which contains the components of the user interface, display, keys, communication ports, etc., is accessible from the outside without the need to remove the mechanism enclosure. The rear contains the X1 and X2 connectors, as well as the wiring that connects it to the power supply board. .

CGM.3-F

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All of the signals that come from the relay go through the board. Hence, the board enables the unit to be checked. Furthermore, there is a volt-free contact (J3) which is activated simultaneously with the relay trip. This enables to use conventional current injection equipment for testing the protection relays. The selfpowered transformers are also connected to the power supply board using the J7 connector in the selfpowered relays. The signal transformers are connected to the board's J8 connector, the function being to inject current into the secondary in order to test the relay. The ekorRPT protection, metering and control unit has three connectors (J1, J3 and J4) to which the user can connect. They are situated on the upper part of the power supply and test board and their functions are as follows: Connector

Name

J1

EXT. TRIP

J3

TRIP

J4

V. AUX

Functions It must be connected to an NO, volt-free contact. When it is activated, the protection device trips if an overcurrent protection function is activated. This is an NO, volt-free contact which is activated when the protection device is tripped. It also works in self powered mode. Auxiliary power supply input: 230 Vac for selfpowered units and 24 to 125 Vdc or 24 to 110 Vac for those with auxiliary power supply (10 kV insulated in relation to the rest of the equipment, in self powered models).

Normal use Transformer THERMOMETER. Protection unit TEST. Trip SIGNAL for remotelycontrolled installations Relay power supply (LVB of the transformer to protect, battery, etc.).

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GENERAL INSTRUCTIONS FOR ekorRP PROTECTION, METERING AND CONTROL UNITS

7.3.4. ekorRPT Electrical Diagram

NOTE For more details, please see electrical diagram No. 990042, which shows the electrical connections between the different parts of the ekorRPG unit and the cubicle.

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7.3.5. Installation of Toroidal-core current transformers The installation of toroidal-core current transformers requires special attention. It is the main cause of untimely tripping problems, and its improper operation can cause trips that go undetected during commissioning. Aspects that must be considered in the installation:  The toroidal-core current transformers are installed on the outgoing cables of the cubicle. The inner diameter is 82 mm, which means that MV cables can easily pass through the inside.  The earthing screen MUST go through the toroidal-core current transformer when it comes out of the part of cable remaining above the toroidal-core current transformer. In this case, the braided pair goes through the inside of the toroidal-core current transformer before it is connected to the earthing of the cubicle. The braided pair must not touch any metal part, such as the cable support or other areas of the cable compartment, before it is connected to the cubicle's earth.

Earth screen: it must pass through the inside of the toroidal-core

 The earthing screen must NOT go through the toroidal-core current transformer when it comes out of the part of cable remaining under the toroidal-core current transformer. In this case, the braided pair is connected directly to the earthing collector of the cubicle. If there is no braided pair for the earthing screen because it is connected at the other end (as in metering cubicles), the twisted pair should also not go through the toroidal-core current transformer.

7.3.6. Checking and Maintenance The ekorRPT protection, metering and control unit is designed to perform the operating test necessary for both commissioning and regular maintenance checks. Several levels of checks are available depending on the possibility of interrupting service and accessing the MV cubicle cable compartment.  Check through the primary: This case corresponds to the tests that are performed on the equipment when it is completely shut down, since it involves actuating the switchdisconnector and earthing the cubicle outgoing cables. When current is injected through the toroidal-core current transformers, you must check that the protection opens the switch within the selected time. In addition, you must make sure that the tripping indications are correct and that all the events are being recorded in the history log. CAUTION To perform this check, the unit must be powered up. Hence more than 5 A must be injected, or it must be connected to 230 Vac for self powered relays. As regards those which have auxiliary power supply, feed the voltage through the board's J4 connector.

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GENERAL INSTRUCTIONS FOR ekorRP PROTECTION, METERING AND CONTROL UNITS

To perform this check, follow the steps indicated below: -

Open the cubicle’s switch-disconnector and then earth the output. Access the cable compartment and pass a test cable through the toroidal-core current transformers. Connect the test cable to the current circuit of the tester. Connect the power supply board's J3 connector to the tester's timer stopper input. Open the earthing switch and close the switch. Reset the latch and remove the actuating lever in order to leave the cubicle ready for tripping. Inject the test currents and verify the tripping times are correct. Check that the trips are correctly displayed.

For phase trips, the test cable must pass through two toroidal-core current transformers. The cable must pass through each of them in opposite direction; in other words, if in the first one current flows up bottom, in the other it must flow bottom up so that the sum of the two currents equals zero and no earth trip occur. For earth trips, the test cable is passed through a single toroidal-core current transformer (zero-sequence or phase toroidal, depending on whether a zero-sequence toroidal is available or not). Trip tests must be performed for all toroidal-core current transformers to check the proper operation of the complete unit.  Check through the secondary. In this case, the tests are performed on the equipment when the cable compartment is not accessible. This occurs because the cubicle outgoing cables are energised and cannot be connected to earth. In this case, it is not possible to feed a test cable through the toroidal transformers and current must be injected from the power supply board. This testing method is much better than using testing equipment (normally more than 100 A).

To perform this check, follow the steps indicated below: -

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Access the control's upper compartment where the power supply board is located. Disconnect the bistable trigger. Disconnect the blue, brown, black and earth cables of the J8 connector, corresponding to points J8-6, J8-8, J8-10 and J8-1 respectively. Connect the previously disconnected cables to the earth points N of connector J83. This operation will short-circuit the current transformers' secondary circuitry.

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-

-

-

Connect the power supply to the J4 connector: 230 Vac for selfpowered units and 24 to 125 Vdc or 24 to 110 Vac for auxiliary power supply units. Connect the test cable to the J8 connector, bearing in mind the following ratio between the connector's points and the phases: Current through L1 – J8-6 and J8-1. Current through L2 – J8-8 and J8-1. Current through L3 – J8-10 and J8-1. Current through L1 and L2 (without earthing current) - J8-6 and J8-8. Current through L1 and L3 (without earthing current) - J8-6 and J8-10. Current through L2 and L3 (without earthing current) - J8-8 and J8-10. Connect the test cable to the current circuit of the tester. Connect the power supply board's J3 connector to the tester's timer stopper input. If the switch can be opened, put it in closed position. Reset the latch and remove the actuating lever in order to leave the cubicle ready for tripping and connect the bistable trigger. If the switch cannot be operated, the bistable trigger should remain disconnected and the checking process should be performed as shown in next section: “Check without switch operation”. Inject the secondary test currents taking into account that the transformation ratio is 300/1 A. Check that the trip times are correct. Check that the trips are correctly displayed.

NOTE It is advisable to perform the CHECK THROUGH THE PRIMARY or the CHECK THROUGH THE SECONDARY annually to guarantee correct equipment operation.  Check without operating the switch. In many occasions, the protection cubicle switch cannot be operated and therefore, the maintenance checks are performed exclusively on the electronic unit. In these cases, the following points shall be considered: - Always disconnect the bistable trigger. This way, the relay can trip without acting upon the opening mechanism. - Inject the current according to the section above "Check through the secondary". - The toroidal-core current transformers can be verified if the approximate consumption is known. The current that circulates through the secondary J8-6 (blue), J8-8 (brown) and J8-10 (black) must correspond to the 300/1 A ratio. - As regards selfpowered relays, check that the selfpowered transformers provide the operating power needed by the relay, if the primary current is greater than 5 A. To do this, check that the voltage in connector J7 (between points 1- blue and 2brown) is greater than 10 Vdc.

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GENERAL INSTRUCTIONS FOR ekorRP PROTECTION, METERING AND CONTROL UNITS

7.4. ekorRPG UNITS 7.4.1. Functional description The ekorRPG unit is used for the general protection of lines, private installations, transformers, etc. It is installed in circuit-breaker cubicles - models CGMCOSMOS-V, CGM-CMP-V and/or CGM.3-V - so that the electronic unit performs all the protection functions. When an overcurrent that is within the relay operational value range is detected, this relay acts upon a low power bistable trigger that opens the circuit-breaker.

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7.4.2. Technical Characteristics The ekorRPG protection unit is used to protect the following power ratings: CGMCOSMOS / CGM-CGC / CGM.3 systems Line voltage [kV]

(1)

6,6 10 13,8 15 20 25 (1) 30 (1)

ekorRPG with 5-100 A toruses Min P. [kVA] 50 100 100 100 160 200 250

ekorRPG with 15-630 A toruses [kVA] 160 200 315 315 400 630 630

Max P. [kVA] 5000 7500 10000 12000 15000 20000 25000

For CGM-CGC and CGM.3 system cubicles

Selection process for the ekorRPG unit protection parameters in CGMCOSMOS-V, CGMCMP-V and CGM.3-V cubicles: 1. Determine the system power to be protected and select the ekorRPG model in accordance with the table above. 2. Calculate the rated current In = S/3xUn. 3. Define the continuous overload level I>. Normal values in transformers of up to 2000 kVA are 20% for distribution installations and 5% for power generation installations. 4. Select the transitory overload curve. Coordination between relay curves and LV fuses is performed with the EI type curve. 5. Define the delay time in transitory overload K. This parameter is defined by the transformer’s thermal constant. This way, the greater the constant, the longer it takes for the transformer’s temperature to increase under an overload condition; and therefore, the protection trigger can be delayed longer. The normal value for distribution transformers is K = 0.2, which means that it trips in 2 s if the overload is 300% in the EI curve. 6. Short-circuit level I>>. The maximum value of the transformer’s magnetisation current must be determined. The current peak produced when a no-load transformer is connected, due to the effect of a magnetised nucleus, is several times greater than the rated current. This peak value, up to 12 times the rated value (10 times for more than 1000 kVA) has a very high harmonic content, so its fundamental 50 Hz component is much less. So, a normal setting value for this parameter is between 7 and 10. In the case of general protections for several transformers, this value can be lower. 7. Instantaneous time delay T>>. This value corresponds with the protection trip time in the event a short-circuit occurs. It depends on the coordination with other protections and the normal values are between 0.1 and 0.5 s.

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In the case of a general protection for two transformers, 1000 kVA each: S = 2000 kVA, Un =15 kV The steps to follow for proper setting of the protection relay are the following:  Rated current. In = S / 3 x Un = 2000 kVA / 3 x 15 kV  77 A  Continuous withstand overload 20%. In x I> = 77 A x 1.2  92 A  Extremely Inverse Curve type. E.I.  Transitory overload factor. K =0.2  Short-circuit level. In x I> x I>> = 77 A x 1.2 x 10  924 A  Instantaneous time delay T>> = 0.1 s The earth unit setting depends on the characteristics of the network where the equipment is installed. In general, the earth fault values are high enough to be detected as overcurrent. In the isolated or resonant earthed neutral networks, when the fault value is very low, in other words, when the earth protection is set to a value below 10% of the rated phase current, it is recommended that an ultrasensitive earth protection be used. The values of the setting parameters must guarantee selectivity with the main switch protections. Given the variety of protection criteria and types of neutral used in the networks, it does not exist a single parameterisation; each case requires a specific parameterisation. For transformers up to 2000 kVA, the settings below are given as a general example. It must be ensured that they properly apply to the protections upstream (general, line or main switch protections, among others.)

Phase setting

Setting of Earth

( )

Rated Current

Curve

Instantaneo us

I>

K

I>>

T>>

In=S/3xUn = 77 A

EI

DT

1,2

0,2

10

0,1

Type of Neutral

Curve

Instantaneo us

Io>

Ko

Io>>

To>>

Solid or impedant

NI

DT

0,2

0,2

5

0,1

Isolated or resonant

NI

DT

0.1 / Ig = 2 A (*)

0,2

5

0,2

* In case a zero-sequence toroidal transformer is used

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7.4.3. Installation in a Cubicle The integral parts of the ekorRPG units are the electronic relay, the power supply and test board and flip-flop trigger and the current sensors. The electronic relay is fixed to the cubicle driving mechanism using anchors. The front of the equipment, which contains the components of the user interface, display, keys, communication ports, etc., is accessible from the outside without the need to remove the driving mechanism enclosure. The rear contains the X1 and X2 connectors (see section § 7.4.4) as well as the wiring that connects it to the power supply board. The signals that are operational for the user are located on a terminal block that can be short-circuited and accessed from the upper part of the cubicle. Furthermore, there is a volt-free contact (G3G4) which is simultaneously activated with the relay trip. This enables to use conventional current injection equipment for testing the protection relays. The functionality of the terminal block G for connecting the user is described below. Terminals

Name

G1-G2

V.AUX

G3-G4

TRIP

G5-G6

EXT.TRIP

G7-…-G12

IP1,IP2,…

Functions Auxiliary power supply input: 230 Vac for selfpowered units and 24 to 125 Vdc or 24 to 110 Vac for those with auxiliary power supply (10 kV insulated in relation to the rest of the equipment, in self powered models). This is an NO, volt-free contact which is activated when the protection device is tripped. It also works in self powered mode. It must be connected to an NO, volt-free contact. When it is activated, the protection device trips if an overcurrent protection function is enabled. Short-circuitable and disconnectable terminals for secondary current circuits.

Normal Use Relay power transformer's battery, etc.).

supply (TS LV board,

Protection unit TEST. Trip SIGNAL for remotelycontrolled installations.

Transformer THERMOMETER.

Current injection secondary relay tests.

for

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7.4.4. ekorRPG Electrical Diagram

NOTE For more details, please see electrical diagram No. 996410, which shows the electrical connections between the different parts of the ekorRPG unit and the cubicle.

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

Front and rear view

7.4.5. Installation of Toroidal-core current transformers In CGMCOSMOS-V, CGM-CMP-V and CGM.3-V cubicles, the current transformers are installed in the cubicle bushings. Therefore there are no problems with connection errors in the earthing grid. Additionally, these toroidal-core current transformers are equipped with a test connection for conducting maintenance operations. The terminals that can be used with the toroidal-core current transformers mounted in the bushings are as follows:

Manufactur er

EUROMOLD

Current rating [A] 400 630 630 630

12 kV 12 kV 24 kV 24 kV 36 kV 36 kV Type of crossType of crossType of crossconnecto section connecto section connecto section r [mm2] r [mm2] r [mm2] 400 TE 400 LB 400 TB 440 TB

70-300 50-300 70-300 185-630

K-400TE K-400LB K-400TB K-440TB

25-300 50-300 35-300 185-630

M-400TB M-440TB

25-240 185-630

For other type of terminals[1], the toroidal-core current transformers must be loosened and installed directly on the cables, in accordance with the instructions listed in section § 7.3.5.

[1]

Consult Ormazabal’s Technical-Commercial Department.

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7.4.6. Checking and Maintenance The ekorRPG protection, metering and control unit is designed to perform the operating test necessary for both commissioning and regular maintenance checks. Several levels of checks are available depending on the possibility of interrupting service and accessing the MV cubicle cable compartment.  Check through the primary: In this case the tests are performed on the equipment when it is completely shut down, since it involves actuating the circuit-breaker and earthing the cubicle outgoing cables. When current is injected through the toroidal-core current transformers, you must check that the protection opens the circuit-breaker within the selected time. In addition, you must make sure that the tripping indications are correct and that all the events are being recorded in the history log. CAUTION To perform this check, the unit must be powered up. Hence more than 5 A must be injected, or it must be connected to 230 Vac for selfpowered relays. As regards those which have auxiliary power supply, feed the voltage through the board's J4 connector. To perform this check, follow the steps indicated below: -

Open the cubicle’s circuit-breaker. Close the earthing switch and then close the circuit-breaker for an effective earthing. Access the cable compartment and connect the test cable to the test connector of the toroidal-core current transformers. Connect the test cable to the current circuit of the tester. Connect terminals G3-G4 to the tester's timer stopper input. Open the circuit-breaker. Open the earthing switch and then close the circuitbreaker. To open the circuit-breaker using the protection unit, the earthing switch must be open. Inject the test currents and verify the tripping times are correct. Check that the trips are correctly displayed.

In order to detect phase trips, the test cable must be connected to the test bars of two toroidal-core current transformers. The current must go through each one in opposite directions. In other words, if the current flows up bottom in one of the test cables, in the other it must flow bottom up so that the sum of the two currents is zero and no earth fault trips occur. For earth trips, the test cable is connected to a single toroidal-core current transformer (zero-sequence or phase toroidal transformer, depending on whether a zero-sequence toroidal is available or not). Trip tests must be performed for all toroidal-core current transformers to check the proper operation of the complete unit.

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 Check through the secondary with circuit-breaker operation: In this case, the tests are performed Test Terminal on the equipment when the cable block compartment is not accessible. This occurs because the cubicle outgoing cables are energised and cannot be connected to earth. In this case, the test cable cannot be connected to the test connection in the toroidal-core current transformers and the current injection is performed through the test terminal block. This testing method is also used when the primary current values being tested are much greater than those produced by test equipment (normally greater than 100 A).

G-7

G12

To perform this check, follow the steps indicated below: - Access the driving mechanism upper compartment where the checks and test terminal block is located. - Disconnect the bistable trigger. - Short-circuit, and then disconnect current circuit terminals G7, G8, G9, G10, G11 and G12. This procedure short-circuits the current transformer secondaries. - Connect the power supply to the G1-G2 connector: 230 Vac for selfpowered units and 24 to 125Vdc or 24 to 110 Vac for auxiliary power supply units. - Connect the test cable to terminals G7 to G12, taking into account the following relation between the connector's points and the phases. Current through L1 – G7 and G12. Current through L2 – G8 and G12. Current through L3 – G9 and G12. Current through L1 and L2 (without earthing current) - G7 and G8. Current through L1 and L3 (without earthing current) - G7 and G9. Current through L2 and L3 (without earthing current) - G8 and G9. - Connect the test cable to the current circuit of the tester. - Connect the G3-G4 connector to the tester's timer stopper input. - If the circuit-breaker can be opened, put it in closed position. If the circuit-breaker cannot be operated, make sure the bistable trigger remains disconnected, and start the check as explained in the following section "Check without circuit-breaker operation". - Inject the secondary test currents taking into account that the transformation ratio is 300/1 A or 1000/1 A, depending on the model. Verify the tripping times are correct. Check that the trips are correctly displayed.

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 Check through the secondary without circuit-breaker operation: In many occasions, the protection cubicle circuit-breaker cannot be operated and therefore, the maintenance checks are performed exclusively on the electronic unit. In theses cases, the following points shall be considered: -

-

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Always disconnect the bistable trigger. This way, the relay can trip without acting upon the opening mechanism. Inject the current according to the section above "Check through the secondary with circuit-breaker operation". The toroidal-core current transformers can be verified if the approximate consumption is known. The current that circulates through the G7 (blue), G8 (brown) and G9 (black) secondaries must correspond to the ratio of 300/1 A or 1000/1 A. As regards selfpowered relays, check that the selfpowered transformers provide the operating power needed by the relay, if the primary current is greater than 5 A. To do this, check that the voltage in connector J7 (between points 1- blue and 2brown) is greater than 10 Vdc.

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8. SETTING AND HANDLING MENUS 8.1. KEYPAD AND ALPHANUMERIC DISPLAY

As can be seen in the image, the ekorRP protection, metering and control units have a total of 6 keys:

SET: gives access to the ‘Parameter Setting’ mode. In addition, the key has a confirmation function within the various menus of the 'Parameter Setting' mode. This function is explained in greater detail in this section.

ESC: This key allows the user to return to the main screen ('Display') from any screen without saving changes made to the settings up to this point. Using this key, the unit's trip indications can be reset. Scrolling keys: The ‛Up’ and ‛Down’ arrows enable the user to scroll through the different menus and change values. The 'Right' and 'Left' arrows allow values in the 'Parameter Setting' menu to be selected for modification, as detailed later. Along with the keypad, the relays have an alphanumeric display which makes it easier to use them. To save energy, the relay has a standby mode (display switched off), which starts to operate any time the relay does not receive an external signal for 1 minute (pressing of any key, except the SET key, or communication via RS-232), or for 2 minutes if the user is modifying the parameters in the ‘Parameter Setting’ mode. Likewise, if either type of external signal is received (pressing of the ESC, arrow up, down, left or right keys; or communication via RS-232) the relay will exit the standby mode and return to its active status, as long as the relay remains powered.

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8.2. DISPLAY The 'Display' mode is the normal mode of the relay when in operation. Its main function is to allow the user to view various unit parameters which can be summarised in 4 groups:  Current metering  Viewing the setting values  Values of the last and penultimate trip  Current date and time The ‛Display’ mode is shown by default in the relay, both when it is switched on and when it returns from its standby status, or when pressing the ESC key from any screen. In this operating mode, the ‛Up’ and ‛Down’ keys are enabled so that the user can scroll through the various parameters in the ‛Display’ mode. The SET key gives access to the ‛Parameter Setting’ mode. The following figure shows an example of several 'Display' mode screens for the ekorRPunits.

The screens shown in the relay display consist of two data lines. The first indicates the parameter for the specific screen; the second establishes the value of this parameter. Additionally, error codes can be indicated in both the display screen and the two data lines (refer to section 8.5: “Error codes”). These indications are displayed with the other indications. A table with the “Display” mode parameters sequence is shown below. This table includes the text that appears on the first line of the relay display, along with an explanation of the corresponding parameter.

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Parameter I1. A I2. A I3. A I0. A I> I 0> I>> I 0>> In. A I> K I>> T>> I 0> K0 I 0>> T 0>> H2. A H2 H2.TM H2.DT H2.YE H2.HR H2.SE H1. A H1 H1.TM H1.DT H1.YE H1.HR H1.SE DATE YEAR TIME SEC

Meaning Phase 1 current metering Phase 2 current metering Phase 3 current metering Zero-sequence current metering Phase curve type (NI, VI, EI, DT, disabled) Zero-sequence curve type (NI, VI, EI, DT, disabled) Instantaneous phase unit enabled/disabled Instantaneous zero-sequence unit enabled/disabled Phase full load current Phase overload factor Constant Phase multiplier Phase instantaneous multiplier Phase instantaneous time delay Earth leakage factor Constant Zero-sequence multiplier Zero-sequence instantaneous multiplier Zero-sequence instantaneous time delay Current at last trip Cause of last trip Time delay of last trip, from start-up to the trip Last trip date Last trip year Hour and minute of last trip Last trip second Penultimate trip current Penultimate trip cause Time delay of the penultimate trip, from start up to the trip Penultimate trip date Penultimate trip year Hour and minute of penultimate trip Penultimate trip second Current date Current year Current time Current second

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8.3. PARAMETER SETTING The 'Parameter Setting' menu can be accessed from any screen of the 'Display' menu by pressing the SET key. The protection remains operational with the initial parameters, until the user returns to the ‘Display’ menu by pressing on the SET key again. As a precautionary measure, the ‛Parameter Setting’ menu is protected by a password, which is entered each time the user wishes to access this menu. By default, all of the ekorRP units have the password 0000. This password can be modified by the user as explained further on. This menu allows the user to make changes to various relay parameters. These parameters can be grouped as follows:  Parameters for the protection and detection functions  Date and time  Communication parameters  Information on the number of trips  Password change When the relay is in the 'Parameter Setting’ menu, the indication SET on the lower middle section of the relay screen allows the user to identify the menu quickly.

8.3.1. Protection parameters The ekorRP units include two methods for selecting the setting parameters. manual and automatic. The manual method consists of entering each protection parameter one by one. On the other hand, the automatic method makes the parameter entry easier and quicker for the user. In this method, the user simply enters 2 pieces of data: Installation transformer power (Pt), and line voltage (Tr). From these 2 pieces of data, the relay sets the parameters according to:

In 

Pt

(Tr  3 )

The selected full load current value is achieved by always rounding up the value.

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The rest of setting values are fixed (see the table below), although the user can change any of the values selected in the program from the manual mode. Phase Protection

Earth Protection

Setting

Automatic Value

Setting

Automatic Value

Overload Factor Curve Type Constant Multiplier Short-circuit Factor Trip Time Tripping Enabled

120 % EI 0,2 10(*) 0,1(*) DT

Earth Leakage Factor Curve Type Constant Multiplier Short-circuit Factor Trip Time Tripping Enabled

20 % NI 0,2 5 0,1(*) DT

( )

* For protection using the ekorRPT-101, 201 or 301 models with 5-100 A range toruses, the short-circuit factor is 7 and the instantaneous tripping time is 0.4.

8.3.2. Parameter Setting Menu When accessing the ‘Parameter Setting’ menu through the SET key, the relay requests a password. The settings introduction area is accessed once it is verified that the password is correct. At this moment, manual configuration (CONF PAR) or automatic configuration (CONF TRAF) must be selected. You can change from one to the other using the ‘right’ and ‘left’ keys. Press the SET key to select the desired option. The diagram on the right graphically explains this process. Once inside any of the two settings entry areas, the user can move from one parameter to another using the ‘up’ and ‘down’ keys, the same as in the ‘Display’ mode. Press the ESC or SET key to exit this menu and access the ‘Display’ menu. The ESC key will disregard all setting changes made previously, whereas the SET key will save all data before continuing.

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To change a setting, proceed as follows: 1. Display the setting to be changed on the screen. 2. Press the ‘Left’ or ‘Right’ keys. The data will start to flash. 3. Adjust the value required with the 'Up' and 'Down' keys. If the setting is numeric, the blinking number can be changed with the 'Left' or 'Right' keys. 4. To exit, press SET (save and exit), or ESC (clear changes and exit).

The password can be modified by first entering the current password. The process is explained graphically in the diagram on the right. As shown in this diagram, password modification consists of four steps. The two following tables show the protection parameters in the ‘Parameter Setting’ menu, along with an explanation of each of them and the values they can have. This information is shown for each of the two setting modes: manual or automatic.

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Manual Setting Menu Parameter

Meaning

I> I 0> I>> I 0>>

Phase curve type / unit disabling Zero-sequence curve type / Unit disabling Enabling instantaneous phase unit Enabling instantaneous earth unit

In. A

Phase full load current

I> K I>> T>> **I0> K0 I 0>> T 0>> DATE YEAR TIME SEC. *NPER *PROT *BAUD *PARI *LEN *STOP DT.AD YE.AD HR.AD SE.AD NTP NTG *V.0 PSWV

Phase overload factor Constant Phase multiplier Phase instantaneous multiplier Phase instantaneous time delay Earth leakage factor Constant Zero-sequence multiplier Zero-sequence instantaneous multiplier Zero-sequence instantaneous time delay Modify current day (day and month) Modify the current year Modify the current time Modify the current second Peripheral number Protocol number Transmission speed (kbps) Parity Word length Stop bits Day and month on which the last setting was made Year in which the last setting was made Time at which the last setting was made Second at which the last setting was made Number of phase trips Number of earth trips Firmware version Password modification

Range OFF, NI, VI, EI, DT OFF, NI, VI, EI, DT OFF, DT OFF, DT 192 A for ekorRPX-X01 480 A for ekorRPX-X02 1,00 – 1,30 0,05 – 1,6 1 – 25 0,05 – 2,5 0,1 – 0,8 0,05 – 1,6 1 – 25 0,05 – 2,5 1 - 31 / 1 - 12 2000 – 2059 00:00 - 23:59 0 - 59 0 – 31 0000[3] MODBUS-0001 1,2; 2,4; 4,8; 9,6; 19,2; 38,4 No, even, odd 7; 8 1; 2 Cannot be changed Cannot be changed Cannot be changed Cannot be changed Cannot be changed Cannot be changed Cannot be changed 0000 - 9999

( )

* Only available for firmware version 18 or later. **) n the case of zero-sequence toroidal transformer, the range is 0.5 A-In and the parameter is Ig. (

[3]

ekorSOFT communication protocol.

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Automatic Setting Menu Parameter

Meaning

tP 0W

Transformer Power (kVA)

Tvol DATE YEAR TIME SEC. *NPER *PROT *BAUD *PARI *LEN *STOP

Line voltage (kV) Current day and month Current year Current time Current second Peripheral number Protocol number Transmission speed (kbps) Parity Word length Stop bits Day and month on which the last setting was made Year in which the last setting was made Time at which the last setting was made Second at which the last setting was made Number of phase trips Number of earth trips Number of external trips Firmware version Password modification

DT.AD YE.AD HR.AD SE.AD NTP NTG NTE *V.0 PSWV ( )

* Only available for firmware version 18 or later

[4]

ekorSOFT communication protocol.

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Range 50; 100; 160; 200; 250; 315; 400; 500; 630; 800; 1000; 1250; 1600; 2000 6,6; 10; 12; 13,2; 15; 20; 25; 30 1-31/1-12 2000-2059 00:00-23:59 0-59 0-31 [4] 0000 (MODBUS)-0001 1,2;2,4;4,8;9,6;19,2;38,4 No, even, odd 7, 8 1, 2 Cannot be changed Cannot be changed Cannot be changed Cannot be changed Cannot be changed Cannot be changed Cannot be changed Cannot be changed 0000-9999

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8.4. TRIP RECOGNITION Whenever a trip occurs, the relay immediately accesses the 'Trip recognition" menu. This menu can be easily identified because a blinking arrow is located on the upper part of the display, just below the name of the function that has caused the trip. The ekorRP units signal five possible trip causes using the upper arrow.  Phase time-delayed trip

I>

 Phase instantaneous trip

I>>

 Earth time-delayed trip I 0>  Earth instantaneous trip

I 0>>

 External trip

Ext

To quit the ‘Trip recognition’ menu, press the ESC key from any of the menu screens. The relay recognises that the user has checked the trip and then returns to the first screen of the ‘Display’ menu. In any case, the trip data will continue to be available to the user from the ‘Display’ menu until two new trips have occurred. The various screens of the of 'Trip Recognition' menu provide two types of information. The initial screen shows the current detected at the tripping moment, by phase or earth depending on the tripped unit. Subsequent ‘Trip Recognition’ screens display the date and time of the trip, along with the time elapsed from the unit start up to the trip. The following table shows the sequence in which the data appear. As in the rest of the menus, the 'Up' and 'Down' keys are used to scroll throughout the various data. Parameter Ix A Ix TM Ix DT Ix YE Ix HR Ix SE

Meaning Current at the tripping moment Time elapsed from unit start up to the trip Day and month on which the trip occurred Year in which the trip occurred Time at which the trip occurred Second in which the trip occurred

Where subscript x depends on the cause of the trip: 3 or zero-sequence, respectively.

e1 f,

e2 f,

e3 f or

e0 f, for phase 1, phase 2, phase

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8.5. ERROR CODES The ekorRP units have a series of error codes used to warn the user regarding the different anomalies that may occur in the system. The different error codes are identified by a number, just as shown in the figure on the right. The following error codes may be displayed on the ekorRP units:

Code shown on the display ER 01 ER 03

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Meaning 230 Vac in the external trip input (this input is to be connected to a volt-free contact) Error when opening switch

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8.6. MENU MAP (QUICK ACCESS) DISPLAY

The menu map is a summary table that indicates all the submenus for the ekorRP units, as well as a brief explanation of each one.

Phase 1 current

Phase multiplier constant

Last trip date

Phase 2 current

Phase instantaneous multiplier

Last trip year

Phase 3 current

Phase instantaneous time delay

Time at last trip

Zero-sequence current (Io or Ig)

Earth leakage factor

Last trip second

Phase curve type

Constant Earth multiplier

Penultimate trip current

Zero-sequence curve type

Earth instantaneous multiplier

Penultimate trip cause

Phase instantaneous enabling

Earth instantaneous time delay

Time at penultimate trip

Zero-sequence instantaneous enabling

Current at last trip

Penultimate trip date

Full load current

Cause of last trip

Penultimate trip year

Overload factor

Time at last trip

Time at penultimate trip

Second penultimate trip

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PARAMETER SETTING

Parameter Configuration Transformer configuration

Prompt for password

Word length

Prompt for old password

Stop bit(s)

Prompt for new password

Date at last setting

Repeat new password

Parameter configuration

Earth leakage factor

Transmission speed

Number of external trips

Phase curve type

Earth multiplier constant

Parity

Firmware version

Zero-sequence curve type

Earth instantaneous multiplier

Word length

Password modification

Modification of date

Year at last setting

Phase instantaneous enabling

Earth instantaneous time delay

Stop bit(s)

Prompt for old password

Modification of year

Time at last setting

Current that caused the trip

Zero-sequence instantaneous enabling

Modification of date

Date at last setting

Prompt for new password

Modification of time

Second at last setting

Trip time

Full load current

Modification of year

Year at last setting

Repeat new password

Modification of second

Number of phase trips

Date at trip

Overload factor

Modification of time

Time at last setting

Peripheral no.

No. Zerosequence trips

Year at trip

Constant Phase multiplier

Modification of second

Second at last setting

Protocol no.

Number of external trips

Time at trip

Phase instantaneous multiplier

Peripheral no.

Number of phase trips

Transmission speed

Firmware version

Second at trip

Phase instantaneous time delay

Protocol no.

No. Zerosequence trips

Parity

Password modification

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Line voltage

Trip recognition

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The on-screen representation of the equipment for LAST and PENULTIMATE trips is detailed below: Cause of last trip Time of last trip Date of last trip Year of last trip Time of last trip Second last trip Current penultimate trip Cause penultimate trip Time penultimate trip Date penultimate trip Year penultimate trip Time penultimate trip Second penultimate trip

Figure 8.1: View of last and penultimate trips on the menu map

FAULT HISTORY LOG Hn Hn A

| amp.

Hn

|Fxy

Hn TM | time Hn DT | date Hn YE | year Hn HR | time Hn SE | sec.

Last trip (n=2). Penultimate trip (n=1) Current at the moment of tripping (A = Amps) Reason for tripping:  x= Trip At phase 1 (R), 2 (S), 3 (T), or (Neutral), Trip External (Ext.)  y= Trip. Time delayed (>) or Instantaneous (>>) Time elapsed from unit start up to the trip (mSg.) Day and month on which the trip occurred Year in which the trip occurred Time at which the trip occurred Second in which the trip occurred

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9. MODBUS PROTOCOL FOR ekorRP RANGE UNITS The two communication ports of the relay use the same protocol: MODBUS in RTU transmission mode (binary). The main advantage of this mode over the ASCII mode is that the information is packed tighter, allowing a higher data transmission rate at the same communication speed. Each message must be transmitted as a continuous string, as the silences are used to detect the end of the message. The minimum duration of the SILENCE is 3.5 characters. RTU message frame Start

Address

Function

Data

CRC

End

Silence

8 BITS

8 BITS

n x 8 BITS

16 BITS

Silence

The MODBUS ADDRESS of the relay (also called peripheral number) is a byte that takes values between 0 and 31. The master addresses the slave, indicating its address in the respective field and the slave answers by indicating its own address. The '0' address is reserved for the 'broadcast' mode so it can be recognised by all slaves.

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9.1. READ / WRITE FUNCTIONS In principle, only two functions will be implemented, one for reading and another for writing data. Data reading Question: Start

Address

Function

Silence

SLAD

‘3’

Data ADDR-H

ADDR-L

NDATA-H

NDATA-L

CRC

End

16 BITS

Silence

CRC

End

16 BITS

Silence

Response: Start

Address

Function

No. of BYTES

Silence

SLAD

‘3’

N

Data DATA1-H

DATA1-L

.......

where: SLAD ADDR-H ADDR-L

Slave address High byte of the address for the first register to be read Low byte of the address for the first register to be read

NDATA-H NDATA-L DATA1-H DATA1-L N

High byte of the number of registers to be read Low byte of the number of registers to be read High byte of the first register requested Low byte of the first register requested Total number of data bytes. This will be equal to the number of registers requested, multiplied by 2.

Data Writing This makes it possible to write a single register at the address indicated. Question: Start

Address

Silence

SLAD

Function ‘6’

Data ADDR-H

ADDR-L

DATA-H

CRC DATA-L

16 BITS

End Silence

Response: The normal response is an echo of the query received. where: SLAD ADDR-H ADDR-L DATA-H DATA-L

Slave address High byte of the address for the register to be written. Low byte of the address for the register to be written. High byte of the data to be written. Low byte of the data to be written.

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Response in case of error Start

Address

Function

Error-Code

CRC

End

Silence

SLAD

FUNC_ERR

CODE_ERROR

16 BITS

Silence

where: SLAD FUNC_ERR CODE_ERROR ‘1’ ‘2’ ‘3’ ‘4’ ‘5’ ‘6’ ‘8’

Slave address. Code of the function requested, with the most significant bit at 1. Code of the error occurred. Error in the number of registers Wrong address Incorrect data attempt made to read a write-only address session error EEPROM error Attempt being made to write in a read-only address

9.2. Password-protected Register Writing The parameters are protected against writing by the USER PASSWORD. A write session of password-protected parameters starts by entering the PASSWORD in the respective address. The write session ends with the update of registers once the respective PASSWORD has been transmitted again. If the timeout period has elapsed, the process is aborted and the system returns to normal mode. In normal mode, any attempt to write a protected registration will result in an error code 2'. The write session is valid for only one port (the one that entered the PASSWORD has priority).

9.3. CRC GENERATION The cyclical redundancy check (CRC) field contains two bytes that are added to the end of the message. The receiver must re-calculate it and compare it with the received value. Both values must be equal. The CRC is the remainder obtained when dividing the message by a binary polynomial. The receiver must divide all bits received (information plus CRC) by the same polynomial used to calculate the CRC. If the remainder obtained is 0, the information frame is deemed correct. The polynomial used will be: X15+X13+1

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GENERAL INSTRUCTIONS FOR ekorRP PROTECTION, METERING AND CONTROL UNITS

IG-159-GB version 07

20.09.2012 84

9.4. REGISTER MAP USER SETTINGS: USER PASSWORD-PROTECTED WRITING Field

Address

In

0x0000

CURVE_ CURVE_ PHASE– ZERO-SEQ PHASE_INST ZERO-SEQ_INST PHASE_INST_OVERLOAD (I>) ZERO-SEQ_CURRENT (Io>)

0x0001

K PHASE_INST _OCCUR PHASE_INST _TIME

0x0005 0x0006

Ko ZEROSEQ_INST_OCCUR ZEROSEQ_INST_TIME

PHASE_TRIP_COUNTER EARTH_TRIP_COUNTER EXTERNAL_TRIP_COUNTER USER_PASSWORD ZERO-SEQ_CURRENT (Io>)

0x0002 0x0003 0x0004

0x0007

0x0008 0x0009 0x000a 0x000b 0x000c

Contents from 5 to 100 if RATED_I=0 from 15 to 630 if RATED_I=1 0:OFF; 1:NI; 2:VI; 3:EI; 4:DT 0:OFF, 1:DT; 0:100%; 1:101%; 2:102%,... 30:130% Vector_sum 0-sequence_toroidal 0:10%;1:11%; 0:0.1; 1:0.2; 2:1.5 A …80% …In 0:0.05; 1:0.06; ... 20:1.6 0:3; 1:4;…17:20 050 ms, 1 60 ms 270 ms, 3 80 ms 490 ms, 5 100 ms, 6200 ms...2,5 s from 0000 to 9999 from 0000 to 9999 from 0000 to 9999 from 0000 to 9999 Vector_sum 0-sequence_toroidal 0:10%;1:11%; 0:0.1; 1:0.2; 2:0.3 A …80% …In

Page 67 of 84

GENERAL INSTRUCTIONS FOR ekorRP PROTECTION, METERING AND CONTROL UNITS

IG-159-GB version 07 20.09.2012

HISTORY LOGS; MEASUREMENTS; INPUTS / OUTPUTS; SOFT VERSION: READ ONLY Field

Address

YEAR

User Setting Date

MONTH HOUR 00 PENULT_TRIP

DAY MINUTE SECONDS LAST_TRIP

0x0200 0x0201 0x0202 0x0203 0x0208

Contents RTC Format Bit 0 1 2 3 4 5 6

7 PHASE_LAST_TRIP_VALUE ZERO-SEQ_LAST_TRIP_VALUE

Tripping History log

PHASE_LAST_TRIP_TIME ZERO-SEQ_LAST_TRIP_TIME YEAR MONTH DAY HOUR MINUTE 00 SECONDS PHASE_PENULT_TRIP_VALUE

ZEROSEQ_PENULT_TRIP_VALUE PHASE_PENULT_TRIP_TIME ZEROSEQ_PENULT_TRIP_TIME YEAR MONTH DAY HOUR MINUTE 00 SECONDS Phase current L1 Phase current L2

Current metering

Phase current L3 Zero-sequence current

0x0209 0x020a 0x020b 0x020c 0x020d 0x020e 0x020f 0x0210 0x0211 0x0212 0x0213 0x0214 0x0215 0x0216 0x0217 0x0218 0x0219 0x021a 0x021b 0x021c 0X021d 0X021e 0X021f 0X0220 0X0221 0X0222 0X0223 0X0224

Inputs Software version

Page 68 of 84

0x0225 functions

0x0226

Contents Trip by phase 1: L1, 2: L2, 3: L3 Zero-sequence trip NOT USED External trip Cause of the phase trip. 0: overload, 1: short-circuit Cause of the zerosequence trip. 0: overload, 1: short-circuit Double tripping

Current in hundredths of an A Current in hundredths of an A Time in hundredths of a s Time in hundredths of a s RTC Format Current in hundredths of an A Current in hundredths of an A Time in hundredths of a s Time in hundredths of a s

RTC Format

Hundredths of on A Hundredths of on A Hundredths of on A Hundredths of on A Bit 0: Input 1, Bit 1: Input 2, etc. from 0 to 99

from A to Z

GENERAL INSTRUCTIONS FOR ekorRP PROTECTION, METERING AND CONTROL UNITS

IG-159-GB version 07

20.09.2012 84

CLOCK

MONTH HOUR 00

Field

Address

Contents

YEAR

0x0300 0x0301 0x0302 0x0303

from 2000 to 2059 from 1 to 12 from 1 to 31 from 0 to 23 from 0 to 59 0 from 0 to 59

DAY MINUTE SECONDS

PASSWORD KEYS: WRITING ONLY Field

Address

Contents

USER PASSWORD KEY

0x0500

from 0 to 9999

Page 69 of 84

GENERAL INSTRUCTIONS FOR ekorRP PROTECTION, METERING AND CONTROL UNITS

NOTES

Page 70 of 84

IG-159-GB version 07 20.09.2012

10. ANNEX A

BRIEF GUIDE FOR COMMISSIONING THE ekorRPG UNIT IN CGMCOSMOS-V, CGM-CMP-V & CGM.3-V

IG-159-GB Annex A version 07

BRIEF GUIDE FOR COMMISSIONING THE ekorRPG UNIT

Page 72 of 84

IN CGMCOSMOS-V, CGM-CMP-V & CGM.3-V

20-09-2012

The following steps must be followed for correct commissioning:

1. Verify the power to be protected: CGMCOSMOS / CGM-CGC / CGM.3 SYSTEMS Line voltage [kV]

(1)

6,6 10 13,8 15 20 25 (1) 30 (1)

ekorRPG with 5-100 A toruses

ekorRPG with 15-630 A toruses

Min P. [kVA]

[kVA]

Max P. [kVA]

50 100 100 100 160 200 250

160 200 315 315 400 630 630

5000 7500 10000 12000 15000 20000 25000

for CGM-CGC and CGM.3 system cubicles only

2. Toroidal-core current transformers already installed: Bushing Protection and power supply toroidal-core current transformers (already installed) Test flatbar

3. Connect the HV terminals:

Connected terminals (shielded). For non-shielded or plug-in terminals the current transformers (CT) must be installed on the cable.

Connect braid to earth collector

4. External connections: Remove the terminal box cover. Connect to terminal block:  

G1-G2: 230 Vac or 48Vdc (depending on model A or B) G5-G6: external trip (thermostat)

IG-159-GB Annex A version 07

BRIEF GUIDE FOR COMMISSIONING THE ekorRPG UNIT

Page 73 of 84

IN CGMCOSMOS-V, CGM-CMP-V & CGM.3-V

20-09-2012

5. Set relay: Automatic mode: Installation kV and kVA. Manual mode: Parameters: I>, I0>, I>>, ...

PHASE SETTING

Table of settings:

IN 

S (UN  3)

EARTH SETTING

Type of neutral

Curve EI Curve

Instantaneo us TD Instantaneo us

Solid or impedant

NI

TD

Isolated or resonant

NI

TD

I>

K

I>>

T>>

1,2

0,2

10

0,1

Io>

Ko

Io>>

To>>

0,2

0,2

5

0,1

0,2

5

0,2

0,1 / Ig=2A(*)

( )

* In case a zero-sequence toroidal transformer is used

6. Trip test with current:

   

Remove earthing switch and close the switch. Remove 230 Vac (G1- G2) to check that the selfpower supply is operating (except B models). Inject test current: In two phase trip flatbars In one earth trip flatbar Repeat for I1, I2 and I3.

IG-159-GB Annex A version 07

BRIEF GUIDE FOR COMMISSIONING THE ekorRPG UNIT

Page 74 of 84

IN CGMCOSMOS-V, CGM-CMP-V & CGM.3-V

20-09-2012

7. External trip test: Short-circuit and G6.

the

G5

Check trip and indication ‘EXT’.

8. Commissioning:   

Check I1≈ I2≈ I3. Check I0≈ 0. Check 230 Vca connection (if available).

9. What to do in the event of: ERROR

REASON

POSSIBLE CAUSES

Error 01

Incorrectly connected thermometer

 Thermometer connected to 230 V (with potentialfree contact).

Error 03

Switch Error

 Switch mechanical blocking  Relay trip wiring error  Auxiliary contact error

I0 ≠ 0

I1≠ I2 ≠ I3 I123 > 5 A and LED ‘On’ switched off Relay trip in I0>> when closing switch Relay trip in I>> when closing switch

Relay will communicate

not

Grid fault incorrectly connected or  Check that the grid and the secondary circuits are secondary circuit not incorrectly connected disconnected.  Incorrect toroidal-core current transformer Unbalance connection  Check secondary circuits  Incorrectly connected toroidal-core current Selfpowered transformer  Incorrectly connected relay wiring  Real fault present. Time T0 >>  Check if T0 >> sufficient, taking into account insufficient toroidal vector sum error.  Real fault present. I >> insufficient  Check parameter I >>, taking into account transformer current peak (10 times In ).  Incorrect communication cable connections.  Relay in energy-saving mode. Press a button of Fault in relay. communication  Incorrect configuration of communication parameters.

IG-159-GB Annex A version 07

DISPLAY

BRIEF GUIDE FOR COMMISSIONING THE ekorRPG UNIT

Page 75 of 84

IN CGMCOSMOS-V, CGM-CMP-V & CGM.3-V

20-09-2012

The menu map is a summary table that indicates all the submenus for the ekorRP units, as well as a brief explanation of each one.

Phase 1 current

Phase multiplier constant

Last trip date

Phase 2 current

Phase instantaneous multiplier

Last trip year

Phase 3 current

Phase instantaneous time delay

Time at last trip

Zero-sequence current (Io or Ig)

Earth leakage factor

Last trip second

Phase curve type

Constant Earth multiplier

Penultimate trip current

Zero-sequence curve type

Earth instantaneous multiplier

Penultimate trip cause

Phase instantaneous enabling

Earth instantaneous time delay

Time at penultimate trip

Zero-sequence instantaneous enabling

Current at last trip

Penultimate trip date

Full load current

Cause of last trip

Penultimate trip year

Overload factor

Time at last trip

Time at penultimate trip

Second penultimate trip

IG-159-GB Annex A version 07

BRIEF GUIDE FOR COMMISSIONING THE ekorRPG UNIT

Page 76 of 84

IN CGMCOSMOS-V, CGM-CMP-V & CGM.3-V

20-09-2012

PARAMETER SETTING

Parameter Configuration Transformer configuration

Prompt for password

Word length

Prompt for old password

Stop bit(s)

Prompt for new password

Date at last setting

Repeat new password

Parameter configuration

Earth leakage factor

Transmission speed

Number of external trips

Phase curve type

Earth multiplier constant

Parity

Firmware version

Zero-sequence curve type

Earth instantaneous multiplier

Word length

Password modification

Modification of date

Year at last setting

Phase instantaneous enabling

Earth instantaneous time delay

Stop bit(s)

Prompt for old password

Modification of year

Time at last setting

Current that caused the trip

Zero-sequence instantaneous enabling

Modification of date

Date at last setting

Prompt for new password

Modification of time

Second at last setting

Trip time

Full load current

Modification of year

Year at last setting

Repeat new password

Modification of second

Number of phase trips

Date at trip

Overload factor

Modification of time

Time at last setting

Peripheral no.

No. Zerosequence trips

Year at trip

Constant Phase multiplier

Modification of second

Second at last setting

Protocol no.

Number of external trips

Time at trip

Phase instantaneous multiplier

Peripheral no.

Number of phase trips

Transmission speed

Firmware version

Second at trip

Phase instantaneous time delay

Protocol no.

No. Zerosequence trips

Parity

Password modification

Line voltage

Trip recognition

11. ANNEX B

BRIEF GUIDE FOR COMMISSIONING THE ekorRPG UNIT IN CGMCOSMOS-V, CGM-CMP-V & CGM.3-V

IG-159-GB Annex B version 07

BRIEF GUIDE FOR COMMISSIONING THE ekorRPG UNIT IN

Page 78 of 84

CGMCOSMOS-V, CGM-CMP-V & CGM.3-V

20-09-2012

The following steps must be followed for correct commissioning:

1. Verify the power to be protected: CGMCOSMOS SYSTEM Line voltage [kV] 6,6 10 13,8 15 20 ( )

Fuse rated MINIMUM transformer power voltage [kV] Fuse rating [A] [kVA] 3 / 7,2 6/12 10/24 10/24 10/24

16 10 16 16 16

MAXIMUM transformer power Fuse rating [A] ( )

50 100 100 125 160

160 ¹ 160 (¹) 100 125 (²) 125

[kVA] 1250 1250 1250 1600 2000

¹ 442 mm cartridge ² 125 A SIBA SSK Fuse

( )

Line voltage

Fuse Rated Voltage [kV]

CGM-CGC / CGM.3 System MINIMUM Transformer Power MAXIMUM Transformer Power

[kV] 6,6 10 13,8 15 20 25 30

( )

3/7,2 6/12 10/24 10/24 10/24 24/36 24/36

Fuse Rating [A]

[kVA]

16 16 10 16 16 25 25

50 100 100 125 160 200 250

Fuse Rating [A] 160 (¹) 125 63 63 63 80 (2) 80 (2)

¹ 442 mm cartridge SIBA SSK fuse (check)

(2)

2. Toroidal-core current transformers: Installed on cables. If the earthing grid originates from:  

underneath the toroidal-core current transformer: do not pass the grid through it. above the toroidal-core current transformer: pass the grid through it. Make sure that the screen does not touch any metal part before connecting it to the cubicle earth collector.

Power supply board

Protection and power supply toroidal-core current transformers Earthing grids Cables

3. Connect the HV terminals

[kVA] 1000 1250 800 1000 1250 2000 2500

BRIEF GUIDE FOR COMMISSIONING THE ekorRPG UNIT IN CGMCOSMOS-V, CGM-CMP-V & CGM.3-V

IG-159-GB Annex B version 07

Page 79 of 84 20-09-2012

4. External connections: Remove the control box cover. Connect to the power supply board: J1: external trip (thermostat) J4: 230Vac or 48Vdc (depending on model A or B)

5. Set relay: Automatic mode: Installation kV and kVA. Manual mode: Parameters: I>, I0>, I>>, ...

PHASE SETTING

Table of settings: Curve

Instantaneous

I>

K

I>>

T>>

EI

TD

1,2

0,2

7

0,4

Type of neutral

Curve

Instantaneous

Io>

Ko

Io>>

To>>

Solid or impedant

NI

TD

0,2

0,2

5

0,4

Isolated or resonant

NI

TD

0,1

0,2

5

0,4

EARTH SETTING

IN 

S (UN  3)

6. Trip test with current:    

Remove earthing switch and close the switch. Remove 230 Vac (J4) to check that the selfpower supply is operating (except B models). Inject test current: Insert the cable in two toroidal-core current transformers for phase tripping Insert the cable in one toroidal-core current transformer for earth tripping Repeat for I1, I2 and I3.

IG-159-GB Annex B version 07

BRIEF GUIDE FOR COMMISSIONING THE ekorRPG UNIT IN

Page 80 of 84

CGMCOSMOS-V, CGM-CMP-V & CGM.3-V

20-09-2012

7. External trip test: Short-circuit the J1

Check trip indication ‘EXT’.

and

8. Commissioning:   

Check I1≈ I2≈ I3 Check I0≈ 0 Check 230 Vca connection (if available)

9. What to do in the event of: ERROR

REASON

POSSIBLE CAUSES

Error 01

Incorrectly connected thermometer

 Thermometer connected to 230 V (with potentialfree contact).

Error 03

Switch Error

 Switch mechanical blocking  Relay trip wiring error  Auxiliary contact error

I0 ≠ 0

I1≠ I2 ≠ I3 I123 > 5 A and LED ‘On’ switched off Relay trip in I0>> when closing switch Relay trip in I>> when closing switch

Relay will communicate

not

Grid fault incorrectly connected or  Check that the grid and the secondary circuits secondary circuit are not incorrectly connected disconnected  Incorrect toroidal-core current transformer Unbalance connection  Check secondary circuits  Incorrectly connected toroidal-core current Self powered transformer  Incorrectly connected relay wiring  Real fault present. Time T0 >>  Check if T0 >> sufficient, taking into account insufficient toroidal vector sum error.  Real fault present. I >> insufficient  Check parameter I >>, taking into account transformer current peak (10 times In ).  Incorrect communication cable connections.  Relay in energy-saving mode. Press a button of Fault in relay. communication  Incorrect configuration of communication parameters.

IG-159-GB Annex B version 07

DISPLAY

BRIEF GUIDE FOR COMMISSIONING THE ekorRPG UNIT IN CGMCOSMOS-V, CGM-CMP-V & CGM.3-V

Page 81 of 84 20-09-2012

The menu map is a summary table that indicates all the submenus for the ekorRP units, as well as a brief explanation of each one.

Phase 1 current

Phase multiplier constant

Last trip date

Phase 2 current

Phase instantaneous multiplier

Last trip year

Phase 3 current

Phase instantaneous time delay

Time at last trip

Zero-sequence current (Io or Ig)

Earth leakage factor

Last trip second

Phase curve type

Constant Earth multiplier

Penultimate trip current

Zero-sequence curve type

Earth instantaneous multiplier

Penultimate trip cause

Phase instantaneous enabling

Earth instantaneous time delay

Time at penultimate trip

Zero-sequence instantaneous enabling

Current at last trip

Penultimate trip date

Full load current

Cause of last trip

Penultimate trip year

Overload factor

Time at last trip

Time at penultimate trip

Second penultimate trip

I

BRIEF GUIDE FOR COMMISSIONING THE ekorRPG UNIT IN

IG-159-GB Annex B

CGMCOSMOS-V, CGM-CMP-V & CGM.3-V

version 07

Page 82 of 84 20-08-2012

PARAMETER SETTING

Parameter Configuration Transformer configuration

Prompt for password

Word length

Prompt for old password

Stop bit(s)

Prompt for new password

Date at last setting

Repeat new password

Parameter configuration

Earth leakage factor

Transmission speed

Number of external trips

Phase curve type

Earth multiplier constant

Parity

Firmware version

Zero-sequence curve type

Earth instantaneous multiplier

Word length

Password modification

Modification of date

Year at last setting

Phase instantaneous enabling

Earth instantaneous time delay

Stop bit(s)

Prompt for old password

Modification of year

Time at last setting

Current that caused the trip

Zero-sequence instantaneous enabling

Modification of date

Date at last setting

Prompt for new password

Modification of time

Second at last setting

Trip time

Full load current

Modification of year

Year at last setting

Repeat new password

Modification of second

Number of phase trips

Date at trip

Overload factor

Modification of time

Time at last setting

Peripheral no.

No. Zerosequence trips

Year at trip

Constant Phase multiplier

Modification of second

Second at last setting

Protocol no.

Number of external trips

Time at trip

Phase instantaneous multiplier

Peripheral no.

Number of phase trips

Transmission speed

Firmware version

Second at trip

Phase instantaneous time delay

Protocol no.

No. Zerosequence trips

Parity

Password modification

Line voltage

Trip recognition

IG-159-GB version 07 20.09.2012

GENERAL INSTRUCTIONS FOR ekorRP PROTECTION, METERING AND CONTROL UNITS

NOTES

Page 83 of 84

TECHNICAL - COMMERCIAL DEPARTMENT: www.ormazabal.com

Page 84 of 84