Megger FREJA546 Relay Test System User Manual
- June 15, 2024
- Megger
Table of Contents
**Megger FREJA546 Relay Test System User Manual
**
DESCRIPTION
The FREJA546 is a multi-purpose, lightweight, field portable test set capable of testing a wide variety of electro-mechanical, solid-state, and microprocessor-based protective relays, motor overload relays, and similar protective devices. The FREJA546 has the “smart” combination of being both small and light weight, while also providing high power.
The FREJA546 test system can be manually controlled with the integrated onboard display on the FREJA546 running the new RTMS,
Relay Testing Management Software. The onboard display, with its large, easy- to-read full colour, high resolution, TFT LCD touch screen allows the user to perform manual, steady-state, and dynamic testing quickly and easily using the manual test screen, as well as using builtin pre-set test routines for most popular relays.
The onboard display eliminates the need for a computer when testing virtually all types of relays. Menu screens and touch screen function buttons are provided to select the desired test function quickly and easily. Tests results can be saved to the internal memory for later download to a USB Thumb drive to transfer or print test reports.
For fully automatic testing every FREJA unit is supplied with Relay Testing Management Software (RTMS) for installing on a PC. It does not require a security dongle or license to operate and can be loaded on as many customer- owned computers as required. There are two different levels of RTMS: Standard and enhanced, see ordering information for details.
APPLICATIONS
The test system may be customised by adding the number of voltage current, “VIGEN”, modules needed for specific test applications, with a maximum of three channels. For example, the FREJA546 with three
VIGEN modules provides complete three-phase testing of three-phase impedance, directional power, negative sequence overcurrent, and other devices that require a three-phase four-wire wye connected sources. The fourth voltage channel provides an AC reference/ synchronising/polarising voltage, or a DC battery simulator voltage source.
Each current channel is rated for 32 A at 200 VA rms continuous, and up to 60 A at 319 VA rms for short durations. For testing relay panels or electromechanical relays, it has a unique flat power curve from 4 to 32 A that always ensures maximum compliance voltage to the load.
With a maximum compliance voltage of 50 V rms per phase, two channels in series provide 100 V to test high impedance relays. Three currents in parallel provide test currents up to 120 A at 600 VA for testing ground overcurrent relays at high multiples of tap rating. With three currents in parallel it can provide up to 180 A at 900 VA for testing all instantaneous overcurrent relays.
Each voltage channel can provide variable outputs of 0–30/150/300 V at 150 VA of output power. Automatic range changing is done on-the-fly and under load. For testing a panel of relays or older electromechanical impedance relays, it has a unique flat power curve from 30 to 150 V always insuring maximum output power to the load. With the VIGEN voltage channels converted to currents, a threechannel unit can provide six currents for testing three phase current differential relays, including harmonic restraint transformer differential relays
MANUAL OPERATION
The RTMS software in conjunction with the onboard display allows the user to perform manual, steady-state, and dynamic testing quickly and easily. Ergonomically designed with the control knob and touch screen, the powerful RTMS software is extremely easy to use.
Figure 1: FREJA546 unit
The most significant feature of the RTMS software is its ability to provide
the user with a very simple way to manually test, for both commissioning and
maintenance, from the simple overcurrent relay to the most complex relays
manufactured today. Manual operation is simplified using a built-in computer
operating system and onboard display. The touch screen display and RTMS
software eliminates the need for a computer when testing virtually all types
of relays. Enhanced graphics, intuitive menu screens, and touch screen icon
buttons are provided to select the desired test function quickly and easily.
Figure 2: RTMS advanced user interface
For more details on the RTMS software test capability, see the RTMS data sheet.
FEATURES AND BENEFITS
Touch screen display – Easy to use and read, the display provides manual control of the test set. Colour contrasts accentuate vital information. This reduces human error and time in testing relays.
Constant power output – The current amplifier delivers maximum compliance voltage to the load constantly during the test, and range changing is done automatically under load. This ensures better test results and saves time by not having to turn the outputs off to change ranges. Constant power output in many cases eliminates the need to parallel and/or series current channels together to test high burdenrelays, which also saves time.
High output current – The FREJA546 provides up 32 A at 200 VA per phase continuous, or up to 60 A at 319 VA with a 1.5 second duty cycle. Three current amplifiers can be paralleled to provide a maximum of 180 A at 900 VA for testing all instantaneous overcurrent relays. PowerV™ Voltage Amplifier high power output – The FREJA546 provides a high VA output on the voltage channel at the lower critical test voltages (from 30 to 150 V). Users who want to test a panel of relays at one time, or certain older electromechanical impedance relays, find it impossible using lower VA rated voltage amplifiers.
RTMS graphics and intuitive navigation – New test graphics and intuitive screen navigation saves test time and reduces human error.
Steady-State and Dynamic test capability – The FREJA546 provides, either through manual control or computer control, both steady-state and dynamic testing of protective relays. This includes programmable waveforms with DC offset and harmonics.
Digital inputs and outputs – Up to ten programmable inputs, and six programmable outputs provide timing and logic operations in real-time with the output voltage and currents. Binary inputs can be programmed, using Boolean logic, for more complex power system simulations. This provides a low cost, closed loop, power system simulator.
Circuit breaker simulator – Binary outputs provide programmable normally closed and normally open contacts to simulate circuit breaker operation for testing reclosing relays. Sequence of operation, timing, and lockout are easily tested.
Performs transient tests – The FREJA546 can perform acceptance or troubleshooting tests by replaying digitally recorded faults, or EMTP/ ATP simulations, in the IEEE- C37.111 / IEC 60255-24, COMTRADE Standard format.
Perform end-to-end tests – Using the RTMS sequencer test with a Megger MGTR GPS satellite receiver (or suitable IRIG-B time code source input into Binary Input #1), the FREJA546 perform sate llitesynchronised end-to-end tests.
Perform multi-phase tests – The FREJA546 can be interconnected with other FREJA units to increase the total number of test currents for testing multi- phase bus differential protection schemes. For example, a three-channel FREJA546 may be interconnected with four more FREJA546 units, providing up to a maximum of 30 current channels.
Ethernet ports – The PC IN port is the primary PC connection port. The OUT ethernet port is primarily used to interconnect multiple FREJA units together for synchronous multi-unit operation may be used to connect to the IEC 61850 substation bus. The ISOLATED ethernet port provides secure isolation when testing IEC 61850 devices (for customers who require secure isolation from their IEC 61850 substation bus).
Immediate error indication – Audio and visual alarms indicate when amplitude or waveforms of the outputs are in error due to short circuit, open circuit, or thermal overload.
IEC 61850 – Optional integrated interface provides real-time testing using the IEC 61850 GOOSE and Sampled Values (IEC 61850 9-2 LE) protocols.
Low-level output capability2/3 – The current generators can provide very low current outputs ranging from 0 to 50 mA full scale or be enabled to provide a voltage output simulating a Rogowski output. In Rogowski mode, the current channel will change from a current source to a voltage source. This will allow the current channel to simulate a low-level voltage source from a Rogowski coil. There are three ranges for the Rogowski outputs: 2, 10, and 40 Volts. In the 50 mA mode, the feedback loop will stay on down to test currents as low as 5 mA. This provides test capability for generator anti-motoring and network relays, which can be set as low as 10 to 7.5 mA.
Variable voltage threshold2/3 – The variable voltage threshold will either start or stop the timer. The continuity indicator will glow (application) or not glow (removal) upon the application or removal of either an AC or DC voltage. The programmable voltage threshold is available on binary inputs 1 and 2, with a programmable range from 5 to 150 Volts AC/DC.
Open communication architecture – The FREJA546 can be used with third
party software for more flexible automated control.
Figure 3: FREJA546N non-display unit
NON-DISPLAY MODEL
A non-display model is offered for those who prefer to only run the RTMS software from a PC. This reduces cost for those not requiring a touch screen display
SPECIFICATIONS1
Input power
90 to 264 Volts AC, 1Ø, 50/60 Hz, 1800 VA.
Outputs
All outputs are independent from sudden changes in line voltage and frequency.
All outputs are regulated so changes in load impedance do not affect the
output. Each output (VIGEN) module consists of one voltage amplifier, and a
current amplifier. The voltage amplifier may be converted to a current source.
Therefore, one amplifier module may be used to test single phase current
differential relays, including harmonic restraint.
Output current sources
The FREJA546 with three VIGEN modules can provide up to six current sources: three high current/high power, and three convertible voltage channels providing lower current/high power. The per channel output current and power ratings are specified in AC RMS values and peak power ratings.
Per channel output
Output current Power Max V
50 mA2 5 VA 10.0 V RMS
1 A 5 VA 15.0 V RMS
4 A 200 VA (282 peak) 50.0 V RMS
15 A 200 VA (282 peak) 13.34 V RMS
32 A 200 VA (282 peak) 6.25 V RMS
60 A 319 VA (430 peak) 5.32 V RMS
DC 200 Watts
Duty cycle: 32 A Continuous, 60 A 1.5 seconds
Three currents channels in parallel
Output current Power Max V
12 A 600 VA (848 peak) 50.0 V RMS
45 A 600 VA (848 peak) 13.4 V RMS
96 A 600 VA (848 peak) 6.25 V RMS
180 A 957 VA (1290 peak) 5.32 V RMS
AC Low-level Rogowski output (converted current channels)2/3 Each current
channel can provide the following voltage outputs with the following Ranges:
Output voltage Max I
0 – 2 V RMS 10 mA
0 – 10 V RMS 100 mA
0 – 40 V RMS 25 mA
Duty cycle: Continuous
Two current channels in series
With two current channels in series, the compliance voltage doubles to provide
4 A at 100 V RMS and up to 32 A at 12.5 V RMS.
Figure 4: Current output power curve
Current amplifier – extended power range
The FREJA546’s current amplifier provides a unique flat power curve from 4 to
32 A per phase to permit testing of electromechanical high impedance relays,
and other high burden applications, with an extended operating range up to 60
A at 319 VA RMS for short durations.
FREJA546 and 546N
Relay Test System
AC voltage output
The FREJA546 can provide three voltage sources 0 to 300 V AC/DC.
The unit can provide a fourth AC/DC voltage source to serve as either a
reference synchronising voltage or as a battery simulator, see AC/DC AUX
voltage channel.
Outputs are rated with the following ranges:
Output voltage Power Max I
2 V2 0.02 VA 10 mA
30 V 150 VA 5 A
150 V 150 VA Variable4
300 V 150 VA 0.5 A
DC 150 Watts
Duty cycle: Continuous
Figure 5: Voltage output power curve
“PowerV™” voltage amplifier – extended power range
The FREJA546’s voltage amplifier provides a flat power curve from 30 to 150 V
in the 150 V range to permit testing of high current applications such as
panel testing, and older electromechanical distance relays which demand a
higher power voltage source to properly test.
Voltage amplifier in current mode
The voltage channels are convertible to a current source with the following
output capability. Output power ratings are specified in AC RMS values and
peak power ratings.
Output current Power Max V
5 A 150 VA (212 peak) 30.0 V RMS
15 A 120 VA 8.0 V RMS
Duty cycle: 5 A Continuous, 15 A for 1.5 seconds
AC/DC AUX voltage channel
The AC/DC AUX voltage channel can be either a variable AC voltage source to
use as a polarising or synchronising voltage source, or a battery simulator
with a variable DC output voltage.
Ranges (AC) Power Max I
30 V 100 VA 3.33 A
150 V 100 VA 0.67 A
Ranges (DC) Power Max I
30 V 100 Watts 3.33 A
250 V 100 Watts 0.4 A
Phase angle, voltage and current
Ranges
0.00 to 359.99 degrees, counter clockwise, or clockwise rotation, or
0.00 to ± 180.00 degrees
Accuracy: ± 0.02° typical, < 0.1 ° guaranteed at 50/60 Hz
Resolution: 0.001
Frequency
The output modules provide a variable frequency output with the following
ranges and accuracy.
Ranges
DC: 0.001 to 1000.000 Hz
Output amplifiers can provide transient signals with a range of DC to 10 kHz
for transient playback using IEEE-C37.111 Standard COMTRADE files.
Resolution: 0.001 Hz
Frequency accuracy: 2.5 ppm typical
25 ppm, 0° to 50° C, at 50/60 Hz maximum
AC/DC AUX: 250 ppm, 50/60 Hz maximum
Metering
Measured output quantities such as AC Amperes, AC Volts, DC Volt, DC Amperes,
and time may be simultaneously displayed on the touch screen. Pre-set AC and
DC outputs display the approximate voltage/ current output prior to
initiation. This provides a fast, easy method for pre-set of outputs. Other
values that may be displayed, depending on which test screen is in view, are
phase angle, frequency, Ohms, Watts, VA, and power factor. Accuracies are
specified from 10 to 100 % of range, 25 °C ± 5 °C, 50 to 60 Hz.
AC voltage amplitude
Accuracy: ± 0.05 % reading + 0.02 % range typical
± 0.15 % reading + 0.05 % range maximum
Resolution: 0.01
Measurements: AC RMS
Ranges: 30, 150, 300 V
AC low-level voltage output2
Range: 2 V
Accuracy: 0 – 1 V: 0.5 mV typical and 1 mV guaranteed
1 – 2 V: 0.5 mV typical and 2 mV guaranteed
Resolution: 0.001
Measurements: AC RMS
AC low-level Rogowski output (converted current channels)2/3
Range: 2 V
Accuracy: 0 – 1 V: 0.5 mV typical and 1 mV guaranteed 1 – 2 V: 0.5 mV
typical and 2 mV guaranteed
Resolution: 0.001
Measurements: AC RMS
Ranges: 10, 40 V
Accuracy: ± 0.05 % of reading + 0.02 % of range typical
± 0.15 % of reading + 0.05 % of range guaranteed
Resolution: 0.001
Measurements: AC RMS
FREJA546 and 546N
Relay Test System
AC current amplitude
Accuracy: ± 0.05 % reading + 0.02 % range typical
± 0.15 % reading + 0.05 % range maximum
Resolution: 0.001/0.01
Measurements: AC RMS
Ranges: 32, 60 A
AC low current2
Range: 50 mA
Accuracy: ± 0.5 mA typical and 1 mA guaranteed
Resolution: 0.0001
Measurements: AC RMS
DC voltage amplitude
Accuracy: 0.1 % range typical, 0.25 % range maximum
Resolution: 0.01
Measurements: RMS
Ranges: 30, 150, 300 V
DC current amplitude
Accuracy: ± 0.05 % reading + 0.02 % range typical ± 0.15 % reading + 0.05
% range maximum
Resolution: 0.001/0.01
Measurements: RMS
Range: 30 A
Convertible source in AC current mode
Accuracy: ± 0.05 % reading + 0.02 % range typical
± 0.15 % reading + 0.05 % range or ± 12.5 mA whichever is greater
Resolution: 0.001
Measurements: AC RMS
Ranges: 5, 15 A
AC/DC AUX voltage channel
AC Accuracy: ± 0.05 % reading + 0.02 % range typical ± 0.15 % reading +
0.05 % range
DC Accuracy: 0.1 % range typical, 0.25 % range maximum
Resolution: 0.01
Measurements: RMS
Ranges: 30, 150 AC/DC
Battery Simulator
The AUX voltage channel can also be used as a battery simulator with a
variable DC output ranging from 5–250 V at 100 W, 4 A max, providing
capability to power up relays with redundant power supplies. At the 250 V
range the accuracy is ±5% of reading.
Total harmonic distortion
Less than 0.1 % typical, 2 % maximum at 50/60 Hz
Timer
The timer-monitor input is designed to monitor and time-tag inputs,
like a sequence of events recorder. In addition, the binary input
controls enable the user to perform logic and/or functions, and
conditionally control the binary output relay to simulate circuit breaker,
trip, reclose, and carrier control operation in real-time. The ‘Timer’
function displays in ‘Seconds’ or ‘Cycles’, with the following range and
resolution:
Seconds: 0.0001 to 99999.9 (Auto ranging)
Cycles: 0.01 to 99999.9 (Auto ranging)
± 0.001 % of reading, typical
± 2 least significant digit
± 0.005 % of reading from 0 to 50 °C maximum
Binary input – start/stop/monitor gate
Up to 10 independent, galvanically isolated inputs monitor operation
of relay contacts or trip SCR, continuity light is provided for the input
gate. Upon sensing continuity, the lamp will glow. In addition to
serving as wet/dry contacts the binary inputs may be programmed to
trigger binary output sequence(s).
Input rating: Up to 300 V AC/DC
Variable voltage threshold:
Range: 5 – 150 V AC/DC
Accuracy: 5 – 30 V, ± 3 V
31 – 150 V, ± 6 V
Binary output relays
FREJA546 have up to six independent, galvanically isolated, output
relay contacts to accurately simulate relay or power system inputs to
completely test relays removed from the power system. The binary
output simulates normally open, or normally closed, contacts for
testing breaker failure schemes. The binary output can be configured
to change state based on binary input logic.
High current output relays 1 to 4:
AC rating: 400 V max., I max: 8 A, 2000 VA max.
DC rating: 300 V max., I max: 8 A, 80 W
Response time: < 10 ms
High speed output relays 5 and 6:
AC/DC rating: 400 V peak, I max: 1 A
Response time: < 1 ms typical
Waveform storage
Each output channel can store waveforms for playback on command.
End-to-end playback of stored waveforms is possible, when triggered
externally by a GPS receiver. Each channel can store up to 256 000
samples.
Protection
Voltage outputs are protected from short circuits and prolonged
overloads. Current outputs are protected against open circuits and
overloads.
FREJA546 and 546N
Relay Test System
www.megger.com 6
DC IN inputs (optional transducer feature)
DC IN voltage
Range: 0 to ± 10 V DC
Accuracy: ± 0.001 % reading + 0.005 % range typical
± 0.003 % reading + 0.02 % range max
Resolution: 0.001
Measurements: Average
DC IN Amperes
Ranges: 0 to ± 1 mA DC
4 to ± 20 mA DC
Accuracy: ± 0.001 % reading + 0.005 % range typical
± 0.003 % reading + 0.02 % range max
Resolution: 0.001
Measurements: Average
Environmental
Operating temperature: 32 to 122 °F (0 to 50 °C)
Storage temperature: -13 to 158 °F (-25 to 70 °C)
Relative humidity: 5 – 95 % RH, non-condensing
CE-marking
EMC EN 61326:
LVD EN/IEC 61010-1:2001 (Second Edition)
Conformance standards
Safety: EN 61010-1
Shock: EN/IEC 60068-2-27
Vibration: EN/IEC 60068-2-6
Transit drop: ISTA 1A
Free fall: EN/IEC 60068-2-32
Drop/topple: EN/IEC 60068-2-31
Electromagnetic compatibility
Emissions: EN 61326-2-1, EN 61000-3-2/3,
FCC Subpart B of Part 15 Class A
Immunity: EN 61000-4-2/3/4/5/6/8/11
Weight
30.09 lb. (13.65 kg)
Dimensions
13.25 W x 6.75 H x 10.75 D in
337 W x 172 H x 273 D mm
Enclosure and transit cases
The unit comes mounted in a rugged metal enclosure for field portability.
IEC enclosure rating: IP30
Optional hard-sided transit case is available. The robust design of the
optional hard-sided transit case provides protection when transporting the
unit over rugged terrain and long distances. An optional soft-sided case has
approximately 1 inch of padding, which provides moderate protection against
rain, dust, vibration, and shock.
FREJA546 and 546N
Relay Test System
ORDERING INFORMATION
STYLE NUMBER IDENTIFICATION
DESCRIPTIONS OF HARDWARE OPTIONS
This modular system lets you select the testing capabilities you need and expand as testing requirements change. Customise the system by selecting floating or grounded common returns, power cord, IEC 61850 test capable, standard hardware or transducer feature added, and with or without test leads. See the following descriptions:
Voltage/current module: The FREJA546 has three voltage/current
modules.
Display option: Enter the number 0 for the unit to be supplied
without a display or the number 2 for the unit to be supplied with an
onboard display.
Common returns option: The floating returns option provides
independent isolated return terminals for each output channel.
The grounded common returns option, the return terminals are
interconnected internally and connected to chassis ground. The CE
Mark, C and E units, have been certified to the IEC standards for EMC
for both the grounded and floating options. The F and G units are
designed to operate in countries which do not require the CE mark.
Hardware option:
0 = Enter the number 0 for the unit to be supplied without the
Bluetooth and low-level option.
1 = Enter the number 1 for the unit to be supplied with the Bluetooth
option.
2 = Enter the number 2 for the unit to be supplied with the low-level
option.
3 = Enter the number 3 for the unit to be supplied with the Bluetooth and
low-level option.
Power cord option: Customers can choose which type of power cord they want the unit to come with.
- A option – NEMA 5-15 to IEC60320 C13 connectors, UL and CSA approved for countries with NEMA outlets.
- I option – International colour-coded wires (light blue, brown, and green with yellow stripe) insulation jacket stripped ready for male connector with IEC 60320 C13 connector. CE marked.
- E option – CEE 7/7 “Schuko” plug to IEC 60320 C13 connector is CE marked.
- U option – United Kingdom power cord with IEC 60320 C13
connector, and 13 A fuse. BS 1363 / CE marked.
Internal software option:
0 = Enter the number 0 for the unit to be supplied with RTMS
Enhanced option.
1 = Enter the number 1 for the unit to be supplied with the IEC 61850
GOOSE hardware license enabled on the unit. The Megger GOOSE
Configurator/Sampled Values Analyser (MGC/SVA) software is
required to test and commission IEC 61850 GOOSE compliant
devices.
2 = Enter the number 2 for the unit to be supplied with the IEC 61850
9-2 LE hardware license enabled on the unit. The Megger GOOSE
Configurator/Sampled Values Analyser (MGC/SVA) software is required to test
and commission IEC 61850 9-2 LE compliant
devices.
3 = Enter the number 3 for the unit to be supplied with IEC 61850
GOOSE and IEC 61850 9-2 LE hardware licenses enabled. The Megger GOOSE
Configurator/ Sampled Values Analyser (MGC)* software is required to test and
commission IEC 61850 GOOSE.
Hardware/enclosure option: S = Standard unit. T = With transducer test capability enabled (requires 3 channel configuration). When equipped with the transducer test feature the total number of binary inputs and outputs are reduced by 1.
Test leads option: Enter the number 1 for the unit to be supplied with test leads. Enter 0 for the unit without test leads.
DESCRIPTION OF SOFTWARE OPTIONS
| Included software | Part Number |
|---|---|
| RTMS Enhanced software | 84973 |
| Optional software | |
| Megger GOOSE Configurator and Sampled Values Analyser stand-alone software |
1007-246
IEC 61850 GOOSE hardware upgrade kit| 83646
IEC 61850-9-2LE Sampled Values hardware upgrade kit| 1013-856
FREJA IEC 61850 GOOSE and IEC 61850-9-2LE Sampled Values hardware upgrade kit|
1013-938
Low-level hardware upgrade kit (includes Rogowski, low-current and variable
voltage on B/I 1 feature)2/3| 87416
DESCRIPTIONS OF SOFTWARE
Included software
Every unit is supplied with Relay Testing Management Software
(RTMS) for installing on a PC. The software does not require a security
dongle or license to operate and can be loaded on as many customerowned
computers as required. The powerful RTMS software can be run directly from a
PC providing both manual and automatic test capabilities. See the RTMS data
sheet for more detailed descriptions of test features and capabilities.
Additional optional software
Megger GOOSE Configurator software – The FREJA unit is certified by KEMA
as being compliant with IEC 61850 protocol. With the IEC 61850 GOOSE hardware
enabled, in conjunction with the Megger GOOSE Configurator (MGC) software, the
FREJA unit can be used in the testing or commissioning of IEC 61850 compliant
devices. See RTMS datasheet for details.
Figure 6: Megger GOOSE Configurator software
Megger Sampled Values Analyser software – The FREJA unit is certified by
KEMA as being compliant with IEC61850-9-2LE guidelines. With the IEC 61850
Sampled Values hardware enabled, in conjunction with the Megger Sampled Values
Analyser software, the FREJA unit is user configurable to provide Sampled
Values for testing or commissioning devices which require Sampled Values. When
configured, the FREJA unit can provide three data streams of four voltages and
four currents each.
Figure 7: Megger Sampled Values Configurator
FREJA IEC 61850 GOOSE license upgrade kit – The IEC 61850 GOOSE test feature is a hardware enabled option. RTMS software will automatically recognize if the GOOSE feature if enabled in the FREJA. There are two ways to determine if the unit has the IEC 61850 test capability enabled: First there is nameplate or a sticker on the back of the unit that will state “IEC 61850 ENABLED”. The second way to determine if the unit has been enabled is to power up the unit and go to the Configuration Screen in the RTMS software and it will either state IEC 61850 ENABLED or DISABLED. The IEC 61850 GOOSE test feature can be enabled by the customer in the field by purchasing the IEC 61850 GOOSE license upgrade kit, part number 1001-044. The kit will include an IEC 61850 GOOSE license certificate, with a unique 32-digit code number assigned specifically to the unit (requires the customer to provide the unit serial number when ordering the kit). The kit also includes step-by-step instructions on how to enable the feature with the 32-digit code.
FREJA IEC 61850 Sampled Values license upgrade kit – The IEC 61850-9-2LE Sampled Values test feature is a hardware enabled option. The IEC 61850-9-2LE Sampled Values test feature can be enabled by the customer in the field by purchasing the FREJA IEC 61850-9-2LE Sampled Values License Upgrade Kit, part number 1013- 856. The kit will include an IEC 61850-9-2LE Sampled Values License Certificate, with a unique 32-digit code number assigned specifically to the unit (requires the customer to provide the unit serial number when ordering the kit). The kit also includes step-by-step instructions on how to enable the feature with the 32-digit code.
FREJA IEC 61850 GOOSE and IEC 61850-9-2LE Sampled Values hardware upgrade kit – The IEC 61850 GOOSE the IEC 61850-9- 2LE Sampled Values test feature is a hardware enabled option. The IEC 61850 GOOSE and IEC 61850-9-2LE Sampled Values test feature can be enabled by the customer in the field by purchasing the IEC 61850 GOOSE and FREJA IEC 61850-9-2LE Sampled Values hardware upgrade kit, part number 1013-938. The kit will include IEC 61850 GOOSE and IEC 61850-9-2LE Sampled Values license certificates, with unique 32-digit code numbers assigned specifically to the unit (requires the customer to provide the unit serial number when ordering the kit). The kit also includes step-by- step instructions on how to enable these features with the 32-digit code.
TEST LEADS AND ACCESSORIES
All units are supplied with a power cord, an Ethernet communication cable, and instruction manual on a USB stick.
| Included standard accessories | Part number |
|---|
Power Cord – Depending on the style number, the unit will be supplied with one
of the following:|
Line cord, North American| 620000
Line cord, Continental Europe with CEE 7/7 Schuko Plug| 50425
Line cord, International colour-coded wire| 15065
Line cord, United Kingdom| 90002-989
Ethernet cable for interconnection to PC, 210cm (7 ft.) long (Qty. 1 ea.)|
90003-684
Instruction manual USB| 80989
TABLE OF ACCESSORIES
Test leads and accessories are supplied with the selection of the test leads option. With the test leads option, the number and type of leads varies depending on the unit that is ordered. Test leads and accessories can be ordered individually, see part numbers below.
Descriptions of test leads and accessories| Quantity| Part
number
---|---|---
| Accessory carry case: Used to carry power cord, ethernet cable, optional
STVI, test leads and accessories.| 1| 2003-725
| Sleeved pair of test leads: Sleeved test leads, one red, one black, 200 cm
(78.7”) long, 600 V, 32 A CAT II| 2| 2008-539-2
| Cable/spade lug adapter (small): Small lug fit most new relay small terminal
blocks. Lug adapter, red, 4.1 mm, rated up to 1000 V/20 A CAT II| 12| 684004
| Cable/spade lug adapter (small): Small lug fit most new relay small terminal
blocks. Lug adapter, black, 4.1 mm, rated up to 1000 V/20 A CAT II| 12| 684005
| Jumper lead: Jumper lead, black, 12.5 cm (5 in) long, use with
voltage/current outputs, 600 V, 32 A CAT II| 4| 2001-573
| Sleeved combination voltage test leads: Three common leads connect to the
test set, which are interconnected to one black common to connect to the
relay. Sleeved, three red and black, 200 cm (78.7 in) long, 600 V, 32 A CAT
II| 1| 2008-540-2
| Sleeved combination current test leads: Three pairs of leads connect to the
test set, and to the relay under test. Sleeved, three red and black, 200 cm
(78.7”) long, 600 V, 32 A CAT II| 1| 2008-541-2
TEST LEADS AND ACCESSORIES (TRANSDUCER OPTION)
The following additional test leads, and accessories are supplied with the
selection of the Transducer option. Test leads and accessories can be ordered
individually, see part numbers and descriptions below.
| Sleeved pair of test leads: Sleeved test leads, one red, one black, 200 cm
(78.7 in) long, 600 V, 32 A CAT II.| 2| 2008-539-2
| Cable/spade lug adapter (small): Small lug fit most new relay small terminal
blocks. Lug adapter, red, 4.1 mm, rated up to 1000 V/ 20 A CAT II| 2| 684004
| Cable/spade lug adapter (small): Small lug fit most new relay small terminal
blocks. Lug adapter, black, 4.1 mm, rated up to 1000 V/ 20 A CAT II| 2| 684005