339 Motor Protection System

339 Motor Protection System
Multilin™
339
MOTOR PROTECTION SYSTEM
Intuitive protection and advanced
communications for AC motors
KEY BENEFITS
• Enhanced Thermal Model including RTD and current unbalance biasing providing complete motor protection
• Easy access to information via multiple communication network
options including USB, Serial, Fiber & copper Ethernet
• Detailed Motor Health Report providing critical motor data
simplifying motor analysis
• Eliminate FT switches, needed for testing with the unique drawout construction
• Increase process uptime by trouble shooting problems faster with
time stamped event reports, waveform capture, motor start and
motor trending
• Reduced wiring with support for remote RTD’s
• Increase security and reduce potential system risks with the
Security Audit Trail capturing setting and command changes
• Customized motor overload curve using Flex curves
• Powerful communication capabilities allowing seamless
integration into most communication architectures
• Reduce setup and configuration time with the Simplified Motor
Setup screen
• Draw out and non draw out options available
APPLICATIONS
• Small to Medium sized Medium Voltage AC Motors
• Applications requiring fast and secure communications
• Protection of pumps, conveyors, fans, compressors, etc.
• Harsh environments requiring protection against corrosive chemicals and humid environments
FEATURES
Protection and Control
• Thermal model biased with RTD and negative sequence current
feedback
• Phase and ground TOC and IOC
• Start supervision and inhibit
• Mechanical Jam
• Current Unbalance
•Overvoltage
•Undervoltage
• Under/Over Frequency
• Voltage Phase Reversal
• Acceleration Time
• Undercurrent / Underpower
• Starts per Hour
Metering & Monitoring
• Current Metering
• RTD Temperature
• Voltage Metering
• Power & Energy Metering
• Frequency Metering
• Event Recorder: 256 events with 1ms time stamping
• Oscillography with 32 samples per cycle and digital states
• IRIG-B clock synchronization
• Motor health diagnostics
• Security audit trail
User Interface
• 4X20 character LCD display
• Control panel with 12 LED indicators
EnervistaTM Software
• Enervista Software- an industry-leading suite of software tools
that simplifies every aspect of working with Multilin devices
• Simplified motor setting configurator
• Front USB and rear serial & Ethernet ports
• Multiple Protocols:
IEC® 61850
IEC 61850 GOOSE
MODBUS TCP/IP, MODBUS RTU,
DNP 3.0, IEC 60870-5-104, IEC 60870-5-103
339 Motor Protection System
Overview
The 339 relay is a member of the 3 Series
family of Multilin relays. This motor
protective device is used to perform
primary motor protection of medium
voltage motor applications.
The basic protection functions of this
relay include motor thermal model, timedelayed and instantaneous overcurrent,
ground overcurrent and sensitive ground
overcurrent protection. Additional control
features such as logic control are available
for applications that require additional
motor control functionality.
The robust 339 streamlines user work flow
processes and simplifies engineering tasks
such as configuration, wiring, testing,
commissioning, and maintenance. This
cost-effective relay also offers enhanced
features such as diagnostics, preventative
maintenance, motor health reports and
advanced security features.
Easy to Use
Easy to Configure
Drawout Construction
Fast & Simple Configuration
The 339 offers a complete drawout
feature eliminating the need for rewiring
after testing has been concluded. The
withdrawable feature also eradicates
the need to disconnect communication
cables, e.g. fiber, copper, RJ45, etc and
helps retain communication status even
after a relay has been withdrawn from its
case.
Providing ease-of-use functionality, the
339 allows for motor configuration in a
simple one page setup screen. Therefore
complete motor protection setup can be
completed in one easy step.
Effortless Retrofit
The compact and withdrawable feature
of the 339 relay minimizes mounting
requirements, enables easy retrofit to
existing cases, and allows multiple relays
to be mounted side by side on a panel.
The 339 also provides a pluggable RS485
& IRIG-B connection for easy trouble
shooting.
Advanced
Communications
Easy integration into new or
existing infrastructure
With several Ethernet and serial port
options, and a variety of communication
protocols, the 339 provides advanced and
flexible communication selections for new
and existing applications.
339 Relay Features
2
Easy to Configure - 1 simple step
Advanced & Flexible
Communication Options
Easy to Use - Draw out case
Diagnostic Alarms
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339 Motor Protection System
Enhanced Diagnostics
Multiple Options
Over/Under Voltage Protection
Preventative Maintenance
Several options for protection and
communications are provided to match
basic to high end application requirements.
Overvoltage/Undervoltage protection
features can cause a trip or generate
an alarm when the voltage exceeds a
specified voltage setting for a specified
time.
The 339 allows user to track relay exposure
to extreme environmental conditions by
monitoring and alarming at high or low
temperatures. This data allows users to
proactively schedule regular maintenance
work and upgrade activities.
Protection & Control
Failure Alarm
The 339 detects and alarms on
communication port and IRIG-B failures.
The 339 also enables users to analyze
system performance via diagnostics
information such as event records,
oscillography, etc. It issues detailed motor
health reports and alarms when thresholds
are exceeded.
The 339 motor protection system is
designed to protect and manage small
to medium sized AC motors and driven
equipment . Flexible and powerful, the
339 provides advanced motor protection,
control and monitoring in one integrated,
economical draw-out design. The 339
contains a full range of self contained
protection and control elements as
detailed in the Functional Block Diagram
and Features table.
Frequency Protection
Motor Thermal Model
Unbalance (Negative Sequence)
Biasing
To provide optimal protection and
maximum runtime, the 339 Motor
Protection System employs GE’s Industry
leading advanced Thermal Model,
consisting of six key elements:
Cost Effective
Robust Design
The 339 is subjected to Accelerated
Life Testing (ALT) to validate accurate
relay functions under specified normal
conditions. The device is further tested for
durability through High Accelerated Life
Testing (HALT), undergoing stress testing
for extreme operating conditions.
• Overload Curves
• Unbalance Biasing
• Hot/Cold Safe Stall Ratio
• Motor Cooling Time Constants
• Thermal Inhibit and Emergency Restart
• RTD Biasing
Reduced Life Cycle Cost
FlexCurves™
The 339 is designed to reduce total
installation and life cycle cost for motor
protection. The draw out construction
of the device reduces downtime during
maintenance and decreases extra
wiring needed for relay testing and
commissioning.
A smooth custom overload curve is created
using FlexCurves. These curves can be
used to protect motors with different
rotor damage and stator damage curves,
allowing total motor design capacity with
complete protection.
The 339 offers overfrequency and
underfrequency protection elements
that provide the ability to detect when
the motor is operating at off-nominal
frequencies which can cause damage to
the process. In such cases, the protection
elements can trip the motor off-line or can
be used to signal to upstream protection
and control devices to implement loadshedding schemes.
Negative sequence current, which causes
additional rotor heating, is not accounted
for in the thermal limit curves provided
by the manufacturer. The 339 measures
current unbalance as a ratio of negative
to positive sequence current. The thermal
model is then biased to reflect the
additional rotor heating.
RTD Biasing
The Thermal Model relies solely on
measured current to determine
motor heating, assuming an ambient
temperature of 40°C and normal motor
cooling. The actual motor temperature will
increase due to abnormally high ambient
temperatures or if the motor cooling
systems have failed.
RTD Biasing enhances the motor thermal
Functional Block Diagram
BUS
ANSI® Device Numbers & Functions
52
27P 59P
47 59_2 81O 81U
37
49
46
50P 50BF 51 50N
Phase CT 3
50G
Ground CT 1
RTD
Stator RTDs
Bearing RTDs
49
TRIP
CLOSE
38
START
START INHIBIT
LOAD
MOTOR
Optional Remote RTD
Ambient air
86
339
MOTOR PROTECTION SYSTEM
Device Number Function
27P
Phase UV
37
Undercurrent,
Underpower
38
Bearing RTD, Stator/
Ambient/Other, RTD
Trouble Alarm
46
Current Unbalance
47
Voltage Phase Reversal
48
Acceleration Time
49
Thermal Protection/Stall
Protection
50BF
Breaker Failure / Welded
Contactor
50G
Ground Fault
Device Number
50P
51P
50N
59_2
59P
66
81O
81U
86
VTFF
Function
Short Circuit
Mechanical Jam
Neutral Instantaneous
Overcurrent
Negative Sequence OV
Phase OV
Starts per Hour & Time
Between Starts, Restart
Block, Thermal Inhibit
Overfrequency
Underfrequency
Lockout
VT Fuse Failure
896814.CDR
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3
339 Motor Protection System
Motor Cool Time Constants
The 339 has a true exponential cooldown
characteristic which mimics actual motor
cooling rates, providing that motor cooling
time constants are available for both the
stopped and running states. When ordered
with RTD’s the stopped and running cool
time constants will be calculated by the
339 based on the cooling rate of the
hottest RTD, the hot/cold stall ratio, the
ambient temperature, the measured
motor load and the programmed service
factor or overload pickup.
Start Inhibit
The Start Inhibit function prevents starting
of a motor when insufficient thermal
capacity is available or a motor start
supervision function dictates inhibit.
3 ACCELERATION SAFETIME (ROTOR LIMITED )
4 MOTOR CURRENT @ 100% VOLTAGE
1000
5 MOTOR CURRENT @ 80% VOLTAGE
1, 000
1
S
2
TIME TO TRIP IN SECOND
100
100
CU RV E
15
12
9
7
10
3
10
4
5
1.0
4
3
Undercurrent
The undercurrent function is used to detect
a decrease in motor current caused by a
decrease in motor load. This is especially
useful for indication of conditions such as:
4
500
600
700
800
900
1000
400
Phase Current
Full Load
Setpoint
(Multiples of full load)
15 Standard Curves available in the 339.
Typical Flexcurve
loss of suction for pumps, loss of airflow
for fans, or a broken belt for conveyors. A
separate undercurrent alarm may be set
to provide early warning.
ground or residual ground currents. The
ground fault trip can be instantaneous or
programmed for a time delay.
RTD Protection
Mechanical Jam
The 339 provides programmable RTD
inputs via the remote RMIO that are used
for monitoring the Stator, Bearing and
Ambient temperatures. Each RTD input has
2 operational levels: alarm and trip. The
339 supports RTD trip voting and provides
open and short RTD monitoring.
During overload conditions, quick motor
shutdown can reduce damage to gears,
bearings and other mechanical parts
associated with the drive combination.
Ground Overcurrent
For zero sequence ground overcurrent
protection, all three of the motor
conductors must pass through a separate
ground CT. CTs may be selected to detect
either high-impedance zero sequence
The remote RMIO RTD module is used with
the 339 in cases where RTD monitoring is
required.
Thermal Capacity Used
100
90
80
These elements guard the motor against
excessive starting duty, which is normally
defined by the motor manufacturer in
addition to the thermal damage curves.
300
MULTIPLE OF FULL LOAD CURRENT SETPOINT
10
Motor Start Supervision
Motor Start Supervision consists of the
following features: Time-Between-Starts,
Starts-per-hour, Restart Time.
200
50
60
70
80
90
100
40
30
20
5
4
3
0.1
1
1
0.1
6
7
8
9
10
2
1
2
The ratio defines the steady state level of
thermal capacity used (TCU) by the motor.
This level corresponds to normal operating
temperature of a fully loaded motor and
will be adjusted proportionally if the motor
load is lower than rated.
2 RUNNING SAFETIME (STATOR LIMITED)
0.5
Hot / Cold Safe Stall Ratio
FAN MOTO R
1 PROGRAMMED 339 CUSTOM CURVE
0.6
0.7
0.8
0.9
1
RTD Biasing does not replace the TCU
calculated using the motor current . It
provides a second and independent
measure of thermal capacity used.
Based on a programmable curve, the
339 will calculate the TCU at any given
temperature. This TCU is then compared to
that of the thermal model, and the larger
of the two will be used.
6500 H P, 138 00 Volt INDUCED DRAFT
10000
10, 000
TRIP TIME (seconds)
model by calculating the thermal capacity
used based on available Stator RTD
temperatures.
FLC Reduction S et @ 20 %
& 100% FLC .
70
60
50
FLC Reduction Set @ 8%
& 40% FLC
40
30
20
10
0. 00
0. 00
27
55
82
Motor cooling curves
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110
137
165
192
220
247
TIME
(in seconds)
339 Motor Protection System
Inputs/Outputs
The 339 features the following inputs and
outputs for monitoring and control of
typical motor applications:
• 10 contact Inputs with programmable
thresholds
• 2 Form A output relays for breaker trip
and close with coil monitoring
• 5 Form C output relays
Advanced Automation
Logic Elements
The 339 relay has sixteen Logic Elements
available for the user to build simple
logic using the state of any programmed
contact, virtual, or remote input, or an
output operand from protection, or control
elements.
The logic provides for assigning up to three
triggering inputs in an “AND/OR” gate for
the logic element operation and up to
three blocking inputs in an “AND/OR” gate
for defining the block signal. Pickup and
dropout timers are available for delaying
the logic element operation and reset
respectively.
Virtual Inputs
Virtual inputs allow communication devices
the ability to write digital commands to
the 339 relay. These commands could be
starting or stopping the motor, changing
setting groups or blocking protection
elements.
IEC 61850
The 339 supports IEC 61850 Logical Nodes
which allows for digital communications
to DCS, SCADA and higher level control
systems.
In addition, the 339 also supports IEC
61850 GOOSE communication, providing
a means of sharing digital point state
information between 339’s or other IEC
61850 compliant IED’s.
• Eliminates the need for hardwiring
contact inputs to contact outputs via
communication messaging.
• Transmits information from one relay to
the next in as fast as 8 ms.
• Enables sequence coordination with
upstream and downstream devices.
• When Breaker Open operation
malfunctions, GOOSE messaging sends
a signal to the upstream breaker to trip
and clear the fault.
This provides the information required
to determine sequence of events which
facilitates diagnosis of relay operation.
Event types are individually maskable in
order to avoid the generation of undesired
events, and includes metered values and
status of all the protection elements at the
moment of the event.
Oscillography
The 339 captures current and voltage
waveforms and digital channels at 32
samples per cycle. The oscillography record
captures 8 individual channels allowing
for detailed analysis. The oscillography is
triggered either by internal signals or an
external contact.
Statistical Data
The 339 records the following statistical
data in order to assist in diagnosing
common motor faults, as well as assisting
in planning preventative maintenance.
• Total running hours
• Number of motor starts
• Total number of motor trips
Monitoring & Diagnostics
Pre-Trip Alarms
Event Recording
The 339 can trigger an alarm prior to a trip
caused by the following conditions:
Events consist of a broad range of change
of state occurrences, including pickups,
trips, contact operations, alarms and self
test status. The 339 stores up to 256 events
time tagged to the nearest millisecond.
• Thermal Overload
• Ground Fault
•Unbalance
•Undercurrent
Sixteen logic elements available for simple logic for applications such as manual control, interlocking, and peer to peer tripping.
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339 Motor Protection System
• Average Motor Load
• Broken RTD sensor
• Average Phase currents
• Internal self-test
• Current unbalance
Security Audit Trail
• Ground current
In accordance with NERC CIP security
reporting requirements and to provide
complete traceability, the 339 maintains a
history of the last 10 changes made to the
339 configuration, including modifications
to settings and firmware upgrades. In
addition, the Security Audit Trail records
the last ten commands sent to the relay
through communications or from the front
panel.
Advanced Device Health
Diagnostics
The 339 performs comprehensive device
health diagnostic tests during startup
and continuously at runtime to test
its own major functions and critical
hardware. These diagnostic tests monitor
for conditions that could impact system
reliability. Device status is communicated
via SCADA communications and the front
panel display. This continuous monitoring
and early detection of possible issues helps
improve system availability by employing
predictive maintenance.
IRIG-B
IRIG-B is a standard time code format
that allows time stamping of events
to be synchronized among connected
devices within 1 milliseconds. An IRIG-B
input is provided in the 339 to allow time
synchronization using a GPS clock over a
wide area. The 339 IRIG-B supports both
AM and DC time synchronization with
an auto detect feature that removes the
requirement for manual selection.
Metering
Actual Values
The 339 provides users with the following
metering information in order to accurately
monitor the operating conditions of the
motor:
• Current: Ia, Ib, Ic, In, Ig, Isg
• Phase-to-phase and phase-to-ground
voltages: Van, Vbn, Vcn, Vab, Vbc, Vca
• Active power (3-phase) kW
• Reactive power (3-phase) kVAR
• Current Unbalance
• Listing of modified changes
• Motor load current as a % of full load
• Method of setting changes - Keypad,
Front serial port, Ethernet, etc. • Motor thermal capacity used
• Stator/Bearing/Ambient RTD
temperature
Based on the graphical representation and
trended values of the motor data gathered
by the 339, this enables users to quickly
identify process and motor issues prior to
a process failure.
The 339 Motor Health Report provides a
summary page detailing information on
related motor performance.
The following information is detailed in the
339 Motor Health Report:
• Starting Current
• Thermal capacity used during starting
• If Password was required to change
settings
• MAC address of user making setting
changes
The Multilin 339 relay provides motor
diagnostic information in a legible easy to
use format that enables the user to make
informed decisions on the health of their
motor.
• Motor Acceleration Time
Security Setting Report includes the
following information:
• Frequency
Motor Health Report
6
Security
• RTD over temperature
The Motor Heath Report allows you to easily “see”
how your motor is doing:
•
•
•
•
Start/stop history
Comprehensive trip details
Learned acceleration time and starting current
Many other motor health details
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339 Motor Protection System
Password Control
With the implementation of the Password
Security feature in the 339 relay, extra
measures have been taken to ensure
unauthorized changes are not made to
the relay. When password security is
enabled, changing of setpoints or issuing
of commands will require passwords
to be entered. Separate passwords
are supported for remote and local
operators, and separate access levels
support changing of setpoints or sending
commands.
Advanced
Communications
The 339 utilizes the most advanced
communication technologies today
making it the easiest and most
flexible motor protection relay to use
and integrate into new and existing
infrastructures. Multiple communication
ports and protocols allow control and
easy access to information from the 339.
All communication ports are capable of
communicating simultaneously.
The 339 supports the most popular
industry standard protocols enabling easy,
direct integration into electrical SCADA
and HMI systems. Modbus RTU is provided
as standard with a RS485 networking
port. The following optional protocols are
available:
• IEC 61850
• IEC 61850 GOOSE
• DNP 3.0,
• Modbus RTU,
The Simplified Motor Setup will generate
a complete 339 setting file based on the
motor nameplate and system information
entered by the user. Once all the
information is entered, the Simplified Motor
Setup will generate the settings file, as well
as provide the documentation indicating
which settings were enabled, along with
an explanation of the specific parameters
entered. The Simplified Motor Setup will
provide a detailed setting file in PDF format
that can be saved or printed for future
reference.
• Modbus TCP/IP,
• IEC 60870-5-104,
• IEC 60870-5-103
Easy to Use
Simplified Motor Setting
Included with every 339 Motor Protection
System is the Multilin Simplified Motor
Setup. The Simplified Motor Setup
provides users with a quick and easy
method to setup and start the motor and
process in applications that require fast
commissioning.
Enervista Software
The Enervista suite is an industry leading set
of software programs that simplifies every
aspect of using the 339 relay. The Enervista
suite provides all the tools to monitor the
status of the protected asset , maintain
the relay, and integrate the information
measured into DCS or SCADA monitoring
systems. Convenient COMTRADE and
sequence of event viewers are an integral
part of the 339 set up software and are
included to ensure proper protection and
system operation.
Launchpad
Enervista Launchpad is a powerful software
package that provides users with all of
the set up and support tools needed for
configuring and maintaining GE products.
The setup software within Launchpad
allows configuring devices in real time by
communicating using serial, Ethernet or
modem connections, or offline by creating
setting files to be sent to devices at a later
time.
Included in Launchpad is a document
archiving and management system
that ensures critical documentation is
up-to-date and available when needed.
Documents made available include:
•Manuals
• Application Notes
• Guideform Specifications
•Brochures
• Wiring Diagrams
•FAQs
Trace any setting changes with security audit trail
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339 Motor Protection System
Power System Troubleshooting
• Service Bulletins
Analyze power system disturbances with transient fault recorder and event records
Viewpoint Monitoring
Viewpoint Monitoring is a simple to use
and full featured monitoring and data
recording software package for small
systems. Viewpoint monitoring provides a
complete HMI package with the following
functionality:
• Plug and play device monitoring
• System single line monitoring and
control
• Annunciator alarm screens
• Trending reports
• Automatic event retrieval
• Automatic waveform retrieval
Viewpoint Maintenance
Viewpoint Maintenance provides tools that
will increase the security of the 339 Motor
Protection System. Viewpoint Maintenance
will create reports on the operating status
of the relay, and simplify the steps to
troubleshoot protected motors.
The tools available
Maintenance include:
in
EnerVista Integrator
Viewpoint
EnerVista Integrator is a toolkit that allows
seamless integration of Multilin devices
into new or existing automation systems.
Included in the EnerVista Integrator is:
• Settings Security Audit Trail
• Device Health Report
• Comprehensive Fault Diagnostics
• OPC/DDE Server
• Multilin Devices
• Automatic Event Retrieval
• Automatic Waveform Retrievel
Dimensions
DRAW-OUT
DESIGN
Front
Top
NON DRAW-OUT
DESIGN
in
mm
in
mm
H
7.93
201.5
7.98
202.7
W
6.62
168.2
6.23
158.2
D
9.62
244.2
9.35
237.5
W1
3.96
100.6
3.96
100.6
D1
7.89
200.4
7.88
200.2
D2
1.73
43.8
1.47
37.3
H1
6.82
173.2
6.82
173.2
W1
H
D2
W
Rear
D1
D
Side
H1
8
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339 Motor Protection System
Wiring Diagram
A
B
A
B
C
MOTOR
WYE VT
CONNECTION
CONTROL
POWER
+
E9 D9 E10D10E11D11
E5 D5 E6 D6 E7 D7 E8 D8 E12 D12
VA VA VB VB VC VC
1A/5A COM 1A/5A COM 1A/5A COM 1A/5A COM 50:0.025 COM
B1 A1
B2
+ -
chassis
gnd
POWER SUPPLY
PHASE A PHASE B PHASE C GROUND SENS GROUND
CURRENT INPUTS
VOLTAGE INPUTS
BREAKER CONTROL CIRCUIT
STOP
Breaker Aux Contacts
52a
52b
H
L
A2
C1
52a
C2
C3
52b
C4
INPUT 4
INPUT 3
C5
INPUT 5
C6 INPUT 6
C7
INPUT 7
339
Motor Protection System
V
2 CLOSE
DC
TRIP
COIL
START
52b
CLOSE
COIL
A4
3 START
INHIBIT
B5
A5
B6
A6
B7
4 AUXILIARY
A7
C11 COMMON
C12 CHASSIS GND
+
A3
B4
V
C8 INPUT 8
C9 INPUT 9
C10 INPUT 10
52a
B3
1 TRIP
DIGITAL INPUTS
C
B8
A8
5 AUXILIARY
Front Panel
B9
A9
USB
B10
A10
TYPE B
6 AUXILIARY
USB
B11
4 WIRE USB
Rear Panel
COMMUNICATIONS
ETHERNET
RJ45
MTRJ
4 WIRE ETHERNET
RMIO
- +
10/100 BASE-T 100 BASE-FX
OPTIONAL
RS485
A11
7 CRITICAL
FAILURE
B12
A12
IRIG-B
SELF TEST ANNUNCIATOR
- + - +
F8 F7 F6 F5 F4 F3 F2 F1
CONTACTOR CONTROL CIRCUIT
CONTROL
POWER
A2
+
B3
1 NOT USED
V
A3
B4
2 NOT USED
A4
V
3 START
INHIBIT
OPEN DELTA VT CONNECTION
B5
A5
B6
A6
B7
4 TRIP
STOP
START
CONTACTOR
COIL
A7
B8
A8
5 AUXILIARY
6 AUXILIARY
CC
B9
A9
B10
A10
B11
E9 D9 E10D10 E11 D11
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7 CRITICAL
FAILURE
A11
B12
A12
SELF TEST ANNUNCIATOR
9
339 Motor Protection System
User Interface
IN SERVICE: This indicator will be on continuously lit if the
relay is functioning normally and no major self-test errors
have been detected.
TROUBLE: Trouble indicator LED will be AMBER if there is a
problem with the relay or if relay is not programmed.
LOCKOUT: Lockout initiates when a lockout trip is active.
RUNNING: Indicates that the motor is running in normal
operation
STOPPED: Indicates that the motor is stopped
STARTING: Indicates that the motor is in the starting process
TRIP: Indicates that the relay has tripped the motor offline
based on predefined programmed conditions.
ALARM: Indicates that the motor is currently operating in an
alarm condition and may proceed to a trip condition if not
addressed.
MAINTENANCE: Environmental alarms such as ambient
temperature alarm, coil monitor or trip counter.
The display messages are organized into Main Menus, Pages,
and Sub-pages.
There are four main menus labeled Actual Values, Quick
Setup, Setpoints, and Maintenance. Pressing the MENU key
followed by the MESSAGE key scrolls through the four Main
Menu Headers.
The ten button keypad allows users easy access to relay
configuration and information.
USER INTERFACE OPTIONS:
Draw out and non draw out options available
Technical Specifications
PASSWORD SECURITY
Master Reset
8 to 10 alpha-numeric characters
Password:
Settings Password: 3 to 10 alpha-numeric characters
for local or remote access
Control Password: 3 to 10 alpha-numeric characters
for local or remote access
NEUTRAL INSTANTANEOUS OVERCURRENT (50N)
Pickup Level:
0.05 to 20 x CT in steps of 0.01 x CT
Dropout Level:
96 to 99% of Pickup @ I > 1 x CT
Pickup - 0.02 x CT @ I <1 x CT
Time Delay:
0.00 to 300.00 sec in steps of 0.01
Operate Time:
<30 ms @ 60Hz (I > 2.0 x PKP), 0 ms
time delay
<35 ms @ 50Hz (I > 2.0 x PKP), 0 ms
time delay
Timer Accuracy:
0 to 1 cycle
Level Accuracy:
per CT input
Elements:
Trip or Alarm
NEUTRAL DIRECTIONAL OVERCURRENT (67N)
Directionality:
0.005 to 3 x CT in steps of 0.001 x T
Polarizing:
Voltage, Current, Dual
Voltage can be:
- Calculated from VT phases (VTs
must be connected in
“Wye”)
- Measured by Vaux input (3V0
provided by an external open
delta connection)
Polarizing Voltage: -V0
Polarizing Current: IG
MTA:
From 0° to 359° in steps of 1°
Angle Accuracy:
±2°
Operation Delay:
20 to 30 ms
UNDERCURRENT
Pickup Level:
Dropout Level:
Time Delay:
Block from Start:
Pickup Accuracy:
Timing Accuracy:
Level Accuracy:
Elements:
10
0.1 to 0.95 x FLA in steps of 0.01
x FLA
101 to 104% of Pickup
1.00 to 60.00 s in steps of 0.01 s
0 to 600 s in steps of 1 s
as per phase current inputs
±0.5 s or ± 0.5% of total time
per CT input
Trip or Alarm
CURRENT UNBALANCE
Unbalance Pickup 4 to 40% in steps of 1%
Level:
Unbalance Time
1.00 to 60.00 s in steps of 0.01 s
Delay:
Single Phasing
unbalance level > 40% or when Iavg
Pickup Level:
≥25%FLA and current in
any phase is less than the cutoff
current
Single Phasing
2 sec
Time Delay:
Dropout Level:
96 to 99% of pickup
Pickup Accuracy:
±2%
Timing Accuracy:
±0.5 s or ± 0.5% of total time
Unbalance
Trip and Alarm
Elements:
Single Phasing
Trip
Elements:
RTD
Pickup:
Pickup Hysteresis:
Time Delay:
Elements:
1 to 250°C in steps of 1°C
2°C
3 sec
Trip and Alarm
RTD TROUBLE ALARM
RTD Trouble Alarm: <-50°C or >250°C
LOAD INCREASE ALARM
Pickup Level:
50 to 150%FLA in steps of 1%FLA
Dropout Level:
96 to 99% of Pickup
Alarm Time Delay: 1.00 to 60.00 s in steps of 0.01 s
Pickup Accuracy:
as per phase current inputs
Timing Accuracy:
±0.5 s or ±0.5% of total time
SHORT CIRCUIT
Pickup Level:
Dropout Level:
Alarm Time Delay:
Pickup Accuracy:
Operate Time:
Timing Accuracy:
Elements:
1.00 to 20.00 x CT in steps of 0.01 x CT
96 to 99% of Pickup @ I > 1 x CT
Pickup - 0.02 x CT @ I < 1 x CT
0.00 to 60.00 s in steps of 0.01 s
as per phase current inputs
<30 ms @ 60Hz (I > 2.0 x PKP), 0 ms
time delay
<35 ms @ 50Hz (I > 2.0 x PKP), 0 ms
time delay
0 to 1 cycle
Trip or Alarm
GEDigitalEnergy.com
MECHANICAL JAM TRIP
Pickup Level:
1.01 to 4.50 x FLA in steps of 0.01 x
FLA, blocked from start
Dropout Level:
96 to 99% of Pickup
Trip Time Delay:
0.10 to 30.00 s in steps of 0.01 s
Pickup Accuracy:
as per phase current inputs
Operate Time:
<30 ms @ 60Hz (I > 2.0 x PKP), 0 ms
time delay
<35 ms @ 50Hz (I > 2.0 x PKP), 0 ms
time delay
Timing Accuracy:
±0.5 s or ±0.5% of total time
GROUND FAULT
Pickup Level:
Dropout Level:
Alarm Time Delay
on Run:
Alarm Time Delay
on Start:
Trip Time Delay
on Run:
Trip Time Delay on
Start:
Pickup Accuracy:
Operate Time:
Timing Accuracy:
Elements:
0.03 to 1.00 x CT in steps of 0.01 x CT
0.50 to 15.00 A in steps of 0.01 A
(CBCT)
Pickup - 0.02 x CT
96 to 99% of Pickup (CBCT)
0.00 to 60.00 s in steps of 0.01 s
0.00 to 60.00 s in steps of 0.01 s
0.00 to 5.00 s in steps of 0.01 s
0.00 to 10.00 s in steps of 0.01 s
as per ground current inputs
<30 ms @ 60Hz (I > 2.0 x PKP), 0 ms
time delay
<35 ms @ 50Hz (I > 2.0 x PKP), 0 ms
time delay
0 to 1 cycle
Trip and Alarm
PHASE/AUXILIARY UNDERVOLTAGE
Pickup Level:
1 to 100% Hz MNR 1%
Dropout Level:
101% to 104% of Pickup
Time Delay:
1.0 to 60.0 s in steps of 0.1
Pickup Accuracy:
as per power monitoring
specification
Timing Accuracy:
±0.5 s or ±0.5% of total time
Elements:
Trip and Alarm
339 Motor Protection System
Technical Specifications (Continued)
THERMAL PROTECTION (49)
Locked Rotor
2.0 to 11.0 x FLA in steps of 0.1 x FLA
Current:
Safe Stall Time:
1.0 to 600.0 s in steps of 0.1 s
Curve Multiplier:
1 to 15 in steps of 1
Pickup Level:
1.01 to 1.25 x FLA in steps of 0.01 x
FLA
Curve Biasing:
Phase unbalance
Hot/cold biasing
Stator RTD biasing
Exponential Running and Stopped
Cooling Rates
TCU Update Rate: 3 cycles
Pickup Accuracy:
per phase current inputs
Timing Accuracy:
± 200 ms or ±2% of total time
Elements:
Trip and Alarm
PHASE/AUXILIARY UNDERVOLTAGE (27P/27X)
Minimum Voltage: Programmable from 0.00 to 1.25 x VT
in steps of 0.01
Pickup Level:
0.00 to 1.25 x VT in steps of 0.01
Dropout Level:
101 to 104% of pickup
Curve:
Definite Time, Inverse Time
Time Delay:
0.1 to 600.0 s in steps of 0.1
Operate Time:
Time delay ±30 ms @ 60 Hz (V < 0.85
x PKP)
Time delay ±40 ms @ 50 Hz (V < 0.85
x PKP)
Time Delay
±3% of expected time, or 1 cycle,
Accuracy:
whichever is greater
Level Accuracy:
Per voltage input
NEGATIVE SEQUENCE/PHASE OVERVOLTAGE (59P/59_2)
Pickup Level:
0.00 to 1.25 x VT in steps of 0.01
Dropout Level:
96 to 99% of pickup
Time Delay:
0.1 to 600.0 s in steps of 0.1
Operate Time:
Time delay ±30 ms @ 60 Hz (V < 0.85
x PKP)
Timing Accuracy:
±0.5 s or ±0.3% of total time
Level Accuracy:
Per voltage input
PHASE REVERSAL (47)
Configuration:
ABC or ACB phase rotation
Time Delay:
100 ms
Timing Accuracy:
±0.5 s
Elements:
Trip or Alarm
UNDERFREQUENCY (81U)
Minimum Voltage: 0.00 to 1.25 x VT in steps of 0.01
Pickup Level:
40.00 to 70.00 Hz in steps of 0.01
Dropout Level:
Pickup +0.03 Hz
Time Delay:
0.1 to 600.0 s in steps of 0.1
Timing Accuracy:
±0.5 s or ±0.5% of total time
Level Accuracy:
±0.01 Hz
Elements
Trip and Alarm
OVERFREQUENCY (81O)
Minimum Voltage: 0.3xVT
Pickup Level:
40.00 to 70.00 Hz in steps of 0.01
Dropout Level:
Pickup -0.03 Hz
Time Delay:
0.1 to 600.0 s in steps of 0.1
Timing Accuracy:
±0.5 s or ±0.5% of total time
Level Accuracy:
±0.01 Hz
Elements
Trip and Alarm
ACCELERATION TIME TRIP
Pickup Level:
Motor start condition
Dropout Level:
Motor run, trip, or stop condition
Timers for
Stopped to running
single-speed:
Timers for
Stopped to high speed, stopped to
two-speed:
low speed, low to high
speed
Time Delay:
1.0 to 250.0 s in steps of 0.1
Timing Accuracy:
±200 ms or ±1% of total time
MOTOR DATA LOGGER
Length:
6 buffers, containing a total of 30
seconds of motor starting
data
Trigger:
Motor start status
Trigger Position:
1-second pre-trigger duration
Logging Rate:
1 sample/200 ms
METERING SPECIFICATIONS
Parameter
3-Phase Real Power (kW)
3-Phase Reactive Power (kvar)
3-Phase Apparent Power (kVA)
3-Phase Positive Watthour (MWh)
3-Phase Negative Watthour (MWh)
3-Phase Positive Varhour (Mvarh)
3-Phase Negative Varhour (Mvarh)
Power Factor
Frequency
Accuracy
±1% of full scale
±1% of full scale
±1% of full scale
±1% of full scale
±1% of full scale
±1% of full scale
±1% of full scale
±0.05
±0.05 Hz
FUSE FAIL
Time Delay:
Timing Accuracy:
Elements
DATA LOGGER
Number of
Channels:
Parameters:
Sampling Rate:
Trigger Source:
Mode:
START INHIBIT
Thermal Start
Inhibit:
Starts per Hour
Inhibit:
Time Between
Starts Inhibit:
Restart Inhibit:
1s
±0.5 s
Trip or Alarm
10
Any available analog actual value
1 cycle, 1 second, 1 minute, 1 hour
All logic elements, Logic operand:
Any Trip PKP/OP/DPO, Any
Alarm PKP/OP/DPO
Continuous or triggered
TRANSIENT RECORDER
Buffer size:
3s
No. of buffers:
1x192, 3x64, 6x32
No. of channels:
14
Sampling rate:
32 samples per cycle
Triggers:
Manual Command
Contact Input
Virtual Input
Logic Element
Element Pickup/Trip/Dropout/Alarm
Data:
AC input channels
Contact input state
Contact output state
Virtual input state
Logic element state
Data storage:
RAM - battery backed-up
EVENT RECORDER
Number of events:
Content:
Data Storage:
256
event number, date of event, cause
of event, per-phase current, ground
current , sensitive ground current ,
neutral current, per-phase voltage
(VTs connected in “Wye”), or phasephase voltages (VTs connected in
“Delta”), system frequency, power,
power factor, thermal capacity,
motor load, current unbalance
Non-volatile memory
LEARNED DATA RECORDER
Number of events: 250
Header:
Date, number of records
Content:
learned acceleration time , learned
starting current , learned starting
capacity, last starting current, last
starting capacity, last acceleration
time , average motor load learned,
average run time after start (days),
average run time after start (minutes)
Data Storage:
Non-volatile memory
CLOCK
Setup:
Date and time
Daylight Saving Time
RTC Accuracy: ± 1 min / month at
25°C
Auto-detect (DC shift or Amplitude
Modulated)
Amplitude modulated: 1 to 10 V
pk-pk
DC shift: 1 to 10 V DC
Input impedance: 40 kOhm ± 10%
IRIG-B:
LOGIC ELEMENTS
Number of logic
elements:
Trigger source
inputs per
element:
Block inputs per
element:
Supported
operations:
Pickup timer:
Dropout timer:
16
3
3
AND, OR, NOT, Pickup / Dropout
timers
0 to 6000 ms in steps of 1 ms
0 to 6000 ms in steps of 1 ms
BREAKER CONTROL
Operation:
Asserted Contact Input , Logic
Element, Virtual Input, Manual
Command, Remote Input
Function:
Opens/closes the motor breaker
Resolution
0.1 kW
0.1 kvar
0.1 kVA
±0.001 MWh
±0.001 MWh
±0.001 Mvarh
±0.001 Mvarh
0.01
0.01 Hz
Range
±100000.0 kW
±100000.0 kvar
100000.0 kVA
50000.0 MWh
50000.0 MWh
50000.0 Mvarh
50000.0 Mvarh
-0.99 to 1.00
40.00 to 70.00 Hz
GEDigitalEnergy.com
Thermal Inhibit Margin: 0 to 25 % in
steps of 1%
Maximum: 1 to 5 starts in steps of 1
Time Between Starts: 1 to 3600 s in
steps of 1 s
Restart Inhibit Delay: 1 to 50000 s in
steps of 1 s
BREAKER FAILURE/WELDED CONTACTOR
Current
Supervision:
Phase Current
Current
0.05 to 20.00 x CT in steps of 0.01 x CT
Supervision
Pickup:
Time Delay 1:
0.03 to 1.00 s in steps of 0.01 s
Time Delay 2:
0.00 to 1.00 s in steps of 0.01 s
Current
1 to 64 ms, selectable, in steps of 1
Supervision
ms
Dropout:
Current
Supervision
Accuracy:
97 to 98% of pickup
Timing Accuracy:
0 to 1 cycle (Timer 1, Timer 2)
BREAKER TRIP COUNTER
Trip Counter Limit
1 to 10000 in steps of 1
(Pickup):
EMERGENCY RESTART
Function:
Defeats all motor start inhibit
features, resets all trips and
alarms, and discharges the thermal
capacity to zero so that a hot motor
can be restarted in the event of an
emergency
Operation:
Contact Input 1 to 10, Virtual Input
1 to 32, Logic Element 1 to 16,
Remote Input 1 to 32
LOCKOUT RESET
Function:
Operation:
RESET
Function:
Operation:
Reset any lockout trips when this
feature is configured
Contact Input 1 to 10, Virtual Input
1 to 32, Logic Element 1 to 16,
Remote Input 1 to 32
Resets any alarms and non-lockout
trips when LOCKOUT RESET is
configured, or resets any alarms
and trips (lockout and non-lockout
trips) when LOCKOUT RESET is not
configured.
Contact Input 1 to 10, Virtual Input
1 to 32, Logic Element 1 to 16,
Remote Input 1 to 32
AMBIENT TEMPERATURE
High Temperature
Pickup:
20°C to 80°C in steps of 1°C
Low Temperature
Pickup:
-40°C to 20°C in steps of 1°C
Time Delay:
1 to 60 min in steps of 1 mins
Temperature
Configurable 90 to 98% of pickup
Dropout:
Temperature
Accuracy:
±10°C
Timing Accuracy:
±1 second
CONTACT INPUTS
Inputs:
Selectable
thresholds:
Recognition time:
Debounce time:
Continuous
current draw:
Type:
External switch:
Maximum input
voltage:
10
17, 33, 84, 166 VDC
1/2 cycle
1 to 64 ms, selectable, in steps of 1
ms
2 mA
opto-isolated inputs
wet contact
300 VDC
CBCT INPUT (50:0.025)
Range:
0.5 to 15.0 A
Nominal
frequency:
50 or 60 Hz
Accuracy (CBCT):
±0.1 A (0.5 to 3.99 A)
±0.2 A (4.0 A to 15 A)
PHASE VOLTAGE INPUTS
Source VT:
100 to 20000 V
VT secondary
range:
50 to 240 V
VT ratio:
1 to 300 in steps of 1
Nominal
50/60 Hz
frequency:
Accuracy:
±1.0% throughout range
Voltage withstand: 260 VAC continuous
11
339 Motor Protection System
Technical Specifications (Continued)
FORM-C RELAYS
Configuration:
Contact material:
Operate time:
Continuous
current:
Make and carry
for 0.2s:
Break (DC
inductive, L/R=40
ms):
Break (DC
resistive):
Break (AC
inductive):
Break (AC
resistive):
PHASE & GROUND CURRENT INPUTS
CT Primary:
30 to 1500 A
Range:
0.05 to 20 × CT
Input type:
1 A or 5 A (must be specified with
order)
Nominal
frequency:
50/60 Hz
Burden:
<0.1 VA at rated load
Accuracy:
±1% of reading at 1× CT
±3% of reading from 0.2 to 20 × CT
±20% of reading from 0.02 to 0.19
× CT
CT withstand:
1 second at 100 × rated current
2 seconds at 40 × rated current
continuous at 3 × rated current
FREQUENCY
Accuracy:
Resolution:
Range:
±0.05 Hz
0.01 Hz
40.00 to 70.00 Hz
RTD INPUTS
RTD Type:
RTD Sensing
Current:
Isolation:
Distance:
Range:
Accuracy:
Lead Resistance:
10 A
100 Ohm platinum (DIN.43760)
5 mA
SERIAL
RS485 port:
Baud rates:
Response time:
Parity:
Maximum
Distance:
Isolation:
Protocol:
2 kV from base unit
250 m maximum
-50 to +250°C
±2°C
25 Ohm max per lead
24 V / 10 A 48 V / 6 A 125 V / 0.5 A
250 V / 0.3 A
720 VA @ 250 VAC Pilot duty A300
277 VAC / 10 A
Opto-coupled
up to 115 kbps
1 ms typical
None, Odd, Even
1200 m (4000 feet)
2 kV
Modbus RTU, DNP 3.0,
IEC 60870-5-103
ETHERNET (COPPER)
Modes:
10/100 MB (auto-detect)
Connector:
RJ-45
Protocol:
Modbus TCP/IP, DNP 3.0,
IEC 60870-5-104, IEC 61850 GOOSE
2 (two) electromechanical
silver-alloy
<8 ms
10 A
ETHERNET (FIBER)
Fiber type:
Wavelength:
Connector:
Transmit power:
Receiver
sensitivity:
Power budget:
Maximum input
power:
Typical distance:
Duplex:
Protocol:
30 A per ANSI C37.90
24 V / 1 A 48 V / 0.5 A 125 V / 0.3 A
250 V / 0.2 A
24 V / 10 A 48 V / 6 A 125 V / 0.5 A
250 V / 0.3 A
720 VA @ 250 VAC Pilot duty A300
277 VAC / 10 A
TRIP / CLOSE SEAL-IN
Relay 1 trip seal-in: 0.00 to 9.99 s in steps of 0.01
Relay 2 close
seal-in:
0.00 to 9.99 s in steps of 0.01
100 MB Multi-mode
1300 nm
MTRJ
-20 dBm
-31 dBm
9 dB
-11.8 dBm
2 km (1.25 miles)
half/full
Modbus TCP/IP, DNP 3.0,
IEC 60870-5-104, IEC 61850 GOOSE
USB
Standard
specification:
Compliant with USB 2.0
Data transfer rate: 115 kbps
HIGH RANGE POWER SUPPLY
Nominal:
120 to 240 VAC 125 to 250 VDC
Range:
60 to 300 VAC (50 and 60 Hz)
84 to 250 VDC
Ride-through time: 35 ms
DIMENSIONS
Size:
Weight:
LOW RANGE POWER SUPPLY
Nominal:
24 to 48 VDC
Range:
20 to 60 VDC
CERTIFICATION
CE:
ISO:
30 A per ANSI C37.90
24 V / 1 A 48 V / 0.5 A 125 V / 0.3 A
250 V / 0.2 A
ALL RANGES
Voltage withstand: 2 × highest nominal voltage for 10 ms
Power
15 W nominal, 20 W maximum
consumption:
20 VA nominal, 28 VA maximum
FORM-A VOLTAGE MONITOR
Applicable voltage: 20 to 250 VDC
Trickle current:
1 to 2.5 mA
FORM-A RELAYS
Configuration:
Contact material:
Operate time:
Continuous
current:
Make and carry
for 0.2s:
Break (DC
inductive, L/R=40
ms):
Break (DC
resistive):
Break (AC
inductive):
Break (AC
resistive):
5 (five) electromechanical
silver-alloy
<8 ms
Refer to Dimensions Chapter
4.1 kg [9.0 lb]
TYPE TESTS
Dielectric voltage
withstand:
Impulse voltage
withstand:
Damped
Oscillatory:
Electrostatic
Discharge:
RF immunity:
Fast Transient
Disturbance:
Surge Immunity:
Conducted RF
Immunity:
Power Frequency
Magnetic
Field Immunity:
Radiated &
Conducted
Emissions:
Sinusoidal
Vibration:
Shock & Bump:
Voltage Dip &
interruption:
Low voltage directive EN60255-5 /
EN60255-27 / EN61010-1
EMC Directive EN60255-26/
EN50263, EN61000-6-2, UL508
Manufactured under a registered
quality program ISO9001
2.3KV
EN60255-5
5KV
IEC 61000-4-18/
IEC 60255-22-1
EN61000-4-2/
IEC 60255-22-2
EN61000-4-3/
IEC 60255-22-3
IEEE C37.90.1
2.5KV CM, 1KV
DM
Level 4
EN61000-4-5/
IEC 60255-22-5
EN61000-4-6/
IEC 60255-22-6
IEC 61000-4-8
Level 3 & 4
CISPR11 /CISPR22/
IEC 60255-25
Class A
IEC 60255-21-1
Class 1
IEC 60255-21-2
IEC 61000-4-11
Level 3
4KV CM & DM
Level 3
Level 4
Ingress Protection:
IEC 60529
Environmental
(Cold):
Environmental (Dry
heat):
Relative Humidity
Cyclic:
Fast Transient
Disturbance:
SWC Damped
Oscillatrory:
Electrostatic
Discharge:
IEC 60068-2-1
Class 1
0, 40, 70, 80%
dips, 250/
300 cycle
interrupts
IP40 front ,
IP10 Back
-40C 16 hrs
IEC 60068-2-2
85C 16hrs
IEC 60068-2-30
6day variant 2
IEEE® C37.90.1
4KV CM & DM
IEEE C37.90.1
2.5KV CM
& DM
8KV CD, 15KV
AD
IEEE C37.90.3
OPERATING ENVIRONMENT
Ambient operating –40°C to +60°C [-40°F to +140°F]
temperature:
Ambient storage / –40°C to +85°C [-40°F to +185°F]
shipping
temperature:
Humidity:
Operating up to 95% (non
condensing) @ 55C (As per
IEC 60068-2-30 Variant 2, 6days)
Pollution degree:
II
Overvoltage
III
category:
Ingress Protection: IP40 Front , IP10 back
Ordering
Base Unit
Language
Phase Currents*
339 Ground Currents*
Power Supply
Input/Output
339 Current Protection
339 Other Options
Communications
339
339
E
**
**
**
*
S
N
*
**
*
*
E
P1
P5
G1
G5
L
H
E
S
N
M
P
SN
1E
2E
3E
Case Design
Harsh Environment
D
N
N
H
Description
Base Unit
English
1A three phase current inputs
5A three phase current inputs
1A ground current input
5A ground current input
24 - 48 Vdc
110 - 250 V dc/110 - 230 Vac
10 Inputs, 7 Outputs (2 Form A, 5 Form C)
Standard Configuration – 14, 37, 46, 48, 49, 50P(1), 50G(1), 50M, 50L, 66, 86, 50BF(1), 50N(1), 51G(1)
No Selection
Voltage Metering
Voltage Protection - 27P(2), 47(1), VTFF(1), 59P(2), 81O(2), 81U(2) , 59_2(1)
Standard :Front USB, Rear RS485 : Modbus RTU, DNP3.0, IEC 60870-5-103
Standard + Ethernet (Copper & Fiber - MTRJ) MODBUS TCP/IP, DNP3.0, IEC 60870-5-104
Standard + Ethernet (Copper & Fiber - MTRJ) MODBUS TCP/IP, DNP3.0, IEC 60870-5-104,
IEC 61850 GOOSE
Standard + Ethernet (Copper & Fiber - MTRJ) MODBUS TCP/IP, DNP3.0, IEC 60870-5-104,
IEC 61850
Draw-out
Non Draw-out design
None
Harsh Environment Conformal Coating
Ordering Notes: 1) G1/G5 and S1/S5 must match corresponding P1/P5 - there cannot be 5A and 1A mixing
12
GE reserves the right to make changes to specifications of products described at any time without notice and without obligation to notify any person of such changes.
Copyright 2013, General Electric Company. All Rights Reserved.
GEA-12779K(E)
English
140121
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