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Transcript
Current Transformer Grounding
May 12, 2000
With the new PowlVac-AT Model ATSB outdoor substation circuit breakers recently introduced by Powell
Electrical Manufacturing Company, several questions should be addressed regarding the ground point
for the Current Transformer (CT) circuits. This Powell Technical Brief investigates the preferred ground
location of typical CT circuits such as transformer and bus differential relays.
IEEE standard C57.13.3 serves as the ANSI guide to standardize instrument transformer grounding
practices. The grounding of current transformers is important to both safety and the proper operation of
the protective relays. To assure the safe and reliable operation, the neutral of the current transformer
secondary should have a single ground location for each circuit. The single ground is irrespective of the
number of current transformers or the chosen grounding location. Utilizing a single ground eliminates the
risk of redundant ground loops and associated problems.
During normal operation more than one ground on a CT circuit is not an obvious problem other than the
difficulties it may cause during testing. However during a fault condition, multiple grounds allow a
different ground potential rise for each current transformer. The result is a significant current flow through
the CT circuit that is not representative of the primary current. This ground loop typically creates a
potential across the operating coil of the differential relay causing the relay to pick up as though a fault
exists in the relay's protective zone. Tripping a differential relay due to a fault external to the zone of
protection, is one of the more popular nuisance trips. These nuisance trips may not only shut down the
load, but may require a maintenance crew to spend days in testing to determine that no real problem
exists in the differential zone. Further, the actual problem may go uncovered until the system is reenergized into the original fault.
Figure 1
To demonstrate what happens with a second ground on the current transformer circuit, Figure 1 shows a
typical differential relay with two current transformers. The recommended method of grounding is to
install a single ground point at the “first point of application (switchboard or relay panel) of the current
transformer secondary circuit.
Powell Industries, Inc.
PO Box 12818
Houston, TX • 77217
©2005 Powell Industries, Inc. • All rights reserved.
Tel: 713.944.6900 • Fax: 713.947.4453
www.powellind.com
[email protected]
Current Transformer Grounding
page 2
Figure 2
A substation circuit breaker should have the wye or delta connections made-up at the CT terminal blocks
in the equipment. If the protective relay is mounted in the breaker the wye connection is grounded at the
circuit breaker. If the protective relays are mounted in a separate building, then the wye connection is in
the breaker but is grounded at the relay house. The same applies for current transformers in the
transformer tank. The CTs are grounded at the place where the metering or relaying is located (see
Figure 2).
Figure 3
Note: For a fault, external to the protective zone, insufficient voltage develops across the
operating relay to pick up the coil.
Powell Industries, Inc.
PO Box 12818
Houston, TX • 77217
©2005 Powell Industries, Inc. • All rights reserved.
Tel: 713.944.6900 • Fax: 713.947.4453
www.powellind.com
[email protected]
Current Transformer Grounding
page 3
For an external fault (see Figure 3), this allows the current flowing through the current transformer on
the line side of the protected zone and the current flowing through the load side current transformers to
develop a voltage of opposite polarities. The result is a voltage of very small magnitude across the
operating coil of the relay. The relay coil does will not operate without sufficient applied voltage.
In the case of a fault internal to the protective zone, the voltage developed by the current transformers is
of the same polarity. The magnitude of voltage drop across the operating coil is sufficient to operate the
relay (see Figure 4).
Figure 4
Note: With a fault in the protective zone, sufficient voltage develops across the operating relay
coil to pick up the coil.
In the final example (Figure 5) there is a second ground is on a current transformer mounted near where
a ground fault occurs. If the fault creates a ground potential rise of 100 volts, then the protective relay will
experience sufficient voltage across the operating coil to cause the relay to nuisance trip even though the
fault was outside the fault zone.
Just as with any other event there is an exception to this standard. Many of the new multifunction relays
(ABB, Schweitzer, GE/Multilin, and Basler) are designed to connect all current transformers coming into
the relay in a wye connection. Each wye has to be grounded. The most desirable way to do this is to bus
the wye points together at the relay panel and have a single conductor to ground, to make certain the
relay has but one ground potential.
As you can see, there are significant considerations in the proper grounding of current transformer
circuits.
Powell Industries, Inc.
PO Box 12818
Houston, TX • 77217
©2005 Powell Industries, Inc. • All rights reserved.
Tel: 713.944.6900 • Fax: 713.947.4453
www.powellind.com
[email protected]
Current Transformer Grounding
page 4
Figure 5
Note: With a second ground at a remote location, the voltage across the operating coil is
sufficient to result in a miss-operation for an external fault and cause a nuisance trip situation.
Jim Bowen
Technical Director
Powell Industries, Inc.
PO Box 12818
Houston, TX • 77217
©2005 Powell Industries, Inc. • All rights reserved.
Tel: 713.944.6900 • Fax: 713.947.4453
www.powellind.com
[email protected]