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41-337.31 C

3

2.1.

Restraint Elements

Each restraint element consists of an “E” laminated
electromagnet with two primary coils and a second-
ary coil on its center leg. Two identical coils on the
outer legs of the laminated structure are connected
to the secondary winding in a manner so that the
combination of all fluxes produced by the electro-
magnet results in out-of-phase fluxes in the air gap.
The out-of-phase fluxes cause a contact opening
torque.

2.2.

Operating Circuit

The operating circuit consists of an autotransformer
and an operating element. The primary of the auto-
transformer, which is the whole winding, is connected
to receive the differential or unbalanced current from
the various transformers connected to the bus. The
secondary winding of the autotransformer, which is a
tapped section of the winding, is connected to the
operating element of the relay.

The operating element consists of an “E” type lami-
nated electromagnet with an autotransformer wind-
ing on its center leg. Two identical coils on the outer
legs of the laminated structure are connected to the
secondary (tapped section) of the autotransformer
winding in a manner so that the combination of all
fluxes produced by the electromagnet results in out-
of-phase fluxes in the air gap. The out-of-phase air
gap fluxes cause a contact closing torque.

2.3.

Sensitive Fault Detector Circuit

The sensitive fault detector circuit consists of an
autotransformer and a contactor switch. The contac-
tor switch is connected across the secondary (tapped
section) of the auto-transformer winding.

The contactor switch is a small solenoid type ele-
ment. A cylindrical plunger rides up and down on a
vertical guide rod in the center of the solenoid coil.
The guide rod is fastened to the stationary core,
which in turn screws into the unit frame. A silver disc
is fastened to the moving plunger through a helical
spring. When the coil is energized, the plunger
moves upward carrying the silver disc which bridges
three conical-shaped stationary contacts. In this posi-
tion, the helical spring is compressed and the plunger
is free to move while the contact remains stationary.
Thus, ac vibrations of the plunger are prevented from
causing contact bouncing. A micarta disc is fastened
to the bottom of the guide rod by two small nuts. Its
position determines the pick-up current of the ele-
ment.

The auto-transformer is designed to saturate at high
values of current to limit the amount of current to the
contactor switch.

2.3.1. Indicating Contactor Switch Unit (ICS)

The dc indicating contactor switch is a small clapper
type device. A magnetic armature, to which leaf-
spring mounted contacts are attached, is attracted to
the magnetic core upon energization of the switch.

When the switch closes, the moving contacts bridge
two stationary contacts, completing the trip circuit.
Also during this operation two fingers on the arma-
ture deflect a spring located on the front of the
switch, which allows the operation indicator target to
drop. The target is reset from the outside of the case
by a push rod located at the bottom of the cover.

The front spring, in addition to holding the target pro-
vides a restraint for the armature and thus controls
the pick-up value of the switch.

3.0

OPERATION

The type CA-16 relay is an induction disc relay with
four electromagnets mounted on two discs that are
fastened on a common shaft. One of the electromag-
nets is the operating element while the other three
are restraint elements. The restraint elements are
energized from the secondaries of current transform-
ers connected to the bus, and the operating circuit is
energized in accordance with the current flowing in
the differential connection of the current transform-
ers.

A current of 5 amperes in at terminal 18 and out of
terminal 19 will produce a definite amount of restrain-
ing torque

 (see Figure 3.) 

Similarly, a current of 5

amperes flowing in at terminal 16 and out of terminal
17 will produce an equal amount of torque. If both of
these currents flow at the same time with the polarity
as indicated above, their effect will be additive and
they will produce the same torque as though 10
amperes are flowing in terminal 16 and out of termi-
nal 17. Conversely, if equal currents flow in these two
coils, but in opposite directions, their ampere turns
will cancel and no torque will be produced. The same
relationship applies for the paired coils of the other
two restraining units of the relay. The restraint effect
will always be additive if currents flow in the coils
which belong to different restraint elements.

Summary of Contents for CA-16

Page 1: ......

Page 2: ...41 337 31 C 2 Figure 1 CA 16 Front View Figure 2 CA 16 Rear View ...

Page 3: ...ed from causing contact bouncing A micarta disc is fastened to the bottom of the guide rod by two small nuts Its position determines the pick up current of the ele ment The auto transformer is designed to saturate at high values of current to limit the amount of current to the contactor switch 2 3 1 Indicating Contactor Switch Unit ICS The dc indicating contactor switch is a small clapper type dev...

Page 4: ...g the lead located in front of the tap block to the desired setting by means of a screw connection 4 2 Trip Circuit Constants Indicating Contactor Switch ICS 0 2 amp rating 8 5 ohms dc 1 0 amp rating 0 37 ohms dc 2 0 amp rating 0 10 ohms dc ENERGY REQUIREMENTS Burden of each restraint coil at 5 amperes VOLT AMPERES POWER FACTOR 75 7 Continuous Rating 14 amperes 1 second rating 460 amperes Burden o...

Page 5: ...onnec tions of Figure 8 CA 16 17 0 amperes 7 Check each individual restraint winding by applying 50 amperes to each winding Apply sufficient operat ing current to the operating circuit until the contacts just close The operating current should be CA 16 3 9 to 5 1 amperes C Time Curve Apply 20 amperes to terminals 12 and 13 of the relays The contacts should close in the following times CA 16 58 to ...

Page 6: ... may be removed and the tab holding the target reformed slightly if necessary However care should be exercised so that the target will not drop with a slight jar If the pickup is low the front cover must be removed and the leaf springs on each side bent outward equally 7 6 Sensitive Fault Detector Loosen the lock nut at the top of the element and run the core screw down until it is flush with the ...

Page 7: ...41 337 31 C 7 Figure 3 Internal Schematic of the Type CA 16 Bus Relay Sub 1 3532A95 ...

Page 8: ...41 337 31 C 8 Figure 4 Typical Time Curves of the CA 16 Differential Relay Sub 1 537956 ...

Page 9: ...41 337 31 C 9 Figure 5 Typical Burden Characteristics of the Types CA 16 and CA 26 Relays Curve 537957 ...

Page 10: ...41 337 31 C 10 Figure 6 External Schematic of One Set of Type CA 16 Relays for the Protection of a Three and Four Circuit Bus Sub 5 187A424 ...

Page 11: ...41 337 31 C 11 Figure 7 External Schematic of the Type CA 16 Relays for Protection of Six Circuit Bus with Three Feeder Groups Sub 5 187A425 ...

Page 12: ...41 337 31 C 12 Figure 8 Diagram of Test Connections for the CA 16 Relay Sub 4 187A426 ...

Page 13: ...41 337 31 C 13 Figure 9 Percentage Slope Curve of the CA 16 Relay with One Restraint Winding Sub 1 849A450 ...

Page 14: ...41 337 31 C 14 Figure 10 Percentage Slope Curve of the CA 16 Relay with Six Restraint Windings in Series Sub 2 849A343 ...

Page 15: ......

Page 16: ...ABB Inc 4300 Coral Ridge Drive Coral Springs Florida 33065 Telephone 1 954 752 6700 Fax 1 954 345 5329 www abb com substation automation IL 41 337 31 Revision C ABB ...

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