JPS6343703Y2 - - Google Patents

Description

[Detailed explanation of the invention] [Industrial application field] This invention is based on a third circuit that connects each circuit and disconnector provided in each of the two lines and the busbar of both lines.
This invention relates to an interlock device for three circuits and disconnectors.

[Conventional technology] Conventionally, due to the increase in transformer capacity and load capacity,
In order to minimize power outages, a power distribution system that connects two systems as shown in Figure 1 is generally used.

In Figure 1, transformer Tr1 is installed in one system, and is connected to the first circuit for the main line and the disconnector.
NFB1 is installed on the secondary side of transformer Tr1. The transformer Tr2 is installed in the other system, and the second main circuit breaker NFB2 is installed on the secondary side of the transformer Tr2. The third circuit breaker (hereinafter referred to as bus tie breaker) NFB3 for connecting the busbar connects the system of transformer Tr1 and the transformer.
This connects the Tr2 strain. Load L ₁ ,
_L2 is connected to the transformer Tr1 system and the transformer Tr2 system via a branch circuit and a disconnector NFB4, respectively.

Next, the operation of the conventional device will be explained. Bus tie breaker NFB3 is normally OFF,
The system of the transformer Tr1 and the system of the transformer Tr2 are each independent and supply power to the respective loads L ₁ and L ₂ . now,
If the main circuit or disconnector NFB1 trips due to a short-circuit accident in the transformer Tr1 system,
Power supply to load _L1 is stopped.

Therefore, by turning on (ON) the bus tie breaker NFB3, power is supplied from the transformer Tr2 system to the load _L1 , thereby minimizing the power outage of the load _L1 . The same is true when the other trunk line circuit or disconnector NFB2 trips.

[Problems that the invention aims to solve] However, in constant operation, main line circuits and disconnectors
When NFB1 and NFB2 are both ON, if you accidentally turn on the bus tie breaker NFB3, the system of transformer Tr1 and the system of transformer Tr2 will become parallel, and the impedance of the transformer and the transformer primary side will become parallel. The higher power supply impedances are each halved. Therefore, in this case, if a short circuit occurs on the load side of the branch circuit or breaker NFB4, a considerably larger short circuit current will flow than in a short circuit during continuous operation, and the branch circuit or breaker NFB4 will There were problems in that they could break down due to insufficient breaking capacity, or that expensive circuits and disconnectors with large breaking capacities had to be used to prevent this.

This idea was made to eliminate the drawbacks of the conventional ones as described above.If two of the three circuit breakers and disconnectors in the power distribution system shown in Figure 1 are ON, the remaining The purpose of this invention is to provide an interlock device between the three circuits in the system shown in Figure 1, since one circuit or disconnector cannot be turned on.

[Means for solving the problem] The circuit breaker interlock device according to this invention includes a tripping coil of the first circuit breaker NFB1.
A contact of SHT1 and second circuit breaker NFB2
A first series circuit that connects AX2c and a second series circuit that connects the tripping coil SHT2 of the second shield breaker NFB2 and the a contact AX1c of the first circuit breaker NFB2.
A first circuit consisting of a series circuit and an a contact AX3a of a third circuit breaker NFB3 which is a bus tie breaker connected in series to a circuit formed by connecting these first and second series circuits in parallel. A second circuit consisting of a series-parallel circuit, the B contacts of the first and second circuit breakers connected in parallel, and an undervoltage tripping device UVT3 of the third circuit breakwater connected in series thereto. It has a series-parallel circuit, and a second series-parallel circuit is connected in parallel to the first series-parallel circuit.

[Function] This device closes each A contact and opens each B contact when the first and second tripping coils are energized, so the third circuit breaker, which is a bus tie breaker, is activated. When the trip coil is not turned on and one of the first and second tripping coils is energized and the other is demagnetized, the bus tie is activated by closing the B contact of the circuit or disconnector on whichever side is demagnetized. This makes it possible to turn on the third circuit or disconnector, which is a breaker.

[Example] An example of this invention will be described below with reference to the drawings.

FIG. 2 is a circuit diagram showing an embodiment of this invention. In Fig. 2, the coil SHT1 of the first voltage tripping device is built into the second main line circuit breaker NFB1, and the coil SHT2 of the second voltage tripping device is built into the second main line circuit breaker NFB1. circuit break
Built into NFB2. The coils SHT1 and SHT2 of the first and second voltage tripping devices electrically trip the respective first and second circuit breakers NFB1 and NFB2 when voltage is applied. . Undervoltage trip device coil UVT3
is built into the bus tie breaker NFB3, and when the control voltage drops, the bus tie breaker NFB
3 is automatically tripped. The first auxiliary switch AX1c is a first circuit disconnector.
Built into NFB1, second auxiliary switch AX2c
is built in the second circuit and disconnector NFB2. These first and second auxiliary switches AX1c,
AX2c is interlocked with the contacts of the first and second circuit breakers, and the first and second circuit breakers are connected to each other.
It has an A contact that closes when it is ON, and a B contact that closes when the first and second circuit breakers are OFF or tripped. Auxiliary switch
AX3a is built into the bus tie breaker NFB3 and includes an a contact that closes when the bus tie breaker NFB3 is ON. The first and second interlock release switches SW1 and SW2 together with the above-mentioned components constitute a circuit to be described below.

The coil SHT1 of the first voltage tripping device and the a contact of the auxiliary switch AX2c are connected in series to form a first series circuit A. The coil SHT2 of the second voltage tripping device and the a contact of the auxiliary switch AX1c are connected in series to form a second series circuit B. The first series circuit A and the second series circuit B are connected in parallel to form a parallel circuit. An auxiliary switch AX3a and a first interlock release switch SW1 are connected in series to this parallel circuit to form a first series-parallel circuit C. The b contact of the auxiliary switch AX1c, the b contact of the auxiliary switch AX2c, and the second interlock release switch SW2 are connected in parallel to form a parallel circuit, and the coil of the undervoltage tripping device is connected to this parallel circuit. The UVTs 3 are connected in series to form a second series-parallel circuit D. The first and second series-parallel circuits C and D are connected to a control power source E, respectively.

Next, the operation of the interlock device having three circuits and disconnectors according to the present invention constructed as described above will be explained.

In FIGS. 1 and 2, the main line circuit breakers NFB1 and NFB2 are always ON, and the bus tie breaker NFB3 is OFF. Since main line circuit breakers NFB1 and NFB2 are ON, the b contacts of auxiliary switches AX1c and AX2c are OFF.
A contact is ON. Therefore, when the second interlock release switch SW2 is OFF, the voltage is not applied to the coil UVT3 of the undervoltage tripping device, so the bust tie breaker NFB3 is tripped, and the bust tie breaker NFB3 is accidentally tripped.
Even if I turn it on (ON), I can't turn it on.

Next, one of the main line circuits and disconnectors NFB1 and NFB2 is ON, and the other is tripped (or
OFF), auxiliary switches AX1c and AX2
Since either the b contact of c is ON, voltage is applied to the coil UVT3 of the undervoltage tripping device, and the bust tie breaker NFB3 does not trip. Therefore, the bus tie breaker NFB3 can be turned on (ON), minimizing power outage of the load _L1 or _L2 and ensuring continuity of power supply.

Next, if the bus tie breaker NFB3 is ON and one of the trunk line circuit breakers NFB1 (or
NFB2) is ON, the other main line circuit is disconnected.
Consider when NFB2 (or NFB1) is OFF. At this time, auxiliary switch AX3a is ON,
A contact of auxiliary switch AX1c (or AX2
(a contact of c) is ON, so if the first interlock release switch SW1 is ON (interlock in progress), the coil SHT2 of the voltage tripping device
(or SHT1), and therefore the main circuit and disconnector NFB2 (or NFB1)
is tripped.

Therefore, even if you accidentally turn on (ON) the main circuit or disconnector NFB2 or NFB1, it will not turn on (ON). The auxiliary switch AX3a is provided to enable both main line circuit breakers NFB1 and NFB2 to be turned ON when the bus tie breaker NFB3 is OFF. The electrical interlock described above can be described in an easy-to-understand manner as follows.

(1) NFB1-ON, NFB2-ON → NFB3-cannot be turned on.

(2) NFB1-ON, NFB2-OFF → NFB3-can be turned on.

(3) NFB1-OFF, NFB2-ON → NFB3-can be turned on.

(4) NFB1-ON, NFB3-ON → NFB2-cannot be turned on.

(5) NFB2-ON, NFB3-ON → NFB1-cannot be turned on.

The first interlock release switch SW1 is normally ON, and the second interlock release switch SW1 is normally ON.
SW2 is normally set to OFF, but if you want to cancel the interlock in an emergency, SW1 is set to OFF.
When SW2 is turned ON, the electrical interlock as described above is canceled. It is desirable that the first and second interlock release switches SW1 and SW2 have a keyed structure to prevent erroneous operation.

In addition, in the above embodiment, the case of a circuit breaker or a disconnector was explained, but it may be a disconnector or other switching device such as an electromagnetic switch, and these are collectively referred to as a circuit breaker or a disconnector. to be called. Also, this idea was introduced in the first
Although the explanation has been made regarding the application to a power distribution system as shown in the figure, it can be used anywhere where interlocking of three circuits or disconnectors is required.

[Effects of the invention] As described above, according to this invention, the voltage tripping device built into the circuit breaker is combined with the minimum number of undervoltage tripping devices and auxiliary switches. When two of the three circuits are ON, the remaining one circuit switch or disconnector cannot be turned on (ON), so it is possible to safely and reliably interlock the three circuits or disconnectors.

[Brief explanation of drawings]

Figure 1 is a power distribution system diagram to which this idea is applied, Figure 2
The figure is an electrical wiring diagram showing one embodiment of the circuit/breaker interlock device according to this invention. In the figure, NFB1, NFB2, and NFB3 are the first, second, and third circuit breakers, SHT1, and SHT.
2 is a coil of the first and second voltage trip device;
UVT3 is the undervoltage trip device coil, AX1
C, AX2C, AX3A are first, second and third auxiliary switches, SW1 and SW2 are first and second interlock release switches, A and B are first and second series circuits, C and D are These are first and second series-parallel circuits.

Claims (1)

[Claims for Utility Model Registration] (1) Tripping coil of first circuit breaker NFB1
A contact of SHT1 and second circuit breaker NFB2
AX2c is connected to the first series circuit, and the second series circuit is connected to AX2c.
Tripping coil SHT2 of circuit breaker NFB2
and a second series circuit connecting the first circuit and the a contact AX1c of the disconnector, and a circuit connected in series by connecting these first and second series circuits in parallel. A first series-parallel circuit consisting of the a contact AX3a of the third circuit breaker NFB3, and the b contact of the first and second circuit breakers connected in parallel and connected in series thereto. a second series-parallel circuit consisting of a third circuit and an undervoltage tripping device UVT3 of a circuit breaker; and disconnection interlock device. (2) The first series-parallel circuit is connected to the third auxiliary switch.
A first interlock release switch SW1 is connected in series with the a contact of AX3a, which is normally in the ON state, but is turned OFF to release the interlock.
The second series-parallel circuit is connected in parallel with the B contacts of the first and second auxiliary switches AX1c and AX2c, and is normally in an OFF state, but is turned ON to release the interlock. An interlock device for a circuit breaker as set forth in claim (1) of the utility model registration claim, comprising a switch SW2.