KR960001935Y1 - Power supply interceptor - Google Patents

Abstract

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Description

Power breaker

1 is a circuit diagram showing the configuration of a power circuit breaker according to the present invention.

The present invention relates to a molded-case circuit breaker that automatically breaks a circuit when an overcurrent or short circuit occurs. More particularly, the present invention relates to a power circuit breaker that can select a breaking capacity in response to an increase or decrease of a load capacity.

A power breaker is an air circuit breaker that assembles a switchgear, a separation device, etc. into a block in an insulator. Such a circuit breaker is not only used as a power switch for opening and closing a load current, but also a thermal separation mechanism or an electronic separation mechanism operates in an overcurrent and short state to automatically cut off a circuit. Opening / closing operation for the normal load condition is performed by closing or closing the operation handle.

Conventional power circuit breakers mostly use bimetal, but since the current capacity is operated in a fixed state, there is a problem of replacing or additionally installing one having a suitable breaking capacity when the load capacity is increased.

An object of the present invention is to provide a power circuit breaker that can change the breaking capacity in response to a change in load capacity as devised to solve the above problems.

In the power circuit breaker according to the present invention to achieve the above object is a power circuit breaker having a solenoid for returning the operation handle when the current flows to cut off the power provided to the load line, the current detection unit for variably detecting the load current of the load line ; A current / voltage converter converting the current detected by the current detector into a voltage; A comparator for comparing the output voltage of the current / voltage detector with a predetermined reference voltage; And a relay which is driven according to the determination result of the comparator and allows a current to flow through the solenoid. Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

1 is a circuit diagram showing an embodiment of a power circuit breaker according to the present invention. The apparatus shown in FIG. 1 includes a current detector 20, a current / voltage converter 30, a comparator 40, a relay 50, and a power breaker 70.

The current detector 20 includes a transformer T having a primary winding connected to a load line and a secondary winding provided with a plurality of tabs, and a switch SW2 selectively connected to respective tabs of the secondary winding.

The current / voltage converter 30 is composed of a resistor R1. The voltage drop across resistor R1 is proportional to the current flowing through it.

The comparator 40 includes a rectifier diode D1, a smoothing capacitor C2, and a zener diode D2.

The zener diode D2 does not conduct when the reverse voltage applied thereto is less than the zener voltage V ₂ , and when the zener diode D2 is large, a current having a substantially constant magnitude flows regardless of the magnitude of the reverse voltage.

The capacitor C1 provided at the front end of the diode D1 is provided for surge voltage protection. The capacitor C1 absorbs when a surge voltage greater than the normal voltage is applied, so that the apparatus shown in FIG. 1 does not malfunction.

The diode D3 provided at the front end of the relay 50 is to protect the coil from the reverse voltage generated during the blocking operation.

The power breaker 60 includes a solenoid S for electromagnetic separation operation and a switch SW1 opened and closed by an operation handle (not shown).

The operation of the upper teeth shown in FIG. 1 will be described in detail.

Taps installed in the secondary winding of the transformer T are selectively connected by a switch SW2. The user selects an appropriate tap according to the use capacity of the load 10.

When a switch SW1 is turned on by operating an operation handle (not shown) of the power circuit breaker 60 to apply power to the load 10, a load current also flows on the primary side of the transformer T. As a result, current is induced in the secondary side.

As I know, the current I ₂

Here, I ₁ is the primary side current, N ₁ is the primary winding number, and N ₂ is the secondary winding number.

At this time, an arbitrary breaking current is set with SW2.

The induced secondary side current I ₂ is converted into a voltage by the resistor R ₁ .

The converted voltage V becomes as follows.

The changed voltage V is rectified and smoothed by the diode D1 and the smoothing capacitor C2. The voltage applied to the smoothing capacitor C2 is proportional to the induced secondary side current I ₂ .

The primary winding of the transformer T is connected in series with the load 10. As the load current increases, the current induced in the secondary winding increases, and accordingly, the voltage applied to the smoothing capacitor C2 increases.

When the voltage applied to the smoothing capacitor C2 is greater than the zener voltage V _Z , the zener diode D2 is turned on so that a current flows in the coil of the relay 50, and the contact is connected. When the contact point of the relay 50 is connected, a current flows through the solenoid S of the power circuit breaker 60, whereby an operation handle (not shown) is returned by the operation of the solenoid S to cut off the power supply.

As is well known, a power circuit breaker having an electronic disconnection mechanism such as a solenoid is returned to the interrupted state by flowing a current through the solenoid. The blocking operation by the solenoid will be described in detail as follows.

Solenoids consist of an armature and an electromagnet that drives them. While no current flows through the electromagnet, the armature is elastically supported by a spring mounted at one end. When an electric current flows through the electromagnet, the armature inside moves in the opposite direction to the direction in which the spring is pulled, moving the operation handle installed at the other end. As a result, the operation handle returns to the blocking position.

When the power is interrupted by the return farming of the power circuit breaker 60, the induced voltage of the transformer T disappears, and the relay 50 returns to the blocked state. At this time, the counter electromotive force is generated by the coil. Since the counter electromotive force is enough to burn out the coil in some cases, it is classified through the diode D3 to protect the coil.

As the relay 50 is turned off, the contact is opened and no current flows to the solenoid S of the power circuit breaker 60. The armature is returned to its original state by a spring.

When the power breaker 60 is in the disconnected state, the operation handle is not affected by the operation of the solenoid S.

The selection operation by the switch SW2 will be described in detail. Increasing the load capacity means that the load current increases by connecting multiple loads in parallel. As the load current increases, the induced current I ₂ of the secondary winding of the transformer T increases.

This means that in the same tap, the induced current increases when the load increases. Therefore, the switch SW2 is adjusted so that the voltage applied to the smoothing capacitor C2 is less than the zener voltage Vz of the zener diode D2 in the state where no overcurrent flows.

On the contrary, as the load current decreases, the induced current of the secondary winding of the transformer T decreases as I ₂ .

This means that in the same tap, the induced current decreases when the load decreases. therefore. The switch SW2 is adjusted such that the voltage applied to the smoothing capacitor C2 is less than the zener voltage Vz of the zener diode D2 in the state where no overcurrent flows.

As described above, since the source breaker according to the present invention can adjust the level of detecting the overcurrent, it is possible to cope with the change in the load capacity.

Claims (1)

A power circuit breaker having a solenoid for returning an operation handle to cut off power provided to a load line when current flows, the power circuit breaker comprising: a current detector for variably detecting a load current of a load line; A current / voltage converter converting the current detected by the current detector into a voltage; A comparator for comparing the output voltage of the current / voltage detector with a predetermined reference line pressure; And a relay which is driven according to a determination result of the comparing unit and supplies a current to the solenoid.