DE2904662A1 - HOLDING MAGNET, IN PARTICULAR FOR FAULT CURRENT CIRCUIT BREAKERS - Google Patents

Description

Fuji Electric Co, Ltd. My mark Kawasaki / Japan YPA 78 P 8543 BRD

Holding magnet, especially for residual current circuit breakers

(The priority of Japanese patent application 14744/1978 of 02/10/1978 is claimed)

The invention relates to a holding magnet, in particular for residual current circuit breakers, on its with a permanent magnet provided yoke a release winding is arranged, which is connected to the secondary winding of a summation current transformer is connected to the yoke of an armature rotatable against a pre-tensioned trigger spring is held, and its armature with an unlatching lever acted upon by a reclosing pin is coupled.

In the case of such holding magnets, the armature drops out when the residual currents of the conductor to be monitored deviates from zero. A voltage is then induced in the secondary winding, which is caused by the release winding of the holding magnet drives a current,

No 2 Council / 18.1.1979

90 9 833/0701

- -β "- VPA 78 P 8543 BRD

which weakens the magnetic field of the permanent magnet in the area of the armature. As a result , the armature can fall off and, by means of the unlatching lever, actuate a release element of a switching mechanism of a fault current circuit breaker that is possibly to be triggered, and the system to be protected can be switched off.

Usually, the armature with an armature carrier is rotatably arranged on an axis on which at the same time the release lever is attached. If the anchor falls off, the anchor carrier transfers to the axle by means of a used driving pin on this a torque, so that the unlatching lever firmly connected to the axis is pivoted and can act on a trigger member.

Such designs on the market have the disadvantage that the driving pin in the axle for the armature transmits bending forces when it is pressed into the axle can, whereby the adherence to exact dimensions of this component are impaired. If on the other hand a Reclosing pin hits the release lever to return it to its on position, transferred such mechanical impacts on the axis of the armature. After several disconnections and reconnections the connection between the unlocking lever, which is pressed onto the axle, and the axle are weakened.

In addition, the axis around which the armature rotates is exposed to bending forces, which can affect the accuracy of the holding magnet.

Holding magnets usually have to be installed in clean air to ensure proper operation. Usual Holding magnets require all components to be assembled in dust-free air.

903833/0701

29Q4662

-X- VPA 78 P S543 BRD

The invention is based on the problem of avoidance of the disadvantages outlined to develop a holding magnet that is easier to assemble, with essentially only the anchor needs to be installed in clean air, and a safe one while reducing installation costs Operation guaranteed.

The solution to the problem described is that the anchor and the unlatching lever have separate axes exhibit. As the axis of rotation for the unlocking lever is designed separately from the axis of rotation for the armature, mechanical shocks are generated when the unit is switched on again from the axis of the release lever on which the reclosing pin acts, added. Such impacts can therefore not reduce the dimensional accuracy of the anchor components affect.

If you arrange a coupling member between the armature axis of rotation and the unlocking lever, the force of the trigger spring transfers from the unlatching lever to the anchor, there is no need to use a drive pin in the axis of the anchor to use. The dimensional accuracy of the armature axis of rotation is therefore retained.

The inventive design, the connection Do not loosen between the coupling link and armature, even in the event of switching impacts, as the reclosing pin only opens the release lever acts. A tension spring can then gently guide the armature back.

The invention is to be illustrated in more detail with reference to the drawing:

909833/0701

-ST- VPA 78 P 8543 BRD

In Fig. 1 is the typical structure of a residual current circuit breaker using a holding magnet when looking at the device base and with the cover removed reproduced.

In Fig. 2, the arrangement of FIG. 1 is in side view shown.

The background for the invention is explained with reference to FIGS. 3 to 5. In Fig. 3 is a conventional holding magnet shown in front view with the housing open.

In FIG. 4, the holding magnet according to FIG. 3 is shown in a view from the rear. In FIG. 5, essential components of the holding magnet according to FIG. 3 are shown in the manner of a kind of exploded view.
In FIGS. 6 to 8, an exemplary embodiment of the holding magnet according to the invention is shown roughly schematically. In FIG. 6, the holding magnet is shown in a view from the front, in FIG. 7 in a view from the rear and in FIG. 8 in a side view - based on FIG.

In Fig. 9, essential components of the holding magnet are shown in an exploded view.

In Fig. 10 a detail is shown with the housing shown broken off.

In Fig. 1, the field of application for a holding magnet 24 is illustrated using a residual current circuit breaker. The residual current circuit breaker essentially consists of a switch bzvi. Switching mechanism 22, a summation current transformer 23, the holding magnet 24 and terminals.

For one phase, the input terminal is 25 and the output terminal denoted by 26 »The components are arranged in a housing 21 which is closed by a cover can be"

Often Ch 0 O Oi / "f« ¹ T Oi i U a ο ο «s / U / U 1

2804662

~ X -. VPA 7β P 8543 BRD

A mounting wall is designated by 100 in FIG. 2. if A fault current occurs in the circuit that is monitored by the residual current circuit breaker, occurs in the Secondary winding of the summation current transformer an electrical signal that is converted into a mechanical force in the holding magnet 24. This mechanical force is released the switching mechanism 22 by actuating the release element 7.

Usual holding magnets are constructed as illustrated in FIGS. 3 to 5. When the holding magnet triggered, he can by a reinsertion pin 8, which on the unlocking lever 6 against the pivoting direction acts when the armature drops, can be returned to the switch-on position. This process supports the tension spring 4. A typical holding magnet on the market will now be based on Fig. 3 to 5 are illustrated in more detail:

An armature support 2 is arranged on an axis 3 in a housing 1. A tension spring is denoted by 4 and a trigger spring is denoted by 5. Other components are a release lever 6, a release member 7, a reinsertion pin 8, a driver 9, an anchor 10 »a yoke 11, a Release winding 12, a permanent magnet 15 and an adjusting screw 16 for the permanent magnet 15.

In normal operation, if there are no fault currents with regard to the conductor to be monitored, the armature is 10 magnetically attracted by yoke 11. The force of the pre-tensioned trigger spring S also acts the anchor 10. If a fault current occurs, the signal from the summation current transformer causes the from Permanent magnets 15 outgoing pull-off force at armature 10

909833/0701

2304662

- JiT - VPA 78 P 8543 BRD

is weakened so that the armature can fall off the yoke 11 under the force of the trigger spring 5. This will make the Driver 9, which is pressed into the axis S, taken counterclockwise. This causes the release lever 6 acts on the release member 7 in the direction of arrow P according to FIG. The line to be monitored is then interrupted.

To switch on again, the switch-on pin 8 is guided in the direction of the arrow Q - Fig. 4 - so that the unlocking lever 6 is returned to the on position. Since this results in the armature support 2 for the armature 10 according to Fig. 3 is moved clockwise, with the support of the tension spring 4, the armature 10 returns to the tightening position to the yoke 11. The restart operation of the holding magnet is thus ended.

As can be seen from Fig. 5, which shows the essential components of the holding magnet in perspective, the Axis 3 of the anchor 10 is firmly connected to the unlocking lever 6. It is used in bearing recesses in housing 1, whereby it reaches through the trigger spring 5. After the tension spring 4 and the armature support 2 on the axis 3 in Housing 1 are mounted, the driver 9 is in a bore of the axis 3 with such conventional holding magnets pressed into its guided end. This force and the manipulations are transferred from the axle to the armature support 2.

The disadvantages outlined are with the invention Holding magnets according to FIGS. 6 to 10 avoided. In the housing 1 are used the armature support 2, the axis 3, the

909833/0701

2304662 -χ

-Jf- VPA 78 P 8543 BRD

Tension spring 4, the trigger spring 5, the unlatching lever 6, the release element 7 as part of the switching mechanism, the reclosing pin 8, the armature 10, the yoke 11 and the release winding 12. The separate axis is essential 14 for the unlatching lever 6, in addition to the axis 3 for the armature support and is also essential in the present case Embodiment the coupling member 13. As can be seen from Fig. 7 best, the axis 3 is for the Armature 10 is firmly connected to the coupling member 13. The other end face is semicircular. Of the Anchor support 2 of the anchor 10 has an angled tab, a support side 2a with a round recess and .Another side 2b with a semicircular recess in a further angled tab. The semicircular Part 3a of the axis 3 according to FIG. 9 is fitted with a press fit into the semicircular recess of the side 2b of the armature support 2, whereby the coupling member 13 with the armature support 2 is firmly connected.

As can best be seen from FIGS. 8 and 9, the unlatching lever 6 receives the trigger spring 5 via its axis of rotation 14. The axis 14 is inserted in the housing 1. The front of the unlocking lever 6 overlaps that of the Coupling member 13, so that the force of the trigger spring 5 and the torque with respect to the axis 14 are transmitted to the coupling member 13 and the armature 10.

The armature 10, which in the retirement is attracted by the yoke 11 against the bias of the trigger spring 5, comes free, when the summation current transformer emits a signal and the tripping winding 12 is excited as a result of a fault current. As a result, the free end of the coupling member 13 drives the release member 7 under the action of the trigger spring 5 in Direction of arrow P to Fig. 7 back. The switch can then interrupt the circuit to be monitored.

909833/0701

29046S2

- JT - VPA 78 P 8543 BRD

After the circuit to be monitored has been interrupted, the restart pin 8 in Direction of arrow Q according to FIG. 7 are moved so that the unlocking lever 6 is returned to the switched-on position will. Since the armature support 2 is firmly connected to the coupling member 13, it is turned clockwise according to FIG. 6 returned under the action of the tension spring 4. The armature 10 is thereby attracted again by the yoke 11, whereby the restart process is ended when the holding magnet according to the invention.

The unlocking lever 6 is advantageously in the area the axis 14 is C-shaped, as can be seen from FIGS. 8 and 9. He thereby takes the axis 14 and the Trigger spring 5 on. The trigger spring 5 is advantageously with its other end according to FIG. 10 behind a L-shaped nose of the housing 1 held. This avoids in a simple manner that the trigger spring 5 and the Unlatching lever 6 can come out of engagement by pulling in the direction of arrow R according to FIG. 10 during assembly. Through this one saves holding means on the axis 14 during assembly.

In the case of the holding magnet according to the invention, shocks of the reclosing pin 8 only to the axis 14 but not to the coupling member 13 and not to the axis 3 of the armature support 2 wear. The safety of tripping is thus maintained even after many shutdowns and reconnections.

Since the axis 14 and the unlocking lever 6 are formed separately from the axis 3 of the armature 10, mechanical Bumps and blows are recorded by the axis 14 of the unlocking lever 6 during the restart process. Such

909833/0701

29046S2

- # - VPA 78 P 8543 BRD

Stresses caused by the switching process can therefore not impair the sensitive dimensional accuracy of the armature 10.

Since the unlatching lever 6 is C-shaped at its reference point for the rotation and there is the trigger spring 5 is hooked behind an L-shaped nose of the housing and at its end from the unlatching lever in the C-shaped area is held, the unlatching lever and the trigger spring 5 remain firmly in place even during assembly tied together. There is therefore no need for assembly aids during assembly, in order to prevent the trigger spring 5 from jumping off the unlatching lever 6. Since the trigger spring 5 and the unlocking lever 6 can be mounted independently of the assembly of the other parts of the holding magnet, and since this assembly does not require particularly clean air, there is the advantage that the assembly of the holding magnet is significantly simplified and cheaper.

2 claims
10 figures

909 83 3/0701

Claims (1)

29046S2 - A- - VPA 78 P 8543 BRD patent claims / 1st holding magnet, especially for residual current circuit breakers, on whose yoke provided with a permanent magnet a release winding is arranged, which is connected to the secondary winding a summation current transformer is connected to the yoke of an armature rotatable against a preloaded standing trigger spring is held, which acts on an unlatching lever coupled to the armature, which is of can be acted upon by a reclosing pin, characterized in that the armature {10) and the unlocking lever (6) separate axes (3; 14) exhibit. 2. Holding magnet according to claim!, Characterized in that that between the armature axis of rotation (3) and the unlocking lever (6) a coupling member (13) is arranged is that coupling member C13) and anchor (10) firmly connected are and that the coupling member (13) the unlocking lever (6) in the sense of the force of the trigger spring (5) below. 909 3 33/0701