JPS604538B2 - Relay shock insensitivity reinforcement structure - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention relates to a relay that cuts off power supply when leakage current to the ground occurs.

As is well known, this type of relay is used in combination with a differential transformer, and power is supplied to the relay winding from the secondary winding of the differential transformer.

The relay typically controls a mechanism for controlling circuit play forces that includes a trip knob and a release knob for manual release. Relays act on elements of the control mechanism. Since the control mechanism and the IJ relay are generally fixed on the same support plate, if the control mechanism trips and a shock is generated, this shock is transmitted back to the relay. This results in the relay reacting to this shock and releasing circuit play power at an inopportune time. It is also clear that if other devices are attached to this support plate, these other devices are also likely to be released at an inopportune time. In order to reduce such inopportune release, it is necessary to increase the adhesion force of the relay. This would result in an increase in the current required to operate the relay in question, and of course such a solution would compromise sensitivity and/or require a larger differential transformer. This will cause An object of the present invention is to eliminate the above-mentioned inappropriate IJ relay operation.

In other words, the invention provides an arrangement that increases the shock insensitivity of the relay, whether the shock is caused by a circuit play force control mechanism or by any other device. It is provided. That is, the present invention provides a shock-insensitive enhancement structure for controlling a circuit play force control mechanism by means of a longitudinally movable control rod, the relay being connected to two side branches and a bottom plate. In a shock insensitivity reinforcement structure in which the control mechanism and the relay are mounted on a U-shaped support bracket having a structure, and the control mechanism and the relay are fixed to the support plate,
The control mechanism includes a trip knob that generates a shock in a plane P when it moves, and this plane P is perpendicular to the support plate, and the relay has an abutting end surface that actuates the rod. a movable piece that is movable in the longitudinal direction of the rod and actuates the rod and the control mechanism;
The bottom plate of the support bracket on which the relay is mounted is fixed via an intermediate support, so that the moving direction of the movable piece and the rod is perpendicular to the plane P and parallel to the support plate. , the shock insensitivity enhancing structure is characterized in that the intermediate support is disposed perpendicularly to the support plate.

DESCRIPTION OF THE PREFERRED EMBODIMENTS The present invention will now be described in detail with reference to preferred embodiments illustrated in the accompanying drawings. In FIGS. 1 and 2, a support plate 1 is used to secure a control mechanism 2, which is known per se.

This control mechanism is a known type of device controlled by a relay 3. The relay 3 is mounted on a U-shaped support bracket 4 having two branches 5 and 6 connected together by a bottom plate 29. This support bracket 4
is fixed to the support plate 1 by an intermediate support 7. The relay 3 containing the movable piece 19 is fixed to the support bracket 4 by two studs 8 and 9, which engage in the interior of the branch 6. The relay 3 is also fixed to the support bracket 4 by means of a stud 01 that engages with a groove in the branch 5. This relay has two branches 12 and 13.
It is maintained in position by a form-locking strap 11. Branch 12 has a curved end 14 that engages within a groove in branch 6 of the support bracket. Branch 1 inserted between branch 5 of the support bracket and the relay
3 has a U-shaped end that engages within the opening of plate 29. The branch 12 of the fixing strap includes a recessed portion 15 in its middle, which recessed portion 15 is connected to the top surface 16 of the relay.
I am in charge of this.

Further, this recessed portion 15 can be elastically deformed. The branch 63 of the fixing strap also includes a recessed portion 17, which rests against the side surface 18 of the relay, so that the relay rests against the branch 6 of the support bracket. . The branches 5 and 6 of the support bracket are parallel to the plane P2 (FIG. 2) defined by the movable piece 19. The two rods supported by the branches 6 of the support bracket are in contact with the movable piece at their end faces 21. The rod 2 includes a cylindrical end 22 which traverses a flange 23 of the control mechanism 2 and comes into contact with a movable plate 24 . When you operate the relay, "Movable piece 1
9 pushes the lever 20 to release the control mechanism 2. In other words, the two bars move in the direction shown by arrow F. From these two rods, the movable plate 24 pivots about the shaft 25 and releases the arm 26. The control mechanism 2 includes a trip knob 27 and a manually operated release knob 28 for release.

As shown in FIG. 2, when the trip knob 27 is pressed during tripping, a shock is applied to the control mechanism 2 in a plane PI passing through the trip knob. In the embodiment illustrated in FIGS. 1 and 2, this plane PI' is perpendicular to the support plate 11. The shock is partially transmitted to the relay 3 via the support plate turtle, the intermediate support plate 7 and the support bracket 4. Since the movable piece 19 is located in a plane P2 that is perpendicular to the support plate 1 and parallel to the plane PI, and the direction of its movement is perpendicular to the direction of the force of the shock, the shock actually acts on the movable piece 19. Never. In order to further reduce the effects of shocks on the relay, it is necessary to reduce the energy of the shocks transmitted to the relay by the support 1, the intermediate support 7 and the support bracket.

This transmitted energy is transmitted when the cross-sectional area of the intermediate support 7 is 4.
The smaller it is, the smaller the transmitted energy is. However, since the cross-sectional area of the intermediate support 7 cannot be reduced to zero in order to fix the support bracket 4 on the support 1, the cross-sectional area of the intermediate support 7 is smaller than the base 29 of the support bracket 4.
The base depth is limited to 1/1 of the surface of the surface. The intermediate support 7 can preferably be a short cylindrical or non-cylindrical rod or several short cylindrical or non-cylindrical rods.

In the latter case, even if the total cross-sectional area of these several rods is large, it is limited to 1'1 star degree of the surface of the base 29. The effect of the shock that occurs on the relay is
The fixed strap 11 in Figures and Figure 2 is attached to the movable piece 1
It can be further reduced by arranging it in a plane perpendicular to plane P2 of No. 9.

fact branches 5 and 6 are these branches 5 and 6
Shocks are more likely to be felt in the direction perpendicular to . The elasticity of the branches 13 of the fixing strap 11 makes it possible to dampen shocks. This elasticity is obtained by the recessed portion 17. FIG. 3 shows a modified example.

In this figure, the support bracket 30 includes two branches 31 and 32 connected by a plate 29.
The branch 31 includes a closure 33 for mounting on a support bracket or for passing a movable piece of the ray 3 as in the case shown in FIGS. 1 and 2. Relay 3 is fixed strap 11
It is fixed to the support bracket 30 by. The recessed portion 17 of the branch of the fixing strap 11 is the branch 31
, 32 in a direction perpendicular to the branches 31, 32.

The movable piece 19 lies in a plane perpendicular to these branches 31, 32, so that the shocks transmitted to the movable piece 19 by these branches practically have no effect on the movable piece. The recessed portion 15 of the branch of the fastening strap 11 dampens shocks due to its elasticity.

This shock is transmitted in a direction perpendicular to the top surface 16 of the relay by the support bracket 4 shown in FIGS. 1 and 2 or the support bracket 30 shown in FIG. 3. The illustrated control mechanism 2, as well as the rod 20, are shown for illustrative purposes only and do not form part of the invention.
It is entirely possible to use other types of known controls and other devices in place of the control rod 20. These devices are functional in the types of control mechanisms commonly used. Similarly, if the plane PI in which the control mechanism produces a shock is not perpendicular to the support plate 1 mentioned above, but is, for example, parallel to this support plate, then the relay can be mounted on the support plate and the movable piece It should lie within a plane P2 perpendicular to the support plate.

This plane P2 is parallel to the plane PI, so that the perpendicular direction of movement of the movable piece is perpendicular to the plane PI. Generally, the relay is mounted on a support plate such that the direction of movement of the movable piece is perpendicular to both PIs along which the shock producing member moves. The member producing the shock is a member of a device fixed to the support plate, which device is generally a circuit play force. The fastening device for the relay is illustratively shown as a fastening strap with elastic portions 15 and 17, but other equivalent fastening devices could of course be used.

Although the present invention has been described above in detail with reference to its preferred embodiments, the present invention is not limited to these specific embodiments, and it goes without saying that many changes and modifications can be made without departing from the spirit of the present invention. .

[Brief explanation of the drawing]

FIG. 1 is a perspective view showing the control mechanism and the arrangement of the silk lining, FIG. 2 is a side view of the apparatus shown in FIG. 1, and FIG. 3 is a perspective view of a modification. 1...Support plate, 2...Control mechanism, 3...Relay, 4
...Support placket, 5, 6...Branch, 7...
... Intermediate support, 8, 9, 10... Stud, 11
...Fixing strap, 12, 13...Franch, 14...Curved end, 15...
Concave portion, 16...Top surface, 17...
Concave portion, 18...Side surface, 19...Movable piece, 20...Bar, 21...End face, 22...
... Cylindrical end, 23 ... Flange, 24
...0 movable plate, 26 ... arm, 27.
...Trypunop, 28...Release knob, 29...
Plate, 30... Support bracket, 31, 32...
...Brunch, 33...Open□. FIG. IFIG. 2 FIG. 3

Claims (1)

[Claims] 1 Shock-insensitive enhancement structure for a relay 3 controlling the control mechanism 2 of a circuit breaker by means of a longitudinally movable control rod 20, said relay 3 being connected to two side branches 5, 6 and a bottom plate. In the shock insensitivity reinforcement structure in which the control mechanism 2 and the relay 3 are fixed to the support plate 1, the control mechanism 2 is mounted on a U-shaped support bracket 4 having The relay 3 includes a trip knob 27 that generates a shock, and its plane P_1 is perpendicular to the support plate 1; The relay 3 includes a movable piece 19 that is movable and actuates the rod 20 and the control mechanism 2;
The plate 29 at the bottom of the support bracket 4 on which is mounted is fixed via the intermediate support 7, and the moving direction of the movable piece 19 and the rod 20 is perpendicular to the plane P_1 and parallel to the support plate 1. The shock insensitivity enhancing structure is characterized in that the intermediate support body 7 is disposed perpendicularly to the support plate 1.