EP3347910A1

EP3347910A1 - Device for thermally triggering, separating, and/or signaling the state of a surge protector

Info

Publication number: EP3347910A1
Application number: EP16760452.9A
Authority: EP
Inventors: Uwe Strangfeld; Stephan Hierl
Original assignee: Dehn and Soehne GmbH and Co KG
Current assignee: Dehn SE and Co KG
Priority date: 2015-09-08
Filing date: 2016-08-31
Publication date: 2018-07-18
Anticipated expiration: 2036-08-31
Also published as: ES2881637T3; PL3347910T3; CN108028153B; DE102015014163A1; WO2017042062A1; CN108028153A; EP3347910B1; SI3347910T1

Abstract

The invention relates to a device for thermally triggering, separating, and/or signaling the state of a surge protector, comprising a blocking element on which a first force acts and the aggregate state and/or the outer shape of which changes when a threshold temperature is exceeded. Furthermore, a slide is provided which is blocked by the blocking element in a first state and on which a second force acts in order to convert the slide into a second state if the aggregate state and/or the outer shape of the blocking element has changed. A latch retaining device, which is connected to the slide and by means of which the blocking element indirectly blocks the slide and the second force is broken down into a sub-force component, acts on the blocking element in a clamping manner. Furthermore, the latch retaining device has at least one elastic flexible jaw which is supported against the blocking element and the surroundings of the slide in the first state, wherein the first force corresponds to the sub-force component.

Description

Device for thermal release, disconnection and / or signaling of the state of an overvoltage protection device

description

The invention relates to a device for thermally triggering, disconnecting and / or signaling the state of an overvoltage protection device with a blocking element on which acts a first force and at

Exceeding a limit temperature changes its state of aggregation and / or its external shape, according to claim 1.

DE 10 2006 037 551 B4 shows a locked separating device, wherein a movable solder preform is set by a prestressed spring under force, but this can not escape, as long as a plunger the

Motion path blocked. The soldering bolt melts through a thermal

Overload, which is caused for example by a high current, moves the solder preform and thus a slider, so that a circuit is closed, for example, emits a warning signal.

DE 10 2010 061 110 A1 likewise discloses a thermal severing device, wherein a first conductor section is galvanically coupled to a second conductor section via a thermally detachable contact. If the temperature is too high, the contact point is released and the first conductor section is conveyed by an always acting on him force in an insulating, so that between the two conductor sections no electrical connection is possible.

DE 10 2005 045 778 A1 relates to a thermal fuse. Two conductor sections are connected via a third conductor section. If too high a temperature, this conductor section is moved by an actuated bolt so that it no longer acts as a connecting element between the other two conductor sections and interrupts a closed circuit over the conductor sections. A controller compares one

sensory detected temperature with a predetermined limit temperature and triggers a movement of the bolt when the limit temperature is exceeded. Instead of an active solution with a controller and a sensor can also be a passive solution realized by a biased spring or flexure, in which a relaxation movement is blocked by a mechanical fuse. Oie mechanical fuse dissolves when a limit temperature is exceeded, whereby the relaxation movement of the spring or flexure element conveys the connecting element from the conductor section and thus interrupts the circuit.

DE 10 2009 022 069 A1 shows a device for thermally triggering or disconnecting an overvoltage protection device with a related blocking element which is under the action of a force and a slide which is blocked by the fixed blocking element and acts on a second force.

In the overvoltage protection device according to DE 10 2013 006 052 A1, the ends of the overvoltage protection unit facing the contact lug are designed such that they have an ironing shape, at least one bracket representing a stop for a visual display pivotable about an axis, the pivoting movement then being released, if with the help of one

Slider the parallel ends of the temples of the tabs laterally move away from the contact lug. In the case of the defect display for overvoltage arresters in accordance with DE 10 2012 01 1 072 A1, mechanical actuation devices are designed as a bolt or pin. At least two overcurrent protection devices are arranged relative to one another such that the

Direction vectors of the bolts or pins cut in an imaginary extension of their movement path, wherein the respective pin or pin acts on a respectively provided surface side of a sliding anchor and the anchor has a variable position in the path of movement, but also at the intersection of the imaginary extension of the movement paths of Bolt is located. Furthermore, the armature has a further surface side, which in turn acts in an armature movement on the error signaling element and for this this further surface comprises at least one wedge slope in order to change the direction of force due to the movement of one of the bolts. A disadvantage of the prior art is in particular high costs,

Maintenance susceptibility and lack of robustness of active solutions. Passive solutions, however, are affected by unnecessarily high forces acting on the locking elements, because at the same time the interruption by the forces and a further effect, such as a movement of a slide, a switching contact or the like to be performed. This can lead to a .schleichenden triggering ^** the separator before ever a relevant thermal overload occurred.

The object of the present invention is to provide a further developed device for the thermal triggering, disconnection and / or signaling of the state of an overvoltage protection device, which has sufficient

provides mechanical forces for actuating a display, a switch contact or the like.

This object is achieved by a device for thermally triggering a slide of an overvoltage protection device according to claim 1. The subclaims relate to at least preferred developments.

The device for thermal release, disconnection and / or signaling of the state of the overvoltage protection device comprises a blocking element on which acts a first force and changes its state of aggregation and / or its outer shape when a limit temperature is exceeded. For example, as the heating increases, the blocking element may take its shape from e.g. Change a circular cross section in an elliptical cross section.

Furthermore, the device comprises a slide, which is indirectly blocked in a first state by the blocking element. On the slider acts a second force. The second force translates the slider into a second state when the locking element has changed its state of aggregation.

In addition, the device has a latching holding device. This is connected to the slider, in particular releasably or firmly. Due to the latching holding device, the blocking element indirectly blocks the slide. The

Holding device is designed so that the second force acting on the slider acts substantially only frictionally and not in the direction of movement of the first force on the locking element. By the blocking element z. B. be closed an electrical circuit. This can in particular take place in that the blocking element is designed to be electrically conductive. Additionally or alternatively, a circuit may be closed by the slider when it is in the first state.

This circuit is preferably interrupted when the slider moves to the second state. In particular, this circuit may be interrupted in the second state.

The basic idea of the invention is to decouple the locking element from the second, larger force required to move the slider and initiate an action. This is done by that in the

Essentially no positive forces, which have their origin in the second force acting on the blocking element. Only the first force works

positive fit, ie directly on the blocking element. The second force works in the

Alone frictionally, ie indirectly to the blocking element.

In particular, as a second force, which is necessary for the movement of the slide, a high force can be realized without thereby the blocking element is pressed long term out of its position and thereby subject the device of a "creeping release".

As already explained, there is a slide which in its first state is blocked by the blocking element and on which the second force acts in order to bring the slide into the second state when the blocking element has changed its state of aggregation and / or its external shape , The locking device connected to the slider, by which the locking element indirectly blocks the slider, disassembles the second force into a partial force component, which acts in a clamping manner on the locking element.

According to the invention, the holding device comprises at least two pincer-like jaws, of which at least one jaw is made yielding, which are supported in the first state against the blocking element and against an environment of the slider. An environment in the sense of the invention can thereby

in particular, a housing or a housing intermediate wall of the device, or a device which is connected to the device according to the invention. In particular, the jaws are elastically yielding, so that after a forced deformation back to their original Get state. As a result, the retaining element in particular

be reused.

The jaws are preferably arranged such that normal forces acting on the blocking element are substantially compensated. This can be realized in particular by two opposing jaws. Also conceivable is a variant with three jaws which are each offset by 60 degrees, so that here also essentially no resultant force acts on the blocking element. According to the same principle, more jaws can preferably be arranged, which are even closer together.

Preferably, one or more jaws may have a chamfered step, which bear against the environment, in particular a housing or a housing partition wall, so supported that the second force causes a yielding of one or more jaws, when they are no longer blocked by the blocking element. In particular, a yielding of one or more jaws is blocked in the first state, in that they are pressed by the stepping against the blocking element and there is essentially no room for yielding. Staging and blocking element cause the larger, second force is diverted to the environment and does not affect the blocking element.

Preferably, a gradation may be part of a groove which is supported against a corresponding cam of the environment. Alternatively, a grading may be part of a cam which bears against a corresponding groove of the environment. In particular, the holding device and / or the slider can be easily and accurately positioned during installation by means of a groove-cam connection, in particular, without a subsequent shift takes place.

In one embodiment, the device has a display surface which signals the respective state (first state, second state) of the slider. The display surface may in particular be arranged fixedly or detachably on the slide.

In one embodiment, the device has a telecommunication device which signals the respective state (first state, further state) of the device. In particular, the telecommunications device is directly connected to the slide and / or is triggered by this. Preferably, the

Telecommunication device for closing or interrupting a circuit set up so that according to a variant of the circuit is interrupted in the first state and is closed in the second state. As a result, active switching to a second state can be realized. Additionally or alternatively, it is also possible that a circuit is closed by the telecommunication device in a first state and interrupted in a second state.

In one embodiment, the blocking element and / or the holding device is friction-reduced coated. As a result, in particular the frictional forces generated by the holding device, via the blocking element by the second force can be reduced. In particular, it is still one

more complete decoupling of the second force from the locking element possible, so that essentially only the first force acts on the locking element and a fast moving out of the locking element is given out of the jaws.

According to one embodiment, the contact area between the blocking element and holding device is small. In particular, one or more jaws of the holding device can be designed such that it essentially rests on the blocking element only at one point. Additionally or alternatively, the

Locking element be designed so that the holding device can essentially rest only at a point or a line. Preferably, the locking element may be wedge-shaped or cone-shaped, so that upon transition to the second state, after a first dislocation, the locking element will snap out of its fixation. In particular, the holding device, in particular one or more jaws, be chamfered so that after a first displacement in the transition to the second state, the power decoupling is canceled and the blocking element is additionally accelerated by the second force.

Features of various embodiments can be advantageously combined with each other in further, not shown embodiments. Further advantages and features emerge from the subclaims and the exemplary embodiments. This shows, partially schematized:

Fig. 1 shows a first embodiment according to the invention with two compliant

Baking in a first state; FIG. 2 shows a second embodiment according to the invention with a deformed blocking element; FIG.

Fig. 3 shows a first embodiment of the invention in a second

State and

4 shows a second embodiment according to the invention with a

yielding and an opposite, rigid cheek.

Fig. 1 shows a device for thermally triggering or disconnecting an overvoltage protection device with a display surface and slider S1 in the first state Z1. On this a force F2 is applied by a coil spring. The coil spring is supported to a housing G, in which the slider S1 is mounted. The coil spring serves as a force storage, wherein the force F2 is correspondingly high to move the slider S1. The slider S1 has a holding device, which is realized by two opposing jaws B.

Furthermore, a blocking element A1 is provided on the housing G. The blocking element A1 is preferably in thermal contact with a heat source, in particular the overvoltage protection device standing and is loosely inserted and held only by the jaws B.

The jaws B of the holding device H l are made resilient, in particular consisting of a flexible plastic material. Furthermore, the jaws B each have an outwardly oriented groove. These are there to accommodate each cam, which are realized as part of the housing G. By the second force F2, the slider S1 is pressed in the direction of the locking element A1. By the cams, which engage in the groove of the jaws B, this force is decomposed into a component force component Fl, so that the jaws are pressed inwards.

Dodge of the jaws B inward, however, is avoided by the locking element A1, which is arranged between the ends of the jaws B. As a result, a movement of the jaws B to each other is prevented and thus also a movement of the slider S1. In this first state, in which the blocking element A1 is dimensionally stable, the blocking element A1 prevents movement the jaws B of the slider to each other. The pliers of the cheeks can not be compressed so. A movement of the slider is excluded by the latching connection H 1.

By opposing jaws B compensate each other

Normal forces acting on the jaws B by the second force F2 on the

Holding device H1 are applied. As a result, the resulting normal force on the blocking element A2 disappears. The second force F2 is thus decoupled from a direct effect on the blocking element A2 in the first state.

FIG. 2 shows the device for thermal triggering of a surge protection device from FIG. 1. In this case, the shape of the blocking element A1 has changed by exceeding a limit temperature and the device is in the second state Z2 (Fig. 3) over.

FIG. 3 shows the device according to FIGS. 1 and 2, wherein the state transition is in a second phase. By the first force Fl, the blocking element A1 has been largely deformed. As a result, the jaws B of the holding devices can move inwards. As a result of the second force F2, the jaws B are pressed inwards via the latching means, in particular through the cams of the housing, so that the right-hand side of the groove of the jaws B no longer blocks a movement of the slider S1. The latching connection H1 is thus overcome. The second force F2 accelerates the slider S1 and thus also moves the display surface A to the right. This signals e.g. a triggering of the overvoltage protection device.

According to the invention and the explanations in the preceding

Embodiment, the locking element is not fixed, but only loosely inserted and held clamped between the jaws B. Furthermore, only a partial force component F1, generated by the spring force F2 via the

Jaws B in a vectorially changed direction on the locking element A1.

It is essential that when a limit temperature is exceeded, the blocking element changes its state of aggregation, ie is deformable by the partial force component F1, so that ultimately the elastic, yielding Jaws B are compressed, with the result of the release of a path of movement of the slider S1, using the usually larger force F2.

The embodiment according to FIG. 4 shows, as a second variant according to the invention, a solution which starts only from an elastic jaw B. The locking element A1 is acted upon by this elastic jaw B against a fixed jaw BF with a force, wherein the fixed jaw BF may be part of the housing G.

Also in this embodiment, the blocking element A1 is in thermal contact with a heat source, e.g. a surge protector, and is loosely inserted between the jaws B and BF held.

Also in this embodiment, the jaw B is an outward

oriented groove into which a cam H l, which may be part of the housing G, engages.

The mechanism of action when heating the barrier element with

subsequent deformation corresponds to that, as described with reference to FIGS. 1 to 3. Again, it is essential that the blocking element A1 at

Exceeding a limit temperature changes its state of aggregation and insofar is deformed by the partial force component Fl, with the result that the elastic clamping jaw B moves in the direction of the fixed jaw BF with the consequence of the release of the path of movement of the slider S1, in which respect the greater force F2 comes into effect ,

Claims

claims

1. Device for thermal tripping, disconnecting and / or signaling the state of an overvoltage protection device with:

- A blocking element (A1) on which a first force (F1) acts and that when a limit temperature is exceeded, changes its state of aggregation and / or its outer shape;

- A slide (S1), in a first state (Z1) through the

Blocking element (A1) is blocked and acts on a second force (F2) to convert the slider in a second state (Z2), when the

Locking element (A1) has changed its state of aggregation and / or its external shape, wherein

a latching holding device (H1) connected to the slide (S1), by which the blocking element (A1) is indirectly blocked and by which the second force (F2) is divided into a partial force component, acts clampingly on the blocking element (A1) , as well as continue

the latching holding device (H1) has at least two jaws (B; BF) which in the first state (Z1) are supported against the blocking element (A1) and against an environment (G) of the slide (S1), the first force ( F1) corresponds to the partial force component, wherein at least one of the jaws (B) is designed to be elastic, yielding.

2. Apparatus according to claim 1,

characterized in that

the second force (F2) is caused by a prestressed spring and / or by a mass.

3. Apparatus according to claim 1,

characterized in that

at least one jaw has a gradation that can be pressed against a fixed point so that the partial force component causes a yielding of the jaw, if it is not blocked by the blocking element (A1).

4. Apparatus according to claim 3,

characterized in that

the grading is part of a groove which rests against a corresponding cam of the environment (G) and / or that the grading is part of a cam which rests against a corresponding groove of the environment.

5. Device according to one of the preceding claims,

characterized in that

the blocking element (A1) is in thermal contact with a heat source, in particular the overvoltage protection device.

6. Device according to one of the preceding claims,

characterized in that

the blocking element (A1) is loosely inserted by the jaws (B, BF).

7. Device according to one of the preceding claims, characterized by a with the slider (S1) connected to the display surface, the

respective state (Z1, Z2) of the device signals.

8. Device according to one of the preceding claims,

characterized by a triggered by the slider (S1),

Telecommunication device which signals the respective state (Z1, Z2) of the device.

9. Apparatus according to claim 8,

characterized in that

a circuit can be interrupted and / or closed by the telecommunication device.

10. Device according to one of the preceding claims,

characterized in that

the contact surface between blocking element (A1) and holding device (H1) is punctiform or linear.