DE29605370U1 - High voltage high power fuse - Google Patents

Description

Dn.-Ing. Reiman/KöKiä ;· »ÖiRL-JI^ Klaus Bergen

Wilhelm-Tell-Stn. 1 &Lgr; AOS. 1 S DüsseldonfVel. O21 1 -93O2SO Patent Attorneys

20 March 1996
41 022 B

Fritz Driescher KG special factory for

Electricity Supply GmbH & Co.,

Industriestrasse 2, 41844 Wegberg

"High voltage high performance fuse"

The invention relates to a fuse, in particular a high-voltage high-performance fuse with a striker pin device and with a fusible element.

Such fuses are widely known, for example from German patent application 1 920 825. This well-known proposal deals with the fundamental problem that fuses of this type, when subjected to relatively small overcurrents, which do not lead to the melting of the fuse element or only do so after a longer period of time, heat up to such an extent that this can cause damage that impairs the fuse function, such as cracks in the fuse housing. The solution proposed there is to connect the fuse element via a selective soldering point to a wire that holds a striker against a spring force, whereby it is achieved that when the fuse heats up to

At a temperature that is not yet critical for the fuse housing, the striker pin is released by liquefying the selective solder and activates a switch that automatically breaks the fuse circuit.

Known proposals deal with essentially the same problem - in which an auxiliary fuse element is provided in addition to a main fuse element, which is connected to a holding wire that holds back the spring that preloads the firing pin. In cases of overcurrents that are still below the I _m in the fuse, small arcs can arise after a certain time in the holes in the main fuse element, so that the auxiliary fuse element or resistance wire melts due to the current flow caused by heating and/or a drop in voltage in the auxiliary fuse element, thereby directly (if the auxiliary fuse element itself is also the holding wire for the firing pin spring) or indirectly (if the auxiliary fuse element is connected to a holding wire) releasing the spring that preloads the firing pin, so that the firing pin can then cause a shutdown via the downstream load-break switch.

Although such fuses have proven themselves for decades, the melting of the resistance wire is based on the voltage drop at the first melting arc that occurs within the fuse wire, i.e. the resistance wire only melts when a certain arc voltage is reached.

wire through. There is therefore a need to avoid unnecessary thermal stress within the fuse.

The invention is based on the problem of creating a fuse in which the triggering occurs independently of the melting principle. This problem is solved with the features specified in the main claim.

The temperature-controlled firing pin lock, which is preferably spring-controlled, creates additional thermal protection which ensures that the firing pin is released at elevated temperatures without a retaining wire or the like melting through, i.e. the safety device can be made ready for use again in a particularly simple manner.

The invention thus creates an additional control option for the triggering of the firing pin, regardless of the state of the holding wire or resistance wire or auxiliary fuse element.

If the control spring of the locking mechanism is made of a shape memory alloy, the present fuse has the surprising advantage that the additional thermal protection requires only a few components, since the spring, made of a shape memory alloy, is both a sensor and an actuator. This means that the problem of overcurrents can be solved thermally, regardless of the occurrence of an arc voltage.

-A-

It is particularly advantageous that the fuse cannot be thermally overloaded, especially since the transformation point, i.e. the response temperature of the shape memory component, can be precisely determined in advance using a suitable alloy. Finally, a very special advantage of the invention is that existing designs can be converted without any changes.

In a special embodiment in which the firing pin is locked by a ball catch and a locking pin that is decisive for the ball movements is subjected to pressure, in particular spring, on both sides, whereby one spring has an opening effect in the event of the holding or resistance wire burning through, while the other, oppositely acting spring essentially fulfills positioning tasks, the latter is made according to the invention from a shape memory alloy and is firmly connected to the locking pin, so that when heated it moves the locking pin in the direction in which the first-mentioned spring would also push it in the event of the holding wire or resistance wire burning through to release the ball lock, i.e. this heating already leads to the firing pin actuation without melting through.

The invention is explained in more detail below using the preferred embodiment shown partially in section in the accompanying drawing:

The tubular housing 1, which is made of insulating material and is shown in the drawing only at the end of interest in this context, is closed at each end with a cap 2, which has a central guide 3 on the side shown here, in which an axially movable striker pin 4 is held. In the position shown, the striker pin 4 is locked in place, namely against the effect of a strong compression spring 5 placed centrally on the outside around the guide 3, which is supported on the one hand on the base 6 of the annular space formed by the guide 3 inside the cap with the inner wall of the housing 1 and on the other hand on a spring plate 7, which is connected to the striker pin 4 in a force-locking manner via a pin 8 which penetrates the striker pin 4 transversely to its longitudinal axis and whose free ends are guided in slots (not shown) in the guide 3.

As can be seen from the figure, the firing pin lock essentially consists of several peripherally arranged balls 9, which are movably mounted in channels running perpendicular to the longitudinal axis of the firing pin 4 in its base. These channels open outwards in alignment with holes provided in the guide 3, which, as the drawing shows, partially accommodate the balls 9 in the locking position, so that a relative movement between the firing pin 4 and the guide 3 is not possible, i.e. the firing pin 4 is held against the force of the spring 5 acting on it to the left in the illustration.

For positioning the balls 9, a locking pin 11 is provided, which is movably housed centrally in a coaxial channel in the base of the striker pin 4 and is conical over at least part of its peripheral surface, so that when the locking pin is moved

11 to the left, the balls 9 move towards the center, since the compression spring 5 acts on the firing pin 4, which leads to the balls being pressed out of their locking holes in the guide 3 into the interior of the firing pin 4 by the tendency of the firing pin 4 to move to the left.

At its end facing the base of the firing pin 4, the locking pin 11 carries a pin 12 which, in the locking position, protrudes outwards through the base surface of the firing pin 4.

On the side opposite the pin 12, a compression spring 13 acts on the locking pin 11, which is fastened on the one hand to the bottom of the blind hole provided for the locking pin 11 and on the other hand to the locking pin 11 and guarantees a secure position of the locking pin 11 and thus the locking of the firing pin 4 via the balls 9.

Finally, in the guide 3, on the side of the locking pin 12, there is a release bolt 14 that is also axially movable in the guide and which is attached to the pin in a manner to be explained below.

12 and is subject to the action of a compression spring 15 in the direction of the locking pin 11, against whose force it is held by means of a shark fin attached to it.

te wire 16, which can either be connected to a resistance wire wound parallel to the fuse element (main fuse wire) or can be the latter itself. The force of the compression spring 15 is selected so that it can, if necessary, move the locking pin 11 against the action of the spring 13.

From the previously explained structure of the high-voltage high-performance fuse, the following options arise for its switching behavior in the case of interest here:

As already mentioned at the beginning, a triggering process can occur when, in the case of overcurrents, small arcs form after some time, for example in the holes in the fuse wire, causing the resistance wire 16 wound parallel to the fuse element 17 to melt and thereby releasing the trigger spring 15, which has only a relatively low spring force and can now move to the left towards the locking pin 11 and hit its pin 12 protruding beyond the base of the firing pin, causing the locking pin 11 to move to the left against the force of the spring 13. The spring 13 ensures that, in the locked state, the pin 12 protrudes beyond the base of the firing pin 4. As soon as the conical narrowing of the locking pin 11 reaches the area of the balls 9 and these are now pressed in their channels from the holes of the guide 3 inwards to the central axis of the locking pin 11, due to the strong compression spring 5 acting on the striker pin 4, which pushes the striker pin 4 out of its guide.

If someone tries to push it to the left, the striker pin 4 is suddenly released, i.e. it is moved to the left by the force of the spring 5. This can then actuate a downstream load-break switch, which switches off the affected circuit.

The additional thermal protection is achieved by the fact that the spring 13 acting on the locking pin 11 in the locking direction consists of a shape memory alloy, which causes the spring to contract when the temperature increases - the size of the required temperature difference can be set to the desired level by selecting the appropriate alloy - i.e. in the present case, due to its firm connection to the bottom of the blind hole on the one hand and the locking pin 11 on the other hand, it pulls the latter to the left, thus exerting an effect on the locking pin 11 as if the holding wire or the resistance wire 16 had melted through, whereby the previously described unlocking of the striker pin 4 is achieved, resulting in the desired shutdown at increased temperatures, without a component melting through.

Claims (10)

Protection claims: ■1. Fuse, in particular high-voltage high-performance fuse, with - a firing pin (4), - a firing pin drive, - a fusible conductor (17), - a retaining wire (16) and - a temperature-controlled firing pin lock. 2. Safety device according to claim 1, characterized by a spring control (13) of the locking mechanism. 3. A fuse according to claim 2, characterized in that the spring control (13) operates independently of the holding wire state. 4. Fuse according to one of claims 1 to 3, characterized in that the control spring (13) consists of a shape memory alloy. 5. Safety device according to one of claims 1 to 4, characterized in that the firing pin drive consists of a compression spring (5). 6. Safety device according to one of claims 1 to 5, characterized by a ball catch as a firing pin lock. - 10 - 7. Safety device according to claim 6, characterized in that the balls (9) mounted in the firing pin (4) can be brought into engagement with the firing pin guide (3). 8. Safety device according to claim 7, characterized by ball receiving channels running perpendicular to the longitudinal axis of the firing pin (4) in its base, which open outwards towards aligned bores which have a maximum diameter corresponding to the ball diameter, and by a locking pin (11) mounted concentrically in the interior of the firing pin (4), movable in the direction of its longitudinal axis, pressurized, conically shaped at least over part of its length and which projects centrally into the circular ball arrangement. 9. Safety device according to one of claims 1 to 8, characterized in that the pressure is applied to the firing pin lock by means of the control spring (13), which acts against the direction of the firing pin drive (5) and is connected to the locking pin (11). 10. Safety device according to claim 8 or 9, characterized by a pin facing away from the pressure-loaded side and protruding through the firing pin base - Ii - (12) on the locking pin (11), which interacts with a release bolt (14) that is spring-loaded against the pressure applied to the locking pin (11) and is attached to the retaining wire (16).