SE514775C2 - Designed for protection against overcurrent in electrical circuits - Google Patents

Abstract

A device for protection against overcurrents in electric circuits. The device comprises at least one electrically conductive elastomeric body (10) and two electrodes (12, 14) which are intended to supply circuit current through said body, and constructed to repel one another under the influence of short circuit currents. Each electrode is in abutment with the elastomeric body at corresponding positions, either directly or through the intermediary of an intermediate part. Abutment pressure is obtained through the medium of a pressure device, so that in the absence of pressure the elastomeric body (10) is deformed by the pressure device at respective abutment sites. The elastomeric body (10) and the electrodes (12, 14) are in respect of their contact areas, located in a liquid environment (44) - which especially can be in paste consistency - with residue solving properties. A contact means, in the form of at least one raster-like layer (20, 22) is arranged so that in contact with at least one electrode and an abutting elastomeric body and/or between two abutting elastomeric bodies, said means will provide an increased contact effect in that the layer will sink into the abutting elastomeric body when pressure is applied.

Description

Elastomer bodies are connected in series, is that only one abutment surface is activated under the influence of overcurrent. This means that the source voltage is not divided in the desired way, which is why the activated surface is "stressed" unnecessarily hard. The voltage resistance in the highly resistive state of the device becomes low, since it depends only on the active surface.

It has been found that in devices which are relatively sensitive, e.g. based on repulsion devices of the type described e.g. in the above-mentioned Swedish patent application 9201223-6, or which completely lacks repulsion devices, a current peak occurs immediately before the device becomes highly resistive. This current peak causes high overvoltages and thus also causes insulation problems in the device.

An object of the invention is also to provide a device intended for protection against overcurrent in electrical circuits of the type mentioned in the preamble, which device makes it possible to eliminate or greatly reduce the said current peak.

This then eliminates the above-mentioned problems in connection with known devices of the intended kind. The device according to the invention thus becomes very durable and is minimally affected by overcurrent, which means that it can function satisfactorily for a very long time.

Some particularly preferred embodiments of the invention also appear from the other dependent claims.

The invention will now be described in more detail below in the form of advantageous embodiments with reference to the accompanying drawings, Fig. 1 shows from the side a section through a preferred embodiment of a current protection device according to the invention; Fig. 2 shows the same view as in Fig. 1 but with an enlarged complementary part, which illustrates the current constriction obtained; Fig. 3 and Fig. 4 show in cross section two preferred embodiments of the current protection device according to the invention, whereby current displacement is obtained.

Fig. 5 shows a diagram regarding the current / time band for a known current protection device and for the current protection device according to the invention; Fig. 6 shows from the side a section through a further embodiment of the new current protection device; Fig. 7 shows from the side a section through a further variant of the new current protection device, wherein parts of the illustrated device are enlarged; Fig. 8 shows in section from the side a further embodiment of the current protection device according to the invention; Figs. 9 and 10 show a further variant of the current protection device, Fig. 9 showing a transverse section from the side and Fig. 10 showing the device in longitudinal view from the side; Fig. 11 shows a modification of the current protection device according to Figs. 9 and 10; Fig. 12 shows in section from the side a current protection device according to the invention, which device comprises a number of current-limiting current limiting elements; Fig. 13 shows the current protection device according to fi g. 12 connected in an electrical circuit; Fig. 14 is a diagram illustrating the voltage distribution with respect to the various current limiting elements included in the device according to Fig. 13; and Fig. 15 shows a cross section through a particularly preferred embodiment of a current protection device according to the invention.

In the various figures, parts corresponding to each other are provided with the same reference numerals, although the parts do not always look exactly the same.

In all the embodiments of the invention shown below, it is particularly important that the elastomer body and electrodes in connection with their mutual abutment locations are in an environment of liquid, by which in the present case also reference is made to paste. This also applies to the embodiments according to fi g. 1-4 and 6-13, although it is not particularly apparent from the drawing, as said figures are intended primarily to illustrate other essential details in connection with advantageous constructions. However, an example of a basic construction, which shows that the elastomeric body and electrodes are actually in a liquid environment, is shown in Fig. 15.

The current protection device illustrated in Fig. 1 comprises as main parts a centrally arranged electrically conductive elastomer body 10 and two electrodes 12, 14 located on opposite sides thereof. When the device is connected in a circuit, a current is supplied between the electrodes 12, 14 via the elastomer body 10. A pressure device not shown in the figure provides an abutment pressure shaft between the respective electrode 12, 14 and the elastomer body 10 and this is illustrated by the arrow denoted by F. It should be noted that the electrodes 12, 14 are always arranged so that, under the influence of short-circuit currents, they strive to repel each other. This can be achieved, for example, in that the electrodes 12, 14, which are placed opposite each other, have an elongate shape, the elastomer body 10 being placed between them in connection with one of their end parts. The circuit current will then pass antiparallel through electrode rows 12, 14 as also indicated by the arrows in fi g. Thus, in the event of a passing overcurrent, the abutment surfaces 16, 18 between the respective electrode 10 and the elastomer body decrease.

At the abutment surfaces 16, 18, between the electrodes 12, 14 and the elastomer body there are, as shown in fig. 1, for increasing the contact action of electrically conductive networks 20, 22, which are formed in connection with the respective electrode surfaces intended for contacting.

The pressure force F acting directly on the electrode 12 normally ensures a good contact between the successive parts 10, 12, 14 and thus also enables the circuit current i to pass through the device, when it is connected to an external electrical circuit. The nets 20, 22 then sink due to the acting compressive force F partly in the elastomer body 10, which contributes to said increased contact action between the respective electrode 12, 14 and the electrically conductive particles of the elastomer body 10 (not shown here). When electrically conductive particles after the passage of the overcurrent have been burned at the interface of the elastomer body 10 towards the meshes, the nets 20, 22 will sink even deeper into the elastomer body due to the pressure force present and thus create new contact with intact electrically conductive particles therein. Thus, the device returns to the initial state, when overcurrent has passed and the circuit has been reopened.

With the new current limiting device, it has now become possible to significantly reduce the relaxation time. In the present case, it is of the order of seconds only.

When the nets 20, 22 have sunk completely into the elastomer body 10, the electrode surfaces between the meshes of the nets 20, 22 come into contact with undamaged elastomer surfaces, which further contributes to extending the life of the device. The sensitivity of the device thus increases through the insertion of networks 20, 22, which results in current peaks being suppressed.

Fig. 5 illustrates the current / time curve of a device which does not include the network described above - solid line. The previously mentioned current peak is clearly visible but is completely missing in the curve - dashed line - which in the same figure refers to a device with a net designed according to the invention. A probable explanation for the increased sensitivity obtained when using nets may be the valve action which arises due to the current constriction in connection with said nets. This relationship appears with the desired clarity of ñg. 2, where the current lines are compressed in electrically conductive mesh wires 24, which are included in the network 20 resp. 22.

A current constriction can be obtained to an even greater degree with the aid of a current protection device according to fi g. 3, the passage of the current intended to pass through the device being reduced at at least one point of contact 13 between the net 20 and the electrode 12 and the elastomer body 10, respectively. The contact member 20 is centrally located with respect to adjacent electrode 12 and elastomer body 10.

Thus, the increased current density in the elastomer body 10 is obtained. Since the electrode 12 and the mesh 20 have very good thermal conductivity and large thermal mass, the temperature increase under normal conditions is negligible. Thus, no increase in resistance occurs at normal temporary overloads, e.g. at a motor start, etc. In the event of a short circuit, when large currents occur, significantly more energy is supplied to the contact point 13 than is removed through the joules heating. Thus, the temperature increases drastically, whereby an abrupt increase in resistance occurs. The described embodiment thus obtains an increased sensitivity of the device to short-circuit currents, with retained properties during normal operation.

A further modification of the current protection device is shown in fi g. 4, where the passage of the current intended to pass through the device is reduced at at least one point of contact 13 'between the electrode 12 and the network 20. In this embodiment, as in the arrangement according to fi g. 3, insulations 11 ', 11 ", arranged at the end portions of the electrode 12, the electrode projecting centrally between the insulations.

The net 20 extends over both the insulations 11 °, 11 "and the intermediate part of the electrode 12.

As a result, the current through the network 20 can partly pass in the transverse direction, as indicated in the figure. To further increase the sensitivity of the device, the net 20 preferably consists of a material with significantly higher resistivity than the resistivity of the electrically conductive filler in the elastomer body 10. The material in the net 20 can e.g. is made of stainless steel while the filler can be made of silver or similar low-resistance material.

The i fi g. 6, the current protection device has a current limiting element, which comprises three separate elastomer bodies 10a, 10b, 10c, used in the two outer elastomer bodies 10a and 10c are each surrounded by separate electrically conductive networks 20a and 10c, respectively. 22a. The circuit may optionally be supplemented with an external resistor drawn in broken lines, which prevents overvoltages and ensures current through the device even after current limitation has taken place.

At uttöringsforrneii according to fig. 7, an arc-emitting substance 26, which may suitably be Al (OH), in powder form, is inserted between the mesh threads 24 of the nets 20, 22. the superstructures.

Fig. 8 relates to an embodiment of the invention, in which networks 20, 22 of the type previously discussed are used to form the electrodes included in the current protection device. Each electrode serving net 20, 22 is in this case fastened in a rigid circular frame 28, which can be likened to the fastening of the strings in a tennis racket. In this way, two integrated functions are obtained.

The current protection device according to fi g. 9 and 10 is formed with cylinder symmetry, an external network 30 here constituting one electrode. The second electrode 32 is arranged centrally. The device offers production technical advantages, as it can be produced and handled as a "fabric".

The i fi g. The current-protected current protection device 11 is provided with an electrode 34, which in this case constitutes a "network equivalent". The wire-shaped electrode 34 has been wound on an elastomer core 10, which encloses a center electrode 36. Between the points 38 and 40, the resistance is suitably large, preferably> 10 mohm. When the contact surface changes to a highly resistive state, a continuous connection of the resistance in the circuit is thus obtained. This transcends and suppresses commutation to any parallel resistors.

At the arrangements according to fi g. 12 and 13, a large number of current limiting elements in the form of elastomer bodies (101 ... 101 ... 10 ,,) have been stacked on top of each other. To the elastomer bodies 101 ... 10 ,, connecting networks 401 ... 40 ,, +, are connected to each other in parallel via resistors RFI, RW. With this, a splitting division is achieved between consecutive current limiting elements. This increases the voltage strength when the device is in a highly resistive state. This in turn results in the respective contact surface not being "stressed" as hard as when only one contact surface is activated.

The diagram in fi g. 14 shows the voltage Up as a function of the consecutive current limiting elements j. The i ñg. The voltage division shown in Fig. 14 refers to the case where most of the elastomer bodies in Fig. 13 are highly resistive. In the example shown, e.g. elastomer body 3 still in its low resistivity state. An external voltage source E is used, a current passing through the device.

At the i fi g. The illustrated embodiment of the new radiation protection device shows that both the electrically conductive elastomer body 10, the electrodes 12, 14, the contact device (indicated by the electrically conductive networks 20, 22), the pressure device (indicated by arrow F) and any additional components belonging to the arrangement are arranged in a preferably hermetically sealed container 42. I fi g. 15 years also the direction of the circuit current through the electrodes 12, 14 marked. In the container 42, which is made of electrically non-conductive material, Lex. ceramic or plastic, a liquid 44 is enclosed in such a way that the environment of the connection points between elastomer body 10 and electrodes 12, 14 always consists of said liquid 44, regardless of the orientation of the current protection device in the room.

The liquid 44, which may be water or water with an addition of glycerin, must have such properties that it dissolves residual products between the various components, so that a low contact resistance is obtained and is largely maintained between the electrodes 12, 14. and the elastomer body 10.

Because electrodes 12, 14 and the elastomer body are present in the said liquid 44, slag products are also effectively prevented from being deposited on the contact surfaces of the electrodes 10, 12 during combustion. Of course, it is also important that the liquid 44 used has arc inhibitory properties.

Further modifications of the above-exemplary embodiments of the current protection device according to the invention can be made within the scope of the patent claims. Thus, in the form of a contact member specified in the embodiments above, it can also consist of a special layer with electrical conductivity substantially only perpendicular to the layer plane. The layer may consist of directionally oriented wires and of an electrically insulating material arranged between them, which may for instance consist of silicone.

The contact means may also be formed, for example, by etching, plasma spraying, etc., on the surface of an electrode. Furthermore, the contact means may comprise two separate mesh networks located next to each other, the mesh size in one network deviating from the mesh size in the other network. It is also possible to disperse arc inhibiting agent in the electrically conductive elastomer body or to disperse said substance in a thin metal layer of the electrically conductive elastomer body, which in this case may have a cylindrical shape. in

Claims (14)

10 15 20 25 30 - 5141775 8 Patent claims Device for protection against overcurrent in electrical circuits, which device comprises at least one electrically conductive elastomer body (10) and two electrodes (12, 14) intended for supplying the circuit current through them, which are arranged so that they, under the influence of short-circuit currents strive to repel each other, and which - each directly or via an intermediate part - abut in corresponding places against the elastomer body, a pressure device producing abutment pressure, the elastomer body (10) being deformed by the pressure device at the respective abutment point at the pressure point. loading, characterized in that the elastomer body (10) and electrodes (12, 14) in connection with their mutual abutment positions are located in an environment of liquid (44) - which in the present case also refers to paste - with residual product dissolving properties and in that a contact means in the form of at least one grid-like layer (20, 22) is arranged so that in connection with at least one electrode and an adjacent elastomeric body and / or between two adjacent elastomeric bodies upon pressure loading cause increased contact action by the layer sinking into an adjacent elastomeric body. Device according to claim 1, characterized in that the liquid (44), which has a substantially higher resistivity than the elastomer body (10), comprises glycol. Device according to one of Claims 1 and 2, characterized in that the liquid has arc-inhibiting properties. Device according to one of Claims 1 to 3, characterized in that the liquid (44) is enclosed in a hermetically sealed container (42), which also holds an elastomer body (10), electrodes (12, 14) and a pressure device. Device according to any one of claims 1-4, characterized in that the passage of the current intended to pass through the device is reduced at at least one contact point (13) between contact means (20) and electrode (12) resp. elastomer cup (10). Device according to one of Claims 1 to 5, characterized in that the passage of the current intended to pass through the device is reduced at at least one contact beam (13 ') between the electrode (12) and the contact means (20). 7. Device according to any one of claims 1-5, characterized in that the contact member consists of a layer with electrical conductivity substantially only perpendicular to the layer plane. kånnetecknad Device according to one of Claims 1 to 6, in that the contact means consists of a separate stitch, which is, for example, punched, etched, woven or knitted. Device according to one of Claims 1 to 6 and 8, characterized in that the contact means (20a, 22a) is arranged to enclose the respective elastomer body (10a, 10c), it also acting as one with this integrated resistor. Device according to one of Claims 8 and 9, characterized in that the wires included in the contact member are made of brass, copper or nickel, preferably with a coating of silver. Device according to one of Claims 8 to 10, characterized in that the wires included in the contact means are insulated from one another. Device according to one of Claims 1 to 6, characterized in that the contact means forms a part integrated with an electrode. Device according to claim 12, is formed by etching, plasma spraying, etc. on the surface of the electrode. characterized by the contact means Device according to any one of claims 1-4, said layer (20, 22) constituting an electrode. characterized avatt