EP0289447A1 - Cutting device for high current rails - Google Patents

Abstract

In order to protect isolating devices for heavy-current busbars (1), which have a plug-in connecting contact (9) between the heavy-current busbars (1) and an alarm switch (12, 13), arranged in an insulated manner, against unacceptable heating, an additional system part (14) is provided, of material which melts at a low temperature, and which melts above the normal operating temperature but below the acceptable limit temperature of the isolating device, in particular the connecting contact (9). When the system part (14) melts, the alarm switch (12) thus moves into the position it occupies when the connecting contact is not plugged in. This position change of the alarm switch (12) can be used to trip an external protection device, by means of which, e.g. the current flow through the heavy-current busbars (1) is immediately interrupted and as a result of which the isolating device for heavy-current busbars (1) is protected against unacceptable heating and possible destruction. <IMAGE>

Description

The invention relates to a disconnecting device for high-current rails, in which the high-current rails at least partially oppose one another, with a plug-in contact that can be inserted between the high-current rails and that has contact lamellae on the surfaces facing the high-current rails, which contains an isolated signaling switch, to which the plug contact in its intended end position with a surface facing it comes to the system and thereby brings the signaling switch by overcoming the actuation path when inserted into a certain switching position, the plug contact being insulated from the signaling switch by an insulating part.

A separating device for high-current rails is known from a publication by Multi-Contact AG, Basel, published as a special print from "Technische Rundschau" 36 and 43, 1975, image 9 on page 3.

In this known isolating device for high-current rails, they are at a certain distance from one another and partially overlap. In the overlap area, an intermediate space is formed by fastening elements, not shown, into which a plug contact can be inserted. The high-current rails are fastened to suitable, provided supports by means of fastening elements. The surfaces of the plug-in contact provided with the handle facing the high-current rails have contact lamellae which, while ensuring a sufficient contact surface, deflect when the plug-in contact is inserted and ensure the necessary contact pressure between the plug contact and the high-current rails. The current flows from one high-current rail via the plug contact to the other high-current rail.

It is common for the known separator for high current rails contained an isolated signaling switch.> This is brought into a certain switching position by overcoming the actuation path when the plug-in contact is fully inserted correctly and thus signals that the plug-in contact is fully inserted and the full cross-section of the plug-in contact is available for power transmission. In order to isolate the high-current plug contact from the signaling switch, it is customary to provide the surface of the plug contact facing the signaling switch with an insulating part. Inadmissible heating of the disconnection device, in particular the insertable plug contact, is not detected by the message provided in the known disconnection device of the correct end position of the plug contact. Inadmissible heating occurs e.g. B. then when the contact resistance between high-current rails and plug contact due to contamination of the contact blades or decreasing contact pressure are too large.

The present invention has for its object to provide a less expensive device for reporting an impermissibly high heating of disconnecting devices for high-current rails of the type described above.

To solve this problem, in a disconnecting device for high-current rails of the type described in the invention, an installation part made of low-melting material is attached to the plug contact on the surface facing the signal switch, the melting point of which is above the normal operating temperature and below the permissible limit temperature of the disconnecting device , and the system part protrudes beyond this surface in the direction of the signaling switch by a height which corresponds at least to the actuation path of the signaling switch, and the plug contact on the signaling switch is only applied via the system part and the insulating part. As a result, a temperature-sensitive element is connected between the plug contact located in its end position and the signaling switch indicating this end position. Now the normal operating temperature of the disconnecting device, in particular that of the plug contact, but which is still below the permissible limit temperature is exceeded, the system part melts and thereby releases a space at least corresponding to the actuation path of the signal switch on the surface of the plug contact facing the signal switch. As a result, the signaling switch moves into a different switch position. This gives the signaling switch an additional temperature-dependent function which, when the specified melting point of the material of the system part coordinated with the permissible operating and limit temperature of the separating device, ensures a temperature-dependent signal by actuating the signaling switch, although the end position of the plug contact remains unchanged. This new function of the signaling switch can advantageously be used to counteract inadmissible heating and possible destruction of the separating device, for example by interrupting the current flow.

The movement of the signaling switch takes place against the insertion direction of the plug contact when the system part melts. It is therefore expedient to design the plug contact on the surface facing the signal switch in such a way that the mounting of the insulating part contains spring elements which press the insulating part against the contact surface of the system part consisting of material melting at low temperature. As a result, the movement of the insulating part against the end face of the plug contact is supported by the force of the spring elements when the system part melts. This action of the spring force is independent of the actuating force of the signaling switch itself, whereby its actuation is ensured in any case.

It is advisable to design the system part as a bolt which is inserted in a hole in the end face of the plug contact facing the signaling switch. A bolt can be easily prefabricated, can be inserted into the plug contact without any further production outlay and can easily be renewed after melting.

As a further advantageous embodiment of the plug contact this has at least one further hole, which connects a surface without contact lamellae of the plug contact with the hole for receiving the bolt. This creates an outlet channel for the molten material of the plant part, which enables the melt to flow out specifically on a surface of the plug contact of the separating device that does not belong to the contact surfaces. Contamination of the particularly sensitive contact blades is thus avoided.

It is also advisable to manufacture the system part from metal that melts at low temperature and has a melting point of 70 ° C. By using metal as the material for the contact part, even if the contact surfaces are contaminated by the melt of the contact part, there can be no significant increase in the contact resistance at the contact surfaces, because such contamination only increases the contact resistance of the contact surfaces only insignificantly. If metal is selected for the system part, the melting point of which is 70 ° C, a particularly simple coordination of the melting temperature of the system part with the normal operating temperature of the separating device and its highest, permissible limit temperature is possible, since the operating temperature is below 70 ° C and the permissible limit temperature is around 80 to 85 ° C. It is advisable to manufacture the system part from a bismuth-lead-tin-cadmium alloy, since this material meets the requirements for a suitable melting temperature.

The invention will be explained in more detail below with reference to the exemplary embodiment shown in FIGS. 1 to 3. 1 shows a top view of a disconnecting device constructed according to the invention for several high-current bars without the insertable plug contact. Fig. 2 shows a section of the separating device along the section line II-II in Fig. 1 with an inserted plug contact. In Fig. 3 the plug contact is shown partially in section.

Figures 1 and 2 show a separating device for high-current rails 1, as z. B. for the power supply large DC motors is used. The high-current rails 1 are parallel to one another and extend over a greater length. The ends of the high-current rails 1 overlap, so that the high-current rails 1 are partially opposite each other there. In the boundary region formed in this way, the high-current rails 1 are supported by spacers 2, 3 made of insulating material against one another and against the angles 4 carrying them, and braced with bolts 5 and nuts 6 with one another and with the angles 4. As a result, a space 7, 8 is formed between the outer and the middle high-current rail 1. For the current-carrying connection, the plug contact 9 is optionally inserted into one of the two spaces 7, 8 by means of its handle 10. It is shown pushed into the left space 7 in FIG. 2.

A web 11 is attached to the outer spacers 3 made of insulating material and carries the signaling switches 12, 13, which are assigned to the spaces 7, 8 between the high-current rails 1. An insulating part 14 is provided between the plug contact 9 and the signaling switch 12, by means of which the high-current plug contact 9 is electrically isolated from the signaling switch 12. The plug-in contact 9 inserted into the left space 7 is in contact with the signaling switch 12 and has brought it into the switch position corresponding to the end position of the plug-in contact 9, the system being carried out only via the system part 16 attached to the end face 15 of the plug-in contact 9 and the insulating part 14. The signaling switch 13 assigned to the right space 8 between the high-current rails 1 is shown in the switch position as it is when the plug contact 9 is not inserted.

In Fig. 3, the plug contact 9 is shown in a position rotated by 90 ° relative to Fig. 2, so that one of the contact surfaces 17 is visible, which bears against a high-current rail 1 after the plug-in contact 9 has been inserted. In order to reduce the contact resistances, obliquely extending contact lamellae 18 are attached to the contact surface 17.

The insulating part 14 is fastened to the lower end face 15. For this purpose there are stud bolts 19 which are screwed into bores 20 in the end face 15. Between the heads 21 of the stud bolts 19 and the insulating plate 14 there are springs 22 which press the insulating part 14 in the direction of the end face 15. So that the insulating part 14 does not come to a stop on the end face 15, the contact part 16 is used, which has the shape of a bolt or circular cylinder. The surface of the contact part 16, which rests on the insulating part 14, projects beyond the end face 15 by the height 27 indicated by arrows. This height 27 corresponds at least to the actuation path of the signal switches 12, 13. When the plug contact 9 is inserted into one of the spaces 7, 8, the respective signal switch 12, 13 is touched by the insulating part 14 and brought into the switch position corresponding to the end position of the plug contact 9.

The system part 16 consists of a bismuth-lead-tin-cadmium alloy, the melting point of which is 70 ° C. If this melting temperature is exceeded, the system part 16 melts and yields to the force exerted by the spring elements 22, the insulating part 14 moving in the direction of this force until it comes to a stop on the end face 15 of the plug contact 9. In this case, the actuation path required for actuating the signaling switch 12 is covered, and the signaling switch 12 reaches a position which corresponds to that when the plug contact 9 is not inserted. This also enables a temperature-dependent actuation of the signaling switch 12, although the actual end position of the plug contact 9 has not changed. The temperature-dependent change in position of the signaling switch 12 can trigger a signal in the same way as the failure to reach the required end position of the plug contact 9 or act on an external protection which interrupts the circuit to avoid overloading the isolating device. By using the bismuth-lead-tin-cadmium alloy for the material of the system part 16, the melting point of which is 70 ° C, a sufficiently large margin is achieved at the maximum permissible limit temperature, so that the reaction time of the plug contact increases very rapidly external Protection can be kept within the usual tripping times, and yet no damage to the separating device is to be expected.

Due to the spring elements 22, when the system part 16 melts, an inevitable movement of the insulating part 14 in the direction of the end face 15 of the plug contact 9 takes place due to the pretension exerted on the insulating part 14, so that the position change of the signaling switch 12 can take place freely and safely.

The middle bore 23 for receiving the contact part 16 designed as a bolt ends in a blind hole 24 into which drain holes 25 open, through which the melt of the contact part 16 can flow specifically to the surfaces 26 of the plug contact 9, to which no contact blades are attached. As a result, in the event of the system part 16 melting, the melt is removed in a targeted manner from the sensitive contact surfaces 17 with the contact lamellae 18. The risk of molten metal collecting on the contact surfaces 17 of the plug contact 9 and possibly solidifying is thus avoided, as a result of which complex cleaning of the contact surfaces 17 and the contact lamella 18 is avoided.

Claims (6)

1. Separating device for high-current rails (1), in which the high-current rails (1) are at least partially opposed, with a plug-in contact (9) which can be inserted between the high-current rails (1) and which has contact lamellae (17) on the surfaces (17) facing the high-current rails (1). 18), which contains an isolated signaling switch (12, 13) to which the plug contact (9) comes into contact in its intended end position with a surface facing it, and thereby the signaling switch (12, 13) by overcoming the actuation path when inserting brings into a certain switching position, the plug contact (9) being insulated from the signaling switch (12, 13) by an insulating part (14), characterized in that on the plug contact (9) on the surface facing the signaling switch (12, 13) (15) a system part (16) made of low-temperature melting material is attached, the melting point of which is above the normal operating temperature but below the permissible size The temperature of the separating device lies above this surface (15) in the direction of the signaling switch (12, 13) by a height (27) which corresponds at least to the actuation path of the signaling switch (12, 13) and that the plug contact (9 ) on the signaling switch (12, 13) only via the system part (16) and the insulating part (14). 2. Separating device according to claim 1, characterized in that the storage of the insulating part (14) contains spring elements (22) which press the insulating part (14) against the contact surface (28) of the system part (16) which melts at low temperature. 3. Separating device according to claim 1 or 2, characterized in that the contact part (16) is a bolt which is inserted in a bore (23) on the face switch (12) facing the end face (15) of the plug contact (9). 4. Separating device according to claim 3, characterized in that the plug contact (9) has at least one further bore (25) which has a surface (26) of the plug contact (9) without contact blades (18) with the bore (23) for receiving the Bolzens (16) connects. 5. Separating device according to claim 1 or one or more of claims 2 to 4, characterized in that the plant part (16) consists of metal melting at a low temperature with a melting point of 70 ° C. 6. Separating device according to claim 1 or one of the other claims, characterized in that the plant part (16) consists of a bismuth-lead-tin-cadmium alloy melting at low temperature.

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