DE2821563C2 - Electrical wound capacitor with switch-off protection - Google Patents

Description

The invention relates to an electrical wound capacitor with switch-off protection, the heat of which action of radially shrinking capacitor winding is arranged on a core tube, which is below the Shrinkage pressure of the winding is axially longer and thereby an electrical lead part between one with the one end of the core tube displaceable first feed point and one with the other Core tube end displaceable second feed point interrupts.

Condenser coils which shrink radially under the action of heat are generally used a film tape made of thermoplastic material, which is stretched in the longitudinal direction of the tape and is therefore molecularly oriented in this direction, so that it moves in the longitudinal direction of the tape under the action of heat contracts and therefore the capacitor coil formed from it at least in the radial direction the radially inner winding areas shrinks. The amount of shrinkage depends on the development of heat.

A core tube can be used as the core for such a capacitor winding, which under the radial shrinkage pressure of the roll where this shrinkage pressure is greatest, d. i. mostly in the Axial center of the roll or slightly offset from the axial center, is compressed radially so that at least one core tube end, mostly both core tube

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bO ends, are pushed axially out of the coil and / the core tube is elongated overall for a given wound capacitor set the amount by which the core tube elongates at a certain temperature

The utilization of the axial elongation of the core tube of a tube that shrinks radially under the action of heat Capacitor winding or dielectric to operate a switch-off fuse, which the circuit of the Capacitor u-tterbricht when it is inadmissible heating is known (DE-OS 26 06 174). Here will the lead in the form of a wire or tape leading to one end of the roll guided tautly through the core tube and mechanically fixed at both core tube ends or into the Material of the core tube embedded and in at least two places, for. B. through the formation of anchoring thickenings, anchored in the core tube, so that the supply line through the axial elongation of the core tube is torn. In the former case, the lead wire will have a relatively large initial length stretched by the total change in length that corresponds to the total change in length of the core tube corresponds in the second part is the starting length of the wire section to be stretched when they are close together Anchoring points are smaller. However, that for stretching it is also correspondingly smaller Wire section leading change in length of the core tube section between these anchoring points. In both cases, this is the ratio of the change in length that has to be passed through until the wire breaks the same and its initial length is large, which means that the wire will tear even with small ones Changes in length of the core tube due to low heat exposure opposes. E: It is possible to keep the modulus of elasticity of the wire small by selecting the appropriate material or a weak part to train by local cross-sectional constriction of the wire (DE-GM 19 84 187), but what the achievement may oppose the desired electrical properties.

On the other hand, when there is some balance between the conflicting desired strength properties and desired electrical properties is to be achieved in that one of the tear wire with appropriate bias between clamps the core tube ends, this requires a correspondingly large manufacturing effort for the defined Adjustment of the pretension, if there is a defined tearing of the wire at relatively wants to achieve tightly specified boundary conditions of the capacitor operation.

The object is achieved by the invention, an electrical wound capacitor of the type mentioned at the beginning Art to create in which largely independent of the strength properties of the Lead part and therefore without the risk of the desired electrical and mechanical properties of the lead part interfere with each other, a defined interruption of the lead part at relatively tightly specified boundary conditions of the capacitor operation can be achieved.

According to the invention, this is done with a first

Proposed solution through this at the two core tube ends an insulating rod extending through the core tube is formed with a notch and that the lead part bridging the notch point is fixed on both sides of the notch point on the insulating rod, and achieved with a second proposed solution that at one end of the core tube a through the Core tube extending insulating rod is set and that the lead part of an electrically conductive Face coating of the other end of the core tube or of a plug attached to it and the one with this Core tube end or the stopper flush free rod end of the insulating rod is formed

By both of the proposed solutions according to the invention is therefore by the elongation of the The core tube to be stressed to the breakage section of the supply part is short and nonetheless the Total length increase of the core tube fully used for interrupting the supply line part, by the total change in length of the core tube of both core tube ends over the under the operating conditions Inextensible insulating rod is transferred to the point at which the lead part should be interrupted. On the one hand, this results in the interruption of the supply line part at a whole certain point and on the other hand it is reliably guaranteed that the lead part at a completely certain boundary conditions of the capacitor operation and thus a relatively narrowly limited one Overload of the capacitor already switches off. At the same time, the invention to be interrupted Lead part can be designed largely freely in terms of its electrical properties, without being limited in this by the required mechanical properties. Moreover, they are Proposed solutions according to the invention do not rely on tightening the supply line with tight certain bias, so that the manufacturing cost for the capacitor is reduced.

With regard to the second proposed solution of the invention, a shutdown safety device is indeed one electrical wound capacitor known per se, in which a front contact layer of the one core tube end merges into the adjacent end contact layer of the capacitor winding via a weak point, so that the weak point breaks if there is a relative displacement between this end of the core tube and the adjacent end face of the capacitor coil comes (DE-AS 20 60 907). Here, however, will not the elongation of the entire core tube is used to achieve the breaking stress at the weak point.

It can be seen that the solution according to the invention can be used not only for single-pole disconnection of the capacitor, but also correspondingly for two-pole disconnection. The solution according to the invention does not depend on the capacitor being accommodated in a housing, although this is also possible. If the capacitor is housed in a housing, it should be ensured that the core tube of the wound capacitor can extend as freely as possible. This can be achieved by a correspondingly axially flexible support of the core tube. For example, you can use the case back. au ^f which the core tube is seated, membrane-like designs. = -o that the bottom can bulge under the pressure of the core. In addition, a free space can be provided in the capacitor housing into which the core tube can expand.

The invention is explained with the aid of two exemplary embodiments that are shown in the drawing can be seen. In the drawing, ϊ F i g. 1 shows a first embodiment of an electrical wound capacitor according to the invention in longitudinal section in the operating state,

F i g. 2 shows the embodiment from FIG. 1 after the cut-out protection has responded,

in Figure 3 a second embodiment in longitudinal section and

4 shows the embodiment from FIG. 3 according to the Activation of the cut-out protection.

According to FIG. The capacitor winding 1 is on a core tube 2 made of thermoplastic plastic wound up This consists of metallized plastic films made from a thermoplastic material. the End faces of the roll 1 are provided in the usual way with end contact layers 18, 19 to which the respective supply line 9.20 is soldered on

The metallized plastic film strips forming the winding 1 are molecularly oriented in their longitudinal direction corresponding to the Uru angsrichtung of the winding 1, so that they contract in their longitudinal direction under a certain amount of excess heat and therefore the winding 1 in its radial direction. line shrinks The temperature distribution over the roll 1 is different due to the heat-insulating properties of the plastic films. ; <»The temperature is highest approximately in the axial center of the coil in the area of the circumference of the core tube 2, since there the self-cooling is lowest due to the most unfavorable heat dissipation conditions there. At this point, the radial shrinkage of the winding 1 J3 is greatest, so that a temperature-dependent increasing pressure is exerted on the outer wall of the core tube, especially in its longitudinal center. The core tube consists of a plastic material that softens under the action of heat, so that after its softening temperature has been exceeded under the shrinkage pressure of the roll 1, it is radially compressed in its longitudinal center, whereby the core tube ends 13, 14 are pushed axially out of the roll 1. This state is shown in FIGS. 2 and 4 shown. According to FIG. 1, an insulating rod 12 extends in the interior of the core tube 2, the rod ends of which are fixed in end plates 21, 22 which are each firmly supported on one of the two core tube ends 13, 14. The insulating rod 12 consists made of a material that is rigid in the application temperature range, for example made of thermoplastic or thermosetting plastic material, and has a notch 8 in its longitudinal center. The leading in Fig.] To the lower end face of the Wkkels 1 feed line 9 is ·>"> axially passed through the core tube 2 and the notch point anchored on both sides 8 at the supply sites 3, 4 to the insulating rod \ 2, so that between the lead bodies 3 , 4 tightly running supply line part 16 bridges the notch 8.

do if therefore the core tube ends through the longer The core tube that is to be pushed apart axially will be due to an elongation of the core tube 2 the shrinkage pressure of the roll 1 in the event of excessive heat development, the two through the notch point 8 -> parts of the insulating rod 12 separated from each other by the core tube ends Π, 14 axially outwardly carried along, so that the notch point 8 breaks through elongation fracture and the one that bridges the notch point 8

Zulciiiingteile eberv'ails Ii i ίΛ:,; ι ..:.; · Οη! ': Ϊι /.errei! "' !. This to ¹ :;. R.; L is in K i; _ '■' lc / ol-.

In the embodiment aiii FIG. 3 is the insulating rod 12 executed without a notch and in the face plate 22 at one end of the core tube 13 firmly supported, whereas it is supported at the other end of the core tube 14 with the end face of the other end plate 21 is flush. On the adjacent end faces of the The end of the rod and the end plate 21 is an electrically conductive bridge bridging the gap between them Face coating 10, 11 set into the feed line 9 is switched on. so that by the elongation of the Core tube 2 is sheared off and according to FIG. 4 interrupts the feed line 9.

In both embodiments, the in the supply line 9 to the one St; m. _'iu · ties dielectric · »or winding | ..lt., Κ ··· ι i-ji ^ ato. ^V emgeseh.i'k'ien supply lines, between which the supply line 9 is to be interrupted, are close to one another, while the entire length change of the core tube 2 is transferred to the supply line part lying between the supply points with a radial thrust of the winding I . As a result, the stress on the lead part increases rapidly to the point of breaking stress, so that a defined interruption of the lead is ensured.

It can be seen that the Abschallsichcrung with the Embodiments shown, possibly even before the winding of the dielectric in the core tube can be present fully assembled.

For this purpose I sheet drawings

Claims (2)

Patent claims: 1.Electric wound capacitor with switch-off protection, its condenser coil, which shrinks radially under the action of heat, on a core tube is arranged, which is axially longer under the shrinkage pressure of the winding and thereby an electrical lead part between a first one which can be displaced with the one end of the core tube Feed point and a second feed point that can be displaced with the other core ίο tube interrupts characterized in that at the two core tube ends (13,14) a the core tube (2) extending insulating rod (12) is formed with a notch (8), and that the Notch point (8) bridging feed line part (16) on both sides of the notch point (8) on the insulating rod (12) is fixed 2.Electric wound capacitor with switch-off protection, the capacitor winding of which shrinks radially μ under the action of heat is arranged on a core tube which becomes axially longer under the shrinkage pressure of the winding and thus an electrical supply part between a first supply point that can be displaced with one end of the core tube and a second that is displaceable with the other end of the core tube Feed point interrupts, characterized in that an insulating rod (12) extending through the core pipe (2) is fixed to one core pipe end (13), and that the feed pipe part is covered by an electrically conductive face coating (10, 11) on the other end of the core pipe (141 or a fixed therein and the stopper is formed or the plug bücrlig final ^ free bar end of the insulating strip (12) with this core tube end (14).