DE1282152B - Electric fuse - Google Patents

Description

Electrical fuse The invention relates to an electrical fuse Fuse, in which a fusible on a carrier made of insulating material Coating is applied, on which at least one power supply electrode rests.

There is an electrical fuse known in which on a carrier made of insulating material, a fusible coating is applied to the at least one feed electrode rests on it. This known fuse consists of an insulating plate to which the fusible coating is applied, and from a long electrical conductor, the end of which has the thin coating on an inside the surface of the covering touches so that in the event of an overload the coating around the point of contact melts. The fuse has now been used up.

The invention is based on the object of a backup of the initially called type so that it can be used several times. This is according to the invention achieved in that the carrier is designed as a ball on its entire Surface is covered with the fusible coating, and that facing each other Resilient power supply electrodes are provided, between which the covering bearing ball is rotatably supported. In the inventive training It is possible to secure the ball by a certain angle after responding to twist, so that the electrodes with as yet uninjured areas of the coating in Come into contact. In this way, the backup can be used again and again until the fusible topping is used up. Because between the individual areas where the pavement has melted, there are still ridges of uninjured pavement, is a electrical connection of sufficient cross-section ensured between the electrodes.

The ball carrying the fusible coating can be in a funnel-shaped Be held cavity of a plug-like insulating sleeve, with a power supply as a centrally arranged electrode that is resiliently movable in the direction of the longitudinal axis is formed, while the second power supply a sleeve encompassing the insulating material Feather is. The centrally arranged electrode can be designed to be ring-shaped be and with a displaceable in the longitudinal direction in the insulating sleeve and exchangeable metal piston are connected, the annular electrode is held in guide grooves of the insulating sleeve, the bases of which in the direction are inclined towards each other on the opening of the sleeve. The insulating sleeve is preferably at least partially from a further spherical insulating material part Surrounded liquid-tight, the cavity of this insulating part filled with oil is. Preferably, the spring surrounding the insulating sleeve is horseshoe-shaped formed and engages with its ends in arranged at the free end of the insulating sleeve Longitudinal grooves, the ends when screwing the fuse into a fuse element abut against its metal thread and furthermore in the spherical insulating material part Guide grooves are provided for the legs of the horseshoe-shaped spring. By doing Spherical insulating material can extend outwards in the area of the guide grooves narrowing openings may be provided in the correspondingly conical pressure pieces are used, which protrude on the outside of the insulating material and inside on the rest on a horseshoe-shaped spring.

The funnel-shaped cavity of the plug-like insulating sleeve is preferably provided with longitudinal keyways on its wall with a phosphorescent Covering are provided, wherein in the spherical insulating material on the keyways directed see-through windows are provided. The phosphorescent coating will stimulated by the spark produced by an overload to glow, so that the interruption of the circuit is visible through the viewing window. Preferably are the see-through windows are provided with optical devices.

The invention is illustrated below with reference to the drawing using an exemplary embodiment explained in more detail. In the drawing, F i g. 1 shows a longitudinal section through a fuse according to the invention, which is not screwed into a securing element, FIG. 2 shows a longitudinal section of the fuse according to FIG. 1, but screwed into a locking element, which is not shown, however, FIG. 3 a longitudinal section through a fuse according to FIGS. 1 and 2, but with the pushbuttons pressed in, FIG. 4 one Longitudinal section through the plug-shaped insulating sleeve, but in an opposite one F i g. 1 plane rotated by 90 °, FIG. 5 shows a longitudinal section through the in a spherical further insulating part used insulating sleeve, namely in the same plane as Fig.4, F i g. 6 shows a cross section through the spherical Insulating part inserted insulating material sleeve, F i g. 7 is a view of the spherical Isolierstoffteils from below and F i g. 8 shows a single representation of the spherical Isolierstoffteils in a section in the direction of the longitudinal axis of the cavity.

In the figures, the same parts are provided with the same reference numerals. With 10 a Isolierstoffkugel is designated, which consists of a material resistant to heat. It has a fusible coating 20 on its surface, the thickness of which is such that it melts when the permissible current strength is exceeded. The ball 10 is mounted in a funnel-shaped cavity of a plug-shaped insulating sleeve 11. It is held in this cavity by two power supply electrodes 13 and 14. These electrodes 13 and 14 are made of a highly electrically conductive and resilient metal. They are of course dimensioned in such a way that they are not excessively heated by the breaking current. The electrodes can be designed as wedge, flat or round wire electrodes.

The electrode 14 is approximately horseshoe-shaped. It rests on the fusible coating 20 of the ball 10 . It also touches the support points 21 (FIG. 3). The ends of the electrode 14 protrude into beveled grooves 23 in the insulating sleeve 11.

The insulating sleeve 11 also contains the electrode 13, which is designed in the form of a ring. This electrode 13 engages in two opposite guide grooves 1s (FIG. 5), the bases of which converge somewhat in the direction of the funnel-shaped cavity, thereby preventing the electrode 13 from sliding out unintentionally. The plane of the electrode 13 is rotated by 90 ° with respect to the plane of the electrode 14. It rests on the one hand against the fusible coating 20 and on the other hand against a displaceable piston 15 which is displaceable in the longitudinal direction of the insulating material sleeve and is loaded with a compression spring 16. 17 is the middle contact pin of the fuse, which is in contact with the fitting screw of the fuse element when the fuse is screwed into a fuse element. The piston 15 is preferably exchangeable. It is possible in this way to set the pressure of the electrode 13 on the ball 10 by inserting pistons 15 of different lengths. The sleeve 11 is also provided with an Edison screw thread 25 with which it can be screwed into a securing element.

The insulating sleeve 11 is inserted into a spherical further insulating part 12 made of resistant insulating material. To facilitate the introduction, guide strips 26 are provided on the insulating material sleeve 11 and engage in guide grooves 29 of the spherical insulating material part 12. The legs of the horseshoe-shaped electrode 14 lie in grooves 19 of the spherical insulating material part. To support the insulating sleeve 11 , support points 21 are provided in the spherical insulating part 12. The spherical insulating material part 12 is sealed against the insulating material sleeve 11. The resulting cavity between insulating material part 12 and sleeve 11 is preferably filled with oil. This oil surrounds the ring-shaped electrode 13 and the ball 10 completely and the horseshoe-shaped electrode 14 partially. The oil is used to cool these parts.

The spherical insulating material part 12 contains in its wall, approximately at the level of the transverse axis, conical holes into which push buttons 22 are inserted. These push buttons protrude from the outside beyond the wall of the ball and rest against the legs of the electrode 14 on the inside. They are pushed outwards by this electrode.

Furthermore, the spherical insulating material part 12 contains holes for the passage of screws (FIG. 5) with which the two parts 11 and 12 are screwed together.

In the wall of the funnel-shaped cavity of the insulating sleeve 11, keyways 27 are provided, which are provided with a phosphorescent coating. In the bottom of the spherical insulating material part 12, small windows are provided which are directed towards the keyways 27. The area 31 (FIG. 8) of the insulating material part 12 opposite the funnel-shaped cavity of the insulating material sleeve can also be provided with a phosphorescent coating in order to increase the luminosity.

The fuse according to the invention is screwed into a fuse element. F i g. 1 shows the fuse not screwed in. When screwing into the securing element, the ends 24 of the electrode 14 come into contact with the metal thread of the securing element, which presses these ends 24 into the guide grooves 23 (FIG. 2). The circuit is then closed via the fusible coating 20 of the ball 10 , the electrodes 13 and 14 and the fusible coating 20 being cooled by oil.

When a given current intensity is exceeded, heat is generated at the contact points of the electrodes 13 and 14 with the covering 20 , which heats the covering 20 . The resulting sparks are extinguished by the oil. The electrical circuit is interrupted by the melting away of the coating in the area of the electrode contact points. The sparks illuminate the phosphorescent coating in the keyways 27 and in the part 31 of the ball 12 and begin to glow and indicate through the windows mentioned that the circuit has been interrupted.

In order to close the circuit again, the fuse does not need to be removed from the fuse element. Rather, it is sufficient to turn the fuse briefly to the left with the pushbuttons 22 pressed in, as a result of which the fuse in the fuse element is loosened. The fuse can then be screwed tight again. By pressing in the buttons 22, the legs of the electrode 14 are pressed inward, as a result of which the electrode 14 is lifted off the ball 10 and moves in the direction of the bottom 31 . The ball 10 then rolls along the inclined wall of the funnel-shaped cavity of the sleeve 11 of the lifted electrode 14 and receives an angular momentum by briefly turning the fuse to the left, whereby the ball is rotated and the electrodes 13 and 14 with other areas of the fusible coating 20 in Come into contact. After tightening the fuse and releasing the pushbuttons 22, the spring pressure of the electrode 14 rotates the ball 10 through a certain angle, pushes it back into the funnel-shaped cavity of the sleeve 11 and fixes it again. The circuit is then closed again.

Due to the spherical shape of the insulating body 10 carrying the covering 20, multiple contact possibilities are given, so that the fuse can be used again and again until the covering 20 is used up. Since webs of uninjured coating still remain between the individual areas where the coating has melted, an electrical connection of sufficient cross-section between the electrodes is ensured. The circuit can be closed and secured several times without replacing the fuse.

Claims (7)

Claims: 1. Electrical fuse, in which on A fusible coating is applied to a carrier made of insulating material, on which at least one power supply electrode rests, d a -characterized in that the carrier is designed as a ball (10), which over its entire surface with the fusible coating (20) is covered, and that opposing resilient Power supply electrodes (13, 14) are provided, between which the covering bearing ball is rotatably supported. 2. Fuse according to claim 1, characterized in that that the fusible coating (20) carrying the ball (10) in a funnel-shaped Cavity of a plug-like insulating sleeve (11) is held and that a power supply as a centrally arranged electrode that is resiliently movable in the direction of the longitudinal axis (13) is formed, while the second power supply is an insulating sleeve (11) is comprehensive spring (14). 3. Fuse according to claim 2, characterized in that that the centrally arranged electrode (13) is ring-shaped and with one that is displaceable and replaceable in the longitudinal direction in the insulating sleeve (11) Metal piston (15) is in communication and that the annular electrode (13) in Guide grooves of the insulating sleeve (11) is supported, the bases of which in the direction are inclined towards each other on the opening of the sleeve (11). 4. Fuse according to claim 2, characterized in that the insulating sleeve (11) is partially surrounded by a spherical further insulating part (12) in a liquid-tight manner and that the cavity of this insulating part (12) is filled with oil. 5. Fuse according to Claims 2 and 4, characterized in that the spring (14) comprising the insulating material sleeve (11) is horseshoe-shaped and engages with its ends (24) in longitudinal grooves (23) arranged at the free end of the insulating material sleeve (11) , the free ends resting against the metal thread of the fuse element when the fuse is screwed in, and guide grooves (19) for the legs of the horseshoe-shaped spring (14) are provided in the spherical insulating material part. 6. Fuse according to claims 4 and 5, characterized in that in the spherical insulating material part (12) in the region of the guide grooves (19) outwardly narrowing openings are provided, into which correspondingly conical pressure pieces (22) are inserted, the outside over the insulating material (12) protrude and rest against the inside of the horseshoe-shaped spring (14). 7. Fuse according to claims 2 and 4, characterized in that the funnel-shaped cavity of the plug-like insulating material sleeve (11) is provided on its wall with longitudinal keyways (27) which are provided with a phosphorescent coating, and that in the spherical insulating material part (12 ) viewing windows directed towards the keyways (27) are provided. B. Fuse according to claim 7, characterized in that the see-through windows are provided with optical devices. Publications considered: German Auslegeschrift No. 1011971.