DE20119411U1 - Electrical fuse - Google Patents

Description

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15803/mj/no

Utility model application

Wilhelm Pudenz GmbH, Klosterseelter Strasse 5

Dunes

Electrical fuse

17, 27243

The invention relates to an electrical fuse comprising at least two electrical contact elements and at least one fuse element arranged in the electrical conduction path between the contact elements.

In known electrical fuses of the type described above, an electrical current path is formed via the contact elements and via the fuse element arranged between the contact elements in the line path. If a current with too high a current intensity occurs, the material of the fuse element will heat up, for example. If the current exceeds a certain current intensity limit or if the fuse element is subjected to stress that continues for a defined time limit, the fuse element will destroy itself and thus interrupt the current path between the contact elements. . _. —· . .· ■ ■ -.-- -

Fusible conductors are often used as fuse elements. These fuses melt when the current is too high, thereby causing an interruption in the current conduction path. The material and/or cross-section of these fuses is dimensioned in such a way that they are destroyed before an electrical consumer or electrical conductor following in the current conduction path is destroyed. The fuse is provided with a characteristic curve in which a time is set for each current load within which the fuse melts.

In known fuses, this characteristic curve is far removed from the corresponding characteristic curve of the electrical conductor to be protected. While an electrical conductor with a cross-section of 6 mm ² , for example, is destroyed after a time period of more than ten seconds with a current load of 100 amps, a 40A fuse is destroyed after only about one second. The electrical cable could therefore theoretically still conduct a current of 100 amps for a short time or a current of, for example, 80 amps for a longer period without the cable being destroyed. However, if the fuse is switched off due to the fuse element being destroyed, this theoretical current-carrying capacity of the conductor is not used satisfactorily.

The invention is based on the object of demonstrating an electrical fuse of the type mentioned at the beginning, with which.

the theoretical current carrying capacity of a cable can be better utilized.

This object is achieved according to the invention in that the fuse element is designed as a fusible conductor whose length between the electrical contact elements is at least 4 cm.

The fuse according to the invention has a long fuse element which is completely formed by a fuse element. Due to its length of 4 cm or more, the fuse element is itself designed like an electrical conductor and therefore takes on the properties of an electrical conductor. The characteristic curve of this fuse element is therefore also adapted to the characteristic curve of an electrical conductor, so that premature triggering of the fuse element is advantageously prevented. The theoretical current-carrying capacity of the electrical conductor protected by the fuse according to the invention is better utilized.

The length of the fuse element can also be more than 4 cm. For example, fuse element lengths of 10 cm are possible. The length of the fuse element is preferably greater than the distance between the electrical contact elements.

According to a first development of the invention, it is provided that the fuse element is punched out of a fuse element material sheet. This punching ensures that the fuse element is formed in one piece and thus a homogeneous

material structure over its entire length. This contributes to the formation of the fusible conductor as an electrical conductor with a conductor-like characteristic curve. In addition, production by punching makes it simple. In addition, the cross-section of the fusible conductor can be easily adjusted by selecting the thickness of the fusible conductor material sheet used for punching.

Different types of the fuse according to the invention can thus be provided by using different cable cross-sections, whereby these types are not differentiated from one another by current strength information but by cable cross-section information.

In addition to punching out, the fuse element can of course also be manufactured in other ways, whereby different cross-sections of the fuse element can be realized in other ways.

According to a further development of the invention, the fusible conductor forms a loop-like winding path between the contact elements. This measure makes it possible to achieve a greater length of the fusible conductor than the size of the distance for a given distance between two contact elements. The size gain is achieved compared to a straight connection between the two contact elements because a fusible conductor wound in loops has a greater length.

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This measure serves to form the fusible element as an electrical conductor with the corresponding characteristic curve.

In order to be able to arrange such a long fuse element in a small space, a further development of the invention provides that the fuse element has a U-shaped design by bending it twice at approximately 90° each time, with the contact elements arranged at the free ends of the U-legs. By bending the fuse element, fuse element sections can be arranged as U-legs in parallel alignment next to one another in a compact space. Space can be minimized by making the length of the U-base shorter than the length of each U-leg. The fuse element is therefore relatively narrow and tall.

In the fuse element according to the invention, the requirement may be that the fusible conductor melts in certain areas of its longitudinal extension and that melting is prevented in other areas. In particular, melting of the fusible conductor in the area of the U-base is not desired, since a closed current path may be formed again by softening the U-base and subsequent flow of the fusible conductor material, for example in the direction of the U-legs.

In order to prevent the U-base of the fusible conductor from melting, a further development of the invention provides that the fusible conductor in the area of the U-base is at least

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has an enlarged cross-section. Due to this enlarged cross-section, the fusible conductor in the area of the U-base is able to absorb greater heat. This greater heat absorption capacity prevents the fusible conductor from melting in this area. The enlarged cross-section is formed, for example, by at least one projection formed on the fusible conductor, which projects, for example, laterally from the longitudinal extension of the fusible conductor in the area of the U-base. Preferably, projections are arranged on both sides of the fusible conductor in a central section of the longitudinal extension of the U-base.

In addition to the fuse element, the projections and the contact elements can also be punched out of the fuse element material sheet. This creates a one-piece construction of fuse element projections and contact elements. Alternatively, the contact elements and the fuse element can also be in a three-part arrangement.

According to a further development of the invention, the fuse has a housing in which the fusible conductor is accommodated and from which the contact elements protrude. The fusible conductor is accommodated in the housing. The fuse is therefore easier to handle and can also be grasped more securely using tools, for example. The housing is preferably made of an insulating plastic.

Due to the U-shape of the fuse element, the housing preferably has a tall, narrow design, with the width of the housing being slightly wider than the length of the U-base of the fuse element and the height of the housing being slightly longer than the length of the U-legs of the fuse element. The tall, narrow design makes it possible to completely accommodate a long fuse element in a U-shape. The contact elements at the free ends of the U-legs protrude from the housing in the area of one end face so that they can be plugged into a fuse holder, for example.

According to a further development of the invention, the housing has at least one housing inner wall, which is arranged approximately in a central plane and which divides the housing interior into two insertion areas for the U-legs of the fusible conductor. The housing inner wall divides the interior of the housing into two sub-areas. A U-leg of the fusible conductor can be inserted into each sub-area, so that the housing inner wall can accommodate both U-legs.
Legs of the fusible conductor are spatially separated and insulated from each other. This advantageously prevents melting of the U-legs from forming an electrically conductive connection with the fusible conductor material of the other U-leg.

To prevent the U-base from collapsing if one or both U-legs melt,

A further development proposes that the end section of the housing inner wall facing away from the contact elements of the fusible link inserted into the housing serves as a support area for the. U

- base of the fusible conductor. If the fusible conductor melts in the area of one or both U-legs, the support of the U-base on the inner wall of the housing remains intact. The U

- Base cannot fall down, so that if the fuse element breaks in the area of one or both U

Leg of the conduction path between the contact elements remains permanently interrupted.

A housing section is preferably designed as a housing cover that is detachably connected to the rest of the housing so that the housing can be opened easily. This makes it possible, for example, to refit the housing with a replacement fuse element.

In order to create a firm but detachable connection between the rest of the housing and the housing cover and between the housing and the fusible conductor, it is finally provided that these components each have locking means which engage with one another in a locking holding connection. These locking means are designed, for example, as projections and undercuts which can engage with one another in a form-fitting manner.

An embodiment of the invention, from which further inventive features emerge, is shown in the drawing. They show:

Fig. 1 is an exploded side view of an inventive
electrical fuse, and

Fig. 2 is a sectional view of the fuse according to
Figure 1.

The fuse in Fig. 1 and 2 is made up of three components. It has a U-shaped fuse element 1, onto which two contact elements 2 designed as flat plugs are integrally formed. This fuse element 1 can be or is inserted into a tall, narrow housing 3 (Fig. 2). A housing cover 4 can be or is brought into a holding connection with the housing 3 (Fig. 2), whereby locking tabs 5 of the housing cover 4 can be guided in a locking manner over projections 6 of the housing 3.

The interior of the housing 3 is divided by an inner housing wall 7 into two insertion areas 8, 8' for the U-legs of the fusible conductor 1. The upper end section of the inner housing wall 7 visible in Fig. 1 serves as a support for the U-base of the fusible conductor 1.

The fusible conductor 1 has a corrugated configuration in the area of the U legs. In the area of the U base, two flag-like projections 9, 9' are integrally formed on the fusible conductor 1. These projections 9, 9' also rest on the inner housing wall 7. The inner housing wall 7 has in its areas facing the housing walls

Recesses 10 which serve for rear ventilation of the projections 9, 9'. Heat absorbed by the projections 9, 9' can thus be dissipated on both sides, so that melting of the projections 9 and thus of the U-base of the fusible conductor 1 is prevented.

The contact elements 2 are also assigned bends 11, which increase the stability of the contact elements 2. In the area of these bends 11, spring-loaded tabs 12 are also provided, which engage with locking means in the housing 3. The locking means are designed as projections 13, which are molded onto the housing inner wall 7.

Claims (18)

1. Electrical fuse, comprising at least two electrical contact elements and at least one fuse element arranged in the electrical conduction path between the contact elements, characterized in that the fuse element is designed as a fusible conductor ( 1 ) whose length between the electrical contact elements ( 2 ) is at least 4 cm. 2. Fuse according to claim 1, characterized in that the length of the fusible conductor ( 1 ) is greater than the distance between the electrical contact elements ( 2 ). 3. Fuse according to claim 1 or 2, characterized in that the fusible conductor ( 1 ) is punched out of a fusible conductor material sheet. 4. Fuse according to one of the preceding claims, characterized in that the fusible conductor ( 1 ) forms a loop-like wound conduction path between the contact elements ( 2 ). 5. Fuse according to one of the preceding claims, characterized in that the fusible conductor ( 1 ) has a U-shaped design by being bent twice by approximately 90° each time, the contact elements ( 2 ) being arranged at the free ends of the U-legs. 6. A fuse according to claim 5, characterized in that the length of the U-base is less than the length of each U-leg. 7. Fuse according to claim 5 or 6, characterized in that the fusible conductor ( 1 ) has at least one cross-sectional enlargement in the region of the U-base. 8. Fuse according to claim 7, characterized in that the cross-sectional enlargement is formed by at least one projection ( 9 , 9 ') formed on the fusible conductor ( 1 ), which projects laterally from the longitudinal extension of the fusible conductor ( 1 ) in the region of the U-base. 9. Fuse according to claim 8, characterized in that a projection ( 9 , 9 ') is formed on both sides of the fusible conductor ( 1 ) in a middle section of the longitudinal extension of the U-base. 10. Safety device according to claim 8 or 9, characterized in that each projection ( 9 , 9 ') is formed in one piece. 11. Fuse according to one of the preceding claims, characterized in that the fusible conductor ( 1 ) and the contact elements ( 2 ) are formed in one piece. 12. Fuse according to one of the preceding claims, characterized in that it has a housing ( 3 ) in which the fusible conductor ( 1 ) is accommodated and from which the contact elements ( 2 ) protrude. 13. Fuse according to one of claims 5 to 12, characterized in that the housing ( 3 ) has a high, narrow structure, the width of the housing ( 3 ) being slightly wider than the length of the U-base of the fusible conductor ( 1 ) and the height of the housing ( 3 ) being slightly longer than the length of the U-legs of the fusible conductor ( 1 ). 14. Fuse according to claim 13, characterized in that the housing ( 3 ) has at least one housing inner wall ( 7 ) which is arranged approximately in a central plane and which divides the housing interior into two insertion areas ( 8 , 8 ') for the U-legs of the fusible conductor ( 1 ). 15. Fuse according to claim 14, characterized in that the end section of the housing inner wall ( 7 ) facing away from the contact elements ( 2 ) of the fusible conductor ( 1 ) inserted into the housing ( 3 ) serves as a support area for the U-base of the fusible conductor ( 1 ). 16. Fuse according to one of claims 12 to 15, characterized in that a housing section is designed as a housing cover ( 4 ) detachably connected to the remaining housing ( 3 ). 17. A fuse according to claim 16, characterized in that the remaining housing ( 3 ) and the housing cover ( 4 ) have locking means ( 5 , 6 ) which engage with one another in a locking holding connection. 18. Fuse according to one of claims 12 to 17, characterized in that the housing ( 3 ) and the fusible conductor ( 1 ) have locking means ( 12 , 13 ) which engage with one another in locking holding connections.