DE19824851A1 - Fuse - Google Patents

Abstract

In order to ensure that the current path is interrupted along the entire length of fusible cut-out elements (4a,4b) in a reliable manner, said elements are provided with burn-up bodies that are arranged at a distance on a strip (5) that is made from an electroconductive material in capsules (8), whereby said bodies are connected by means of a continuous igniter wire (9) and ignition of one burn-up body triggers ignition of the rest. The burn-up bodies can be placed in a recess in the central support body, over which the strip (5) runs. Said burn-up bodies contain an explosive material with an ignition temperature of 245 DEG C. During burn-up, the explosive material gives off 480 J/g of energy, whereby a temperature of approximately 2,000 DEG C is reached and conversion into quenching gas, essentially nitrogen, occurs.

Description

Technical field

The invention relates to a fuse for the middle and High voltage range. Such fuses should both short, strong overcurrent surges, as z. B. as a result of Short circuits occur as well as long-lasting weak ones Interrupt overcurrents.

State of the art

US-A-4 638 283 is a generic fuse known, which distributed several over its length Burning body made of combustible material, which at certain overcurrents are ignited. The ignition takes place by means of an ignition circuit made in series, each embedded in one of the burnup bodies Resistance elements that melt through, the resulting gaps can be bridged by arcs. This formation of the ignition circuit complicates the structure of the Backup considerable and creates alongside the Securing elements another connection between the electrical connections of the same, their influence on the Function of the fuse is not clear for all cases is manageable. The ignition circuit can also safe and reasonably simultaneous response of the Do not guarantee burn-off bodies.  

Presentation of the invention

The invention has for its object a Generic security training in such a way that at Occurrence of an overcurrent the current path quickly and on simple and reliable way over a long length interrupted and thus the overcurrent quickly and safely is suppressed. This task is characterized by the features in Characteristic of claim 1 solved.

The invention creates a backup at which spread that over the length of the fuse Burning element is ignited quickly along its entire length and at least one securing element also in the essential over its entire length or over several its length melts or rips open places, so that a long arc arises in a very short time forms or a larger number of shorter arcs, which in a rapid increase in resistance has and extinguishing the arc and suppressing the Overcurrent accelerates.

The effect of the burn-off element is thereby preferred reinforced that as an erosion material an explosive a high percentage of extinguishing gas is used, preferably predominantly nitrogen is reacted. Thereby is the interruption of the current paths by mechanical Influence on the securing elements intensified and on this interruption suppresses subsequent arcs more quickly.

Brief description of the drawings

Exemplary embodiments are shown in the drawings, which only serve to explain the invention. It demonstrate  

Fig. 1a shows schematically a plan view of a fuse according to the invention according to a first embodiment, wherein the housing is cut,

FIG. 1b shows a section along BB in Fig. 1a,

Fig. 1c increases a plan view of a fuse element of the fuse of Fig. 1a, b,

Fig. 1d enlarged a section along DD in Fig. 1c,

FIG. 2a increases a plan view of a fuse element of a fuse according to the invention according to a second embodiment,

Fig. 2b enlarged a section along BB in Fig. 2a,

Fig. 3a increases a plan view of a fuse element of a fuse according to the invention according to a third embodiment,

FIG. 3b enlarged a section along BB in Fig. 3a,

FIG. 4a shows schematically a plan view of a fuse according to the invention according to a fourth embodiment, wherein the housing is cut, and

Fig. 4b shows a section along BB in Fig. 4a.

Ways of Carrying Out the Invention

The fuse according to the invention has in a cylindrical housing 1 , the z. B. can consist of ceramic, a support body 2 arranged in the axis, which can also be made of ceramic or plastic or a composite or other suitable electrically insulating material and is tubular with radially projecting ribs. At the opposite ends of the housing 1 , a first electrical connection and a second electrical connection are arranged, which are designed as caps 3 a, b made of metal. The caps 3 a, b are electrically conductively connected by two parallel securing elements 4 a, b wound helically around the support body 2 .

According to a first embodiment, the securing elements 4 a, b each ( FIG. 1 c, d) consist of a strip 5 made of a suitable fusible, electrically conductive material, preferably made of silver or a silver alloy or also of copper or aluminum. The strip 5 has constrictions 6 at regular intervals, which are formed by mutually opposite semicircular recesses.

An explosive element 7 made of explosive is arranged on the strip 5 between two successive constrictions 6 . It is arranged in a cylindrical capsule 8 , which consists of a solid, inert material, for. B. metal, such as steel or aluminum, ceramic or plastic and completely fills them. Against the strip 5 , the capsule 8 has a wall section which is relatively thin, in any case thinner than the other wall sections. Successive erosion bodies 7 are connected by sections of a thread, in particular an ignition thread 9 , which is fastened centrally over the entire length of the strip 5 and is pulled through the capsules 8 such that it is in contact with the erosion body 7 . The ignition thread 9 also consists of a combustible material, in particular a material that burns very quickly, such as. B. nitrocellulose and thus connects the erosion body 7 to a coherent erosion element 10 which extends parallel to the respective fuse element 4 a, b substantially over the entire length of the same. Since both the erosion element 7 and the ignition filament 9 are made of electrically insulating material, the erosion element does not influence the electrical properties of the fuse.

There are various modifications to the securing element possible according to the first embodiment. For example each burning body in the area of a narrowing of the strip be arranged. The capsule of the burning body can be opened be open on their side facing the strip or a Have hole that z. B. is designed like a nozzle. Finally, the narrowing itself can, at least in the case of combustion bodies arranged between the same other ways, e.g. B. by punching holes in the center Strips are made. It is crucial that one local reduction of the cross section is guaranteed.

Short, strong overcurrents cause one of the fuse elements 4 a, b to melt through at one or more of the constrictions 6 , so that short arcs occur. This leads to ignition of the ignition thread 9 , which triggers the ignition of the burn-off bodies 7 of the respective burn-off element 10 . Long-term low overcurrents lead to a heating of the fuse elements 4 a, b to the ignition temperature of the explosive and in this way to the ignition of one of the burn-off bodies 7 at a point from which the burn-off then spreads rapidly over the burn-off element 10 through the ignition thread 9 . In any case, the spread of the erosion to the entire fuse element 4 a, b usually lasts less than 100 ms.

The explosive should have a relatively low ignition temperature, preferably not higher than approx. 300 ° C., and a relatively high energy output during combustion, preferably at least 200 J / g. The strips 5 can then be dimensioned such that the resistance at nominal current is low and no high losses occur during normal operation, but the fuse still responds reliably at a certain multiple of the nominal current. Thanks to the high energy density, burning temperatures of approximately 2,000 ° C. are reached, which leads to a rapid melting of the material of the strips 5 . Because of the explosive course of the combustion, the heat-related destruction of the strips 5 is supported by the mechanical action of the explosive thereon. This effect is favored by the fact that the wall section of the capsule 8 facing the strip 5 is relatively thin, so that the explosion of the explosive is effective primarily on this side.

For use in the security device according to the invention, explosives which are harmless to the environment and whose reaction products have a high proportion of nitrogen are known, above all, from so-called airbags, which are widely used as safety devices in motor vehicles. An example is 21NaN ₃ + KNO ₃ + 4Fe ₂ O ₃ + 2.5SiO ₂ , which is converted into 10.5Na ₂ O + 0.5K ₂ 0 + 4Fe + 2.5SiO ₂ + 4FeO + 32N ₂ during the explosion. This explosive does not contain halogens and is otherwise environmentally friendly. Another example of a suitable explosive is a mixture of 71.6% SrNiO ₃ , 3.77% V6MO15O60, 3% paraffin, 21.6% guanidine-5,5'-azotetrazolate, in 8.2% CO ₂ , 31 , 1% H ₂ O, 43.7% N ₂ and 15.6% SrCO _{3 is} reacted.

The latter substance has an ignition temperature of approx. 245 ° C and releases an energy of 480 J / g when implemented. It is also converted into extinguishing gas, in particular nitrogen, with a high degree of efficiency, which favors the rapid extinguishing of the arc which forms after the interruption of the securing elements 4 a, b. The conversion of the explosive to extinguishing gas should preferably be at least 0.2 l / g, the proportion of nitrogen in the latter being at least 30 mol%. To support the arc extinguishing, the interior of the housing 1 is made of the same material, e.g. B. Filled with quartz sand.

When the burn-off element is ignited on one of the parallel securing elements 4 a, b, the increase in the current load on the remaining one within a short time also triggers the ignition of the burn-off element there. However, it is also possible to use the erosion elements of both securing elements 4 a, b. B. by a fuse or several of them.

According to a second embodiment ( Fig. 2a, b), the securing elements 4 a, b are each formed as a closed tube 11 , which is clamped at regular intervals and at the same time stretched, so that it forms constrictions 6 , which divides the tube 11 into successive sections each of which contains a portion of explosive that forms a burn-up body 7 . Only one ignition thread 9 extends over the entire length of the tube 11 and connects the burnup elements 7 to form a coherent burnup element 10 .

According to a third embodiment, the securing elements 4 a, b are designed as shown in FIGS . 3a, b. Here, the strip 5 is folded, folded over and pressed, so that it forms a tube 11 which encloses a cavity which extends over its entire length. This contains a continuous erosion element 10 of constant cross-section, which consists of explosive and preferably an ignition thread 9, which is arranged in parallel in the cavity and extends over the entire length of the strip 5 , but which can also be dispensed with. An edge strip 12 runs parallel to the tube 11 and is formed from the folded material of the strip 5 which is folded three times one above the other. The strip 5 likewise has, at regular intervals, successive constrictions 6 formed by semicircular recesses in the edge strip 12 .

According to a fourth embodiment ( FIGS. 4a, b), the ribs of the support body 2 have grooves 13 on their outer sides in the axial direction, in which the burn-off bodies 7 are arranged. The two securing elements 4 a, b are in turn each formed as strips 5 , which are provided with constrictions 6 at regular intervals, in each case at the points where they cross one of the grooves 13 . At the same points, the erosion elements 7 are also arranged in the grooves 13 , ie under the constrictions 6 . They are similar to those in the first embodiment, but they each have a nozzle-like opening on the outside facing the strip 5 , the diameter of which corresponds approximately to the width of the strip 5 in the center of the constriction 6 , against which it is directed. The combustion bodies arranged in one of the grooves 13 are each connected by an ignition thread 9 , with which they form a continuous combustion element 10 which extends essentially over the length of the fuse. In contrast to the other embodiments, where an erosion element runs closely connected to a fuse element in parallel, the fuse elements 4 a, b and the erosion elements 10 only touch in the area of the constrictions 6 and the erosion body 7 .

It is of course possible to do all of the different Grooves arranged in the burn-up body by further ignition threads or by pulling a single thread together to connect to a single burn element. The same it is possible instead of the grooves for each of the burn-off bodies a depression in the supporting body that just encloses him to provide. In this case, especially if the Strip the recess completely covering a capsule be dispensed with and the erosion body z. B. as pressed Explosive tablet can be formed.

In any case, the same explosives can be used as in the other embodiments. The triggering also proceeds accordingly. An essential advantage of the fourth embodiment, on the other hand, is that the burn-off bodies 7 are supported on the support body 2 and escape of gas or escape of the burn-off body 7 in the direction away from the strip 5 is not possible. The impact of the explosion on it is therefore particularly concentrated so that it is quickly and effectively interrupted.

Reference list

1

casing

2nd

Support body

3rd

a, bcaps

4, 4

a, bFuse elements

5

Stripes

6

Narrowing

7

Burning body

8th

capsule

9

Fuse

10th

Burning element

11

pipe

12th

Edge strips

13

Groove

Claims (14)

1. Fuse with a first electrical connection and a second electrical connection and with at least one fuse element ( 4 a, 4 b) made of electrically conductive fusible material, which connects the first electrical connection to the second electrical connection and with an ignitable burn-off element ( 10 ) Made of electrically non-conductive erosion material, which is distributed essentially over the entire length of the fuse, characterized in that the erosion element ( 10 ) is formed contiguously over its length. 2. Securing element according to claim 1, characterized characterized that when the burning material burns at least 200 J / g of heat is released. 3. Securing element according to claim 1 or 2, characterized characterized that the erosion material a Ignition temperature of at most 300 ° C. 4. Securing element according to one of claims 1 to 3, characterized in that the erosion material is at least partially an explosive. 5. Securing element according to one of claims 1 to 4, characterized in that the erosion material in particular at least 0.2 l / g in extinguishing gas is implemented. 6. Securing element according to claim 5, characterized characterized that the extinguishing gas at least 30 mol% consists of nitrogen.   7. Fuse element according to one of claims 1 to 6, characterized in that the erosion element comprises a plurality of spaced-apart erosion bodies ( 7 ) distributed over the length of the at least one fuse element ( 4 a, 4 b), which are connected by combustible thread sections. 8. Safety element according to claim 7, characterized in that each erosion body ( 7 ) is arranged in a capsule ( 8 ) made of solid inert material. 9. Securing element according to claim 8, characterized in that each capsule ( 8 ) on the securing element ( 4 a, 4 b) is arranged and the same opposite open or separated from it only by a wall section whose thickness is less than that of the rest Wall sections. 10. Fuse element according to one of claims 1 to 6, characterized in that the erosion element ( 10 ) is substantially uniform in its composition over its length. 11. Fuse element according to claim 10, characterized in that the erosion element ( 10 ) has at least approximately constant cross section over its length. 12. Fuse according to claim 10 or 11, characterized in that the securing element ( 4 a, 4 b) comprises an at least approximately over its length extending tube ( 11 ) which surrounds the erosion element ( 10 ). 13. Fuse according to one of claims 7 to 9, characterized in that it has a support body ( 2 ) made of electrically insulating material and each erosion body ( 7 ) is arranged between a fuse element ( 4 a, 4 b) and the support body ( 2 ) . 14. Fuse according to claim 13, characterized in that the erosion body ( 7 ) is each arranged in a recess in the support body ( 2 ), via which a securing element ( 4 a, 4 b) is guided.