DE19735552A1 - Fuse element for automobile current circuit - Google Patents

Abstract

The fuse element (2,3,12) has a fuse insert which is destroyed when the current exceeds a given value for disconnection of the current circuit, provided with an exothermic reaction element (12), of aluminium and iron or aluminium and nickel, connected to a semiconductor switch (7), controlled in dependence on the detected current in the current circuit, provided by a current sensor (9).

Description

The invention relates to a fuse element for electrical systems, in particular for Vehicles.

Especially in motor vehicles are used to protect electrical lines Fuses are used. Fusing with fuses has the disadvantage that optimal fuses cannot be achieved with these fuses.

If short-term overcurrents occur, a conventional electrical line in the Vehicle carry much more electricity than the fuse, so that for short-term Overcurrents a conventional fuse is undersized. Lasts longer in the area On the other hand, excess currents switch off the fuse too late, so that in this case a electrical line and / or consumer is not adequately protected. With an over current of 35% compared to the nominal tripping current of the fuse can reach up to one take half an hour until a fuse actually triggers. In the event of an overcurrent of 250%, which corresponds to 3.5 times the nominal tripping current of the fuse, it can it takes another 5 seconds until the fuse is triggered.

Another problem arises from the fact that with fuse values with high nominal Tripping current values the actual tripping current must be significantly higher to the Si trigger quickly enough. For a fuse with a nominal Tripping current of 250 A or more, this means that with an overcurrent of 250% after a current of at least 875 A must flow to make the fuse fast enough trigger. In the event of a short circuit of several lines, especially in a vehicle an accident, it can not be guaranteed that the battery will be sufficient at all can provide large current to trigger such a fuse.  

DE-A1-195 27 997 discloses an arrangement with which the triggering of a Fusible fuse is easier to specify. The electrical current is passed through the safety tion and a thyristor connected in parallel to the line to be protected of an overcurrent can be switched on in a defined manner. As soon as a threshold value is exceeded the thyristor switches on and generates an additional, high overcurrent in the Fuse that should trigger the fuse. The disadvantage of this arrangement be is that for large fuse values with high nominal tripping currents, large Thy ristors with nominal currents of a few hundred amperes, or several thyristors in parallel must be used. There is no guarantee that the necessary nominal currents for the triggering of appropriate thyristors from a battery in a vehicle can be applied.

The invention has for its object to provide a fuse that a defined tripping current and which is also suitable for high tripping nominal currents.

The object is solved by the features of the independent claims. Further and advantageous refinements can be found in the subclaims and the description to take.

The invention consists in that the securing element has a fuse element which is at least partially formed by a reaction element in which an ignition signal to a exothermic reaction at which the melting temperature of the reaction element and / or of the fuse element is exceeded at least locally.

The reaction element preferably has aluminum and / or nickel and / or iron.

The reaction element preferably consists of a welding foil, which consists of a layer follow a plurality of alternately arranged, very thin metal foils. Of the The advantage here is that a reaction of the metal foils to one another by an ignition signal can be triggered, the welding foil melts and the circuit remains very quickly interrupts.  

A preferred embodiment is that the reaction element at least in some areas is formed by a fine-grained powder.

The heating element can preferably be switched on in a controlled manner by an ignition signal being dependent can be triggered by undesirable operating conditions in the vehicle electrical system and / or a vehicle.

A particularly advantageous embodiment consists in securing the securing element with a Connect control unit for controlling the ignition pulses. This allows using same characteristics and different characteristics simulate nominal tripping currents, so that the tripping curve of the fuse element is dynamically changeable.

In the following the features, insofar as they are essential for the invention, are detailed explained and described with reference to a schematic diagram of a circuit.

Usual fuses according to the prior art consist of a defined shaped electrical conductor with a defined resistance. Through the flow of electricity the conductor heats, preferably in a specially prepared area, in the following melting called conductor, and, depending on the type of fuse, is between 420 ° C and over 1000 ° C a melting point. The melting of the fuse leads to an interruption of the Circuit. Often a tin pill is applied to the fuse element, which upper half of 230 ° C melts and a reaction with the fuse element material occurs, the lowers the melting point of the fusible conductor.

By means of a thyristor connected in parallel to the consumer in accordance with that from DE-A1 195 27 997 known prior art, the fuse element with an additional, high Current loaded, which through additional ohmic losses the fuse element to through melt brings without the line being burdened with the additional overcurrent occurring becomes.  

A fuse element according to the invention has a fuse element which is at least par consists of a material that performs a self-sustaining exothermic reaction, as soon as this is triggered by an ignition pulse.

It is very particularly advantageous if means are provided which defi the ignition pulse made times and / or in defined states. More appropriate only triggered when an error is pending. As switch-on criteria can under different states, in particular error signals, are used, preferably overcurrent signals for overcurrent monitoring of a consumer and / or temperature signals for overtemp temperature monitoring of a consumer and / or voltage signals and / or crash signals, in particular to electrical consumers in the event of a vehicle accident from the vehicle electrical system to separate. The controlled switching on of the ignition signal ensures that in the Normal operation the fuse is not triggered accidentally, in the event of a fault can be triggered very quickly and reliably.

An advantage of the solution according to the invention is that the requirements for original securing element can be reduced in terms of design tolerances can.

Another advantage is the ohmic resistance of the fuse elements can be lowered, since the fuse element no longer even the ohmic Must generate power loss for triggering the fuse element. This will make the chip Loss of voltage from the battery to the consumer is advantageously reduced.

A great advantage of the invention is the possibility of using the same securing element simulate different characteristics and / or different nominal trip currents the. The triggering time of the securing element can advantageously be determined by a suitable one intelligent control unit can be changed dynamically. This has the favorable consequence that the same securing element for different loads on an electrical conductor ver can be used, especially with different vehicles or vehicle variants This makes it possible to use different vehicles with a relatively uniform electrical system  protective equipment, which simplifies the production and cost advantage brings.

Advantageously, several such security elements according to the invention can be are preferably controlled via multiple switches.

A preferred exothermic reaction element consists in particular of a welding foil, which triggers a strongly exothermic reaction through the action of an ignition pulse and in very reached very high temperatures in a short time. The welding foil preferably consists of a series of very thin metal foils, especially aluminum and nickel foils and / or iron foils that are alternately stacked on top of one another. A typical layer thickness the individual foils range from a few atomic layers to 100 atomic layers. By triggered a suitable ignition pulse, the metal foil constituents react with each other and typically heat up from 25 ° C to over 1000 ° C in a few milliseconds.

Other combinations of materials that undergo such an exothermic reaction are also suitable as reaction elements in foil or powder form. The reaction can ment surround the fusible conductor, in particular a powdered reaction material surround the fuse element in a capsule or adjacent to the fuse element in one Capsule can be arranged. The grain size of the powder is preferably in the submicron Area.

A preferred method of ignition is the reaction element with a transistor or with egg to apply a surge from a capacitor. Another preferred Zünd is the method, the reaction element by means of optical excitation, in particular with ultravio letter radiation, and / or thermal external heating. It’s enough to heat the reaction element locally in order to start the reaction there. A Another suitable ignition method is to fire the reaction element a battery or an arc.

The advantage here is that this design of a reaction element does not have its own current supply required for ignition, but only a suitable ignition pulse. It is advantageous  that the ignition impulse can be generated and / or controlled by a suitable control, so that a reliable and fast triggering is possible in the event of a fault.

In Fig. 1, an arrangement according to the invention is shown. A battery 1 in an on-board network supplies a consumer 10 . Between battery 1 and consumer 10 , a hedging element is arranged, which has a consumer-side connection 3 , a battery side connection 2 and an intermediate fuse element 12 . Here, the fuse element is formed entirely from the reaction element. However, it is possible to form the fuse element only partially through the reaction element. The fuse element 12 is connected to a component 7 , in particular to the drain connection of a MOSFET which is connected to ground on the source side. The component 7 is connected to the reaction element 12 via a contact point 13 designed as a control connection.

The component 7 , which is controlled as a function of a fault, can, depending on the ignition method used, also comprise a capacitor, a heating source, a battery, a high-voltage element or a light source, which provide or switch the triggering energy in the event of a fault.

With the help of a current sensor 9 and an evaluation and tripping unit 8 , the current in a line 11 can be determined, which leads from the fuse element 2 , 3 , 12 to the consumer 10 . A triggering curve of the securing element is stored in the evaluation unit 8 . In the simplest case, this can be a threshold value and / or a current / time behavior of the fuse element.

If the current value in line 11 exceeds this tripping curve or correspondingly defined limit values, unit 8 switches component 7 on , so that a start or ignition pulse is generated and the reaction element, which acts as a fuse element, ignites. This heats up very quickly due to the exothermic heating of its material and melts, as a result of which the circuit is interrupted safely and in a short time.

In the present exemplary embodiment, in the event of a fault, the MOSFET used as a switch is controlled by the tripping unit 8 in the conductive state, so that in addition fault current also a short-circuit current flows through the fuse element 2 , 3 , 12 to ground and the additional heating of the fusible conductor 12 triggered thereby is its exothermic Initiates self-destruction.

In addition, the evaluation unit 8 can also be controlled by an impact sensor which, in the event of an accident in the vehicle equipped therewith, the z. B. as main fuse set fuse element 2 , 3 , 12 or other fuse elements triggers.

Claims (19)

1. Fuse element for a circuit, in particular in vehicles, with a fuse which interrupts permanently at a current load of the circuit which is above the nominal current, characterized in that the fuse element ( 2 , 3 , 12 ) has an exothermic reaction element in a region provided for melting ( 12 ). 2. Securing element according to claim 1, characterized, that the reaction element has aluminum and iron. 3. Securing element according to claim 1 or 2, characterized in that the reaction element ( 12 ) has aluminum and nickel. 4. Securing element according to claim 1, 2 or 3, characterized in that the reaction element ( 12 ) is a powder. 5. Securing element according to claim 1, 2 or 3, characterized in that the reaction element ( 12 ) is a welding foil. 6. Fuse element according to one or more of the preceding claims, characterized in that the fuse element ( 2 , 3 , 12 ) in the region of its exothermic reaction element ( 12 ) has an additional control connection ( 13 ). 7. A method of operating a fuse element, in which a current through the fuse element is measured, the fuse element being triggered at a current load above the rated current and the circuit permanently interrupting, in particular according to claim 1 or one of the following, characterized that when an error signal occurs in the circuit, at least the fuse element ( 12 ) of the fuse element ( 2 , 3 , 12 ) is subjected to an ignition pulse. 8. The method according to claim 7, characterized, that a current threshold is used as an error signal. 9. The method according to claim 8, characterized in that the current threshold value is determined from a trigger curve of the fuse element, which is stored in an evaluation unit ( 8 ). 10. The method according to claim 7, 8 or 9, characterized, that a temperature threshold is used as an error signal. 11. The method according to one or more of the preceding claims, characterized, that a voltage threshold is used as an error signal. 12. The method according to one or more of the preceding claims, characterized, that an impact signal is used as an error signal. 13. The method according to one or more of the preceding claims, characterized in that the ignition pulse is generated by external heating of the reaction element ( 12 ). 14. The method according to one or more of the preceding claims, characterized in that the ignition pulse is generated by the action of a current surge on the reaction element ( 12 ). 15. The method according to one or more of the preceding claims, characterized in that the ignition pulse is generated by the action of a light pulse on the reaction element ( 12 ). 16. The method according to one or more of the preceding claims, characterized in that the ignition pulse is generated by the action of an ignition spark of a battery on the reaction element ( 12 ). 17. The method according to one or more of the preceding claims, characterized in that the ignition pulse is generated by the action of an arc on the reaction element ( 12 ). 18. The method according to one or more of the preceding claims, characterized in that the ignition pulse is generated by the action of an ignition spark of a capacitor on the reaction element ( 12 ). 19. Circuit arrangement for performing the method according to claim 7 or one of the following, characterized in that the fuse element ( 2 , 3 , 12 ) is connected in series in a line ( 11 ) between a current source ( 1 ) and a consumer ( 10 ) and has an additional control connection ( 13 ) which is connected to a controllable component ( 7 ) via which additional energy can be connected to the fuse element ( 2 , 3 , 12 ).