DE102005006100A1 - Protection circuit e.g. overvoltage protection circuit, for protecting electronic circuit arrangement in motor vehicle, has fuse unit and circuit formed such that separation of arrangement from power supply unit is accomplished - Google Patents

Abstract

The circuit has a fuse unit (TS) and a circuit (WS) that are formed such that a voltage pulse is generated in case of voltage reversal and overvoltage based on temporal current change arising at a connection of circuit and transmission ratio of transformers. The unit and the circuit are further formed such that a separation of electronic circuit arrangement from a power supply unit is accomplished based on the voltage pulse. An independent claim is also included for a method of protecting an electronic circuit arrangement before breakdown during voltage reversal of a connected power supply unit or during overvoltage.

Description

The The invention relates to a fuse circuit and a method to protect an electronic circuit from damage Reverse polarity of a connected power supply unit or in Trap of overvoltage.

It is known that all arranged in a motor vehicle electrical circuitry, such as electrical control devices and other electrical components must be equipped with a reverse polarity protection. Such polarity reversal protection is required so that the control devices and components suffer no damage in the event of a polarity reversal start or reverse polarity reversal of the motor vehicle battery. Without such Verpolschutzmaßnahmen a reverse polarity would cause the components, in particular the semiconductor devices would be damaged or destroyed in the electrical circuitry. In order to prevent such destruction of the components or the electrical circuitry, various reverse polarity protection measures are known. In this regard, it is known that as polarity reversal protection usually a diode or an additional transistor can be used. A polarity reversal protection circuit is from the German patent application DE 100 59 800 A1 known. This polarity reversal protection circuit has a diode which is connected between terminals of a battery such that it short-circuits the terminals in the event of an incorrect polarity. If a polarity reversal occurs, the terminals of the battery are short-circuited and a large current flows through the diode, causing it to heat up due to its electrical resistance. Part of this heat is transferred via the thermal coupling to a fuse and depending on the corresponding amount of heat and / or the resulting temperature of the fuse interrupts this electrical connection between the battery and the connected electronic circuitry. A major disadvantage of this polarity reversal protection circuit is that the diode must be thermally stable than the fuse must be formed. This can not be reliably represented because semiconductors are destroyed at temperatures of approx. 200 degrees Celsius and melting fuses only significantly above a temperature of 200 degrees Celsius.

Therefore It is an object of the invention, a fuse circuit and a method to provide, in which or at which not only in case of reverse polarity but also in case of overvoltage not inadmissible Voltage is passed to the electronic circuitry. Furthermore, it is the object of the invention to provide a security circuit and to provide a method in which no power loss through a reverse polarity protection measure arises and which or which can be realized inexpensively. The aim is thus an improved protection of electronic circuitry to achieve both in a reverse polarity and in an overvoltage.

These Task is performed by a fuse circuit, which features according to claim 1, and a method which the features according to claim 11, solved.

A fuse circuit according to the invention is designed to protect an electronic circuit from damage when reverse polarity of a connected power supply unit. Furthermore, the fuse circuit according to the invention is designed such that it also ensures protection of the electronic circuit arrangement from damage in the event of overvoltage. An essential idea of the invention is that the fuse circuit has means which are designed in such a way that, in the polarity reversal and / or overvoltage case, a voltage pulse is generated in the safety circuit at least as a function of a temporal current change occurring at a first terminal of the fuse circuit. The fuse circuit and the corresponding means are further designed such that, depending on the generated voltage pulse, a disconnection of the electronic circuit arrangement is performed by the power supply unit. With the fuse circuit according to the invention can be achieved that both in the case of reverse polarity and in the event of overvoltage significantly improved protection of the electronic circuitry from damage or destruction can be achieved. With the fuse circuit according to the invention can be ensured that in the case of reverse polarity and / or in the event of overvoltage no impermissible voltage to e-electronic circuit arrangement is passed, which causes no damage or destruction of the electronic circuitry. The fuse circuit according to the invention and the means arranged therein make it possible to generate a corresponding voltage pulse already at a minimal change in the time of current in order to be able to carry out a disconnection of the electronic circuit arrangement from the power supply unit relatively quickly. In addition to this advantage that, in the case of polarity reversal or in the event of overvoltage, a very rapid disconnection of the electronic circuit arrangement from the power supply unit can be carried out, further advantages include the fact that the inventive fuse normally no power dissipation generated and relatively inexpensive can be realized. Furthermore, no reverse polarity and / or overvoltage protection measures in individual control units are required. Another significant advantage of the security circuit according to the invention is the fact that is not intervened in the regular circuit in the case of reverse polarity and / or overvoltage by the fuse realized by means of the fuse circuit backup concept. In addition, it can be noted that the fuel consumption can be reduced by the fuse circuit according to the invention.

In Particularly advantageously, the security circuit has at least three connections on. The at least three connections are formed such that a first terminal is formed as a ground terminal is. About that In addition, the fuse circuit has at least one input terminal and at least one output terminal. The fuse circuit according to the invention can be designed in a flexible manner and to the required conditions be adjusted. Compared to known simple fuses, which two connections and are not expandable or flexible, can by the fuse according to the invention only by the addition not only a significantly improved at least one other pins Reverse polarity protection and / or overvoltage protection measure reached but also their manifold Use and applicability can be achieved. In particularly preferred Case, the fuse circuit is designed as a fuse, which is formed with at least three pins or three terminals. A Such fuse has over one of the prior art known fuse the additional functions of a "polarity reversal" and a "surge protection".

A Another advantageous embodiment is characterized in that the means have a thermal fuse and another circuit. The another circuit comprises a transformer and a fuse element, wherein the voltage pulse generated by the transformer adjacent the dependence the temporal change of current additionally dependent on from the gear ratio between primary and secondary winding of the transformer can be generated. This can be achieved that already a minimal temporal current change by the transmission ratio of the transformer leads to a voltage pulse, which is so big a disconnection of the electronic circuitry from the Polarity or overvoltage source he follows.

It can be provided that the further circuit is a pyrotechnic Has element and / or a thermal element. The further circuit is about that Pyrotechnic element and / or the thermal element with the thermal fuse coupled to the security circuit.

It can also be provided that the pyrotechnic element and / or the thermal element with the secondary winding of the transformer are electrically connected. The pyrotechnic element and / or the Thermal elements are designed such that they by the voltage pulse can be activated and in the activated state on the thermal fuse act, that the thermal fuse the electrical connection between the electronic circuit arrangement and the power supply unit separates. The thermal fuse can be used as a fuse element be formed, which by the pyrotechnic element and / or destroys the thermal element and thus the connection between electronic circuitry and power supply unit interrupts. In this regard can For example, the voltage pulse cause the pyrotechnic Element detonated and thereby the thermal fuse, such as a fuse, is blown up. It can also be provided that the voltage pulse via a fuze a thermal element which is used, for example, as thermite (composition made of aluminum and ferric oxide ignited, with the development of heat of the inflamed Thermits for interrupting the thermal fuse, such as the Fuse, leads. In this case, the detonator or the thermite be interpreted so that no effect on the environment of the fuse (for example, no splinter parts, not too big Heat development, etc.).

In an advantageous embodiment of the fuse circuit, the fuse element of the further circuit is electrically connected to the first terminal of the fuse circuit and the primary winding of the transformer. It can be provided that this fuse element is designed as a diode and is electrically connected to the anode to the first terminal of the fuse circuit and the cathode to the primary winding of the transformer. It is advantageous to design the diode in such a way that it clamps the applied voltage to the diode breakdown voltage (approx. 1 V) in the case of overvoltage or in the event of overvoltage until the thermal fuse interrupts the current flow. The diode can also be designed as a zener diode (zener voltage about 18 to 20V). In this case, a reliable surge protection can be achieved in a so-called jump-start (about 28V). However, the fuse element of the further circuit can also be designed as any other suitable electronic component. In this regard, the fuse element, for example Also as Diac as UJT (Uni-junction transistor) or other active circuit, with which any characteristic of the fuse can be realized, be formed.

It can be provided that the primary winding of the transformer with a first output terminal of the further circuit and the first Output terminal of the fuse circuit is electrically connected. It can also be provided that the transformer has a primary winding, a secondary winding and another third winding, this further winding with a first end to the first terminal of the fuse circuit and a second end having a second output terminal of Fuse circuit is electrically connected.

In Particularly advantageously, it can be provided that the fuse circuit in a housing is arranged and the input terminals and output terminals and the ground terminal of the fuse circuit by at least partially differently shaped, protruding from the housing electrical Contacts are characterized. Furthermore, it can be provided that in addition or instead of the at least partially different shape the electrical contacts the input and output terminals and the ground connection in each case characterizing manner at different Positions of the housing led out are. This makes possible, that the fuse box with a fuse circuit according to the invention arranged therein can be made simple and compact and at least three Connection contacts in diverse Way can be formed. this makes possible Furthermore, the housing and form the appropriate contacts security and use dependent to be able to. As a result, with regard to a wide variety of uses of the fuse circuit according to the invention and the corresponding design of the housing and the contacts an optimal Protection for misuse or wrong Installation of the fuse guaranteed become. In particular, a fuse can be realized, soft has a compact extent and is formed with at least three terminal contacts.

The Fuse circuit can be used as reverse polarity protection and / or overvoltage protection circuit for energy sources, in particular motor vehicle batteries, be formed. In a such embodiment can the fuse circuit having a first input terminal with the Power supply unit and with a first output terminal electrically connected to the electronic circuit arrangement be.

One inventive method is to protect an electronic circuit from damage Reverse polarity of a connected power supply unit and / or for an overvoltage designed. When a polarity reversal and / or overvoltage event occurs becomes at least dependent from one occurring at a first terminal of a fuse circuit temporal change of current generates a voltage pulse in the fuse circuit. The production The voltage pulse takes place in such a way that depends on the voltage pulse disconnecting the electronic circuitry is performed by the power supply unit. This ensures that in the case of reverse polarity or overvoltage a relatively fast and safely disconnecting the electronic circuitry from the power supply unit is enabled. Furthermore, can already at a minimum current change a corresponding Voltage pulse for disconnecting the electronic circuitry be generated by the power supply unit. This will be in the Polarity reversal and / or overvoltage case not inadmissible Voltage passed to an electronic circuitry, which however for the electronic circuitry is harmless.

In Advantageously, in the polarity reversal and / or overvoltage case in the Fuse circuit arranged fuse element electrically conductive and dependent from the temporal change of current and a gear ratio between a primary and a secondary winding a transformer of the fuse circuit a voltage pulse generated. Advantageously, with the through the transformer generated voltage pulse a pyrotechnic element and / or a thermal element activated and a thermal fuse through the activated pyrotechnic element and / or the thermal element influenced such that the electronic circuitry of the power supply unit is disconnected.

advantageous Embodiment of the fuse circuit according to the invention can in their associated functions as advantageous embodiments for the considered method of the invention become.

following be several embodiments of the invention explained in more detail with reference to schematic drawings. Show it:

1 a circuit arrangement in which a fuse circuit according to the invention is connected;

2 a first embodiment of a fuse circuit according to the invention;

3 A second embodiment of a fuse circuit according to the invention;

4 A third embodiment of a fuse circuit according to the invention; and

5a to f several embodiments of fuse boxes with a fuse design according to the invention.

In all embodiments become the same or functionally identical elements with the same reference numerals Mistake.

In 1 a circuit is shown, in which a fuse circuit SSC according to the invention is connected. In 1 a generator G is shown, wel cher with a first terminal to ground potential and a second terminal to a first input E1 of the fuse circuit SSC is electrically connected. Furthermore, a power supply unit EQ, which in the exemplary embodiment is a battery in a motor vehicle, is guided with its negative pole to ground potential and electrically connected to the positive pole with the first input E1 of the fuse circuit SSC. In the embodiment according to 1 The inventive fuse circuit SSC has three connections. In addition to the first input E1, the fuse circuit SSC has a connection M, which is connected to ground potential. Furthermore, the security circuit SSC has a first output terminal A1. This first output terminal A1 is electrically connected to an electronic circuit arrangement, for example an electrical control unit ES. Another connection of the electrical control unit ES is connected to ground potential. By way of example, a plurality of components, in particular semiconductor components, are shown in the electronic circuit arrangement or in the electrical control unit ES. The electrical control unit ES is electrically connected via outputs to a motor M. Furthermore, in 1 2 shows that a charge source LQ is electrically connected in reverse polarity to the poles of the energy supply unit or battery EQ. In the case of such a reverse polarity connection of the charge source LQ to the battery EQ, a pulse or a current flow is caused via the common ground connection. The current I also passes through the ground terminal M to the fuse circuit SSC. The pulse caused by the polarity reversal and the associated change in the current within a time interval is detected or detected by the safety circuit SSC. The fuse circuit SSC changes from the locked to a conductive state and generates a voltage pulse depending on the current change dl / dt. The voltage pulse is such that the electrical connection between the battery EQ and the electrical control unit ES, which leads via the fuse circuit SSC, is disconnected. In this case, a minimal change of the current is sufficient in order to be able to generate a corresponding voltage pulse for a disconnection of this electrical connection in the safety circuit SSC. This makes it possible to achieve effective protection for the electrical control device ES at a reverse polarity and / or an overvoltage even with minimal currents or infinitesimally small current changes. To the control unit ES itself passes through the ground terminal in the case of a reverse polarity, only the clamping voltage of the diode D1, which can be handled by the rule electrical control unit ES, without causing damage or destruction of the electrical control unit ES. Detailed embodiments of the fuse circuit SSC are explained in more detail in the following figures.

A first embodiment of the inventive security circuit SSC is in 2 shown. The fuse circuit SSC has a thermal fuse TS, which is designed in the embodiment as a fuse element. The fuse element TS is electrically connected to the first input terminal E1 and the first output terminal A1 of the fuse circuit SSC. In addition, the security circuit SSC has a further circuit WS. This further circuit WS comprises a transformer, which is designed in the embodiment as a ring transformer. This ring transformer has a primary winding PW, a secondary winding SW and a ring core RK. Furthermore, the further circuit WS a fuse element, which in the embodiment according to 2 is designed as a zener diode D1. The anode of the zener diode D1 is electrically connected to the ground terminal of the fuse circuit SSC. Furthermore, the cathode of the zener diode D1 is electrically connected to a first end of the primary winding PW. The second end of this primary winding PW is electrically connected to a first output of the further circuit WS and to the first output A1 of the fuse circuit SSC. In addition, the further circuit WS has a pyrotechnic element PE, which is electrically connected with a first terminal to the first end of the secondary winding SW and with a second terminal to the second end of the secondary winding SW. The further circuit WS is thermally coupled via the pyrotechnic element PE with the thermal fuse TS.

The operation of the according to 2 shown embodiment of the fuse circuit SSC explained in more detail. In case of a Verpo ment and / or an overvoltage occurs a temporal change of the current at the ground terminal M and is detected by the fuse circuit SSC, in particular by the zener diode D1. The zener diode D1 changes from the blocking to the conducting state, whereby the current flows through the primary winding PW of the transformer. Due to the induction process in the transformer, a voltage pulse is generated by the transformer depending on the gear ratio (number of turns of the primary winding to the number of turns of the secondary winding) and the current change dl / dt. Like from the 2 can be seen, the number of turns of the secondary winding SW is greater than the number of turns of the primary winding PW. It can thus be achieved that a relatively large current or a minimal change in the current generates a relatively large voltage pulse. The voltage pulse is such that the pyrotechnic element PE is ignited. Due to the ignition process of the pyrotechnic element PE, the fuse or thermal fuse TS is blown open and the electrical connection between the battery EQ ( 1 ) and the electrical control unit ES ( 1 ), which leads via the terminals E1 and A1 of the fuse circuit SSC, interrupted or disconnected.

A further embodiment of a security circuit according to the invention is shown in FIG 3 shown. In contrast to the embodiment according to 2 is in the embodiment in 3 the pyrotechnic element PE replaced by an ignition element Z. Furthermore, between the ignition element Z and the thermal fuse TS is a thermal element, which is formed in the embodiment as Thermit TE arranged. In the embodiment according to 3 the voltage pulse generated by the transformer is transmitted to the ignition element Z, which ignites the Thermit TE. The thermite TE is heated by the ignition and leads to the interruption of the fuse element or the thermal fuse TS. Thus, here too, the electrical connection between the battery EQ and the electrical control unit ES ( 2 ) in the event of reverse polarity or overvoltage relatively quickly and safely separated.

A further exemplary embodiment of the security circuit SSC according to the invention is shown in FIG 4 shown. The thermal coupling of the further circuit WS for thermal fuse TS is also carried out in this embodiment via an ignition element Z and a thermal element or a thermite TE. According to the first embodiment according to 2 can also in the in 4 shown embodiment, the thermal coupling of the other circuit WS with the thermal fuse TS only via a pyrotechnic element PE ( 1 ) respectively. In the embodiment according to 4 For example, the transformer has, in addition to the primary winding PW and the secondary winding SW, another third winding WW, which is electrically connected to a second end to a second output of the further circuit WS and to a second input A2 of the fuse switch SSC. The first end of the further winding WW is electrically connected to the ground terminal M of the fuse circuit SSC and to the anode of the zener diode D1. It can also be provided that the fuse circuit SSC has a third input terminal A3 to which the second end of the further winding WW is additionally electrically connected. This third input terminal A3 of the fuse circuit SSC can be used as an additional terminal for a possible remote ignition. In this regard, it can be used as a connection for a possible remote ignition, for example, a line protection by means of monitored shielding or with regard to a crash shutdown or to avoid vehicle fires z. B. by phototransistor or NTC or even be used to switch off detected parallel arcing.

It It should be noted that in the fuse circuit SSC as a fuse element Zener diode D1 also wired as a simple diode or as a another suitable electronic component, such as a diac or a UJT or else be designed as an active circuit can, so that any characteristic of the fuse circuit SSC can be realized.

In the case of the fuse concept according to the invention, a corresponding polarity reversal and / or overvoltage case can thus be detected at even the smallest current changes, in which the fuse element of the fuse circuit SSC, which is embodied as Zener diode D1 in the exemplary embodiments, clamps the applied voltage to a low value, in particular clamps the diode breakdown voltage, whereby the connected consumer, in particular the electronic circuit arrangement or the electrical control unit ES ( 1 ) is no longer damaged or destroyed.

With regard to an optimal realization of a housing with the corresponding contact feet, in which the fuse circuit SSC according to the invention is arranged, are in the 5a to 5f several embodiments shown. The fuse circuit SSC according to the invention can be arranged, for example, in a housing of a conventional fuse arrangement. It is essential that from the housing G at least three pins are led out. According to the execution in 5a is a Housing G shown, on which on one side three equal connection contacts are formed. The three terminal contacts are arranged substantially equidistant from each other. Diesbezüg Lich thus a maxifuse or littlefuse fuse can be formed with a third connecting blade between the two main terminals. The execution according to 5a is little effort in the realization and also low-cost with regard to use in a motor vehicle.

Likewise, the embodiment according to 5b realized in a relatively simple manner and used in a relatively low-effort manner in the vehicle. In this embodiment in 5b the third middle connection contact is narrower than the two other connection contacts and arranged with respect to the positioning closer to one of the two main connections. Due to the asymmetrical design can be achieved that a false or twisted installation of the fuse can be prevented in the motor vehicle.

In a similar manner, such a wrong installation in the motor vehicle by the embodiment of the fuse according to 5c be prevented. In this exemplary embodiment, a terminal contact located at the edge is narrower than the other two terminal contacts. Another advantage of this embodiment according to 5c is due to the fact that a plugging a conventional fuse without overvoltage and reverse polarity protection in the corresponding slot of the fuse is not possible. The use of a false fuse or a fuse without the inventive fuse concept with regard to protection against overvoltage and reverse polarity protection can be prevented.

Housing G and Anschlusskontaktrealisierungen for a fuse circuit according to the invention SSC, as in the embodiment in 4 are represented by the housing and Anschlusskontaktbeispiele in the 5d and 5e shown. With regard to the embodiment of the security circuit SSC with an input E1 ( 4 ), a ground terminal M and two or three output terminals A1 to A3 have these embodiments of the housing forms G with the corresponding terminal contacts according to 5d and 5e five or four led out of the housing G connection knife. These embodiments thus have additional connections for a remote ignition and can not be installed twisted in a corresponding slot of the fuse in the motor vehicle in view of the asymmetrical formation of the positioning of the terminal contacts.

As in the embodiment according to 5e is shown, five connection contacts or 5 connection blades are led out of the housing G. Three terminal contacts are led out with substantially the same strip width of the contacts with respect to the viewing plane on the left side of the housing base G. These three first connection contacts are arranged substantially equidistantly to each other. In addition, two further terminal contacts are led out with respect to the viewing plane on the right side of the housing base G. The width of these two connection contacts is greater than the width of the first three connection contacts. The distance between the two wider connection contacts arranged on the right-hand side is substantially the same as the distance between the middle-wide connection contact and the immediately adjacent first narrower connection contact. The distances and the arrangement of the five terminal contacts can also be varied in many ways.

In the embodiment according to 5e a housing G is shown, are led out of the only four terminals or connection knife. In this regard, two first connection blades are led out with respect to the viewing plane on the left side of the housing base G and two further connection contacts led out on the right side of the housing G, wherein the width of the arranged on the right side terminals is greater than the width of the on the left Side led out connection knife. As in the embodiment according to 5d are in the embodiment in 5e shown narrower terminal contacts formed substantially with a same strip width. In a corresponding manner, the wider terminal contacts are formed substantially with a same strip width.

A further embodiment of a housing G with corresponding connection contacts with regard to a realization as a strip fuse is in the embodiment according to 5f shown. It should be noted that in the 5a to 5f shown embodiments of fuse housings and correspondingly formed terminal contacts is not exhaustive. Also for a variety of other types of fuses integration of the fuse protection concept according to the invention or the inventions to the invention fuse circuit for overvoltage and reverse polarity protection is possible.

Claims (13)

Fuse circuit to protect an electronic circuit (ES) from Be damage or destruction in reverse polarity of a connected power supply unit (EQ) and / or overvoltage, wherein the fuse circuit (SSC) means (TS, WS) has such that in the polarity reversal and / or overvoltage case at least depending on a at a first terminal (M ) of the fuse circuit (SSC) occurring temporal current change, a voltage pulse in the fuse circuit (SSC) is generated such that, depending on the voltage pulse, a separation of the electronic circuitry (ES) from the power supply unit (EQ) is performed. Fuse circuit according to claim 1, characterized through at least three ports (M, E1, A1 to A3), wherein the first terminal (M) as a ground terminal is formed and at least one input terminal (E1, A2, A3) and at least one output terminal (A1) are formed. A fuse circuit according to claim 1 or 2, characterized characterized in that the means (TS, WS) comprise a thermal fuse (TS) and a further circuit (WS), wherein the further circuit (WS) a transformer (PW, SW, WW, RK) and a fuse element (D1) and the voltage pulse generated by the transformer (BW, SW, WW, RK) additionally dependent from the gear ratio between Primary winding (PW) and secondary winding (SW) of the transformer (PW, SW, WW, RK). Fuse circuit according to claim 3, characterized the further circuit (WS) is a pyrotechnic element (PE, Z) and / or a thermal element (TE) and via the pyrotechnic Element (PE, Z) and / or the thermal element (TE) with the thermal fuse (TS) coupled, in particular thermally coupled. Fuse circuit according to Claim 4, characterized that the pyrotechnic element (PE, Z) and / or the thermal Element (TE) with the secondary winding (SW) of the transformer (PW, SW, WW, RK) are electrically connected and by the voltage pulse the pyrotechnic element (PE, Z) and / or the thermal element (TE) are activatable such that the thermal fuse (TS) the electrical connection between the electronic Circuit arrangement (ES) and the power supply unit (EQ) separates. Fuse circuit according to one of claims 3 to 5, characterized in that the securing element (D1) of the other Circuit (WS) with the first connection (M) of the security circuit (SSC) and the primary winding (PW) of the transformer (PW, SW, WW, RK) is electrically connected. Fuse circuit according to Claim 6, characterized that the fuse element is designed as a diode (D1) and the Diode (D1) with its anode to the first terminal (M) of the fuse circuit (SSC) and with its cathode to the primary winding (PW) of the transformer (PW, SW, WW, RK) is electrically connected. Fuse circuit according to claim 2 and 3 characterized characterized in that the primary winding (PW) of the transformer (PW, SW, WW, RK) with a first output terminal the further circuit (WS) and the first output terminal (A1) of Fuse circuit (SSC) is electrically connected. Fuse circuit according to claim 2 and 3, characterized characterized in that the transformer (PW, SW, WW, RK) in addition to his Primary winding (PW) and its secondary winding (SW) has a further winding (WW), wherein the further winding (WW) with a first end to the first terminal (M) of the fuse circuit (SSC) and with a second end with a second input port (A2) of the fuse circuit (SSC) is electrically connected. Fuse circuit according to Claim 2, characterized that the fuse circuit (SSC) is arranged in a housing (E) and the input terminals (E1, A2, A3), the output terminals (A1) and the ground terminal (M) of the fuse circuit (SSC) at least partially differently shaped, out of the housing (G) outstanding electrical contacts characterized and / or at different Positions of the housing (G) brought out are. Method for securing an electronic circuit arrangement (ES) at damage Reverse polarity of a connected energy supply unit (EQ) or at overvoltage, wherein in the polarity reversal and / or overvoltage case at least dependent from one to a first terminal (M) of a fuse circuit (SSC) occurring temporal current change a voltage pulse is generated in the fuse circuit (SSC) such that depending on the voltage pulse disconnecting the electronic circuitry (ES) is performed by the power supply unit (EQ). A method according to claim 11, characterized in that in polarity reversal and / or overvoltage case in the fuse circuit (SSC) arranged fuse element (D1) becomes electrically conductive and depending on the temporal current change and the transmission ratio between a primary (PW) and a secondary winding ( SW) of a transformer (PW, SW, WW, RK) of the fuse circuit (SSC) a voltage pulse is generated. Method according to claim 12, characterized in that that with that generated by the transformer (PW, SW, WW, RK) Voltage pulse a pyrotechnic element (PE, Z) and / or a thermal element (TE) is activated and a thermal fuse (TS) by the activated pyrotechnic element (PE, Z) and / or the thermal element (TE) is influenced such that the electronic Circuitry (ES) from the power supply unit (EQ) is disconnected.