DE10301905A1 - Security switch for electric motor vehicle, has power output controlled by switch with circuit having normal operating and monitoring conditions - Google Patents

Abstract

The security switch for an electric motor vehicle door lock has a power output (2) for supplying the electric drive and power switch (3) for controlling the output. A gauge (4) determines the operating condition of the drive and produces an electrical measurement signal. The circuit has a normal operating condition and a monitoring condition. In the latter, the output (5) remains independent of further measured load conditions of the drive.

Description

The present invention relates to a fuse circuit for an electrical consumer of a motor vehicle door lock o. Like. With the features of the preamble of claim 1 and a connection arrangement for one electrical consumers of a motor vehicle door lock or the like with Features of the preamble of claim 11. Present are below the term motor vehicle door lock all types from door, Hood or flap locks summarized.

When operating electrical consumers in Motor vehicles is fundamental make sure to bear that in In the event of a fault, the respective consumer is switched off, to protect the consumer from destruction to protect and the emergence of high temperatures and the associated Counteract the risk of fire. This is especially true for consumers with relatively high power consumption, such as the drive motors of control elements in motor vehicle door locks.

One possible error is, for example Jamming of the drive motor of the central locking device a motor vehicle door lock. By blocking the drive motor, high short-circuit currents flow through whose windings so that high Temperatures arise and the drive motor may be destroyed. Another source of error is the incorrect control of a Consumer, for example if a drive motor over a longer Period is operated above its nominal power.

A number of consumers point Today, built-in safeguards that help consumers one inadmissible high current or at an impermissible switch off high temperature. When switched off, the Current and the temperature so that after If the minimum values are not reached, switch on again of the consumer. For the design of these protective mechanisms are state of the art Technique known a number of variants. In the simplest case PTCs switched into the supply line of the consumer, so that at an elevated temperature the effective value of the PTC resistance increases and that at the consumer applied voltage drops. Thermal protection switches are also known, which are designed, for example, as a bimetal switch and at increased Temperature switch off the consumer until the temperature has dropped accordingly. The protection mechanisms mentioned can, as described, integrated into the consumer or separately be arranged by the consumer.

Those described above are particularly effective Protection mechanisms if the fault only lasts for a short period of time. This is the case, for example, if the motor vehicle door lock ices only slightly is and the drive motor of the central locking device start several times must to the motor vehicle door lock finally at third or fourth attempt to unlock. It is different if the source of the error is always present, for example, if a winding of the drive motor of the central locking device has a short circuit. In this case the drive motor with one of the above protective mechanisms at its Control can be switched on and off continuously, which is not only leads to disturbing noises, but also a load on the corresponding electrical components. In particular with thermal circuit breakers, there can be one Case that the maximum switching limit is reached and there is a sticking of contacts is coming.

In addition to the protective mechanisms described, consisting of a few components, complex fuse circuits are known today ( DE 101 10 046 A1 ), which are coupled on the one hand to a consumer and on the other hand to a bus system. This fuse circuit, from which the present invention is based, is coupled to the consumer via a circuit breaker. Furthermore, a current detection arrangement is provided, the signals of which are evaluated by an evaluation unit. The circuit breaker is controlled by the evaluation unit in such a way that the consumer is switched off in the event of a fault. For the sake of completeness, it should be mentioned here that this fuse circuit primarily serves to control consumers, and therefore also performs switching functions. However, these switching functions only play a subordinate role in the present case, so that a detailed explanation is dispensed with.

It should be noted that the known Fuse circuit is not a satisfactory solution for a permanent one In the event of an error, since here too, a permanent and switching off the consumer is to be expected. Furthermore, the known one Fuse circuit with a considerable amount of circuitry connected.

The present invention lies based on the problem of designing the known fuse circuit in this way and develop that with minimal A satisfactory effort even in the event of a permanent error Protective effect is achieved.

The problem at hand is at a fuse circuit with the features of the preamble of Claim 1 by the features of the characterizing part of claim 1 solved.

First of all, it is important to consider that the consumer that is switched off in the event of a fault remains in the switched off state until further notice. This has the advantage that, in the event of a persistent fault, the ongoing switching on and off of the consumer does not have to be accepted. Specifically, this means that with In the event of a fault, the evaluation arrangement coupled to the circuit breaker falls into a fault state and remains in the fault state regardless of the further measured load state of the consumer. This takes into account the knowledge that the repeated energization of a consumer in the event of a fault can lead to the destruction of the consumer or to the development of high temperatures. The fact that the evaluation arrangement that once fell into the fault state also remains in this fault state or is blocked in the fault state guarantees that such a further load on the consumer is avoided.

There are a variety of ways to design and develop the teaching of the invention mentioned. For this purpose, reference may be made to the subclaims become.

In the present case, the Question about how the evaluation arrangement from the above error state back to the Normal state can be brought.

In a preferred embodiment according to claim 4 is for this a reset operation intended. This reset process is preferably that the Fuse circuit is separated from the supply voltage, and when the supply voltage is reapplied, the evaluation arrangement assumes the normal state. Basically, there are numerous possibilities for the Design of the reset process, for example by actuation a button or the like

A particularly preferred embodiment of the Evaluation arrangement forms the subject of claim 6. For blocking The evaluation arrangement in the fault state is a simple latch circuit here provided from two transistors. This leads to a particularly simple one and compact circuit structure.

Furthermore, the configuration according to claim 8 particularly advantageous because it allows overloading of the consumer over to "tolerate" a preset period of time until the evaluation arrangement is in the fault state falls.

After another lesson, the independent meaning comes, the present problem for a connection arrangement with the features of the preamble of claim 11 by the features of the characterizing part of claim 11 solved.

What is essential here is the fact that the Connector assembly, which is designed as a cable harness in a preferred embodiment, has the fuse circuit described above. Such a configuration the connection arrangement is with the preferred embodiment of the fuse circuit according to claim 6 particularly advantageous in that the resulting arrangement extremely compact is.

The invention is explained below one is just an embodiment illustrative drawing closer explained. The only figure of the drawing shows a fuse circuit for an electrical Consumer of a motor vehicle door lock or the like.

First of all, it should be noted that a connection terminal for the supply voltage U ₀ and a connection terminal for ground (0V) are provided in the drawing, to which a safety circuit for an electrical consumer (not shown in more detail) of a motor vehicle door lock is connected. All types of door, hood or flap locks can also be provided for the motor vehicle door lock. The fuse circuit has a power output 2 to which the electrical consumer can be connected and which ensures the supply of the consumer with electrical energy. They are also a circuit breaker 3 , a measuring arrangement 4 and an evaluation arrangement 5 provided, the circuit breaker 3 and the measuring arrangement 4 are summarized here in a single component.

The circuit breaker 3 serves to connect the power output 2 , It is essential for the present consideration that the power output 2 through the circuit breaker 3 can be switched off. With the shutdown of the power output 2 is meant here that the circuit breaker 3 no further electrical power via the power output 2 to the consumer.

By means of the measuring arrangement 4 In the present case, the load condition of the consumer can be measured and converted into an electrical measurement signal. The measurement signal is at a signal output 6 the measuring arrangement 4 on. In the present case, the term “load condition” summarizes all information that provides information about the electrical power consumption of the consumer. The typical information here, as already explained in the introduction to the description, is the temperature and the current flowing through the consumer.

The measuring arrangement 4 is over its signal output 6 with the evaluation arrangement 5 coupled so that at the signal output 6 applied measuring signal from the evaluation arrangement 5 can be processed further.

If the consumer is overloaded, it is now provided that the evaluation arrangement 5 falls from the normal state to an error state. The evaluation arrangement in the error state 5 causes a coupling to the circuit breaker to be explained in more detail 3 the shutdown of the power output 2 ,

Depending on the application, "overload" can mean different states of the consumer. In general, "overloading" a consumer means that the consumer has an undesirably high power consumption. For example, the fact that the current flowing through the consumer has a certain current threshold briefly exceeded, can already be defined as overload. It may also be the case, however, that in the sense of low-pass filtering, this overcurrent has to stop for a predetermined period of time to justify the overloading of the consumer. The same considerations apply to possible definitions of the overloading of the consumer using temperature values. In the present case, the term “overload” should apply generally and should not be limited to one of the definitions described.

It is now essential that the evaluation arrangement 5 is designed in such a way that the evaluation arrangement which is in the fault state 5 remains in the fault state regardless of the further measured load condition of the consumer. The advantages of this special embodiment have been explained in the general part of the description. This may be referred to.

In a particularly preferred embodiment, the measuring arrangement 4 a current detection arrangement, the current detection arrangement preferably converting the current flowing through the consumer into a voltage proportional to the current flowing through the consumer. That from the measuring arrangement 4 generated and at the signal output 6 The applied measurement signal consists of a voltage proportional to the current. However, it may also be the case that the measurement signal is, for example, a pulsed voltage and that the pulse length is proportional to the current. Numerous other possibilities are known from the prior art for converting the measured current. This may be referred to.

It can also be advantageous that the measuring arrangement 4 has a temperature detection arrangement. This can be used, for example, to measure the temperature of the consumer. However, it is also possible to record the at the circuit breaker 3 prevailing temperature, which also provides information about the power consumption of the consumer. On the conversion of the temperature into a measuring signal by means of the measuring arrangement 4 the solutions presented in connection with the current detection arrangement are applicable.

For a particularly secure detection of the load status of the consumer it finally conceivable that the measuring arrangement both a current detection arrangement and a temperature detection arrangement having.

The blocking capability of the evaluation arrangement described above 5 In a preferred embodiment, the fault condition is realized in that the evaluation arrangement 5 has a latch circuit. The self-holding circuit has a control input 7 on, by applying a voltage to the self-holding circuit can be brought into its holding state. The self-holding circuit also has a switching output 8th on that with the circuit breaker 3 , especially with a control input 9 of the circuit breaker 3 , is coupled. The control input 7 the latch circuit is present with the signal output 6 the measuring arrangement 4 coupled.

In the following it is assumed that the measuring arrangement 4 only has a current detection arrangement and that at the signal output 6 the measuring arrangement 4 a voltage proportional to the current is present. In principle, however, the following statements can be applied to all other variants already explained.

The self-holding circuit is now designed so that it switches to its holding state when the consumer is overloaded - fault state of the evaluation arrangement 5 - And that the self-holding circuit in the holding state via the switching output 8th and the control input 9 of the circuit breaker 3 the power output is switched off.

Numerous variants are known from the prior art for realizing the self-holding circuit (for example RS flip-flop). This may be referred to. A particularly preferred embodiment is that the self-holding circuit consists of two transistors connected in series 10 . 11 is constructed. The design of the two transistors 10 . 11 is largely arbitrary, in the present case it is provided that the first transistor on the left in the drawing 10 as an npn transistor and the second transistor shown on the right in the drawing 11 is designed as a pnp transistor.

What is essential for self-retention is the fact that the collector 12 of the first transistor 10 with the base 13 of the second transistor 11 is coupled so that when the first transistor is conductive 10 over the base-emitter path of the second transistor 11 there is a voltage present through the resistors 14 and 15 and the supply voltage U _{0 is} determined. With appropriate design of the resistors 14 . 15 becomes when the first transistor is conductive 10 also the second transistor 11 conductive so that a current flow from the second transistor 11 across the diode 16 further via an intermediate circuit to be described, through the base-emitter path of the first transistor 10 is possible. This will make the first transistor 10 through the second transistor 11 "activated", and the second transistor 11 again through the first transistor 10 "Activated". This has a self-holding effect here.

It is also essential that the coupling between the signal output 6 the measuring arrangement 4 and the control input 7 the self-latch circuit described a low-pass circuit 17 having. This low-pass circuit is made up of the two resistors 18 . 19 and capacity 20 together. This ensures that a short-term overload of the consumer does not immediately lead to a shutdown of the power output 2 leads, but that a desired time constant can be set here.

In the case of current measurement, the signal output 6 the measuring arrangement 4 preferably a voltage proportional to the current flowing through the consumer, which is initially applied to the low-pass circuit 17 acts. Depending on the time constant of the low-pass circuit 17 becomes the capacitor 20 loaded until the first transistor 10 falls into the conductive state, whereby, as described above, the self-holding circuit is brought into its holding state.

If now the evaluation arrangement 5 the second transistor is in the fault state and thus the self-holding circuit is in the holding state 11 in the conductive state, so that a corresponding current through the resistor 21 flows. This is above the switching output 8th the self-holding circuit a voltage at the control input 9 of the circuit breaker 3 at what a shutdown of the power output 2 at the circuit breaker 3 causes. This ensures that when the evaluation arrangement is in the fault state 5 the power output 2 is basically switched off.

With what has been said above, the meaning of the diode 16 clear. It prevents the signal output 6 the measuring arrangement 4 directly to the control input of the circuit breaker 3 acts and possibly an unwanted shutdown of the power output 2 causes.

The condenser 22 is a buffer capacitor for stabilizing the power supply to the circuit breaker 3 or the measuring arrangement 4 ,

There are at least two options for operating the fuse circuit described with a consumer. One possibility is that at the clamp 2 a relay is connected, via which the consumer can be switched on or off. Another possibility is that the circuit breaker 3 itself is used as a relay, so that the consumer is controlled even in the normal state via the circuit breaker 3 he follows. Another possibility could be to switch the consumer on or off by switching the supply voltage U ₀ on or off. However, this would mean that the evaluation arrangement would be reset each time the consumer was switched off 5 connected since the transistors fell into their non-conductive state when switched off. Depending on the application, this can be advantageous or undesirable.

The question of how the evaluation arrangement 5 can be brought back from the fault state to the normal state, is of particular importance in the present case. In a preferred embodiment, the evaluation arrangement is provided 5 by resetting from the fault state to the normal state. This reset process can be carried out manually, for example by actuating a switch, by a timer or by similar measures. As can be seen from the drawing, a reset process can also be realized in that the control input 7 the self-holding circuit is switched to ground in the holding state.

In a particularly preferred embodiment, no “own” circuitry measure is provided for the reset process, so that the reset process can be accomplished only by separating the fuse circuit from the supply voltage. This is advantageous, for example, if the evaluation arrangement 5 should remain in the error state until the error has been repaired.

Numerous possibilities are conceivable for the configuration of the hardware of the fuse circuit. In a preferred embodiment, at least part of the fuse circuit is designed as an integrated circuit (IC). This leads to low component costs, especially when standard components are used. In the illustrated and preferred embodiment, the circuit breaker is 3 on the one hand and the measuring arrangement 4 on the other hand realized in a single component. This leads to a particularly compact configuration of the circuit arrangement.

After another lesson, the independent meaning comes a connection arrangement for one electrical consumer of a motor vehicle door lock or the like. Such a connection arrangement is used for the electrical supply of the motor vehicle door lock or individual consumers of the motor vehicle door lock. So that the connection arrangement on the one hand to the electrical interface of the motor vehicle door lock, especially to the consumer of the motor vehicle door lock and on the other hand connectable to a control device or the like. On The control device can also be a simple relay or the like.

What is essential here is the fact that the connection arrangement itself has the fuse circuit described above 1 having. This is particularly in view of the compact configuration of the fuse circuit described above 1 easy to implement. The fact that the fuse circuit 1 no additional space in the control or in the consumer has to be granted. To a certain extent, it can be wired "on the fly". In a preferred embodiment, the connection arrangement is then configured as a cable harness, the fuse circuit 1 is integrated in the cable harness. This is a preferred variant, in particular for tailgate locks.

Claims (12)

Safety circuit for an electrical consumer of a motor vehicle door lock or the like with a power output ( 2 ) for supply of the electrical consumer, with a circuit breaker ( 3 ) for wiring the power output ( 2 ), with a measuring arrangement ( 4 ) and with an evaluation arrangement ( 5 ), whereby by means of the measuring arrangement ( 4 ) the load state of the consumer is measurable and convertible into an electrical measurement signal, the measurement signal at a signal output ( 6 ) of the measuring arrangement ( 4 ) is applied, the measuring arrangement ( 4 ) via their signal output ( 6 ) with the evaluation arrangement ( 5 ) is coupled, whereby if the consumer is overloaded, the evaluation arrangement ( 5 ) falls from the normal state into an error state and the evaluation arrangement (error state) 5 ) via their coupling to the circuit breaker ( 3 ) the shutdown of the power output ( 2 ), characterized in that the evaluation arrangement in the error state ( 5 ) remains in the fault state regardless of the further measured load condition of the consumer. Safety circuit according to claim 1, characterized in that the measuring arrangement ( 4 ) has a current detection arrangement and that the current detection arrangement preferably converts the current flowing through the consumer into a voltage proportional to the current flowing through the consumer. Safety circuit according to Claim 1 or 2, characterized in that the measuring arrangement ( 4 ) has a temperature detection arrangement. Safety circuit according to one of the preceding claims, characterized in that the evaluation arrangement ( 5 ) can be brought from the fault state to the normal state by a reset process. Safety circuit according to claim 4, characterized in that the Reset process, preferably exclusively, can be effected by separating the fuse circuit from the supply voltage is. Safety circuit according to one of the preceding claims, characterized in that the evaluation arrangement ( 5 ) a latching circuit with a control input ( 7 ) and with a switching output ( 8th ) has that the control input ( 7 ) with the signal output ( 6 ) of the measuring arrangement ( 4 ) is coupled that the switching output ( 8th ) with the circuit breaker ( 3 ) is coupled that the self-holding circuit when the evaluation arrangement is in the fault state ( 5 ) is in its hold state and that the self-hold circuit in the hold state is via the switch output ( 8th ) and the circuit breaker ( 3 ) a shutdown of the power output ( 2 ) causes. Safety circuit according to Claim 6, characterized in that the self-holding circuit consists of two transistors connected in series ( 10 . 11 ) is constructed, preferably one transistor ( 10 ) as the npn transistor and the other transistor ( 11 ) is designed as a pnp transistor. Safety circuit according to Claim 6 or 7, characterized in that the coupling between the signal output ( 6 ) of the measuring arrangement ( 4 ) and the control input ( 7 ) the self-hold circuit has a low-pass circuit ( 17 ) - integrator - has. Safety circuit according to one of the preceding claims, characterized in that at least part of the safety circuit ( 1 ) is designed as an integrated circuit (IC). Safety circuit according to claim 9, characterized in that the measuring arrangement ( 4 ) on the one hand and the circuit breaker ( 3 ) are realized on the other hand by a single component. Connection arrangement for an electrical consumer of a motor vehicle door lock or the like, the connection arrangement being connectable on the one hand to the electrical interface of the motor vehicle door lock, in particular to the consumer of the motor vehicle door lock, and on the other hand to a control device or the like, characterized that the connection arrangement is a fuse circuit ( 1 ) for the consumer and that the fuse circuit ( 1 ) has the features of one of the preceding claims. Connection arrangement according to claim 11, characterized in that the connection arrangement is designed as a cable harness and that the fuse circuit ( 1 ) is integrated in the cable harness.