EP3744934A1 - Functional component of a motor vehicle lock arrangement - Google Patents

Abstract

The invention relates to a functional component of a motor vehicle lock arrangement (2), the functional component (1) having a drive arrangement (3) with an electric drive motor (4) and an actuating element (5) which is or can be coupled to the drive arrangement (3), the actuating element ( 5) can be deflected in a deflection movement (6) out of a predetermined incidence position and wherein the deflected adjusting element (5) can be reset in a return movement (7) into the incidence position, the deflection movement (6) being able to be generated by means of the drive arrangement (3) and the drive motor (4) works in motor mode and the return movement (7), in particular exclusively, is spring-driven and the drive motor (4) works in generator mode. It is proposed that the functional component (1) has a monitoring unit (8), which is derived from the motor voltage (U _M) of the drive motor (4) according to a monitoring rule (9) which is contained in the return movement (7) actually reached position of the adjusting element (5) determined.

Description

The invention relates to a functional component of a motor vehicle lock arrangement according to the preamble of claim 1 and a method for operating such a functional component according to the preamble of claim 16.

The motor vehicle lock arrangement in question has at least the functional component “motor vehicle lock” and possibly further functional components such as an external, motorized closing unit or an external, motorized opening unit for the motor vehicle lock. The motor vehicle lock can be assigned to any locking element of the motor vehicle. These include tailgates, trunk lids, front hoods, side doors or the like. All of these closure elements can be designed in the manner of pivoting doors or in the manner of sliding doors.

The well-known functional component designed as a motor vehicle lock ( EP 1 536 090 A2 ), from which the invention is based, is equipped with the usual locking elements "lock latch" and "pawl". The motor vehicle lock has a drive arrangement with an electric drive motor for lifting the pawl. The drive arrangement acts on the pawl via a drive cable in which the drive cable is wound onto the motor shaft of the drive motor. After the pawl has been lifted out by the drive cable, the pawl spring drives the entire drive train back, which is accompanied by the drive cable being unwound from the motor shaft.

One challenge with the known motor vehicle lock is to detect an incomplete return movement. In such a case, the pawl does not reach its original retracted position, for example due to mechanical stiffness, so that the correct engagement between the lock latch and the pawl does not exist. In order to detect such a lock state, a corresponding pawl sensor is provided in the known motor vehicle lock.

The sensorless monitoring of drive arrangements of a motor vehicle lock for actuating element movements that are generated by a motorized drive arrangement is basically known ( DE 100 21 186 A1 ). The so-called "current wave counting" or the so-called "ripple count method" is used here. However, this can only be used if a corresponding drive current closes, which is regularly not the case, especially with the restoring movement that is in the foreground here.

The invention is based on the problem of designing and developing the known functional component of a motor vehicle lock arrangement in such a way that the approach to the retracted position of the actuating element in the return movement can be monitored with little effort.

The above problem is solved in a functional component according to the preamble of claim 1 by the features of the characterizing part of claim 1.

First of all, according to the proposal, it is assumed that the adjusting element can be deflected out of a predetermined retraction position in a deflection movement, the deflected adjusting element being able to be reset into the retraction position in a return movement. It is also assumed that the deflection movement can be generated by means of the drive arrangement and the drive motor then works in motor mode, while the return movement, which here and preferably exclusively, is spring-driven and the drive motor works in generator mode.

The proposed solution is based on the fundamental consideration that the actual adjustment of the adjusting element in the return movement can be derived from the motor voltage of the drive motor. This is due to the fact that the drive motor works in generator mode during the return movement. In the case of a direct current motor, this means that the drive motor has shafts in the motor voltage, usually half-waves, which provide information about the range of rotation of the motor shaft. Alternatively, the adjustment speed of the motor shaft and thus of the control element can be deduced from the level of the motor voltage. The position of the adjusting element can then be deduced from the integration over time. In any case, the motor voltage of the drive motor is used to determine the position of the actuating element actually approached in the return movement.

Correspondingly, it is proposed in detail that the functional component has a monitoring unit which, from the motor voltage of the drive motor, determines the position of the actuating element actually moved to in the return movement according to a monitoring specification.

In the event that the functional component according to the proposal is a motor vehicle lock, a false closure of the motor vehicle lock, which is due to an incomplete return movement of the pawl, can be recognized and reduced by suitable connection measures. The proposed solution can be implemented without the need for an additional sensor.

For the sake of clarity, it should be pointed out that the functional component is claimed as such here, that is to say without the motor vehicle lock arrangement otherwise.

Preferred variants for the reaction of the monitoring unit to the detection of an incomplete return movement is the subject matter of claim 2. In the simplest case, a corresponding warning message is output to the vehicle operator as part of an alarm routine.

Claim 3 clarifies that the determination of the position of the adjusting element actually approached in the return movement is preferably carried out with reference to a reference position, which is further preferably the position of the adjusting element actually approached in the deflection movement. In a particularly preferred embodiment, the deflection movement is assigned an end stop or a limit switch so that the reference position of the adjusting element is approached in a correspondingly reproducible manner.

Two preferred variants for determining the position of the adjusting element actually approached in the return movement emerge from the claims 4 and 5. The ripple of the motor voltage (claim 4) and the level of the motor voltage (claim 5) each provide a starting point for solid monitoring of the position of the actuating element actually approached in the return movement. This applies in particular when the drive motor is a direct current motor according to claim 6.

The further preferred refinements according to claims 7 and 8 relate to the situation in which the monitoring regulation, in particular the relationship represented by the monitoring regulation between the motor voltage and the position of the actuating element actually approached in the return movement, depends on certain ambient conditions such as the ambient temperature.

In order to ensure that the monitoring rule corresponds to the prevailing conditions in each case, an adaptive system according to claims 8, 9 or 10 is proposed. Then, in a particularly advantageous embodiment, the monitoring rule, in particular the above relationship represented by the monitoring rule, is learned so that an exact determination of the position of the adjusting element is ensured in the return movement. It is assumed that the deflection movement and / or the return movement is or are mechanically fixed.

The further preferred refinements according to claims 11 to 13 relate to preferred applications for the proposed solution, in which the functional component is a motor vehicle lock of the motor vehicle lock arrangement. The embodiment according to claim 12, in which the pawl of the motor vehicle lock is the actuating element, is particularly advantageous. With the proposed solution, it is thus possible to check in an elegant way whether the pawl has reached its completely collapsed position or not.

The further preferred configurations according to claims 14 and 15 relate to equipping the drive arrangement with a flexible traction means. In particular with the winding of the flexible traction means onto the drive shaft of the drive motor according to claim 15, the return movement of the actuating element is always associated with an unwinding of the flexible traction mechanism and thus with a backdriving of the drive motor, so that the proposed monitoring function can be implemented without further structural measures.

According to a further teaching according to claim 16, which is of independent importance, a method for the operation of a proposed functional component of a motor vehicle bumper assembly is claimed.

According to the method, it is essential that a monitoring unit of the motor voltage of the drive motor is used to determine the position of the actuating element actually moved to in the return movement according to a monitoring specification. In this respect, reference can be made to all statements on the mode of operation of the functional component according to the proposal.

Fig. 1

eine als Kraftfahrzeugschloss ausgestaltete vorschlagsgemäße Funktionskomponente bei in der Einfallstellung befindlichem, als Sperrklinke ausgestaltetem Stellelement und

Fig. 2

die Funktionskomponente gemäß Fig. 1 während der Rückstellbewegung des als Sperrklinke ausgestalteten Stellelements.

The invention is explained in more detail below with the aid of a drawing that shows only one exemplary embodiment. In the drawing shows

Fig. 1

a functional component according to the proposal designed as a motor vehicle lock when the actuating element is in the collapsed position and designed as a pawl and

Fig. 2

the functional component according to Fig. 1 during the return movement of the adjusting element designed as a pawl.

The functional component 1 shown is designed as a motor vehicle lock of a motor vehicle lock arrangement 2. The functional component 1, here the motor vehicle lock, can be assigned to any locking element of a motor vehicle. In this respect, reference may be made to the introductory part of the description.

The functional component 1, here the motor vehicle lock, has a drive arrangement 3 with an electric drive motor 4 and an actuating element 5 which is or can be coupled to the drive arrangement 3. The adjusting element 5 is designed here and preferably as a pawl, as will be explained below.

The adjusting element 5 is in a deflection movement 6 from a predetermined incidence position ( Fig. 1 ) can be deflected out, the deflected adjusting element 5 ( Fig. 2 ) can be reset in a return movement 7 into the collapsed position.

It arises from a synopsis of Fig. 1 and Fig. 2 that the deflection movement 6 can be generated by means of the drive arrangement 3, the drive motor 4 then operating in motor mode. From this synopsis it can also be seen that the return movement 7, here and preferably exclusively, is spring-driven, the drive motor 4 then working in generator mode.

It is now essential that the functional component 1, here the motor vehicle lock, has a monitoring unit 8 that determines the position of the actuating element 5 actually moved to in the return movement 7 from the motor voltage U _{M of} the drive motor 4 according to a monitoring rule 9.

According to the proposal, it is therefore assumed that the adjusting element 5 can be adjusted in the return movement into the predetermined retraction position which is shown in FIG Fig. 1 is shown in solid line. However, according to the proposal, it has also been recognized that the return movement can also be incomplete in such a way that it is not the predetermined incidence position, but rather a misalignment preceding the predetermined incidence position is approached. This can be due to soiling, icing or the like, for example, which leads to the fact that the spring force still to be explained and acting on the actuating element 5 is not great enough to overcome such an obstruction.

A predetermined deviation of the position actually approached in the return movement 7 of the actuating element 5 from the retracted position can mean, using the example of the functional component 1 configured as a motor vehicle lock, that there is a pseudo-closure, i.e. incomplete closure. This is in dashed line in Fig. 1 shown. As indicated above, this apparent closure is due to the fact that the return movement 7 is an incomplete return movement. When such a discrepancy is detected, the monitoring unit 8 carries out an alarm routine which carries out a corresponding measure. In a first In a variant, it is provided that the alarm routine issues a warning message to the vehicle operator. Alternatively or additionally, it can be provided that the alarm routine blocks further operation of the drive arrangement 3 in order to avoid further risks.

The monitoring unit 8 determines the position of the actuating element 5 actually approached in the return movement 7 according to the monitoring regulation 9 based on a reference position of the actuating element 5. Here and preferably according to the monitoring regulation 9, the reference position is the position of the actuating element actually approached in the deflection movement 5 that are in Fig. 2 is shown. In the embodiment shown in the drawing, which is preferred in this respect, this is also appropriate, since the reference position is defined by the end stop 10 in the above sense.

A particularly robust determination of the position of the actuating element 5 actually approached in the return movement 7 results from the fact that, according to the monitoring specification 9, the position of the actuating element 5 is determined from the course of the motor voltage U _M. This is in Fig. 2 shown. It is assumed that the supply connections 11, 12 of the drive motor 4 are free of a supply voltage during the return movement 7. Particularly in the design of the drive motor, a sequence of half-waves 13 then results in the motor voltage U _M , the term "half-wave" being interpreted broadly in the present case.

According to the representation Fig. 2 it can be seen that the path covered by the drive motor 4 and thus by the actuating element 5 can be deduced from the number of half-shafts 13. Here, only a counting mechanism is to be provided in the monitoring unit 8.

Alternatively, it can be provided that the monitoring unit 8 determines the position of the actuating element 5 actually approached in the reset movement 7 according to the monitoring rule 9 from the level of the motor voltage U _M. The term "motor voltage level" can mean the maximum in Fig. 2 half-waves 13 shown, an average value over the in Fig. 2 represent half-waves 13 or the like shown. Regardless of the specific definition, the level of the motor voltage U _{M is} proportional to the Adjustment speed of the drive motor 4 and thus the adjustment speed of the adjusting element 5. Accordingly, it is preferably provided that the monitoring unit 8 determines the adjusting speed of the adjusting element 5 actually prevailing in the reset movement 7 according to the monitoring rule 9 from the level of the motor voltage U _M and from the determined actually prevailing adjustment speed of the adjusting element 5, the position actually approached by the adjusting element 5, based on the above reference position, is determined. The position of the control element 5 is preferably obtained by integrating the adjustment speed and / or the motor voltage U _M over time. This variant is particularly easy to implement insofar as the above-mentioned counting mechanism for the half-waves in the motor voltage U _{M is} not required. However, this determination is dependent on ambient conditions, in particular on the ambient temperature, which requires additional compensation measures. This is explained below.

The proposed solution can be implemented particularly well if the drive motor 4 is designed as a direct current motor that is preferably separately excited here. Other types of electrical machines are applicable here. These include, in particular, brushless DC motors.

Fig. 1 shows that the monitoring unit 8 is part of a control unit 14 which, in addition to the monitoring unit 8, has a driver unit 15 for supplying the drive motor 4 with electrical drive power. The control unit 14 ensures that the drive motor 4 is free from a supply voltage, in particular from the driver unit 15, during the return movement 7. The supply connections 11, 12 of the drive motor 4 are preferably not electrically coupled to one another during the reset movement 7, in particular not short-circuited, in order to avoid a braking effect in the manner of short-circuit braking.

In general, the above monitoring regulation 9 represents the relationship between the motor voltage U _M and the position of the actuating element 5 actually approached in the reset movement 7. The above, second alternative is the relationship between the motor voltage U _M and that in the reset movement 7 actually ruling Adjustment speed of the drive motor 4 and thus of the adjustment element 5. In particular in the case of the second-mentioned alternative, this relationship is dependent on ambient conditions, here and preferably on an ambient temperature. In a particularly preferred embodiment, the monitoring unit 8 determines the ambient temperature and adapts the monitoring specification 9 to the ambient temperature. The adaptation is indicated in the drawing with the reference number 16. In the simplest case, the ambient temperature can be determined by the monitoring unit 8 via the Can bus of the motor vehicle, since it can be assumed that a corresponding temperature sensor is accessible via the Can bus in modern motor vehicles.

The adaptation of the monitoring rule 9 can be carried out, for example, based on a physical engine model of the drive motor 4. However, it is also conceivable that the monitoring unit 8 is designed to be capable of learning to a certain extent for this purpose. For this purpose, it is preferably provided that the monitoring unit 8 determines the ambient temperature in a reference run of the actuating element 5 from the motor current I _M. In the simplest case, the known temperature dependency of the ohmic resistance of the motor winding of the drive motor 4 can be used here.

Alternatively or additionally, it can be provided that the relationship between the motor voltage U _M and the actual position of the actuating element 5 that is approached in the return movement 7, here and preferably the adjustment speed of the actuating element 5 actually prevailing in the return movement 7, in a reference run from the motor current I _M can be determined. The reference travel is preferably the deflection movement of the actuating element 5, i.e. the movement of the actuating element 5 generated by the drive arrangement 3 as a motor. Alternatively or additionally, the reference travel can also be the return movement of the actuating element 5. If the above relationship is based on a physical motor model of the drive motor 4, a parameterization of the motor model can be determined from such a reference run and the determination of the resulting motor current I _M , in particular in the first-mentioned case, which is then used to determine the position of the actuating element actually approached in the return movement 5 can be used as a basis.

Alternatively or additionally, it can be provided that the monitoring unit 8 determines the motor voltage U _{M of} the drive motor 4 in a reference run and generates or adapts the monitoring rule as a function of the determined motor voltage U _M. It is preferably the case that the monitoring unit 8 determines the relationship between the motor voltage U _M and the position actually approached in the return movement 7, in particular the adjustment speed of the actuating element 5 actually prevailing in the return movement 7, from the motor voltage U _M , in particular from the voltage curve , determined. In the simplest case, a characteristic voltage curve can be stored in the monitoring unit 8, a conversion factor for determining the actual position of the actuating element 5 being determined from the deviation of the voltage curve determined in the reference run from the characteristic voltage curve. The conversion factor can, however, also simply result from the number of above half-waves in the motor voltage U _M. A system for determining the conversion factor can be determined, for example, in test series. As mentioned above, it is preferably assumed that the deflection movement and / or the return movement is or are fixed mechanically, for example by appropriate blocking stops.

As mentioned above, the functional component 1 is preferably a motor vehicle lock of the motor vehicle lock arrangement, as shown in the drawing. The functional component 1 then preferably has the locking elements lock latch 17 and pawl 18, which interact with one another in a conventional manner.

Furthermore, it is preferably such that the motor vehicle lock has a lock housing 19, the monitoring unit 8, more preferably, being arranged in the lock housing 19. In principle, it can also be provided that the entire control unit 14 is arranged in the lock housing 19. Furthermore, it is conceivable that the monitoring unit 8 and possibly the entire control unit 14 is or are arranged outside the lock housing and otherwise spatially separated from the motor vehicle lock.

Here and preferably it is also the case that the actuating element 5 is the pawl 18 of the motor vehicle lock, the deflection movement 6 being a lifting of the pawl 18 as part of a motorized opening function. The pawl 18 is here and preferably assigned a pawl spring 20 which provides the spring-driven return movement 7 indicated above.

Alternatively and not shown, it can be provided that the actuating element 5 is the lock latch 17 of the motor vehicle lock, the deflection movement 6 being a closing movement of the lock latch 17 within the framework of a motorized closing function.

As a further alternative, it can be provided that the adjusting element 5 is a function lever for setting a lock state. These include, for example, a central locking lever, an anti-theft lever or a child safety lever. Other fields of application for the proposed solution are conceivable.

The above explanation shows that the drive arrangement 3 is designed to be drivable, the drive arrangement 3 being coupled to the actuating element 5 in such a way that the spring-driven return movement of the actuating element 5 is accompanied by a backdriving of the drive motor 4. This corresponds to the mode of operation of the exemplary embodiment shown in the drawing, which is preferred in this respect. Here the drive arrangement 3 has a flexible traction means 21 which directly or indirectly connects the drive motor 4 to the actuating element 5 and which can be wound up by the drive motor 4 to generate the deflection movement 6. The flexible traction means 21 can be, for example, a rope, a band, a chain or the like. The flexible traction means 21 can be designed from a plastic material, from a metal material or the like.

It is preferably provided that the flexible traction means 21 can be wound onto a drive shaft 22, here and preferably on the motor shaft of the drive motor 4, by means of the drive motor 4. It can be seen in the drawing that the spring-driven return movement from the Fig. 2 situation shown out to an unwinding of the flexible traction means 21 from the drive shaft 22 leads, whereby a corresponding motor voltage U _{M is} generated at the supply connections 11, 12 of the drive motor 4.

According to a further teaching, which is of independent importance, a method for operating a proposed functional component 1 of a motor vehicle lock arrangement 2 is claimed as such.

According to the proposed method, the functional component 1 has a drive arrangement 3 with an electric drive motor 4 and an actuating element 5 which is coupled or can be coupled to the drive arrangement 3. The adjusting element 5 is deflected in a deflection movement 6 out of a predetermined collapsed position, the deflected adjusting element 5 being reset into the collapsed position in a restoring movement 7. Furthermore, the deflection movement 6 is generated by means of the drive arrangement 3, while the return movement is spring-driven.

According to the proposed method, it is essential that a monitoring unit 8 determines the position of the actuating element 5 actually approached in the return movement 7 from the motor voltage U _{M of} the drive motor 4 according to a monitoring rule 9. In this respect, reference may be made to all statements regarding the mode of operation of the functional component 1 according to the proposal.

Claims (16)

Functional component of a motor vehicle lock arrangement (2), the functional component (1) having a drive arrangement (3) with an electric drive motor (4) and an actuating element (5) which is or can be coupled to the drive arrangement (3),
wherein the adjusting element (5) can be deflected in a deflection movement (6) out of a predetermined collapse position and wherein the deflected adjusting element (5) can be reset into the collapse position in a restoring movement (7),
wherein the deflection movement (6) can be generated by means of the drive arrangement (3) and the drive motor (4) works in motor mode and the return movement (7), in particular exclusively, is spring-driven and the drive motor (4) works in generator mode,
characterized,
that the functional component (1) has a monitoring unit (8) which, from the motor voltage (U _M ) of the drive motor (4) according to a monitoring rule (9), determines the position of the actuating element (5) actually approached in the return movement (7). Functional component according to Claim 1, characterized in that the monitoring unit (8) executes an alarm routine in the event of a predetermined deviation of the position actually approached in the return movement (7) from the engagement position, preferably that the alarm routine outputs a warning message to the vehicle operator, and / or that the alarm routine blocks further operation of the drive arrangement (3). Functional component according to Claim 1 or 2, characterized in that the monitoring unit (8) determines the position of the actuating element (5) actually approached in the return movement (7) according to the monitoring rule (9) in relation to a reference position of the actuating element (5), preferably, that, according to the monitoring regulation (9), the reference position is the position of the actuating element (5) actually approached in the deflection movement (6). Functional component according to one of the preceding claims, characterized in that the monitoring unit (8) determines the position of the actuating element (5) actually approached in the return movement (7) according to the monitoring rule (9) from the course of the motor voltage (U _M ), preferably from the Ripple of the motor voltage (U _M ), more preferably from the number of half waves of the motor voltage (U _M ), determined. Functional component according to one of the preceding claims, characterized in that the monitoring unit (8) determines the position of the actuating element (5) actually approached in the return movement (7) according to the monitoring specification (9) from the level of the motor voltage (U _M ), preferably, that the monitoring unit (8) determines the adjustment speed of the adjusting element actually prevailing in the return movement (7) according to the monitoring regulation (9) from the level of the motor voltage (U _M ) and from the actually prevailing adjustment speed of the adjusting element (5) the actually reached position of the Control element (5) determined. Functional component according to one of the preceding claims, characterized in that the drive motor (4) is designed as an in particular separately excited direct current motor. Functional component according to one of the preceding claims, characterized in that the relationship between the motor voltage (U _M ) and the position actually approached in the return movement (7), in particular the adjustment speed actually prevailing in the return movement (7), represented by the monitoring regulation (9) of the adjusting element (5), depends on ambient conditions, in particular on an ambient temperature, preferably that the monitoring unit (8) determines the ambient temperature and adapts the monitoring regulation (9) to the ambient temperature. Functional component according to one of the preceding claims, characterized in that the monitoring unit (8) determines the ambient temperature in a reference run of the adjusting element (5) from the motor current, and / or that the monitoring unit (8) determines the relationship between the motor voltage (U _M ) and the position actually approached in the return movement (7), in particular the adjustment speed of the control element (5) actually prevailing in the return movement (7), determined in a reference run from the motor current (I _M ). Functional component according to one of the preceding claims, characterized in that the monitoring unit (8) determines the motor voltage (U _M ) of the drive motor (4) in a reference run and generates or adapts the monitoring rule as a function of the determined motor voltage (U _M ), preferably, that the monitoring unit determines the relationship between the motor voltage (U _M ) and the position actually approached in the return movement (7), in particular the adjustment speed of the control element (5) actually prevailing in the return movement (7), from the motor voltage (U _M ). Functional component according to Claim 8 or 9, characterized in that the reference travel is the deflection movement (6) and / or the return movement of the adjusting element (5). Functional component according to one of the preceding claims, characterized in that the functional component (1) is a motor vehicle lock of the motor vehicle lock arrangement (2) and that the functional component (1) has the locking elements lock latch (17) and pawl (18), preferably that the motor vehicle lock a Has lock housing (19) and, preferably, that the monitoring unit (8) is arranged in the lock housing (19). Functional component according to one of the preceding claims, characterized in that the adjusting element (5) is the pawl (18) of the motor vehicle lock and that the deflection movement (6) is a lifting of the pawl (18) as part of a motorized opening function, preferably that the pawl (18) is assigned a pawl spring (20) which drives the return movement (7). Functional component according to Claim 11 or 12, characterized in that the adjusting element (5) is the lock latch (17) of the motor vehicle lock and that the deflection movement (6) is a closing movement of the lock latch (17) as part of a motorized closing function. Functional component according to one of the preceding claims, characterized in that the drive arrangement (3) has a flexible traction means (21) which directly or indirectly connects the drive motor (4) to the adjusting element (5) and from the drive motor (4) to generate the deflection movement (6) can be wound, preferably that the flexible traction means (21) is designed as a rope, band or chain. Functional component according to Claim 14, characterized in that the flexible traction means (21) can be wound onto a drive shaft, in particular on the motor shaft of the drive motor (4), by means of the drive motor (4). Method for the operation of a functional component (1) of a motor vehicle lock arrangement (2), in particular a functional component (1) according to one of the preceding claims, wherein the functional component (1) has a drive arrangement (3) with an electric drive motor (4) and one with the drive arrangement (3) having coupled or couplable adjusting element (5),
wherein the adjusting element (5) is deflected in a deflection movement (6) out of a predetermined collapse position and wherein the deflected adjusting element (5) is returned to the collapse position in a return movement (7),
wherein the deflection movement (6) is generated by means of the drive arrangement (3) and the drive motor (4) works in motor mode and the return movement (7), in particular exclusively, is spring-driven and the drive motor (4) works in generator mode,
characterized,
that by means of a monitoring unit (8) from the motor voltage (U _M ) of the drive motor (4) according to a monitoring rule (9) the position of the actuating element (5) actually approached in the return movement (7) is determined.

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