EP1110291A1 - Drive device and method for moving a vehicle part - Google Patents

Abstract

The invention relates to a method for moving a vehicle part between at least two positions, wherein the vehicle part is driven by an electric motor, pulse signals corresponding to the rotational movement of the electric motor are generated and fed to a control unit for controlling the electric motor and wherein a first value for the momentary force effect on the vehicle part is determined in a first calculation (50) with a first parameter set from the detected pulse signals at given first times. Parallel to the first calculation, a second value for the momentary force effect on the vehicle part is determined in at least a second calculation (52) with a second parameter set from the detected pulse signals at given second times, wherein both values are taken into account for the momentary force effect in order to determine whether or not the motor should be disconnected or reversed. The invention also relates to a device for implementing said method.

Description

 Drive device and method for adjusting a vehicle part

The invention relates to a method for adjusting a vehicle part between at least two positions according to the preamble of claim 1 and a drive device for a vehicle part adjustable between at least two positions according to the preamble of claim 9.

DE 43 21 264 AI discloses a generic method and a generic drive device. An electric motor drives a car window pane. By means of two Hall sensors offset by 90 degrees, which interact with a magnet arranged on the motor shaft, a signal is generated from which the current period of the motor rotation and thus the. Monentane speed of the engine is determined at any point in time at which such a signal arrives at a control unit for controlling the engine. As soon as the instantaneous speed change, which results from the difference between two successive speed measured values, exceeds a predetermined threshold value, the motor is reversed in order to release a possibly jammed object.

From DE 195 11 581 AI a similar drive device is known, in which, however, the threshold value is selected as a function of the position, the speed change between two adjacent positions recorded in a previous run being stored in a memory for certain positions of the adjustment path in order to be dependent on this to calculate the cut-off threshold for the speed depending on the position from the last position and speed currently recorded.

From DE-OS 29 26 938 it is known to detect the engine speed in a sliding roof drive at constant time intervals, the differences in succession Forming values, adding up these differences if they are greater than a predetermined threshold value, and triggering a shutdown or reversing of the motor as soon as the total added exceeds a predetermined threshold value.

From DE 43 12 865 AI a drive device for a motor vehicle window is known which detects the motor speed by means of two Hall detectors and reverses the motor when a threshold value for the relative change in speed is exceeded. The threshold value is constantly recalculated as a function of the detected motor voltage and the ambient temperature determined by a temperature sensor on the motor. The standstill / operating times of the motor are also taken into account in order to be able to infer the ambient temperature from the motor temperature.

From DE 196 18 219 AI it is known for a sliding roof drive to determine the speed threshold or the speed change threshold of the motor, from which the motor reverses, from the position-dependent speed data of a previously performed reference run depending on the position of the cover.

A disadvantage of these generic speed-detecting drive devices is that they, e.g. by selecting the trigger threshold, only for a pinching speed, i.e. a rigidity of the overall system can be optimized. The rigidity of the overall system is made up of the rigidity of the drive mechanism, the pinched body and the vehicle body. On the one hand, the stiffness of the pinched body depends on the type of body. On the other hand, the rigidity of the body is heavily dependent on the place where the body is pinched. The stiffness can thus vary from pinching to pinching, which means that only a small part of the pinching cases can be optimally recognized in the known systems.

It is an object of the present invention to provide a drive device for a vehicle part movable between at least two positions and a method for adjusting a movable vehicle part between at least two positions, by means of which a more reliable detection of the jamming of an object is made possible. This object is achieved according to the invention by a method according to claim 1 and a drive device according to claim 9.

In this solution according to the invention it is advantageous that the pinch protection detection can be optimized for at least two different pinch scenarios.

In an advantageous development of the invention, it is determined whether the first value for the force effect determined in the first calculation exceeds a predetermined first trigger threshold value or whether the second value for the force effect determined from the second calculation exceeds a predetermined second trigger threshold value, the results of the two Comparisons can be linked in an OR operation. This represents a particularly simple pinch detection.

The first calculation and the second calculation are preferably optimized for the detection of the expected fastest or slowest changes in force. This creates reliable pinch detection in the widest possible range of pinch scenarios.

In the second calculation, a new value of the force effect is preferably calculated only after every nth input of a pulse signal, while in the first calculation the time of the input of each pulse signal is recorded at the control unit and between two such input times at certain extrapolation times from at least one Part of these measured times, the first value for the current force on the vehicle part is determined. This enables the detection of both very fast and very slow pinching processes.

Further preferred embodiments of the invention result from the subclaims.

In the following, embodiment of the invention is explained in more detail with reference to the accompanying drawings. Show it:

FIG. 1 shows a schematic illustration of a drive device according to the invention,

FIG. 2 shows a graphical representation of an exemplary temporal course of the period of the motor rotation, FIG. 3 shows a schematic exemplary representation of the method according to the invention, and

FIG. 4 schematically shows a vehicle roof to illustrate the method according to FIG. 3.

Referring to FIG. 1 drives an electric motor 10 designed as a direct current motor via a shaft 12, a pinion 14 which is in engagement with two drive cables 16 which are guided with tension and compression resistance. A worm gear (not shown) is optionally located between the electric motor 10 and the pinion 14. The movable covers 54 of vehicle sunroofs, today predominantly designed as sliding / lifting roofs or spoiler roofs, are mostly driven by means of such drive cables 16. The window lifters of a motor vehicle door often act on the movable part via a cable drum and a smooth cable, i.e. the disc. For the following consideration, it does not matter how the force is applied to the moving vehicle part. The cover 54 of a sliding / lifting roof is preferably driven, which, however, is only shown in FIG. 4 for better clarity.

A magnetic wheel 18 with at least one south and one north pole is mounted on the shaft 12 in a rotationally fixed manner. Of course, several, for example, 4 north and south poles can also be arranged on the magnetic wheel 18, as a result of which the period of the signals is correspondingly shortened. Two Hall sensors 20, 22 are arranged near the magnetic wheel 18 in the circumferential direction, each of which sends a pulse signal to a control unit 24 provided with a microprocessor 36 and a memory 38 each time the north or south pole of the magnetic wheel 18 passes emit, which thus receives a signal about every quarter turn of the shaft 12. The period duration results in each case from the distance between two successive signals on the same sensor 20 or 22, which are received at a distance of one full rotation of the shaft 12. Because of the 90 degree arrangement of the two sensors 20, 22, the period is alternately calculated from the time difference between the last two signals on the sensors 20 and 22, so that every quarter turn a new value of the period is available. This type of determination of the period duration affects deviations from the exact 90 degree Geometry of the sensor arrangement does not depend on the period, as would be the case when determining the period from the time difference between the last signal of one sensor and the other sensor.

The direction of rotation can also be determined on the basis of the phase shift of the signals of the two sensors 20, 22. In addition, the current position of the cover 54 can also be determined from the signals of the Hall sensors 20, 22 by feeding these signals to a counter 40 assigned to the control unit 24.

The direction of rotation of the motor 10 can be controlled by the control unit 24 via two relays 26, 28 with changeover contacts 30, 32. The speed of the motor 10 will be controlled by pulse width modulation via a transistor 34.

The essential aspect of the present invention is that two calculations 50, 52 are carried out in parallel and independently of one another in order to derive a value for the momentary force acting on the roof cover from the times of the signal input from the Hall sensors 20, 22 on the control unit 24 to be determined, both values being taken into account when deciding whether there is a trapping event. The calculations are each carried out with their own parameter set and their own sampling rate. The sampling rate means the distance between the times at which a value for the momentary force is determined.

As previously mentioned, the rigidity of the overall system depends on the type of body being pinched and the location where the body is pinched. This applies in particular to the lowering movement of a cover 54 from an opening position, see FIG. 4. If a body 56 is clamped in the area of the roof center (indicated in FIG. 4 with 58), the overall system is considerably softer than if it were clamped in the edge area (indicated in Fig. 4 with 60).

If a system works with a single fixed sampling rate, the parameter set of the calculation, in particular the threshold or limit values, and the selected sampling rate can only be optimized for a single stiffness of the overall system, although in practice each Depending on the type and location of the pinched body, different stiffnesses of the overall system can be decisive.

By performing a second parallel calculation, it is possible to select the calculation parameters and the sampling rate on which the calculation is based, i.e. the choice of the times at which a new value of the momentary force is calculated to optimize this second calculation for a different stiffness.

The second calculation is for the detection of slow changes in force, i.e. small stiffness, optimized during the first calculation for the detection of rapid changes in force, i.e. great stiffness is optimized.

For this purpose, the first calculation 50 uses an extrapolation algorithm described in the following, an estimated value for the current force acting on the vehicle part being determined between two signal input times at specific extrapolation times from a part of these measured times.

As a rule, the second calculation does not require an extrapolation of measured values of the period, but, depending on the relevant stiffness range, it is calculated after a new measured value has been received or only after every nth input of a measured value Value of the momentary force applied. In principle, however, if necessary, the second calculation can also use an extrapolation algorithm, the extrapolation times being selected at a greater distance than in the first calculation.

The first calculation including the extraplation algorithm is described below.

From the time of the signal input from the Hall sensors 20 and 22, the microprocessor 36 determines the monthly period of the rotation of the shaft 12 and thus also of the electric motor 10. Thus, a measurement value for the period is available approximately every quarter of a revolution of the shaft 12. To be one between these times too To ensure protection against trapping, estimated values for the period are continuously extrapolated from previous measured values of the period in a fixed time grid, for example every 1 ms, for example according to the following formula:

T * [k] = T [i] + k ^• (al ^• T [i-1] + a2 ^• T [i-2] + a3 ^• T [i-3]) (1)

where al, a2, a3 are parameters, i is an index that every quarter, incremented, and k is the running index of the fixed time grid, which is reset to zero for each new measurement for the period. Instead of the last four measured values, more or fewer measured values can be taken into account depending on the requirements.

The parameters al, a2, a3 model the overall system of the drive device, i.e. Motor 10, power transmission components and cover, and are determined by the spring stiffness, damping and friction of the overall system. This results in a bandpass effect with the property that spectral components of the period over time that result from vibrations are rated weaker than those that result from a pinching event. FIG. 2 schematically shows an exemplary temporal course of the measured period durations T and the period durations T * estimated therefrom. The dashed curve represents the true course of the period.

The speed change at time [k], based on the previous time [k-1], is then estimated from the estimated values for the period, using a motor voltage filter and a travel profile filter to determine the influences of the motor voltage and the position at which the moving vehicle part, ie the cover, just located, to eliminate the engine speed using the following formula:

ΔN * [k] = (T * [k] - T * [k-1]) / (T * [k]) ² - Vu (Um [k]) - Vr (x [k]) (2)

where Um [k] is the motor voltage at the time [k], Vu is a motor voltage filter which simulates the dependency of the speed on the motor voltage detected by the control unit 24, x [k] is the position of the cover at the time [k] and Vr on O

Path profile filter that simulates the dependence of the engine speed on the position of the cover.

The motor voltage filter Vu simulates the dynamic behavior of the motor when the voltage changes. The motor voltage filter Vu is preferably designed as a low-pass filter, the time constant of which is equal to the motor time constant. The time constant depends on the operating case, i.e. the opening or closing of the cover 54 in the sliding or lowering direction, and the magnitude of the change in voltage.

The path profile filter Vr is automatically determined by a learning run after installation of the drive device in the vehicle. As mentioned above, the position of the cover 54 is determined from the pulse signals of the Hall sensors 20, 22 which are summed up by means of the counter 40.

The decision of the first calculation 50 as to whether or not there is a jamming is made using the following formula:

Σ (Vf- ΔN * [k]) = Σ (ΔF [k])> Fmax (3)

The estimated speed changes ΔN * [k] are compared with a fixed lower limit that is constant over time. As soon as they exceed this lower limit, they are each multiplied by a proportionality factor Vf, which represents the steepness of the motor characteristic of the electric motor 10 (torque versus speed). The slope is approximately constant at constant motor voltage and motor temperature, but is different for each electric motor 10. In order to eliminate these influences, on the one hand the ambient temperature is detected by a temperature sensor and the motor temperature is approximated by recording the operating time (instead of the ambient temperature, the motor temperature can also be detected directly by a temperature sensor on the electric motor 10). On the other hand, two pairs of values for speed and torque are determined for each electric motor 10 before connection to the cover 54 in the course of the final production test with constant motor voltage and are stored in the memory 38. The gradient of the engine characteristic curve is determined from these measured values, from which the proportionality factor Vf is calculated. The product of ΔN * [k] and Vf corresponds to the change ΔF [k] in the application of force at the time [k], based on the time (k-1], on the displacement movement of the cover 54.

The ΔF [k] values are added up as long as the ΔN * [k] values are above the specified lower limit. As soon as two consecutive ΔN * [k] values are below it again, the sum is set to zero. If a ΔN * [k] value exceeds a fixed upper limit, only the value of the upper limit is included in the sum instead of this ΔN * [k]. This serves to eliminate as far as possible the effects of vibrations, which lead to brief, periodic peaks in the speed change, on the detection of a trapping event. In the simplest case, this upper limit can be chosen to be constant. In order to increase the accuracy of the triggering, however, the upper limit can also be selected in a time-dependent manner depending on the currently determined speed change, e.g. in the form that the upper limit is increased with increasing current speed change.

Finally, it is determined in the first calculation 50 whether the sum of the ΔF [k] exceeds a maximum permissible clamping force Fmax or not.

3, in a speed detection stage 62, the input variables period T, motor voltage, cover position x and motor temperature according to formulas (1) and (2) above with the first (higher) sampling rate, ie at the measuring times [i] and the extrapolation times [k], the current speed change ΔN * or the current speed N * (this results from N * [k] = 1 / T * [k] - Vu (Um [k]) - Vr (x [k]; instead of [k] it can also be [i]) Furthermore, the engine temperature is taken into account when determining the speed when converting speed change into force change according to formula (3) .The first sampling rate is selected so that it is used for the detection of pinching with the The highest detection system stiffness is optimal The speed detection stage 62 is used jointly by the first calculation 50 and the second calculation 52. In the first calculation 50, the change in speed ΔN * is converted to the by means of the formula (3) in the manner described above using a first value for the fixed lower limit, a first value for the fixed upper limit and a first value for the threshold value Fmax the first sampling rate specified points in time, ie the extrapolation points in time [k], determined whether the momentary force effect exceeds this first threshold value Fmax. The values of this first parameter set are optimized for the detection of pinching cases with the greatest expected system rigidity.

In the second, parallel calculation 52, the sampling rate is selected so that it is optimal for the detection of pinching cases with the lowest expected system stiffness. This second sampling rate can e.g. should be chosen so that only every fourth measured value of the period T should be taken into account. In this case, the second calculation is only carried out by the Hall sensors 20, 22 every fourth signal input, i.e. only every fourth speed N [i] determined by the stage 62, which goes back to a measured period T is taken into account in the sampling stage indicated by 66 in FIG. 4 (indicated by 66 in FIG. 4), which corresponds to a measured period T goes back. The speeds N * [k] determined from extrapolated period durations T * are of course not taken into account anyway. The second calculation 52 is therefore only carried out every fourth point in time [i].

First the speed change ΔN [i] compared to the last measured value is determined. Then it is determined in an analogous manner by means of the formula (3) using a second value for the fixed lower limit, a second value for the fixed upper limit and a second value for the threshold value Fmax whether the momentary force action exceeds this second threshold value Fmax. The values of this second parameter set are optimized for the detection of pinching cases with the lowest expected system rigidity.

The results of the first and the second calculation are logically linked to one another in a logic stage 64 for the decision as to whether there is a jamming situation, ie the engine should be switched off or reversed. In the simplest case, this is an OR operation. In this case, the motor is switched off or reversed if one of the has detected a case of pinching in both calculations. The decision is made at any point in time when the first calculation 50 delivers a new result. Since new results of the second calculation 52 are available much less frequently, the last result of the second calculation 52 is always supplied to the logic stage 64. If a pinching case has been detected on the basis of the linkage, the control unit 24 triggers reversing of the motor 10 by actuating the relays 26, 28 via the switches 30, 32 in order to immediately release a jammed object.

By linking the results of the two calculations 52, 54, both rapid and slow changes in force can be optimally recorded.

Instead of only performing a second parallel calculation, it is also possible to additionally carry out a third or even more parallel calculations in order to optimize the pinch protection for more than two pinch scenarios, i.e. System stiffness.

In order to further reduce the probability of false triggering when vibratory forces occur, a spectral analysis of the changes in speed determined at the time of analysis can be carried out within a specific time window. If certain spectral characteristics occur, in particular if a clearly pronounced peak occurs, which is not in the spectral range typical for pinching cases, triggering is prevented, even if the logic stage 64 has actually detected a pinching case.

Reference list

Electric motor 10

Wave 12

Pinion 14

Drive cable 16

Magnetic wheel 18

Hall sensors 20, 22

Control unit 24

Relays 26, 28

Switches 30, 32

Transistor 34

Microprocessor 36

Memory 38

Counter 40 first calculation 50 second calculation 52

Cover 54

Pinch body 56

Position in the center of the roof 58

Position in the roof edge area 60

Speed detection level 62

Logic level 64

Scanning stage 66

Claims

Expectations

1. A method for adjusting a vehicle part (54) between at least two positions, the vehicle part being driven by an electric motor (10), pulse signals being generated in accordance with the rotary movement of the electric motor (10) and being fed to a control unit (24) for controlling the electric motor , and in a first calculation (50) with a first parameter set from the detected pulse signals at certain first times ([k]) a first value for the momentary force on the vehicle part is determined, characterized in that parallel to the first calculation (50 ) in at least one second calculation (52) with a second parameter set from the detected pulse signals at certain second times ([i]), a second value for the momentary force acting on the vehicle part (54) is determined, both values being taken into account for the momentary force acting to decide whether the engine (10) is switched off or reversed or n not.

2. The method according to claim 1, characterized in that it is determined whether the first value determined in the first calculation (50) for the force-acting effect exceeds a predetermined first triggering threshold value or whether the second value determined from the second calculation (52) for the force effect exceeds a predetermined second trigger threshold.

3. The method according to claim 2, characterized in that the results of the two comparisons are combined in an OR operation of a logic level (64).

4. The method according to claim 1 to 3, characterized in that the first calculation (50) and the second calculation (52) are optimized for the detection of the expected fastest or slowest changes in force.

5. The method according to claim 4, characterized in that the distance between the first times ([T]) is smaller than the distance between the second times ([i]).

6. The method according to claim 5, characterized in that in the second calculation (52) only after every nth input of a pulse signal, a new value of the force is calculated.

7. The method according to claim 4 to 6, characterized in that in the first calculation (50) the time ([i]) of the input of each pulse signal at the Control unit (24) is detected and between two such input times at certain extrapolation times ([k]) from at least part of these measured times the first value for the current force on the vehicle part is determined.

8. The method according to claim 7, characterized in that in the first calculation from the measured times, the instantaneous period (T [ij) of the motor rotation is determined, the instantaneous period (T * [k]) at the extrapolation times ([k] ), taking into account several previous measured periods (T [i-1], T [i-2], T [i-3]), an estimated speed change (ΔN * [k]) is determined for each extrapolation time from the estimated periods is and the first value of the force acting on the vehicle part is determined from the estimated speed changes at each extrapolation time.

9. Drive device for a vehicle part (54) movable between at least two positions, with an electric motor (10) for driving the vehicle part (54) and a device (18, 20, 22) for generating a pulse signal corresponding to the rotary movement of the electric motor (10) , which is fed to a control unit (24) for controlling the electric motor (10), the control unit (24) being designed such that in a first calculation (50) with a first parameter set from the detected pulse signals at certain first times ([k ]) a first value for the momentary force on the vehicle part (54) is determined, characterized in that the control unit (24) is designed such that in parallel with the first calculation (50) in at least one second calculation (52) with a second parameter set from the detected pulse signals at certain second times ([i]) a second value for the momentary force on the vehicle part (54) is determined, w Both values for the momentary force are taken into account in order to decide whether the electric motor (10) is switched off or reversed or not

10. Drive device according to claim 9, characterized in that the control unit (24) is designed to carry out the method according to one of claims 2 to 8.