DE3829405A1 - Actuating device for parts of motor vehicles movable by electric motors - Google Patents

Abstract

A description is given of an actuating device for parts of motor vehicles movable by electric motors, which comprises a desired value transmitter and a digital actual value transmitter with incremental detection of the actual value as well as a microprocessor for the control of the electric motor. The actuating device is characterised in that, additionally to the actual value transmitter delivering incremental counting pulses, an absolute value transmitter is provided which is connected to the incremental actual value transmitter via gearbox elements and, over the whole displacement distance of the part to be moved, emits only one signal or one pair of signals which is assigned to a specific position of the movable part. This position can be, for example, the closed position of a sliding roof or of a window pane. The emission of the absolute signal at a specific position of the parts to be displaced corrects any errors arising in counting the incremental pulses and effects the calibration of the actuating device at each passage of the parts to be moved through the closed position (Fig. 1). <IMAGE>

Description

The invention relates to an actuating device for electromotive movement bare parts of motor vehicles according to the preamble of claim 1.

The invention is based on a prior art, as in DE-OS 33 24 107 is disclosed. The actuator described there includes a setpoint generator, by means of which a certain position of the movable Part is preselectable, and it also includes a control loop that is the actual position of the movable part is compared with the target position and the movable drives the bare part until the actual position is equal to the target position.

Among the several execution examples listed in DE-OS 33 24 107, one is described with reference to FIG. 10, in which the actual value, ie the position of the movable part, is determined by means of an incremental actual value transmitter. The digital value is then converted into an analog value, and the control loop is compared using a pure analog value comparison. In another exemplary embodiment ( FIG. 11), both the setpoint values and the actual value acquisition are carried out via potentiometers, that is to say with analogue, and these analogue values are converted into digital values via an A / D converter and fed to a microprocessor which carries out the control adjustment digitally .

In the case of the known actuating device, the processor receives the Use of an incremental actual value encoder is not mandatory information about the absolute position of the movable part. The absolute position must are therefore saved in the processor when it is started up for the first time. This can e.g. B. happen by moving to a defined end position. Erlei the processor then detects counting errors during normal operation, for example due to high-frequency electrical interference, the setpoint and actual value run in uncontrollably apart. Power supply interruptions can also occur lead to such malfunctions. These can be particularly uncomfortable Impact errors in the meter reading if the actuating device has a Clamping protection in the form of a clamping force limit, which is included in the Stel immediately before moving the movable part into a seal (e.g. with a window pane) must be kept in order to complete the enable the necessary high actuating force. Due to a deficit in the count, the protective mechanism is now triggered unintentionally, whereby  the movable part would no longer be closed. When using a absolute actual value transmitter, such as a potentiometer, there is the difficulty the entire adjustment range of the potentiometer by means of a positive Ver to map the binding (gearbox) with sufficient accuracy. This is without electrical / me Chanel adjustment work hardly possible.

The invention has for its object to overcome these disadvantages and specify an actuator in which the microprocessor one clear and precise information about the absolute position of the movable part les is fed.

This object is achieved by an actuating device which the in has given characteristics 1. The term "sunroof" generally understood; that is, it should have sunroofs, spoiler roofs and lifting roofs with one or more lids or lid parts as well grasp like folding roofs or combinations of such roofs.

In the actuating device according to the invention is therefore in addition to the incremental actual value encoder an absolute actual value encoder is provided which is based on the entire displacement of the movable part a signal, in particular a Pulse indicates that a certain position of the movable part, for. B. the Closed position of the sunroof is assigned. Both actual value transmitters are there when fixed by gear elements in their position to each other. The absolut te actual value transmitter can signal this immediately when reaching the predetermined Submit position. The absolute actual value transmitter can also be designed in this way be that it is at a fixed distance to either side of the particular one Position emits a signal. This signal enables the processor to Set the payment register to a value that corresponds to this position just reached speaks.

In a preferred embodiment there is the incremental actual value transmitter from a magnetic ring magnetized with multiple poles in the axial direction one or two magnetic sensors and one of the desired positions corresponding number of counts on the microprocesses sor delivers.  

The absolute actual value transmitter also advantageously consists of an axial magnet magnetized ring, but only a very limited one Has magnetic pole, while the remaining part may or may not be opposite is tized.

Further features of the invention emerge from the subclaims.

An embodiment of the actuator according to the invention is described below with reference to the drawing. Show it:

Fig. 1 is a block diagram of the control device with the electromechanical drive parts,

Fig. 2 schematically shows the graphs of the output from the incremental and absolute actual value pulses as a schematic view of the two Istwer donor,

Fig. 3 is an exploded view of the actuating device.

In Fig. 1 is referred to an electric motor 1, which acts via an image represented only in FIG. 3 worm gear 34 on a shaft 2. A toothed pinion 3 is connected in a rotationally fixed manner to this shaft and engages in two coiled cables 4 , 4 a , so-called pitch cables, which are resistant to tensile pressure. Sunroofs, today mainly designed as spoiler roofs or sliding / lifting roofs, are mostly driven by such pitch cables. The window regulators in a car door often act on the movable part via a rope drum and a smooth rope. For further consideration, however, it does not matter which means are used to apply the force to the movable part. For a better overview, the movable part, that is, the roof cover in Fig. 1 is not Darge. For a sliding-lifting roof it is characteristic that the closed position of the cover is not in an end position of the riser cable 4 , 4 a , but in an intermediate position that is not secured by any mechanical locking, but only by the standstill of the motor 1 in one position to be observed exactly is given. The end positions of the riser cables 4 , 4 a correspond on one side to the open position of the cover and on the side to the full lift position of the cover.

The setpoint of the sunroof adjustment can be preselected on a setpoint generator 5, which is designed as a potentiometer in this embodiment. The analog voltage tapped there during the preselection is fed via an A / D converter 6 to a microprocessor 7 which compares the digitized setpoint with a digital actual value which is derived from the position of the sunroof and which stops the engine 1 when the difference between the given setpoint and the position-dependent actual value has become zero.

This actual value is supplied by an incremental actual value encoder 8 , the egg NEN magnetic ring 9 with z. B. has 20 magnetic poles ( Fig. 2). The magnetic ring 9 rotates with the shaft 2 and generates pulses in magnetic sensors 10 and 10 a , which are fed to the microprocessor 7 and are counted there by means of a counting register indicated at 7 a . The sensors 10 and 10 a are arranged phase-shifted to one another and therefore supply phase-shifted pulses, from the direction of displacement of which the information about the direction of rotation of the motor 1 is obtained in a known manner.

Over the entire displacement path of the movable part, the incremental actual value transmitter 8 thus supplies a predetermined number of pulses, from the number of which the respective position of the sunroof can be recognized, in particular the two end positions (open position and unfolded position) and above all the intermediate closed position.

As already mentioned at the beginning, this is purely based on the counting of the pulse based information on the actual position of the movable part, For example, a sunroof, not reliable in practice because in Microprocessor counting errors can occur that decrease over time can add up rejections that are no longer tolerable.

This deficiency is remedied in the present case in that, in addition to the incremental actual value transmitter 8 , an absolute actual value transmitter 11 is also provided, which provides the microprocessor 7 with absolute information about the position reached at a specific position of the movable part and which counts the register 7 a Processor can reset. In the present exemplary embodiment, this absolute information is assigned to the closed position of the sunroof. This is particularly advantageous since, as already mentioned, this position must be taken particularly accurately and reliably and, on the other hand, it is the most frequently selected position, ie the position most suitable for error correction. However, it should be expressly pointed out here that this assignment is not mandatory, but can be chosen freely. The absolute information could e.g. B. also be assigned to an end position of the displacement path, it having proven practical to then select the lifting position of the roof.

The absolute encoder 11 consists of a magnetic ring 13 arranged on a toothed wheel 12 , with which a magnetic sensor 14 interacts. The magnetic ring 13 has only a narrow pole area 15 on its circumference, while the remaining part is opposite or not magnetized ( FIG. 2). The gear 12 is driven by a single-tooth gear 16 , which in turn is rotated by the shaft 2 . The arrangement shown in FIG. 1 is purely schematic in order to better illustrate the function. In the practical embodiment, this gear part can be designed completely different in construction.

In order to achieve the position determined by the setpoint generator 5 , the direction of rotation of the motor 1 can be controlled accordingly by two relays 17 and 17 a and their changeover contacts 17 ′ and 17 a ′. Depending on the kinematics of a sliding and lifting roof, it can be difficult to set a selected position of the cover precisely by the control loop and without overshoot. The relationship between the angle of rotation of shaft 2 and the cover position is strongly non-linear in the lifting area. The friction and wind forces as well as the varying vehicle electrical system voltage influence the behavior of the control loop. It is therefore advantageous to continuously adjust the engine speed by means of pulse width modulation by the processor 7 in accordance with the adjustment program. So z. B. the entry into the closed position is slowed down in order to be able to react to a possible correction of the counter reading in good time before the closed position is exceeded. The mechanics and the electrical system are relieved by a soft engine start.

A pulse width modulator 18 provided for this speed adjustment consists of a triangle generator 19 and a comparator 20 , which compares the triangular voltage with an analog voltage supplied by the processor 7 on a line 21 and controls the resulting square-wave voltage to a transistor 22 in the supply circuit of the electric motor 1 .

The mean voltage acting on the motor 1 can thus be adjusted by changing the analog voltage on the line 21 . Since processors generally have no analog outputs, this can be generated by averaging a square-wave voltage at a processor riser 25 by means of downstream integrating elements 23 and 24 . In this illustration, all aids required in practice, such as freewheels, protective circuits, etc., are omitted.

To measure the motor current, a shunt resistor 26 connected in series with the collector-emitter path of the transistor 22 and, since the motor current flows through this shunt resistor only in the switch-on phases of the transistor 22 , a sample-hold connected to the resistor 26 Scarf device 27 . From the current curve, the speed curve and the battery voltage, the processor 7 can decide whether an object is jammed or whether the movable part is stiff.

At control inputs 28 , 29 , 30 are, for example, a signal from the ignition lock to switch the entire device ready for operation, a signal from the central locking to automatically close the movable part, and a signal from the speedometer to the movable part above one Limit speed to close automatically. The processor software can be used to select the exact mode of operation. Other signals from the vehicle can also be included in the functions. A protective circuit 31 protects the processor 7 from overvoltages and interference signals from the vehicle cable set. A power supply and a so-called watch-dog for the processor are indicated as block 32 .

It has proven to be practical to trigger certain optional functions by a pushbutton 33 combined with the potentiometer 5 . For example, the central locking system can be deactivated here in order to consciously keep the roof slightly open despite the automatic door locking system.

In FIG. 2, an advantageous mapping of the signals of the incremental and absolute actual value shown another. Top 10 is of the incremental actual value sensor 8 consisting of a multi-pole magnetized ring magnet 9 and the two magnetic sensors 10, a, shown, in the direction of arrow proposed for the two illustrated by 90 electrical degrees displaced pulse trains A and B upon rotation of the Mag netrings 9, that clearly indicate the direction of rotation. Below is the absolute actual value transmitter 11 , consisting of the magnetic ring 13 with the relatively narrow, oppositely magnetized pole segment 15 and the magnetic sensor 14 , which shows a pulse C lying symmetrically to the closed position during the rotation given by the single tooth gear 16 in the direction of the arrow delivers. As soon as the absolute encoder 11 emits the rising edge C _{1 of} the pulse C , the counter reading can be checked and, if necessary, corrected, and in this example 5 half-periods have to be counted until the exact closed position is reached. The Pro 7 processor therefore has enough time to control or regulate a smooth and accurate entry into the closed position by regulating the motor voltage, even if the meter reading was wrong. The probability that an unreliably large counting error occurs on the short path from this rising edge C ₁ to the closed position is extremely low. It would be checked and corrected again the next time the roof was opened slightly in one of the possible directions. This also applies to the initial start-up from the closed position, so that any adjustment work is not necessary.

The absolute actual value transmitter can also be designed such that it delivers a single pulse edge in the closed position, as is shown in dashed lines at D in FIG. 2. This pulse shape has the advantage that it gives the processor 7 clear information even on a completely incorrect or unset counting register, on which side of the closed position the mechanism is located. However, it is disadvantageous that the counting register can only be reset when the roof is opened if the exact closed position is passed again, and that the roof is always reset when the roof is closed, so that the position could be audibly corrected occasionally.

Since permanent errors are avoided by automatically resetting the counting register, counting can be simplified in that only one magnetic sensor, e.g. B. 10 , used, and the counting direction is assumed according to the relay control.

Fig. 3 shows an embodiment of the actuator in Explosionsdar position. The motor unit consists of the motor 1 and the worm gear 34 . On the underside of this worm gear there are not visible the pinion 3 for the indirect drive of the movable part and the single-tooth gear 16 for advancing the gear 12 (teeth not drawn) and the magnetic ring 13 with the pole segment 15 . The parts 35 , 36 are fastening elements for the gear wheel 12 . The electronics unit is located in an at least partially made of plastic housing 37 , which is held on the motor unit by screwing in the eyelets 38 . The magnetic sensor 14 is fastened in the inner housing wall in such a way that it can detect the position of the magnetic ring 13 through the plastic wall of the housing 37 . The electronics are built on a circuit board 39 . On it are also the two magnetic sensors 10 and 10 a , which scan the two-pin magnetic ring 9 . This magnetic ring is brought into contact with a washer 40 on a dome 41 of the housing 37 projecting through the plate 39 , so that a small, defined distance between the sensors and the magnetic ring is maintained. The shaft 2 has at least one key surface 2 a , via which the magnetic ring 9 is mechanically coupled in a defined angular position when the electronic unit is plugged onto the motor unit. A lid 42 closes the electronics unit.

Claims (14)

1. Actuating device for electromotively movable parts of motor vehicles, in particular for window regulators and sunroofs, which are driven by a reversible electric motor in its direction of rotation; with a setpoint generator for the desired position of the movable part, with an incremental actual value generator for the actual position of the movable part, and with a microprocessor for comparing the setpoint and actual value and for executing control programs, characterized in that in addition to which in incremental actual encoder ( 8 ) there is an absolute actual value transmitter ( 11 ) which emits a signal or a signal pair when or almost when a certain position of the movable part is reached, and that the incremental and absolute actual value transmitter ( 8 , 11 ) are fixed in relation to one another by gear elements ( 2 , 16 , 12 ). 2. Actuating device according to claim 1, characterized in that the certain position of the movable part the closed position of the slide roof or window pane.   3. Actuating device according to claim 1, characterized in that the specific position of the movable part in a sliding-lifting roof is the end position of the lifting area. 4. Actuating device according to one of the preceding claims, characterized in that the absolute actual value transmitter ( 11 ) emits a signal ( C ) at a fixed distance on both sides of the specific position and the fixed distance a certain number of counts of the incremental actual value transmitter ( 8 ) assigned. 5. Actuating device according to one of the preceding claims, characterized in that the processor ( 7 ) during a closing operation by means of the counting pulses ( A , B ) emitted by the incremental actual value transmitter ( 8 ) and a current measurement calculates the current change over the path and at one steep increase in the current aborts the closing process and opens the movable part again. 6. Actuating device according to one of the preceding claims, characterized in that the processor ( 7 ) when reaching the specific position or receiving a signal from the absolute actual value transmitter ( 11 ) an incremental actual value transmitter ( 8 ) associated with the counting register ( 7 a ) puts. 7. Actuating device according to one of the preceding claims, characterized in that the processor ( 7 ) after the first start-up and an adjustment of the setpoint generator ( 5 ) automatically causes a search to the specific position and the counting register ( 7 a ) of the incremental actual value generator ( 8 ) puts. 8. Actuating device according to one of the preceding claims, characterized in that the gear elements ( 2 , 16 , 12 ) form a reduction gear, in particular a single-tooth gear, which is the absolute actual value transmitter ( 11 ) when the movable part is displaced almost over the possible adjustment path has a round run. 9. Actuating device according to one of the preceding claims, characterized by the following features:

• a) the incremental actual value transmitter ( 8 ) consists of a magnet ring ( 9 ) magnetized with multiple poles in the axial direction, to which at least one magnetic sensor ( 10 , 10 a ) is assigned,
• b) the absolute actual value transmitter ( 11 ) consists of an axially magnetized magnetic ring ( 13 ) with a narrow, magnetically opposed segment ( 15 ) to which a magnetic sensor ( 14 ) is assigned, which determines the specific position of the movable part or the fixed distance from it certain position by a signal.

10. Actuating device according to claim 9, characterized in that the magnetic sensors ( 10 , 10 a , 14 ) of the actual value transmitter ( 8 , 11 ) are within a housing ( 37 ) enclosing the electronics unit and the parts are spatially arranged so that after Assembly of motor unit and electronics unit of at least one of the magnetic sensors of one of the magnetic rings ( 9 , 13 ) can be activated through the housing wall. 11. Actuating device according to claim 10, characterized in that at least one of the magnetic rings ( 9 , 13 ) is located within the housing ( 37 ) and after assembly of the motor unit and Elektronikein unit a positive connection between this magnetic ring and a drive shaft ( 2 ) Motor unit is manufactured. 12. Actuating device according to one of the preceding claims, characterized in that the processor ( 7 ) acts on a transistor actuator ( 22 ) assigned to the drive motor ( 1 ) via a pulse width modulator ( 18 ) in order to start and stop the drive motor smoothly and the Infinitely variable engine speed. 13. Actuating device according to claim 12, characterized by a sample-hold device ( 27 ) for detecting the pulsed motor current. 14. Actuating device according to one of the preceding claims, there characterized in that the motor current regardless of the operating condition stand and the vehicle electrical system voltage is limited to a maximum value.