DE3612620C1 - Circuit arrangement with a drive motor - Google Patents

Abstract

A circuit arrangement with a drive motor, in particular a windscreen wiper motor is described, in which a switching element which can be operated in a specific rotary angle position triggers switching signals from which control signals are to be derived in a delayed fashion in a program generator for the purpose of switching on and off a further load. So that these control signals are triggered as exactly as possible at predetermined times even under different operating conditions, the delay times between the switching signal and the switch-on control signal and/or the pulse duration of this switch-on control signal are dependent on the rpm of the drive motor.

Description

The invention relates to a switching arrangement with a drive motor according to the features of the preamble of claim 1.

A switching arrangement of this type for a window cleaning system Motor vehicles are known from DE-OS 22 62 692. The electric one The drive motor for a wiper operates at the end of each Wipe cycle a parking position switch, the switching signal one Programmer is fed. This programmer includes one Delay stage that is triggered by this switching signal. After expiration the delay time of this delay stage becomes another timer triggered that then a consumer for a predetermined period of time, namely turns on the wash pump motor of a car wash. This The programmer triggers control signals for switching on and off with a time delay of this additional consumer, who is thus assigned to Angular position of the wiper is switched on or off. With a Such a switching arrangement is intended to ensure optimal wetting of the parts to be cleaned Washer can be guaranteed with a minimum of washing liquid.

In practice, however, it has been found that this goal with the known switching arrangement is not solved in a fully satisfactory manner becomes. With such a pure time control, the switching points can namely to switch the washing system on and off with the required Accuracy can be adapted to different operating conditions. These Compared to the likewise known designs, the switching arrangement where the washing system is operated by contacts operated by an electric motor Switch disc can be controlled directly, i.e. depending on the angle of rotation, disadvantages on. On the other hand, the system can be easily changed by changing the Delay time or the activation time of the timer different systems can be adapted while the other is known Execution each time the switching disc must be changed.

The present invention is therefore based on the object To improve the switching arrangement of the first-mentioned embodiment in such a way that it as far as possible with the accuracy of the switching points with the  in itself better, but more expensive second-mentioned version agrees.

This object is achieved with the characterizing features of Claim 1 solved. The invention is based on the idea that one can adjust the switching points to the operating conditions of a wiper system, if one when determining the delay time and / or the Activation time the speed of the drive motor, especially the Period of a wiping cycle taken into account. So while at the known execution fixed these times for a particular wiper system are specified, these times should be in the embodiment according to the invention depending on the speed of the drive motor or the wiping speed can be varied. The switching points for switching the washing system on and off then agree much better with the switching points in the known angle-dependent control.

The invention is illustrated below with reference to the drawing Embodiment explained in more detail. It shows

Fig. 1 is a view of a wiping field and

Fig. 2 is a schematic diagram of a switching arrangement, data bus lines are sometimes only shown as individual lines for reasons of clarity.

In Fig. 1, a wiper system is shown schematically, to which a windshield wiper 10 belongs, which is driven in a known manner via a crank mechanism 11 by an electric drive motor 12 . When the crank 13 of this crank drive rotates through 360 °, the windshield wiper 10 is moved from the rest position R shown into its reversed position U and back to the rest position R over the windshield to be cleaned. In Fig. 1 further comprises a water box 15 is indicated in the central region of the swept by the wiper 10 wiper field 16. This water field 15 is wetted by a windshield washer during operation. In this case, washing water should only be sprayed onto the windshield when the windshield wiper 10 moves between 0 ° and 70 ° in the wiping field area during the advance. During the return, water should also be sprayed onto this water field 15 , but only if the windshield wiper 10 is in the wiping field region between 180 ° and 250 °. It is easy to see that in the known design mentioned at the outset, with a pure time control of the switching points of the washing system, these requirements cannot be met under all operating conditions. In the case of a relatively wet windshield, the windshield wiper will already reach or even run over the water field 15 within a predetermined period of time, so that in this case the entire amount of wash water is not used for cleaning. In the case of a dry windscreen, it can happen that the wash water sprayed onto the water field 15 has already run out before the windshield wiper 10 runs into the water field 15 in the angular range between 70 ° and 110 °. This disadvantage is avoided with the switching arrangement according to the invention, the principle of which is shown in FIG. 2.

In FIG. 2, 20 denotes a parking position switch assigned to the wiper motor 12 in a known manner, which serves as a switching element and triggers a switching signal in the park or rest position of the windshield wiper. This switching signal is fed to a program generator, which triggers control signals for switching on and off a further consumer, namely a washing pump 30 , with a time delay. This washing pump 30 is actuated with the washer switch 31 switched on via the relay 32 , which is connected to the output 33 of the programmer.

A counter 41 , to which clock pulses from an oscillator 42 are supplied, belongs to the programmer, which is denoted overall by 40 . In addition, the switch signal of the parking position switch 20 is supplied to this counter 41 . When the parking position switch 20 is closed, the counter 41 is reset. Outside the park position of the windshield wiper 10 , this park position switch 20 is open and the counter 41 can count the clock pulses of the oscillator 42 . At the end of each wiping cycle, the counter reading of this counter 41 is fed to a divider 61 via a gate circuit designated 50 in total. The gate circuit includes two controllable gate circuits 51, 52 which are connected directly or via an inverter 53 to the output of a monostable multivibrator 54 which can be triggered via the operating switch 55 , for example the ignition starter switch of a motor vehicle. In the illustrated switching position of this ignition starter switch 55 , the gate circuit 52 is permeable, so that the counter reading of the counter 41 is fed via this gate circuit 52 and a further gate circuit 56 to the divider 61 of an arithmetic unit, designated overall by 60 , to which four multipliers 62, 63 , 64 and 65 belong. This divider 61 may divide the counter reading of the counter 41 by 360. In this case, the multiplier stages are designed such that in the multiplier stage 62 the result of the divider 61 is multiplied by 0, in the multiplier stage 63 by 70, in the multiplier stage 64 by 180 and in the multiplier stage 65 by 250. These multipliers correspond to the angular positions in angular degrees shown in FIG. 1. At the output of these multiplier stages, there is then a numerical value which depends on the count of counter 41 at the end of each measuring cycle or wiping cycle. If the windshield wiper moves relatively slowly when the windshield is dry, these numerical values are large because the counter reading in counter 41 is also large. In contrast, in the case of a windscreen wiper that runs relatively fast when the windscreen is wet, these numerical values at the outputs of the multiplier stages are smaller.

The output signals of these multiplier stages 62 to 65 are each fed to an associated comparator 72 to 75 , which compares these numerical values of the multiplier stages with the current counter reading of the counter 41 . The comparators 72 to 75 each trigger a switching signal if the two values to be compared match. The switching signal of the comparator 72 is fed to the set input of a memory 80 , the reset input of which is connected to the output of the comparator 73 . Accordingly, the set input of a second memory 81 is connected to the output of the comparator 74 , while the output of the comparator 75 is connected to the reset input of this memory 81 . The output signals of these two memories 80 and 81 are linked to one another via an OR gate 82 and fed to the output 33 of the program generator for controlling the relay 32 .

This results in the following control sequence, whereby it is initially assumed that certain numerical values can be measured at the output of the multiplier stages 62 to 65 :

When the windshield wiper comes into its park or rest position, the counter 41 is reset so that the comparator 72 determines that its two comparison values match and thus sets the memory 80 . The relay 32 is switched on via the OR gate 82 , provided that the washer switch 31 is actuated and thus activates the washer system via the pump 30 . If the windshield wiper now moves out of the park position, the counter reading of the counter 41 is continuously increased until finally a counter reading is obtained which corresponds to the numerical value at the output of the multiplier stage 63 . The comparator 73 then triggers a switching signal and resets the memory 80 , as a result of which the pump 30 is switched off again. As the windshield wiper moves further, the counter 41 finally reaches a level which corresponds to the numerical value at the output of the multiplier stage 64 . The comparator 74 then sets the memory 81 and, as a result, the pump 30 is switched on again. Finally, the counter 41 reaches a value when the windshield wiper returns, which corresponds to the numerical value of the multiplier stage 65 . The memory 81 is then reset via the comparator 75 and the pump 30 is thus switched off again. At the end of this wiping cycle, the maximum counter reading of the counter 41 is fed to the divider 61 of the arithmetic unit 60 by trigger signals (not shown in more detail), which calculates new numerical values in the multiplier stages, which represent the time-dependent points in time for switching the pump 30 on and off in the following wiping cycle .

Overall, it can be seen that the programmer 40 evaluates the speed of the drive motor 12 for the windshield wiper, because the counter reading in the counter 41 is a measure of the speed or a measure of the duration of a wiping cycle. The delay times between the switching signal of the parking position switch 20 and the switch-on control signal provided by the memories 80 or 81 for the further consumer 30 and also the pulse duration of this switch-on control signal depend on the speed of the motor 12 , because the numerical values at the output of the multiplier stages via the arithmetic logic unit 60 are derived from the speed-dependent counter reading of the counter 41 . The delay time between the switching signal of the parking position switch 20 and the first switching on of the pump 30 is 0 and the pulse duration of this first switching-on control signal depends on the numerical value at the output of the multiplier stage 63 . The delay time between the switching signal of the parking position switch 20 and the second switch-on of the pump 30 depends on the numerical value at the output of the multiplier stage 64 , while the pulse duration of this second switch-on control signal depends on the difference between the numerical values at the output of the multiplier stages 65 and 64 .

Since the numerical values at the outputs of the multiplier stages are not defined when the entire switching arrangement is switched on for the first time, the arithmetic logic unit 60 must be given a specific counter reading which should correspond to an average speed of the drive motor 12 or an average wiping speed. This is realized via the gate circuit 50 , because when the ignition starter switch 55 is switched on, the monostable multivibrator 54 is triggered, which then briefly blocks the gate circuit 52 , but instead activates the gate circuit 51 . Then values from a read-only memory 85 are fed to the divider 61 . If the wiper system is now switched on, the switching points initially depend on this default value, which cannot correspond exactly to the operating conditions. When wiping for the first time, an optimal cleaning result will not be achieved in some cases, but after this first wiping cycle the counter reading supplied to the divider 61 is changed in accordance with the operating conditions present, so that an improved cleaning effect can be expected in the subsequent wiping cycle.

Such a switching arrangement can easily be adapted to different wiping systems. By changing the multipliers of the individual multiplier stages and the divisor of the divider 61 , the switching points can be individually adapted to a specific wiper system. This is particularly simple if the functions of all of these components are implemented by a microprocessor circuit, because then only the program of the respective wiper system or the wiping angles of this wiper system need to be adapted.

The invention was explained on the basis of an exemplary embodiment relates to a window cleaning system of a motor vehicle. It will however, finally pointed out that the basic idea always with  Advantage can be used when it comes from a switching signal one of a switching element operated by a motor control signals for others Derive consumers and no complicated and therefore more expensive Switch disks should be used, but you still value one Setting the switching points as precisely as possible, even with different ones Operating conditions.

Claims (7)

1. Switching arrangement with a drive motor with a switchable in a certain angular position switching element, the switching signal is fed to a programmer that triggers control signals for switching on and off another consumer, characterized in that the programmer ( 40 ) directly or indirectly also the speed evaluates the drive motor ( 12 ) and that the delay time between the switching signal and the switch-on control signal and / or the pulse duration of this switch-on control signal for the further consumer ( 30 ) depends on the speed of the drive motor ( 12 ). 2. Switching arrangement according to claim 1, characterized in that for detecting the speed of the drive motor ( 12 ) of the programmer ( 40 ) has a counter ( 41 ) which, during a measurement time between two successive switching signals of the switching element ( 20 ), the clock pulses of an oscillator ( 42 ) counts that numerical values are derived from the counter reading of this counter ( 41 ) at the end of a measuring cycle in an arithmetic unit ( 60 ), which are continuously compared with the counter reading of the counter ( 41 ) during the following measuring cycle and that if the counter reading of the Counter ( 41 ) with the numerical values control signals for switching the additional consumer ( 30 ) on or off. 3. Switching arrangement according to claim 1 or 2, characterized in that, when the programmer ( 40 ) is switched on, the arithmetic logic unit ( 60 ) is given a specific counter reading, which is changed during operation of the drive motor ( 12 ) depending on its speed. 4. Switching arrangement according to at least one of the preceding claims, characterized in that the drive motor ( 12 ) is an electric motor for driving a windshield wiper ( 10 ) of a windshield wiper system in motor vehicles, that this electric motor ( 12 ) has a parking position switch ( 20 ) is actuated as a switching element and that the time span between two successive switching signals of this parking position switch ( 20 ) is detected and evaluated to determine the delay time between the switching signal and the switch-on control signal and / or to determine the pulse duration of this switch-on control signal. 5. Switching arrangement according to claim 4, characterized in that the counter ( 41 ) in the rest position of the windshield wiper ( 10 ) is reset via the parking position switch. 6. Switching arrangement according to at least one of the preceding claims, characterized in that the further consumer is the pump ( 30 ) of a windshield wiper system and that this windshield wiper system is optionally switched on and off several times during a wiping cycle such that the washing water in the direction of movement in front of the windshield wiper ( 10 ) is sprayed onto the disc. 7. Switching arrangement according to at least one of the preceding claims, characterized in that the programmer as an integrated module, is designed in particular as a microprocessor.