DE2510885B2 - SENSOR FOR CONTROLLING A WIPER MOTOR - Google Patents

Description

turned out to be unusable, since the wind pushes the water droplets against the Pertinax carrier, so that this is ultimately covered with a thin film of moisture. This becomes under the airstream too held for a long time on the carrier and thus gives an undesirably long control signal for actuating the Wiper motor. On the other hand, the wind pushes in the free distance in front of their wearer arranged sensor elements, the water droplets at least to a large extent from the measuring section ίο out. The latter is therefore constantly exposed to newly introduced water droplets and, if the Precipitation ceases, largely cleaned of the adhering moisture

The sensor according to the invention can be further improved in that the strip-shaped sensor element on its longitudinal edge adjacent to the comb teeth downward and rearward in the form of a cutting edge is sharpened. It is also possible that the strip-shaped sensor element in addition to its lower Sharpening on its upper longitudinal edge has an upward and rearward bevel bevel. This allows the moisture hitting the sensor to be split up into moisture that flows downwards and proportion used for contact measurement as well as in flowing water discharged upwards. Besides, it will this makes it possible to make the strip-shaped sensor element wider and thus more stable.

If the sensor elements are in vertical planes, it is advantageous if the lower sensor element is opposite the upper sensor element approximated to the rear by the material thickness of the comb teeth is arranged. This ensures that the water droplets caught by the upper sensor element due to their own weight and possibly also under the influence of the airstream over the lower sharpening of the strip-shaped sensor element on the tips of the upward Comb teeth of the lower sensor element are derived.

The free end of each comb tooth can be sharpened in the shape of a cutting edge on its rear side. The water drop picked up by the upper sensor element is then split up by the cutting edge, so that the greater surface wetting achieved in this way together with the associated greater adhesive force an accelerated removal of the water droplet from the measuring section is achieved. The aerodynamic conditions can be improved by the fact that the free end of each Comb tooth has a lateral bevel running downwards and backwards from the tip in front having.

The comb teeth can be at an angle with respect to the perpendicular within the range determined by the sensor elements formed plane be arranged inclined. This allows the side chamfering of the comb teeth enlarge.

The sensor elements be pivotable within a perpendicular plane and / or out of this plane.

In an advantageous embodiment, a sensor with a small electrode spacing can be a sensor be electrically connected upstream with a larger electrode spacing. The sensor is used with the minor Electrode spacing for measuring fog and light rain, while larger drops are used heavy rain on the electrodes of the other sensor cause an electrical resistance that is lower is than the resistance at the upstream sensor. The sensor with the larger Electrode spacing have two perpendicular, horizontally spaced electrodes.

To prevent ice formation on the sensor elements, electrical heating of the sensor elements can be used are provided. A further improvement of the new sensor can be achieved by a Block time securing electrical circuit in such a way that a single output control signal a certain Number of windshield wiper movements This results in a sufficiently long windshield wiper activity also ensured if there is only a single application of the sensor, z. B. at a quick overtaking maneuver on a damp road.

Finally, the new sensor can also be improved by the fact that an output from the sensor Control signal is also applied to a windscreen washer system at the same time

In a perfect embodiment, a continuously heated sensor can have an additional, intermittent Heatable sensor for ice reporting can be switched on via an electronic control circuit comparative measurement of the two sensors.

An exemplary embodiment of the invention is shown in the drawing. It shows

F i g. 1 shows a sensor in a front view;

F i g. 2 shows a section along the line A -A in FIG. 1,

3 in an enlarged representation in front view a comb tooth in a modified embodiment,

F i g. 4 shows the representation according to FIG. 3 in rear view and

Fig. 5 is a block diagram of a windshield wiper and windshield washer controls.

According to this, the illustrated electronic sensor consists of an upper, horizontally arranged strip-shaped Sensor element 1, which is assigned a lower, comb-like sensor element 2, whose upwardly directed comb teeth 3 each terminate in a point. The sensor shown has four such sensor units I, the two left units I with the two right units I a Form a flat "V" from which FIG. Figure 1 shows a top view. These sensor units with relatively If the electrode spacing is small, a sensor II with a larger electrode spacing is electrically connected upstream. The latter consists of two perpendicular, horizontally spaced electrodes 4, the could also be arranged horizontally per se.

The in F i g. 1 shown sensor can with its nut 5 on a not shown Plug connection are attached to the front of a motor vehicle.

F i g. 2 shows that the strip-shaped sensor element 2 is adjacent to the comb teeth 3 Longitudinal edge 6 is sharpened blade-shaped downwards and backwards. Since at the same time the lower sensor element 2 with respect to the upper sensor element 1 offset to the rear by the material thickness of the comb teeth 3 is arranged, water droplets are from the sharpened longitudinal edge 6 directly on the tips of the Comb teeth 3 derived.

The free end of each comb tooth 3 is sharpened in the shape of a cutting edge on its rear side and shows a lateral tip from the front

chamfer 7 running at the bottom and at the rear, which takes into account the aerodynamic conditions. aside from that are in a modification of the representation according to FIG. 1 the comb teeth shown in Figures 3 and 4 with respect to the perpendicular by an angle within the plane formed by the sensor elements 2 arranged inclined. This inclination would run in the two right units I to the right and the two other units to the left.

F i g. 5 shows a basic circuit diagram of a windshield wiper and windshield washer control. Even a single, very small drop of water with a dwell time of only a few microseconds between the sensor elements I ₁ 2 leads to an electrical voltage jump that passes through a DC voltage amplifier and a pulse amplifier. A time cycle is started by the latter, which is determined by a preselected block time of z. B. 1 to 4 see controls a relay amplifier for a water pump and puts a windshield washer in operation. The block time of the time circuit is simultaneously fed to a storage circuit, in which it is extended by several seconds and used to control a relay amplifier stage 1 and a changeover relay.

The windshield wiper, not shown, now runs at level 1 over the preselected block time plus the Extension generated by the storage circuit over a period of several seconds. This will ensures that the vehicle window is clean and dry.

If another drop of liquid hits the measuring section in the storage circuit during the extension period of the sensor, then the entire cycle including the block time and extension is repeated started. In the block diagram shown, an additional manual control is provided with which

30th

35 a cycle can also be called up if additional cleaning of the window is desired.

When it rains, the raindrops that hit the ground close together cause the voltage to jump in the DC voltage amplifier as a DC voltage signal and the relay amplifier for stage 1 and the Switching relay controls and the windshield wiper motor, not shown, with correspondingly slower Speed starts. If it rains heavily, a relay amplifier stage 2 as well as the Switching relay controlled so that the windshield wiper motor is then at a correspondingly greater speed runs. Further stages can be provided in an appropriate design.

If two sensors are provided, a comparative measurement on the two sensors will result in one Ice message possible as frozen water increases its electrical resistance. For this purpose the reference sensor is provided with permanent heating so that no ice formation is possible here and the through The electrical resistance caused by drops of water remains correspondingly low Counter sensor ice, this creates a correspondingly higher electrical resistance. In an electronic view Control circuit can produce different electrical signals at the two sensors Resistors to switching functions for signal lamps and an intermittent heating for the Opposite sensor are converted. If ice forms on the opposing sensor, the intermittent working heating of this sensor can be switched on to thaw the ice that has formed. At through that Thawing due to a drop in electrical resistance, the heating of the counter sensor is restored switched off

For this 2 biatt drawings

5

Claims (11)

Patent claims: 1. Electronic sensor for electrically conductive deposits for controlling a windshield wiper motor, consisting of at least two at a distance from each other and free in front of their holder arranged bare electrical conductors exposed to the conductive precipitate as Sensor elements that form part of a corresponding electrical circuit when the resistance changes emit a control signal between them, characterized in that at least one upper, approximately horizontally arranged strip-shaped sensor element (1) is assigned a lower, comb-like sensor element (2) is, whose upwardly directed comb teeth (3) each in a tip with tapering Run out cross-section. 2. Sensor according to claim 1, characterized in that the strip-shaped sensor element (1) on its longitudinal edge (6) adjacent to the comb teeth (3) downward and rearward in the shape of a cutting edge is sharpened. 3. Sensor according to claim 2, characterized in that the strip-shaped sensor element (1) on its upper longitudinal edge has a bevel (8) directed upwards and backwards. 4. Sensor according to claim 1, 2 or 3, characterized in that the lower sensor element (2) compared to the upper sensor element (1) approximated by the material thickness of the comb teeth (3) is arranged offset to the rear. 5. Sensor according to one of the preceding claims, characterized in that the free The end of each comb tooth (3) is sharpened in the shape of a cutting edge on its rear side. 6. Sensor according to one of the preceding claims, characterized in that the free End of each comb tooth (3) a lateral, from the front tip downwards and backwards having running chamfer (7). 7. Sensor according to one of the preceding claims, characterized in that the comb teeth (3) with respect to the perpendicular by an angle («) within the through the sensor elements (2) formed plane are arranged inclined. 8. Sensor according to one of the preceding claims, characterized in that the sensor elements (1,2) can be pivoted within a vertical plane and / or out of this plane are. 9. Sensor according to one of the preceding claims, characterized in that a sensor (I) a sensor with a small electrode gap (II) is electrically connected upstream with a larger electrode spacing. 10. Sensor according to claim 9, characterized in that that the sensor (II) with the larger electrode spacing two vertical, with horizontal Having electrodes (4) arranged at a distance from one another. 11. Sensor according to one of the preceding claims, characterized by an electrical one Heating of the sensor elements (1,2). The invention relates to an electronic sensor for electrically conductive deposits for controlling a Wiper motor, consisting of at least two at a distance from each other and free in front of their holder arranged bare electrical conductors exposed to the conductive precipitate as sensor elements, as part of a corresponding electrical circuit when changing the resistance between give them a control signal. Such a sensor can be shown in FIG. 2 and 4 of the Take DT-OS 22 55 264. In this embodiment, the sensor elements consist of several, Fan-like and standing metal rods. The distance and thus the electrical resistance between the sensor elements increases over the length of the measuring section. This sensor has in principle Although it has been tried and tested, the responsiveness appears particularly in changing weather conditions not always sufficient. It could be established that the main cause for so far Unsatisfactory results can be seen in the smallest droplets that are located in the measuring section between the Fix sensor elements and, under certain circumstances, signal a weather situation over a longer period of time, which no longer corresponds to the actual circumstances. Although this problem could be fundamentally solve by increasing the distance between the electrodes, but this would reduce the sensitivity of the sensor reduced so much that the device would no longer be usable in practice. The invention is based on the object of the electronic sensor explained above with regard to to improve its response speed and responsiveness. This object is achieved according to the invention in that at least an upper, approximated horizontally arranged strip-shaped sensor element a lower, comb-like sensor element is assigned, the upwardly directed comb teeth each in a tip with tapering Run out cross-section. The tip can be needle-shaped. Each comb tooth tip forms a measuring section with the opposite strip-shaped sensor element, whereby each individual measurement triggers a specific control signal. Due to the pointed formation of the comb teeth on the one hand, a rapid drainage of the water droplets from the upper sensor element and on the other hand, a quick "transfer" of these water droplets to the lower comb teeth is achieved. The after The tip of the comb teeth protruding from the top prevents small droplets from sticking in the measuring section and thus ensures a fast response speed to changing weather conditions. The F i g. 1 of the above-mentioned DT-OS 22 55 264 shows a sensor with a copper-clad Pertinax carrier, which has two interlocked conductor fields that are isolated from one another. The respective The distance between the conductor fields increases from a minimum to a maximum value. That below Conductor field lying on the ground could be referred to as a comb-like sensor element. In contrast to however, this previously known, comb-shaped sensor element lies on the newly claimed sensor not free in front of its holder. In addition, the upwardly directed comb teeth do not each run into one Tip with a tapered cross-section. This known sensor has in practice as