DE2255264A1 - Windscreen wiper sensors for automatic operation - have gradually increase-ing distance to match wiping frequency to rain fall - Google Patents

Abstract

A moisture sensor to record rain or fog or to operate windscreen wipers on cars automatically uses 2 sensors which have a high resistance between them when dry. The presence of moisture provides a path and the leakage current is amplified to actuate a relay. To be able to operate a windscreen wiper at a speed proportional to the amt. of rainfall, the 2 sensors have a gradually increasing distance from each other, each section controlling the wiper motor at a different speed.

Description

"Electronic sensor for electrically conductive substances" The invention relates to an electronic sensor for electrically conductive substances, preferably Rainwater, with at least two spaced apart, between them exhibiting a high electrical resistance, exposing the conductive substance exposed bare electrical conductors as sensor elements that are part of a, corresponding electrical circuit when reducing the resistance between give them a control signal.

It is already known to use such a sensor for switching on or off.

Turning off a wiper to use. There is the Sensor made of an insulated carrier that has two interlocked conductor fields that are isolated from one another having. The resistance between the two fields is very high when dry high.

If the sensor becomes damp from rain, snow or fog, the Resistance strongly decreases. This change in resistance is converted into a signal, e.g. into a Voltage converted to a relay too switch. The signal itself is generated in a converter, which has a relay control part and the relay itself are connected downstream, whereby the normally open contact of the relay is parallel to the e.g. in a vehicle built-in wiper switch (see article in t'Elektor ", Marz 1972, pages 338 to 339).

This sensor is only intended to and also from the outset only suitable for the meteorological information "rain" or "no rain" to only convert a corresponding electrical signal to switch on or off effect of the windshield wiper. The strength of the rain is not taken into account.

In addition, the sensor cannot differentiate between rain and fog. However, every motorist knows the need to constantly adjust the wiper performance to have to adapt to the respective jetter conditions. For example, actuation is sufficient in fog of the windshield wiper at relatively large intervals, while with strong Rain a high cleaning frequency is desirable.

The invention is based on the object of the known sensor to improve so that it not only indicates the presence or absence of a conductive substance can report, but also depending on the density this substance can give off signals.

This object is achieved according to the invention in that the distance and thus the electrical resistance between the two sensor elements via the Length of the measuring section increases. The opposing sensor elements be divided into separate measuring ranges. Are just a few of the ones to be measured Substance particles, e.g. water droplets or certain Dust particles, is only present at the narrowest point between the two sensor elements an electrical connection can be established. The characteristic change in resistance for this of the sensor is converted into a corresponding signal that is used for control It is particularly useful to use the new sensor as a control element for the speed bnd / or interval time of a windshield wiper. The sensor could be installed at a suitable location on the front of a vehicle, whereby then with the electrical signals that correspond to the respective changes in resistance, the wiper not only switched on and off, but especially in his Wiper frequency is controlled in adaptation to the respective weather conditions The driver is no longer affected by the constant use of the windshield wiper diverted. This relief represents a significant improvement in road safety represent.

The sensor can be concealed from a head in a manner known per se Pertinax, epoxy or the like exist that isolate two from each other, having interlocked conductor fields, the respective distance between the conductor fields increases from a minimum to a maximum value.

When used as a control for a windshield wiper be available the two sensor elements preferably consist of at least two upright bare ones 9 i.e. non-isolated Meta'7 "bars, strips or the like, their distance from one another can increase from top to bottom. This enables a quick replacement of e.g. a liquid substance reached so that the sensor on situation changes quickly can react. The metal rods or the like can be displaced relative to one another be to the set the required sensitivity to can.

Especially when used as a control element for a windshield wiper It is also particularly advantageous if the metal rods or the like. At a distance are arranged in front of their holder.

This results in constant self-cleaning of the sensor rods the driving air, so that the sensor is immediately put back into the state changes of state to eat. In addition, there can only be a change in resistance between the two rods caused by moisture contained in the air, while at Use of two conductor fields that are provided on an insulating support moisture that is deposited on the wearer over a period of time that may be too long a reduction in resistance and thus a loading of the log wiper even after the rain has stopped.

To prevent snow or the like from settling on the sensor rods to avoid it, a direct or indirect heating of the metal rods can be expedient provided, e.g. by warm air.

In itself it is desirable, even after the sudden end of rain let the windshield wipers run a few more bars to get the ones on the windshield to remove any remaining moisture. A switch-off delay is therefore desirable. This can be achieved, for example, by a drop of water running off decelerating roughening of the surface of the metal rods or the like Stop the rain in the narrowest gap between the sensor elements Drops under the influence of their gravity do not abruptly on the smooth metal rods downwards. The braking ensures that the windshield wiper continues to run the The way in which the new sensor works can still be seen. refine through several, fan-like arranged and mutually adjustable metal rods, strips or the like.

If the sensor is used in motor vehicles, it is useful to Provide lateral shields to prevent unwanted interference by others Prevent vehicles.

About the flow rate of the liquid on the sensor elements and thus to be able to change their response time, it is advantageous if the sensor elements arranged pivotably with respect to the direction of flow of the substance to be measured are.

Depending on the position, e.g. the airflow then drives the raindrops against it the narrowest point of the sensor, or it presses the. Liquid from the closest Sensor point out. In the latter case, for example, when the rain stops, an immediate Switch off. the windshield wiper.

In particular when measuring fog or the like, in addition to the Sensor elements can be arranged baffles that collect the substance to be measured and to the narrowest measuring point between the sensor elements. To the impeccable Catching the mist, collecting the moisture and condensing it, e forwarding it To ensure that the guide plates are appropriately designed to be approximately wedge-shaped, have a raised edge on their long sides and end with theirs. top directly next to the narrowest measuring point between the sensor elements. Such a one Awordaung can advantageously be designed as a switchable fine sensor, which z..B. only at. Fog: connected in addition to a sensor of the type described above will.

In the drawing are some exemplary embodiments of the invention shown. 1 shows a schematic representation of a Sensor made up of two interlocking conductor fields; Figure 2 also in schematic Representation of a sensor made of two metal rods; Figure 3 in an enlarged view a top view of a sensor element with a roughened surface; Figure 4 # a sensor made of several metal rods arranged like a fan; Figure 5 shows a sensor with a wedge shape trained baffles; FIG. 6 shows a circuit for the step control of a windshield wiper motor; Figure 7 shows a circuit according to Figure 6 with relay for a three-stage Sensor and FIG. 8 a circuit for regulating the speed of a windshield wiper motor.

The sensor shown in Figure 1 consists of a copper cladding Pertinax carrier 1, the two insulated, interlocked conductor fields 2 has. The respective Distance a between the conductor fields takes from a minimum to a maximum value.

In the case of your sensor according to FIG. 2, the two sensor elements consist of two standing bare metal rods 3, whose ab stood from each other by increases from top to bottom. The metal rods 3 are at a distance in front of their holder 4 and can, according to FIG Have roughening 5.

A sensor according to Figure 4 consists of several, fan-like arranged and mutually adjustable metal rods 3.

In the embodiment of FIG. 5, in addition to the two sensor elements Arranged guide plates 6, which are wedge-shaped, one on their long sides have upstanding edge 7 and with its tip 8 directly next to the narrowest measuring point 9 end between the sensor elements. The baffles 6 can, if the sensor is e.g. to control a windshield wiper is used, opposite the direction of the wind be pivoted up about its longitudinal axis. -In addition, this sensor can do the same like the construction shown in Figure 2 about its transverse axis 10 in or against the Direction of travel can be pivoted.

Finally, the sensor according to Figure 5 in combination with a Sensor according to FIG. 2 can be used as a fine sensor. FIG. 6 shows a circuit for step control of a windshield wiper motor. The one acting on the sensor Rain changes the sensor conductivity according to the amount of rain0 The transistor Tr 1 amplifies the electrical signal coming from the sensor. If the Set on controller P 1 Threshold is through the transistors Tr 2, Tr 3 and Tr 4 give the switching signal to stage 1 of the motor. The motor now runs at slow speed or Sn intervals.

As the conductivity of the sensor increases, the value that can be set by P 2 becomes Threshold reached and through the transistors Tr 5, Tr 6 and Tr 7 the switching signal given to stage 2 of the engine. At the same time, the switching signal for level 1 repealed. The engine now runs at medium speed.

When the sensor is fully leak-proof, the value that can be set with P 3 becomes Threshold exceeded and the transistors Tr 8, Tr 9 and Tr 10 conduct the switching signal to level 3 of the engine, which is now running at full speed. The switching signals for levels 1 and 2 are canceled. When the conductivity decreases again, level 3 is blocked again and level 2 is switched on.

IQi further decrease in the sensor conductivity will also increase the levels 2 and 1 switched off.

The circuit according to FIG. 7 has an analogous structure. Here, however, takes place a three-stage sensor use, with the first stage e.g. by a sensor can be formed according to FIG. 5, while stages 2 and 3 from a sensor according to Fig. 2 exist, the metal rods 3 then being halved by a separation insulation are.

FIG. 8 shows a circuit for the speed control of a Wiper motor. The amount of rain that hits the sensor becomes formation an electrical signal is used. Drops of water bridge the gaps the sensor contact surfaces and cause electrical conductivity, accordingly the droplet size and quantity. In the postponed Transistor DC amplifier the adaptation takes place, to the power requirement of the wiper motor. Low conductivity of the sensor, caused by a small amount of rain, also controls the wiper motor reduced speed; strong conductivity, brought about by large amounts of rain, lets the wiper motor run at full speed.

The controller P 1 is used to set the optimum sensitivity.

Claims (14)

Claims 1 electronic sensor for electrically conductive substances, preferably Rainwater, with at least two spaced apart, between them having a high electrical resistance, the conductive substance free exposed bare electrical conductors as sensor elements that are part of a corresponding electrical circuit when reducing the resistance between give them a control signal that the Distance (a) and thus the electrical resistance between the two sensor elements (2,3) increases over the length of the measuring section. 2. Sensor according to claim 1, g e k e n n z e i c h n e t by his Use as a control for the speed and / or interval time of a Wipers. 3. Sensor according to claim 1 or 2, d a d u r c h g e k e n n -z e i c h n e t that he made a copper-clad Pertinax, Epoxy carrier (1) or the like consists of the two isolated from each other, with each other has toothed conductor fields (2), the respective distance (a) between the Conductor fields increases from a minimum to a maximum value. 4. Sensor according to claim 1 or 2, d a d u r c h g e k e nnz e i c h n e t that the two conductors forming the sensor elements are made up of at least two arranged bare metal rods (3), strips or the like. 5. Sensor according to claim 4, d & a d u r c h g e k e n n -z e i c h n e t that the distance (a) between the two metal rods (3), strips o, the like. Increases from top to bottom. 6. Sensor according to claim 4 or 5, d a d u r c h g e k e n n -z e i c h n e t that the butcher bars (3), strips or the like. are mutually displaceable. 7. Sensor according to claim 4, 5 or 6, d a d u r c h ge -k e n n z E i c h n e t that the metal rods (3), strip or the like. At a distance from their Bracket are arranged. 8. Sensor according to one of claims 4, 5, 6 or 7, g e k e n nz e i c h n e t by direct or indirect heating of the metal rods (3), strips o. the like. 9. Sensor according to one of the requirements 4 to 8, g e k e n n -z e i c h n e t due to a roughening that slows down the run-off of a water droplet (5) the surface of the metal rods (3), strips or the like. 10. Sensor according to one of claims 4 to 9 ,, g e k e n n -z e i c h n e t by means of several metal rods arranged in a fan-like manner and mutually adjustable (3), strips or the like. 11. Sensor according to one of claims 4 to 10, d a d u-r c h g e k It is noted that the sensor elements (2, 3) are opposite to the direction of flow the substance to be measured are arranged to be pivotable. 12. Sensor according to one of claims 4 to 11, g e k e n n -z e i c h n e t through baffles (6) arranged next to the sensor elements (3), which the Catch the substance to be measured and the narrowest measuring point (9) between the sensor elements respectively. 13. Sensor according to claim 12, d a d u r c h g e k e n n -z e i c h n e t that the guide plates (6) are approximately wedge-shaped, on their Lingsseiten have an upstanding edge (7) and with its tip (8) directly next to the the narrowest measuring point (9) between the sensor elements (3). 14. Sensor according to claim 12 or 13, d a d u r c h g e k e n n -z ei c h n e t that the sensor elements (3) equipped with the guide plates (6) as switchable fine sensor are formed. Blank page