DE4307479C1 - Opto-electronic sensor device detecting vehicle windscreen wetting level - uses associated heating element to aid fixing of sensor block to windscreen and thermal release from windscreen - Google Patents

Abstract

The sensor device has an associated heating element in the form of a resistance path (2) for bringing an optical light conductive block (1) to the required working temp., e.g. 30 degrees C, the light transmission of the block being dependent on the wetting level of the vehicle windscreen. The heating element has an associated regulation circuit providing overheating protection and is attached to both the front surface of the light conductive block and the surface facing the windscreen. Two discrete temp. levels can be provided after reaching th operating temp. respectively used to assist hardening of the optical adhesive used to attach the light conductive block to the windscreen and for subsequent thermal release of the adhesive to allow removal of the block from the screen. ADVANTAGE - Allows secure fixing of sensor light conductive block and subsequent release for repair or replacement.

Description

The present invention is based on one according to the preamble of the main claim designed sensor device. This can the quantitative and / or qualitative recording of on one serve a transparent disc of existing precipitation.

Such devices are particularly intended to depending on the one on the windshield Amount of precipitation to influence assigned wiper system.

DE 38 23 300 C1 is a sensor device in the Preamble of the main claim presupposed art known. With this subject one is im Radiation guide arranged metallic reflection means one consisting of a self-regulating thermistor element Heater assigned to the sensor device within a more or less short time on a certain one Temperature level z. B. from 30 degrees C and  protect against overheating at the same time. This will make one partial heating of the pane or heating of the Radiation guide for defrosting ice layers or Evaporation of removed dampening reached.

Furthermore, DE 42 02 121 C1 Sensor device became known in which in a recess of the radiation guide body, a heating device is arranged. The recess is in the middle of the rear surface of the Radiation guide. The stands over a coupling medium Heater connected to the radiation guide.

The present invention has for its object a optoelectronic sensor device of the type mentioned at the beginning to create z. B. in the event of a defect including the optical beam guide simple and can be removed from the window without being destroyed.

According to the invention the task is characterized by Part of the main claim specified features solved. An advantage of such training is that in the Attaching the optoelectronic sensor device to the Slice the optical glue to a temperature level can be heated, in which the optical adhesive best adhesive effect unfolds.

Further advantageous embodiments of the invention Subject matter are specified in the subclaims and are based on four shown in the drawing Exemplary embodiments explained in more detail. Show

Fig. 1 is a side view of an optical beam control element having formed as a resistance heating element web,

FIG. 2 shows the bottom view of the optical beam guide designed according to FIG. 1,

Fig. 3 shows the bottom view of another optical beam control with a vapor deposited or printed heating element serving as a resistance layer,

Fig. 4 is a means of resistance track frame-shaped heating element formed with introduced cross-sectional constrictions,

Fig. 5 is a side view of an optical beam control in section, wherein the heating element in a groove-like recess is provided,

Fig. 6 is a functional circuit diagram of the heating device.

As can be seen from the drawing, such an optoelectronic sensor device mainly consists of an optical radiation guide body 1 and a heating element designed as a resistance track 2 or a resistance layer 3 . For the sake of simplicity, the electrical / electronic components and the associated control device have not been shown.

As can be seen in particular from FIGS. 1 and 2, the resistance track 2 , which represents the heating element and is assigned to the optical radiation guide body 1 , consists of an almost closed frame, the frame sides of which have a flat rectangular cross section. The resistance track 2 is assigned to the front surface of the radiation guide body 1 , which faces the pane, not shown.

Over the resistive track 2 integrally molded retaining elements 4 is mounted, the heating element configured as a frame to the optical light conducting. 1 To attach the heating element, there are also at least two closely spaced notches 5 in each of the four side surfaces of the radiation guide body 1 . The heating element forming resistive track 2 with its holding portions 4 pass through these notches 5 in the manner of loops, wherein the conductor 2 with its holding parts 4 to 5 created by the notches of the lugs 9 applies beam control element. 1 The two end regions of the resistance track 2 , which represents the heating element, are angled 90 degrees out of their plane and are designed as connection contact parts 6 . Via the two connection contact parts 6 , the heating element is connected to a control device, not shown, which influences the heating power.

As can be seen in particular from FIG. 4, the heating element designed as a resistance track 2 is partially provided with cross-sectional constrictions 7 that increase the resistance value, so that a high temperature level is reached with certainty.

FIG. 5 shows an optical light conducting 1 having a groove-like recess 8. The groove-like recess 8 is circumferentially present in the edge area of the optical radiation guide body 1 in the front surface facing the pane and serves to hold the heating element formed therein as a resistance track 2 . The resistance path 2 projects with its surface facing the pane slightly beyond the front surface of the radiation guide body 1 facing the window, so that the radiation guide body 1 rests with the resistance path 2 on the window. The remaining cavity between the pane and the optical radiation guide body 1 is filled with optical adhesive for the purpose of coupling.

As can be seen in particular from FIG. 3, a heating element in the form of a vapor-deposited or a resistance layer 3 applied using the screen printing method can be assigned to the optical radiation guide body 1 for the purpose of temperature control. The heating element is connected to the control device (not shown) via connection contact parts 6 connected to the resistance layer 3 . The resistance layer 3 representing the heating element can, as shown, be designed as a wide, almost closed frame. However, it is entirely possible to provide the entire front surface of the optical radiation guide body 1 facing the pane with the resistance layer 3 , only the optical paths of the radiation guide body 1 being spared from the vapor deposition or from the printing on the resistance layer 3 . This offers the advantage that the measurement process to be carried out for the control of the windshield wiper device is only influenced to a very small extent in an undesired manner by the ambient or external light that is coupled in. Resistance layers 3 applied to structures on the radiation guide body 1 can also be used, for example to B. to achieve a particularly uniform heating of the radiation guide body 1 .

As can be seen in particular from FIG. 6, the heating element is supplied with current when the optoelectronic sensor device is started up. At the same time, the control device designed as a microcomputer receives the determined current ambient temperature as an input variable from a temperature sensor arranged in its vicinity. Depending on the determined ambient temperature and depending on the temperature level specified by the control device, the control device activates a switch by means of which the power supply is interrupted when there is a risk of the heating element overheating. In the same way, the power supply is ensured again when there is no longer any danger of overheating.

By means of the control device, the resistance track 2 or the resistance layer 3 of the optical radiation guide body 1 can be brought to three different temperature levels in a defined manner. A first temperature level of approximately 60 degrees Celsius is provided to accelerate the adhesive process of the optical adhesive by a defined supply of heat during the assembly or coupling process of the optical radiation guide body 1 to the pane.

In order to ensure that the optoelectronic sensor device operates properly, the optical radiation guide body 1 should be brought to a specific operating temperature at the place of use or, if possible, kept at an operating temperature that is not too low. For this purpose, the control device generates a second temperature level of approximately 30 degrees Celsius in the vicinity of the radiation guide body 1 by means of the heating element designed as a resistance track 2 or as a resistance layer 3 . This second temperature level ensures, on the one hand, that the electrical / electronic components of the optoelectronic sensor device are operated at a not too low operating temperature (at approximately 30 degrees Celsius), on the other hand, this second temperature level ensures that deposits on the disk, such as, for. B. ice or moisture build-up on the radiation guide 1 forming moisture can be dissolved. During operation, the temperature sensor directly assigned to the control device continuously measures the temperature prevailing in the immediate vicinity of the optoelectronic sensor device. If there is a risk of overheating, the control device switches the heating device off or on again when the temperature falls below a certain level. In addition, the detection of the direct ambient temperature can determine the temperature level at which the electrical / electronic components of the optoelectronic sensor device are operated. Known temperature errors (temperature drift) of these electrical / electronic components can thus be compensated for by suitable measures by means of the control device.

A third temperature level on the optical radiation guide body 1, which can be set by the control device by means of the resistance track 2 or resistance layer 3 , of well over 90 degrees Celsius ensures that the adhesive effect of the optical adhesive is destroyed. So the entire optoelectronic sensor device together with the optical radiation guide 1 z. B. in the event of repair from the disc or replaced with a new one.

Claims (18)

1.Optoelectronic sensor device for detecting the degree of wetting of a transparent pane, preferably made of glass, with, in particular, drop-shaped precipitation, the front surfaces of a surface under the influence of a heating element being exposed to the surface of the pane which is not exposed to precipitation in the region of the wiping field detected by a motor-operated window wiper device optical radiation guide body, which has optical paths, is coupled by means of optical adhesive, the radiation transmission of the radiation guide body depending on the degree of wetting of the pane and, in order to protect against overheating, regulation of a heating device assigned to the heating element, which serves to generate an operating temperature level, is carried out, characterized in that the heating element of the heating device is arranged on the front, that is to say on the surface of the optical radiation guide body ( 1 ) facing the pane, and with a de R-like control device is in communication that, in addition to reaching the operating temperature level, two further discrete temperature levels can be achieved, one of which serves to accelerate the curing of the optical adhesive when the radiation guide body is mounted on the pane, and the other of which is dimensioned such that it has the effect of the optical adhesive destroyed and thus allows disassembly of the radiation guide body from the pane. 2. Sensor device according to claim 1, characterized in that that they have the temperature prevailing in their area detecting temperature sensor, which to the control device is connected. 3. Sensor device according to claim 2, characterized in that the temperature sensor in the immediate vicinity of the Control device is arranged. 4. Sensor device according to claim 2, characterized in that the temperature sensor is arranged in the immediate vicinity of the optical radiation guide body ( 1 ). 5. Sensor device according to one of claims 1 to 4, characterized in that the optical adhesive in the form of a film between the front surface of the optical radiation guide body ( 1 ) and the disc is at least partially present. 6. Sensor device according to one of claims 1 to 4, characterized in that the optical adhesive can first be brought in the form of a liquid at least in regions between the front surface of the optical radiation guide body ( 1 ) and the pane in order to subsequently harden there. 7. Sensor device according to one of claims 5 or 6, characterized characterized in that the optical adhesive is transparent.   8. Sensor device according to one of claims 5 or 6, characterized characterized in that the optical adhesive is colored dark and in the wavelength range of the light used has a high transmission value. 9. Sensor device according to one of claims 1 to 8, characterized in that the heating element is formed as a vapor-deposited resistance layer ( 3 ) on the front surface of the optical beam guide body ( 1 ), at least the surface portions of the beam guide body ( 1 ) associated with the optical paths. remain uncoated and the resistance layer ( 3 ) is connected to the control device influencing the heating power via two connection contact parts ( 6 ). 10. Sensor device according to one of claims 1 to 8, characterized in that the heating element of the heating device is designed as a resistance layer ( 3 ) applied to the front surface of the optical radiation guide body ( 1 ) by screen printing, at least the surface portions of the optical paths belonging to the Radiation guide body ( 1 ) remain uncoated and the resistance layer ( 3 ) is connected to the control device influencing the heating power via two connection contact parts ( 6 ). 11. Sensor device according to claim 10, characterized in that the resistance layer ( 3 ) is applied in a structured form to the front surface of the optical radiation guide body ( 1 ). 12. Sensor device according to one of claims 1 to 8, characterized in that the heating element of the heating device is designed as a flat cross-sectionally rectangular resistance track ( 2 ) with its two free ends via two connection contact parts ( 6 ) with the control device influencing the heating power in Connection is established. 13. Sensor device according to one of claims 1 to 8, characterized in that the heating element of Heater as a round resistance wire in cross section is formed, with its two end regions over Connection contact parts with the influence on the heating output Control device is connected. 14. Sensor device according to one of claims 1 to 13, characterized in that the heating element is assigned to the edge regions of the optical radiation guide body ( 1 ) and is substantially frame-shaped. 15. Sensor device according to one of claims 1 to 14, characterized in that a groove-like recess ( 8 ) is provided all around in the edge region of the front surface of the optical radiation guide body ( 1 ), through which the heating element is received holding. 16. Sensor device according to claim 14, characterized in that the optical adhesive is present exclusively in the region of the groove-like recess ( 8 ) on the optical radiation guide body ( 1 ) or the heating element. 17. Sensor device according to one of claims 1 to 16, characterized in that the heating element is partially provided with at least one cross-sectional constriction ( 7 ) which increases the resistance value of the heating element. 18. Sensor device according to claim 12, characterized in that the resistance track ( 2 ) during the manufacturing process of the radiation body ( 1 ) of the radiation guide body ( 1 ) forming material can be received.