DE4300741A1 - Sensor arrangement for detecting degree of moisture on transparent screen caused by precipitation - Google Patents

Abstract

The sensor arrangement has a light conducting body (2) coupled to the screen (1) surface (1b) not accessible to precipitation and at an exposed point. The body consists of at least one light input region (2b) which works in conjunction with a light source. Light passes from the source to the receiver by reflection at the screen depending on the degree of moisture on the screen.The receiver produces a signal proportional to the degree of moistening. The surfaces of the light conducting body are coated with a protective film (5) on the base region.

Description

The present invention is based on one according to the preamble of the main claim designed to capture the Degree of wetting of a pane with. e.g. B. teardrop-shaped Precipitation provided sensor device.

Such devices are particularly designed to on the front or rear window of a motor vehicle Precipitation of moisture per unit of time in representative form and depending on it automatically assigned to the windshield wiper system influence.

DE 33 14 770 C1 is a device for controlling a motor-driven windshield wiper became known at the one on the inner surface of a transparent Disk attached radiation guide from an associated Radiation transmitter emits rays in the transparent pane  coupled and after at least one reflection on the outer Surface of the disc over the radiation guide again decoupled and to an assigned radiation receiver be directed.

In such a case, usually by means of optical adhesive on the Radiation guide to be attached to the pane, there is the problem that because of his education this is a huge size and in particular has a very considerable height. Furthermore is essential for a usable measurement required exact assignment of the radiation transmitter and the Beam receiver to the beam guide not easily and certainly not with simple means. Furthermore the light guide is not easily closed on the pane fasten and protect against external influences.

The present invention is therefore based on the object a sensor device of the type mentioned above to further develop that an influence on the measurement result beams not directly associated with the measuring section itself minimum spatial dimensions of the sensor device largely avoided and optimal functionality of the cooperating components is guaranteed.

According to the invention the task is characterized by Part of the main claim specified features solved. Advantageous in such a configuration Sensor device is that a very compact, only relatively little Space and a design that requires minimal effort can be realized.

In connection with a sensor device designed in this way it is favorable if the same one in particular on the Radiation guide acting heater is assigned. This ensures that the entire sensor device to a certain one within a relatively short time Temperature level, e.g. B. 40 degrees C, which brings  on the one hand a reduction in temperature errors and on the other hand partial heating of the pane is achieved. Through the Heating the disc is considered a snowflake on the Disc of existing thawed thaw, which thus detects can be.

Further advantageous embodiments of the invention Subject matter are specified in the subclaims and are based on one shown in the drawing Embodiment of a built accordingly Sensor device explained in more detail. Show

Fig. 1 is a view of the beam control element mounted from a direction shown in a partial disk sensor means

Fig. 2 shows the beam guide body held on the disc according to Fig. 1 in side view

Fig. 3 shows the light conducting body of FIG. 1 in section along line AB of FIG. 1

Fig. 4 shows the radiation guide of Fig. 1 in a side view rotated by 90 degrees.

As can be seen from the drawing, a sensor device provided for detecting the degree of wetting of a pane 1, preferably made of glass, with, for example, drop-shaped precipitation, essentially consists of at least one radiation transmitter (not shown for the sake of simplicity) and at least one radiation receiver (also not shown for the sake of simplicity) assigned radiation guide body 2 , which is attached by means of optical adhesive 4 to the surface 1 b of the pane 1 which is not exposed to precipitation. The pane 1 is, in particular, the windshield of a motor vehicle, on which the sensor device arranged in a housing is present at an exposed point, that is to say one which does not impair the view, but which is predestined for detecting the precipitation. The light conducting 2 consists of a flat-shaped base portion 2 a and the and the beam transmitter (s) associated with the radiation inlet area 2 b ', and a the or the beam receiver (s) associated with the beam exit area 2 c, which on the side remote from the disk 1 Surface 2 a '' of the base area 2 a are present.

The radiation entry area 2 b, like the radiation exit area 2 c, is each provided with at least one radiation window 2 b ′, 2 c ′, which the radiation transmitter (s) or radiation receiver (s) each have an associated radiation lens 2 b '', 2 c '' is assigned or are. The beam window 2 b ', 2 c' are each aligned at an angle of approximately 45 degrees with respect to the surface 2 a of the base region 2 a and arranged at the beam entry area 2 b or beam exit area 2 c so that their center lines at an angle of approximately Are offset by 90 degrees.

In order to ensure that the measurement result is largely prevented by rays that do not directly belong to the measuring section, the radiation guide body 2 is on its surface 2 a facing away from the pane 1 of the base region 2 a and the associated surfaces of the radiation entry region 2 b and the radiation exit region 2 c almost completely, ie provided with a protective layer 5 except for the surface portions intended for the intended radiation passage. Specifically, this means that the protective layer 5 consisting of a reflecting and / or absorbing material has the surfaces of the radiation guide body 2 facing away from the pane 1 except for the surface portions associated with the radiation lenses 2 b '', 2 c '' and optionally up to one provided for an ambient light detector provided radiation window 6 covered surface portion coming.

In order to enlarge the measuring area to be scanned on the disk, a multiple reflection of the rays in the area of the disk 1 is realized, as is known per se. For this purpose, the protective layer 5 present on the surface 2 a ′ ′ of the base region 2 a facing away from the pane 1 in the section lying between the radiation entry region 2 b and the radiation exit region 2 c is formed as a reflection layer 5 ′. So that this reflection layer 5 'adheres well to the relevant surface of the radiation guide body 2 , it is made of a material whose coefficient of expansion comes very close to that of the material of the radiation guide body 2 . In the case of a radiation guide body 2 made of glass, it has proven to be advantageous to produce this layer from a material having a relatively high chromium content, while in the case of a radiation guide body made from plastic it is advantageous to produce the layer from a material having a relatively high copper content, especially since such a material has particularly good reflection properties for IR rays.

To prevent that in the radiation guide 2 in addition to rays of a certain wavelength such. B. IR rays can also occur with a different wavelength, the radiation guide 2 is treated at least with regard to its surface in a suitable manner. One such possibility can be seen in the fact that the material is colored in a manner that is transparent to IR rays. The coloring z. B. be made dark and thus opaque to the range of visible light.

Likewise, the surface of the radiation guide body 2 can be partially provided with a filter layer for the purpose of tuning the sensor device to rays with a specific wavelength.

In order to minimize the dimensions and, in particular, the length and height of the beam guide body 2 , which are determined by the optical laws, the beam window or beams 2 b 'and the associated beam lens (s) 2 b are or are now '' Of the radiation entrance area 2 b and the radiation window or windows 2 c 'and the associated (n) radiation lens (s) 2 c''of the radiation exit area 2 c partially in one in the surface facing away from the disc 1 2 ''of Base area 2 a existing, preferably a wedge-shaped course recess 2 a *, 2 a ** arranged. This also minimizes the measurement path, which is of considerable importance for the required transmission power and the measurement result due to the associated minimized attenuation.

The respective radiation window 2 b ', 2 c.' Or the respective associated radiation lens 2 b '', 2 c '' is assigned to the respectively associated recess 2 a *, 2 a ** in such a way that a point on the circumference thereof or the same touches the deepest section of the associated depression 2 a *, 2 a **. The deepest section of the recess 2 a *, 2 a ** is located in the central material zone of the base region 2 a, in order not to impair the mechanical stability of the same.

In order to fix the radiation guiding body 2 to the pane 1 in a flawless manner, a material is preferably used for the same, which corresponds to that of the pane 1 or at least has an expansion behavior which quasi corresponds to that of the pane 1 . For fixing an optically transparent adhesive 4 is used, which is supplied via a in the center of the base portion 2 a known, preferably rotationally symmetrically designed opening 3 by means of the injection device. The flat-shaped, at least quasi parallel to the disk curve extending base portion 2 a of the beam control element 2 advantageously has an ellipse-like contour. This is because it is achieved that the initially evenly between the inner surface 1 b of the disc 1 and the surface 2 a 'facing it' of the base region 2 a spreading adhesive 4 when reaching the edge of the base region 2 a (which is initially near the ends the secondary axis of the ellipse) is braked there due to the holding forces exerted on it (surface tension of the adhesive, etc.) and only then spreads further in the direction of the main axis of the ellipse. With a precisely metered amount of the adhesive 4 it is achieved that practically the mutually arranged surface areas of the pane 1 and the radiation guide body 2 are completely wetted without substantial portions of the adhesive exceeding it and without the thickness of the adhesive layer influencing the measurement result Scope changed.

For the purpose of correct, ie exact assignment of the radiation transmitter (s) and the radiation receiver (s) to the associated radiation window 2 b ', 2 c' or to the associated radiation lens 2 b '', 2 c '' - what for A perfect measurement is of great importance - the radiation guide body 2 is provided with holding means 2 b *, 2 b **, 2 c *, 2 c **, which are not shown for the sake of simplicity, on a component carrier which is also not shown for the sake of simplicity existing fasteners cooperate. In addition to a printed circuit board with electronic components arranged thereon, the component carrier (s) and the radiation transmitter (s) and the radiation receiver (s) are also held in a corresponding orientation. The holding means are composed, on the one hand, of recesses 2 b *, 2 c **, which are provided in the top surfaces of the beam entry region 2 b and the beam exit region 2 c, preferably rotationally symmetrical, for exact fixing of the component carrier in the x and y directions, and in two opposing side walls of the beam entry area 2 b and the beam exit area 2 c present notches 2 b **, 2 c ** provided for fixing the component carrier in the z direction.

Claims (20)

1. Sensor device for detecting the degree of wetting of a transparent pane (1) with precipitation, wherein at least one (b 1) on their non-accessible to the deposition surface is angekoppeit at an exposed location of existing light conducting (2) to the disk (1) which is substantially at least extending from a quasi-parallel to the disc, the base region of relatively flat design (2 a) and a co-operating with at least one beam transmitter radiation inlet area (2 b) and a cooperating with at least one radiation receiver beam outlet region (2 c), wherein the radiation inlet area (2 b) and the beam outlet region (2 c) on the side remote from the disc (1) surface (2 a '') of the base region (2 a located) and each with at least one opposite to the surface (2 a '') of the base region (2 a) aligned at an angle of about 45 degrees, with a radiation lens (2 b ' , 2 c '') connected to the radiation window (2 b 'are 2 provided c') such that reflected by the beam transmitter emitted radiation as a function of the end on the disc (1) precipitation of the wafer surface (1 a) and the radiation receiver are passed, which provides an amount of precipitation inversely proportional signal, characterized in that on the light conducting body (2) at least the side facing away from the disk (1) surface (2 a '') of the base region (2 a) and the same associated surface of the The radiation entrance area ( 2 b) and the radiation exit area ( 2 c) are provided with a protective layer ( 5 ) except for the surface portions intended for the intended radiation passage. 2. Sensor device according to claim 1, characterized in that the protective layer ( 5 ) is absorbent and / or reflective. 3. Sensor device according to claim 1 or claim 2, characterized in that the protective layer ( 5 ) facing away from the disc ( 1 ) surfaces of the radiation guide body ( 2 ) except for the surface portions of the radiation lenses ( 2 b '', 2 c '' ) and a radiation window ( 6 ) provided in the base area ( 2 a) for assigning an ambient light detector are covered. 4. Sensor device according to one of claims 1 to 3, characterized in that in the between the radiation entry region ( 2 b) and the radiation exit region ( 2 c) existing section of the disc ( 1 ) facing away from the surface ( 2 a '') of Base area ( 2 a) is the portion of the protective layer ( 5 ) which reflects the rays emanating from the radiation transmitter (s) on the outer surface ( 1 a) of the pane ( 1 ) in the direction of the pane ( 1 ) Reflective layer ( 51 ) is formed. 5. Sensor device according to claim 4, characterized in that the reflection layer ( 5 ') consists of a material whose coefficient of expansion corresponds at least almost to that of the material of the radiation guide body ( 2 ). 6. Sensor device according to claim 5, characterized in that the reflection layer ( 5 ') consists of a relatively high copper content material. 7. Sensor device according to claim 5, characterized in that the reflection layer ( 5 ') consists of a relatively high chromium content material. 8. Sensor device according to claim 1 or one of the following, characterized in that the radiation guide body ( 2 ) is at least surface-treated in a manner permeable to rays of a certain wavelength. 9. Sensor device according to claim 8, characterized in that the material of the radiation guide body ( 2 ) is colored in a manner permeable to IR rays. 10. Sensor device according to claim 8 or claim 9, characterized in that the material of the radiation guide body ( 2 ) is impermeable to rays falling in the visible light range. 11. Sensor device according to one of claims 8 to 10, characterized in that the radiation guide body ( 2 ) consists of dark colored glass. 12. Sensor device according to claim 1 or one of the following, characterized in that the radiation window ( 2 b ', 2 c') or the associated radiation lenses ( 2 b ') provided at the radiation entry region ( 2 b) or radiation exit region ( 2 c) ', 2 c') respectively in a) depression (2 existing a, 'are partially in a respective one of the side facing away from the disk (1) surface (2 a'') of the base region (2 * 2 ** a) arranged. 13. Sensor device according to claim 12, characterized in that the recess ( 2 a *, 2 a **) has a wedge-shaped course falling from the surface ( 2 a '') to approximately in the central material zone of the base region ( 2 a). 14. Sensor device according to claim 12 or claim 13, characterized in that the radiation window ( 2 b ', 2 c') or the associated radiation lenses ( 2 b '', 2 c '') each with a point of their circumference the deepest Tangent section of the depression assigned to them ( 2 a *, 2 a **). 15. Sensor device according to one of claims 12 to 14, characterized in that at the radiation entry region ( 2 b) and the radiation exit region ( 2 c) cooperating with each arranged on a provided for the radiation transmitter and the radiation receiver and the radiation receiver component holder or fasteners Holding means ( 2 b *, 2 b **, 2 c *, 2 c **) for the exact three-dimensionally effective assignment of the radiation transmitter and radiation receiver to the associated radiation lens ( 2 b ′ ′, 2 c ′ ′) or radiation window ( 2 b ', 2 c') are available. 16. Sensor device according to claim 15, characterized in that the holding means cooperating with the fastening means present on the component carrier are determined on the one hand by a positioning of the component carrier in the x and y directions, on the top surface of both the radiation entry region ( 2 b) and and the beam outlet region (2 c) provided in the recess (2 b *, * 2 c) and on the other hand, each fixing of a positioning of the parts carrier in the z-direction, on at least one side surface of each of the radiation inlet area (2 b) and the beam exit area ( 2 c) Assemble the existing notch ( 2 b **, 2 c **). 17. Sensor device according to claim 16, characterized in that the recesses ( 2 b *, 2 c *) are each designed as a rotationally symmetrical blind hole. 18. Sensor device according to claim 1 or one of the following, characterized in that the at its side facing away from the disk (1) surface (2 a '') the radiation inlet area (2 b) and the beam outlet region (2 c) having the base region (2 a) has an ellipse-like contour that the beam entry area ( 2 b) and the beam exit area ( 2 c) are each arranged at the same distance from the center of the base area ( 2 a) and that in the center of the base area ( 2 a) one of that of the disc facing surface ( 2 a '') to the disc ( 1 ) facing surface ( 2 a ') extending opening ( 3 ) is present. 19. Sensor device according to claim 18, characterized in that both on the surface facing away from the disc ( 1 ) ( 2 a '') of the base region ( 2 a) existing radiation entry area ( 2 b) and also the radiation exit area ( 2 c) each have two radiation windows, on the one hand two radiation transmitters and on the other hand two radiation receivers are assigned. 20. Sensor device according to claim 18 or claim 19, characterized in that the opening ( 3 ) present between the beam entry area and the beam exit area ( 2 c) is rotationally symmetrical.