JPS6349713Y2 - - Google Patents

Description

[Detailed Description of the Invention] The present invention relates to a raindrop sensor installed in, for example, a vehicle wiper, and detects when raindrops adhere to a window glass or the like.

Conventionally, as shown in FIG. 1, a raindrop sensor of this kind has been provided with a light emitting part (light source) 3 and a light receiving part 4 inside a window glass 2, and a prism 1 on the inside of the window glass 2. It is configured by installing.

The incident light that enters the window glass 2 from the light projecting section 3 through the prism 1 is totally reflected at the interface between the window glass 2 and the air outside thereof, and the reflected light enters the light receiving section 4.

When raindrops adhere to the outer surface of the window glass 2, part of the incident light leaks from the raindrops to the outside, and the amount of reflected light, that is, the amount of light received by the light receiving section 4 decreases. As a result, the output of the light receiving section 4 changes and it is detected that raindrops have attached.

However, according to the above raindrop sensor, complicated circuit processing is required to remove disturbances such as external light, such as sunlight entering the light receiving section 4 from the window glass 2 through the prism 1. In this case, there was a problem in that the light receiving section 4 became saturated with external light, making it impossible to detect raindrops.

The present invention was made in view of the above circumstances, and its purpose is to provide a raindrop sensor that can remove disturbances and perform stable detection without requiring complicated circuit processing.

An embodiment of the present invention will be described below with reference to the drawings.

FIG. 2 is a schematic diagram showing an example of the raindrop sensor of the present invention. In the figure, the same parts as those shown in FIG. 1 are given the same reference numerals, and the explanation thereof will be omitted.

In this embodiment, the prism 6 has reflective surfaces 6b and 6.
c, 6e, and 6f are formed. These reflective surfaces 6b, 6c, 6e, and 6f are each inclined at a predetermined angle so as to totally reflect the incident light. In other words, the light emitted perpendicularly from the light projector 3 to the window glass 2 through the incident surface 6a is reflected by the first reflective surface 6b of the prism and becomes parallel to the window glass 2. The reflective surface 6b of the window glass 2 is inclined at an angle of 45 degrees with respect to the inner surface of the window glass 2.

Furthermore, the light that has become horizontal on the first reflective surface 6b is
The second reflection surface 6c reflects again and reaches the boundary surface _M1 between the window glass 2 and the air, and the second reflection surface 6c enters the window glass 2 at an incident angle θ.
The inclination of the reflective surface 6c with respect to the perpendicular to the window glass 2 is 90-(90-θ/2)=45+θ/2. Here, the incident angle θ with respect to the window glass 2 is set to Θ ₁ <θ<Θ ₂ . Θ ₁ is the critical angle at the interface M ₁ between the window glass 2 and the air outside it,
Θ ₂ is the critical angle at the interface M ₂ between the window glass 2 and the raindrop 5 attached to its outer surface (see FIG. 3).

If the refractive index of the window glass 2 is 1.5 and the refractive index of air is 1.0, then the critical angle Θ ₁ is 45° or less, and if the refractive index of the raindrop 5 is 1.33, the critical angle Θ ₂ is 62° or more. .

Therefore, the angle of incidence θ on the window glass 2 is
For example, if it is 60 degrees, the inclination angle of the second reflective surface 6c is inclined at an angle of 75 degrees with respect to the perpendicular V to the window glass 2, that is, it is inclined at an angle of 15 degrees with respect to the inner surface of the window glass 2. .

Further, the third and fourth reflective surfaces 6e and 6f are
The first and second reflective surfaces 6b and 6c are formed at positions symmetrical to the perpendicular line V of the window glass 2, respectively.

On the other hand, the second reflecting surface 6c and the third reflecting surface 6
In the window glass 2 side portion opposite to the reflecting surface 6e, surfaces 6h, 6i, 6j, and 6k are formed between the first reflecting surface 6b and the fourth reflecting surface 6f and the mounting surface 6d of the prism 6 bonded to the inner surface of the window glass 2, and the surfaces 6h, 6i, 6j, and 6k are determined by the boundaries of the range of the optical path irradiated from the light projecting unit 3 to the first reflecting surface 6b, and the surface 6h is determined by the boundaries of the range of the optical path irradiated from the light projecting unit 3 to the first reflecting surface 6b.
The surfaces 6h, 6i and 6j, 6k are formed in positions that are symmetrical with respect to a perpendicular line V of the window glass.
These prism surfaces 6h, 6i, 6j,
A light absorbing layer is formed on 6k using black paint or the like.

Furthermore, the mounting surface 6d of the prism 6, which the light reflected by the second reflective surface 6c reaches, is configured such that the light enters the window glass 2 from the surface 6d, that is, no reflection occurs at the boundary surface of the window glass. As such, it is formed in close contact with the inner surface of the window glass 2.

Therefore, when no raindrops 5 are attached, the light incident on the window glass 2 is totally reflected at the boundary surface M ₁ and enters the prism 6 again, and the light enters the prism 6 again.
After repeated reflections at e and 6f, the light is emitted from the output surface 6g and enters the light receiving section 4.

Furthermore, when the raindrops 5 adhere, the light incident on the window glass 2 enters into the raindrops 5 from the boundary surface _M2 . The light incident on the raindrops 5 leaks to the outside except for the light that is totally reflected at the interface between the raindrops 5 and the air outside. Therefore, the amount of reflected light, that is, the amount of light received by the light receiving section 4 decreases.

External light passes through the surface 6d from the window glass 2 and enters the prism 6, but this external light is transmitted to the light receiving section 4.
It will not be incident on the .

This will be explained with reference to FIG. According to the law of refraction, n ₁ sin θ ₁ = n ₂ sin θ ₂ holds true. However, n ₁
is the refractive index of air, n ₂ is the refractive index of the window glass 2 and prism 6, θ ₁ is the angle of incidence of external light on the window glass 2, and θ ₂ is the angle of incidence of external light on the window glass 2.
and the refraction angle when passing through the prism 6.
Here, the critical angle within the prism 6 is given by the refractive index n ₁ of air being 1 and θ ₁ being 90°, sin90° = n ₂ sinθ ₂ sinθ ₂ = 1/n ₂ Therefore, the critical angle = sin ^-1 1/n ₂ .

In other words, external light incident from any angle has an angle of θ ₂ <sin ⁻¹ 1/n ₂ .

Therefore, the external light either exits from the prism 6 through the surface 6e, or is directed toward the surface 6k after being totally reflected on the surface 6e.

Therefore, if the surface 6k is set to be long enough, even if external light is totally reflected on the surface 6e, it will be absorbed by the light absorption layer 7 on the surface 6k, and there is a possibility that it will be reflected on the surface 6f and enter the light receiving section 4. That's not it.

Although not shown, the output of the light receiving section 4 is input to the drive section of the vehicle wiper.
When the output becomes, for example, a predetermined value or less, this becomes an operation start signal.

Next, the operation of the first embodiment will be explained.

When no raindrops 5 are attached to the outer surface of the window glass 2, the light from the light projecting section 3 is reflected on the reflective surface 6.
After repeated reflections at b and 6c, it enters the window glass 2, and is totally reflected at the boundary surface _M1 ,
The reflected light enters the prism 6 again and is repeatedly reflected by the reflecting surfaces 6e and 6f, and then exits from the surface 6g and enters the light receiving section 4.

When the raindrops 5 adhere, the light from the light projecting section 3 enters the raindrops 5 through the window glass 2, and a portion of the light leaks out from the raindrops 5, reducing the amount of light received by the light receiving section 4. As a result, the output of the light receiving section 4 changes to detect that raindrops 5 have adhered, and the vehicle wiper starts operating.

At this time, external light that has entered the prism 6 from the window glass 2 through the surface 6d exits the prism 6 through the surface 6e, or is reflected by the surface 6e and then is reflected by the light absorption layer 7 on the surface 6k. There is no risk that the light receiving section 4 will be saturated due to external light.

5 and 6 show a second embodiment of the invention. In this second embodiment, the light projecting section 3 and the surface 6a
A slit 8a is interposed between the light receiving portion 4 and the surface 6g, and a slit 8b is interposed between the light receiving portion 4 and the surface 6g.

The slit 8b blocks the light that has passed straight through the slit 8a and the prism 6, and is arranged so that the light passing portion of the slit 8a and the light blocking portion of the slit 8b are opposed to each other. Therefore, under normal conditions when raindrops 5 are not attached, the light from the light projecting section 3 is blocked by the slit 8b, and no light enters the light receiving section 4.

When the raindrops 5 adhere, a part of the light that enters the raindrops 5 is totally reflected at the interface between the raindrops 5 and the air outside, and the optical path is bent, making the optical path different from the normal optical path when no raindrops are attached. takes different optical paths and passes through the slit 8b.

That is, in the second embodiment, when no raindrops 5 are attached, no light is incident on the light receiving section 4, and its output is, for example, at L level. raindrops 5
When the raindrops 5 adhere, the light is bent and enters the light receiving section 4, and its output changes to H level, and it is detected that the raindrops 5 have adhered.

In this second embodiment, even if the amount of light projected changes due to deterioration of the light projecting section 3, electrical noise, etc., the detection of raindrops 5 is not affected in any way.

In addition, although the said Example showed the case where the light projection part 3 was arrange|positioned inside the window glass 2, the same effect can be obtained even if this is arrange|positioned outside.

Further, although the case where the present invention is applied to detecting raindrops 5 is shown, the present invention is not limited to this, and can also be used as a general water droplet sensor or a fogging detection sensor for glass.

As explained above, according to the present invention, surfaces (reflecting surfaces 6e, 6k) are formed on the prism to prevent external light entering the prism from the transparent body (window glass) from entering the light receiving section. This enables stable detection without disturbance from external light.
Further, there is no need for complicated circuit processing, and costs can be reduced simply by processing the prism.

[Brief explanation of the drawing]

Figure 1 is a schematic diagram of a conventional raindrop sensor, Figure 2~
Fig. 4 shows an embodiment of the present invention, Fig. 2 is a schematic diagram, Figs. 3 and 4 are explanatory diagrams of the operation, and Figs.
FIG. 6 shows a second embodiment of the present invention, FIG. 5 is a schematic diagram, and FIG. 6 is an explanatory diagram of the operation. 2... Transparent body (window glass), 3... Light projecting section, 4... Light receiving section, 6... Prism, 6a, 6
k...face.

Claims (1)

[Claims for Utility Model Registration] (1) A light emitting part and a light receiving part are arranged inside a window glass, a prism is attached to the inner surface of the window glass, and light is irradiated from a light source onto the window glass. In a raindrop sensor configured so that when the optical path of light changes due to raindrops etc. adhering to the outer surface of a window glass, this is detected by a light receiving section, the prism is configured with one polyhedron having a plurality of reflective surfaces, and the above-mentioned projection A first reflective surface is formed at an angle of 45 degrees to the window glass, and the light irradiated perpendicularly to the window glass from the light section through the incident surface is reflected. The light is reflected by the second reflective surface,
The second reflected light is incident on the window glass at an incident angle θ that is larger than the critical angle at the interface between the window glass and the air outside the window glass and smaller than the critical angle at the interface between the window glass and the raindrops attached to the outside. A fourth and third reflective surface is formed at an angle of (45+θ/2) with respect to the perpendicular line of the window glass, and fourth and third reflective surfaces are formed at positions symmetrical to the first and second reflective surfaces, respectively, with respect to the perpendicular line of the window glass. The light reflected at the boundary surface of the window glass is sequentially reflected at the third and fourth reflective surfaces, and is transmitted from the output surface to the light receiving part as outgoing light perpendicular to the window glass. The first reflective surface and the fourth reflective surface are bonded to the inner surface of the window glass at a portion on the window glass side opposite to the second reflective surface and the third reflective surface. A raindrop sensor characterized in that a surface is formed between the mounting surface and the mounting surface where light incident from the light projecting section does not reach, and a light absorption layer is formed on this surface. (2) A slit is provided between the light projecting section and the entrance surface of the prism and between the light receiving section and the exit surface of the prism, and a light passing section of the slit on the entrance surface side;
The raindrop sensor according to claim 1, characterized in that the slits on the exit surface side are arranged so that the light-blocking parts thereof face each other.