JPH0110587Y2 - - Google Patents

Description

[Detailed Description of the Invention] [Industrial Application Field] The present invention relates to a raindrop sensor that detects when raindrops adhere to a window glass or the like.

[Conventional technology]

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 known that the structure is configured by attaching a .

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 5 adhere to the outer surface of the window glass 2, part of the incident light leaks from the raindrops 5 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.

[The problem that the idea aims to solve]

However, the raindrop sensor described above has a problem in that depending on the amount, size, etc. of attached raindrops 5, the amount of light leaking from the raindrops 5 to the outside is small and the detection sensitivity is low. As a solution to this problem, for example, processing using a circuit may be considered, but this would be costly.

The present invention has been made in view of the above circumstances, and its purpose is to provide a raindrop sensor that does not increase costs, has sufficient detection sensitivity, and is free from malfunction.

[Means to solve the problem]

In order to achieve the above object, the present invention attaches a prism to the inner surface of the window glass, and
A light receiving and emitting section consisting of a light source and a light receiving element is arranged on one side of this prism, and the light from the light source is irradiated onto the window glass.When the optical path of this light changes due to raindrops etc. adhering to the outer surface of the window glass. In the raindrop sensor, the prism is arranged in a rectangular prism piece and one side of the rectangular prism piece, and the light from the light source of the receiving and emitting part is transmitted to the rectangular parallelepiped. A light receiving/emitting prism piece is arranged on the other side of the rectangular prism piece, and a window and a reflection side prism piece having at least two reflective surfaces so that the light reflected by a part of the glass enters the rectangular prism piece again and is reflected by the other part of the window glass, A gap portion is provided between the prism piece and the prism piece on the receiving and emitting side and the reflecting side prism piece, and the boundary surface between the rectangular parallelepiped prism piece and the gap portion is formed approximately at right angles to the window glass.

[Effect]

A reflection side prism having at least two reflective surfaces on the other side of the rectangular prism piece so that the light reflected by a part of the window glass enters the rectangular prism piece again and is reflected by the other part of the window glass. Since the pieces are arranged, the light path (outward path) where the light from the light source is first reflected on the window glass,
The optical path (return path) in which the light reflected by the window glass is reflected again by the window glass does not overlap.

〔Example〕

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

FIG. 2 shows a first embodiment of the invention. Reference numeral 6 in the figure is a prism, and a rectangular parallelepiped prism piece 6
a, a triangular prism piece 6b, and a square prism piece 6d having two reflective surfaces 62d and 63d.These prism pieces are attached to the inner surface of the window glass 2. It is glued to prevent reflections at the interface with the The prism piece 6b is
As will be described later, the receiver is configured such that light from the light source of the light receiving/emitting section 7 is incident on the rectangular prism piece 6a, and reflected light emitted from the rectangular prism piece 6a is incident on the light receiving element of the receiving/emitting section 7. Works as a prism piece on the light emitting side.

A light receiving and emitting section 7 incorporating a light source and a light receiving element (not shown) is provided at a position facing the surface 61b of the prism piece 6b. In addition, the prism piece 6b
between the surface 62b of the prism piece 6a and the surface 61a of the prism piece 6a,
and the surface 62a of the prism piece 6a and the prism piece 6d
There is a small air gap part 8 between the surface 61d and the surface 61d.
are provided for each.

The incident angle θ of the light that enters the window glass 2 from the light source of the light receiving/emitting section 7 through the prism pieces 6b and 6a is set to Θ<θ< _Θ2 .

Here, Θ ₁ is the critical angle at the interface between the window glass 2 and the air outside thereof, and Θ ₂ is the critical angle at the interface between the window glass 2 and the raindrops 5 attached to its outer surface.

Therefore, when no raindrops 5 are attached, the light from the light source of the light receiving/emitting unit 7 passes through the optical path (outgoing path) in the figure and is completely absorbed at the interface between a part of the window glass 2 and the air outside of it. reflected. This reflected light enters the prism piece 6a again, exits from the surface 62a, and enters the prism piece 6d. and,
After being reflected twice by the surfaces 62d and 63d of the prism piece, it enters the prism piece 6a again, and is totally reflected again by the interface between the other part of the window glass 2 and the air outside of it, resulting in the above-mentioned optical path ( The light is emitted from the prism piece 6a through another optical path (return path) in the figure that does not overlap with the outgoing path (outward path), and is incident on the light receiving element of the light receiving/emitting section 7.

When a plurality of raindrops 5a and 5b adhere to the window glass 2, the light from the light receiving and emitting section 7 first enters the raindrop 5a, a part of which has adhered to a part of the window glass 2, on the outward path. The light incident on the raindrop 5a leaks to the outside except for the light that is totally reflected at the interface between the raindrop 5a and the air outside. Similarly, on the outward journey, a portion of the light is incident on the raindrops 5b attached to other parts of the window glass 2, and the light, except for the part that is totally reflected at the interface between the raindrops 5b and the air outside, is transmitted to the outside. Leak.

That is, when a plurality of raindrops 5a and 5b adhere, the light from the light source of the light receiving and emitting section 7 leaks to the outside twice, once on the outbound trip and on the return trip.

Incidentally, the surfaces 61a and 62a of the prism piece 6a are substantially perpendicular to the inner surface of the window glass 2, and totally reflect external light incident on the prism piece 6a from the window glass 2.

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. Here, the critical angle within the prism 6 is the refractive index of air equal to 1,
Assuming θ ₁ = 90°, sin90° = n ₂ sin θ ₂ sin θ ₂ = 1/n ₂ , so the critical angle = sin ^-1 1/n ₂ .

In other words, light incident from any angle,
The angle is θ ₂ <sin ^-1 1/n ₂ .

Here, in order for the incident light to be totally reflected by the surface 61a, sin ^-1 1/n ₂ <θ ₃ is satisfied.

Therefore, θ ₂ <sin ^-1 1/n ₂ <θ ₃ ... Since the surface 61a is perpendicular to the interface between the window glass 2 and the air outside thereof, θ ₂ +θ ₃ = 90° ... From θ ₂ < θ ₃ ... Substituting from θ ₃ = 90° − _{θ 2} , θ ₂ < 90° − _{θ 2} Therefore, θ ₂ < 45° Similarly, θ ₂ < 45° < θ ₃ obtain.

Therefore, if the critical angle is smaller than 45°, θ ₂ will be smaller than 45°, and therefore θ ₃ will be 45°, that is, larger than the critical angle, and total reflection will occur at the surface 61a.

Since n ₂ >1.414 based on the condition that the critical angle sin ^-1 1/n ₂ <45°, if the refractive index of the prism 6 is set larger than 1.414, all external light is totally reflected by the surface 61a and the drawing 62a.

That is, the light receiving element of the light receiving/emitting section 7 is not saturated by external light.

Although not shown, the output of the light receiving element of the light receiving and emitting section 7 is inputted to the driving section of the vehicle wiper, and when the output becomes less than a predetermined value, this becomes an operation start signal.

Therefore, according to the first embodiment, when a plurality of raindrops 5a and 5b adhere to each other, the light from the light source of the light receiving and emitting section 7 leaks to the outside from some of the raindrops 5a on the outward path and decreases. Since the reduced light further leaks to the outside from raindrops 5b in other parts on the return path that does not overlap with the outgoing path, the reduction rate of the amount of light received by the light receiving element in the light receiving/emitting section 7 is large, and it is difficult to make a large change in the output of the light receiving element. , raindrops 5 can be detected reliably.
Furthermore, since the outbound and return trips do not overlap, raindrops 5 can be detected on either the outbound or return trip, and the detection performance is improved accordingly.

In this regard, with the raindrop sensor shown in FIG. 5, the raindrops 5 cannot be detected at all.

4 to 6 show a second embodiment of the present invention. In the second embodiment, in the raindrop sensor shown in the first embodiment, slits 10a and 10 are provided between the light receiving and emitting section 7 and the surface 61b of the prism piece 6b.
It is mediated by b.

The slit 10b prevents the light passing through the slit 10a from returning to the light receiving/emitting section 7 when no raindrops 5 are attached.

When the raindrop 5 adheres, as shown in FIGS. 5 and 6, a portion of the light is totally reflected at the interface between the raindrop 5 and the air outside, and enters the prism piece 6a again. When this light is reflected, its optical path is refracted, so when it returns to the light receiving and emitting section 7 through the return path, it passes through the slit 10b.

That is, in the second embodiment, when no raindrops 5 are attached, no light enters the light receiving element of the light receiving/emitting section 7 due to the slit 10b, and the output thereof becomes, for example, L level. When the raindrops 5 adhere, the light whose optical path is refracted by the raindrops 5 passes through the slit 10b.
The light enters the light receiving element through the light receiving element, and its output changes to H level, and it is detected that the raindrops 5 have adhered to the light receiving element.

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

In addition, although the above-mentioned each Example showed the case where it applied to the detection of the raindrop 5, it is not limited to this and can also be used as a general water droplet sensor or a fogging detection sensor for glass.

[Effect of idea]

As explained above, according to the present invention, light is irradiated from the light source onto the window glass, the reflected light is refracted and irradiated again onto the window glass, and the optical path of the light is changed by raindrops etc. attached to the outer surface of the transparent body. When the light changes, it is detected by the light receiving part (the light receiving element of the light receiving/emitting part), and the structure is configured so that the outgoing and returning paths of the reflected light do not overlap, so that the change in the amount of light during the two reflections on the outgoing and returning paths is As a result, the rate of decrease in the amount of light received by the light-receiving element is greater than the conventional change in light amount in only one direction, and the output change of the light-receiving element can be increased to increase detection sensitivity. It can detect raindrops more reliably and there is no risk of malfunction. Furthermore, since raindrops can be detected reliably, no circuit processing is required and costs are not high.

[Brief explanation of the drawing]

Fig. 1 is a schematic diagram of a conventional raindrop sensor, Fig. 2 is a schematic diagram showing a first embodiment of the present invention, and Fig. 3 is an explanatory diagram illustrating that external light does not enter the light receiving element.
4 to 6 show a second embodiment of the present invention, in which FIG. 4 is a schematic diagram, and FIGS. 5 and 6 are explanatory diagrams of the operation. 2... Window glass, 5a, 5b... Raindrops, 6... Prism, 6a, 6b, 6d... Prism pieces, 7... Receiving and emitting section.

Claims (1)

[Claims for Utility Model Registration] A prism is attached to the inner surface of the window glass, and a light receiving and emitting section consisting of a light source and a light receiving element is arranged on one side of the prism, and the window glass is irradiated with light from the light source. In a raindrop sensor configured so that when the optical path of the window changes due to raindrops etc. adhering to the outer surface of the window glass, this is detected by a light receiving element of a light receiving/emitting part. A light receiving/emitting device disposed on one side of the light receiving/emitting section so that light from the light source of the receiving/emitting section is incident on the rectangular prism piece, and reflected light emitted from the rectangular prism piece is incident on the light receiving element of the receiving/emitting section. a side prism piece; and at least two prism pieces arranged on the other side of the rectangular prism piece so that the light reflected by a part of the window glass enters the rectangular prism piece again and is reflected by the other part of the window glass. a reflecting side prism piece having a reflective surface, a gap part is provided between the rectangular parallelepiped prism piece, the receiving/emitting side prism piece and the reflecting side prism piece, and an interface between the rectangular parallelepiped prism piece and the gap part. A raindrop sensor characterized in that a raindrop sensor is formed substantially perpendicularly to the window glass.