WO2007022960A1

WO2007022960A1 - Sun sensor for a motor vehicle

Info

Publication number: WO2007022960A1
Application number: PCT/EP2006/008258
Authority: WO
Inventors: Matthias Richwin
Original assignee: Leopold Kostal Gmbh & Co. Kg
Priority date: 2005-08-25
Filing date: 2006-08-23
Publication date: 2007-03-01
Also published as: DE102005040147A1

Abstract

The invention relates to a sun sensor for a motor vehicle having: a sensitivity that depends on the direction of incident radiation, and; an optical body, which is placed in front of the window of incidence of the radiation receiver and which has a facet structure.

Description

Sun sensor for a motor vehicle

The invention relates to a sun sensor for a motor vehicle with a sensitivity dependent on the irradiation direction, with a radiation receiver and an optical body arranged in front of the entrance window of the radiation receiver.

Solar sensors are used in motor vehicles for determining the solar radiation intensity and / or the solar irradiation direction. The acquired data are provided in particular for the control of air conditioning machines, since the solar radiation significantly influences the subjective temperature perception of the vehicle occupants. The vertical angle, that is to say the angle of the sun above the horizon and the horizontal angle which indicates the direction of the sun relative to the direction of travel of the motor vehicle, are preferably detected. Furthermore, z. B. for a two-zone automatic climate control to determine the solar radiation on the driver and passenger side separately, for a one-zone automatic climate control the total solar radiation.

Sun sensors generally have a sensitivity dependent on the irradiation direction. As a result, sun sensors can be realized with a radiation receiver, in which the detected solar radiation intensity is weighted as a function of the direction of incidence. Typical directions for the maximum sensitivity are about 45 ° to the direction of travel and about 45 ° to the horizon.

In the prior art, the angular characteristic of the sun sensors is achieved by a correspondingly aligned installation of the radiation receiver. However, a precise alignment of the radiation receiver means a high assembly cost. From EP 0350 866 B1 a photodetector system with a hemispherical diffuser is known. Such a diffuser has a relatively large height and leads to a large overall height of the sensor.

It set itself the task of creating a simple and inexpensive to produce sun sensor, which is also characterized by a flat sensor structure.

This object is achieved in that the optical body has a facet structure.

Such an optical body is simple and inexpensive to produce as a disc-like plastic injection molded part.

It is advantageous if the optical body simultaneously forms a housing part of the sun sensor. As a result, it is also possible without much effort to advantageously combine a sun sensor with other optical sensors, such as moisture or ambient light sensors, arranged on the windshield, for example, and to integrate them in a common housing.

Optical bodies with facet structures on their surface are also used to form light guides or diffusers, the facets in many cases forming refractive prisms. The im

The optical body used in conjunction with a sun sensor likewise forms a light guide body whose inlet and / or exit surfaces can act as diffusers.

As a facet structure, any, preferably periodic, structuring of a substantially planar optical body can be considered has at least two groups of differently oriented surfaces. The facet structure is preferably designed as an asymmetric sawtooth structure, wherein shorter sawtooth edges extend approximately parallel to the surface normal of the optical body and longer sawtooth edges are arranged at an angle thereto.

Due to the sawtooth structure, a transmission dependent on the angle of incidence can already be achieved. The effect is further enhanced when the shorter and longer sawtooth edges have different optical properties. Thus, the longer Sägezahnflanken be provided with light-collecting cylindrical surfaces and / or with a diffuse surface in order to collect the largest possible amount of light and / or distributed over the largest possible area of the radiation receiver.

Accordingly, it is advantageous if the shorter sawtooth edges are designed to be as light-permeable as possible and, for this purpose, preferably have an absorbing or reflecting surface.

When installing the sun sensor in a motor vehicle, the edges of the prism-shaped facets can first in a direction parallel to

Vehicle vertical axis and parallel to the windshield. In this arrangement, the maximum sensitivity in the horizontal direction is below the angle specified by the facet angle, in the vertical direction it is in the direction of the disc solder.

If you now turn the edges of the facets around the disk slot, the direction of the main sensitivity also shifts vertically.

These two angles (facet angle and rotation angle of the whole structure) allow the horizontal and vertical direction of the Main sensitivity can be set. The width of the angular characteristic is adjusted by the scattering intensity of the diffuse surfaces.

It is particularly advantageous to provide at least two radiation receivers with different orientation. This makes it possible to detect both the exact irradiation direction and the absolute irradiation intensity.

The radiation receiver can advantageously be designed as simple and cost-effective photodiodes and preferably have the largest possible entrance window on. It is advantageous if the photodiodes are especially sensitive to infrared radiation. For this purpose, it is advantageous to form the optical body by coloring as a filter for infrared radiation.

A particular advantage of the arrangement according to the invention lies in its tolerance insensitivity, which distinguishes it from diaphragm or lens arrangements. The angular characteristic is generated here independently of the position of the radiation receiver to the optical structure, as long as the radiation receiver is completely below the structure.

The invention is described below by means of embodiments with reference to the accompanying figures.

Show it:

FIG. 1 shows a schematic diagram of the structure of a sun sensor,

Figure 2 is a sketch of an advantageous embodiment.

1 shows the basic structure and operation of a sun sensor according to the invention in a schematic representation. Of the Sun sensor consists of a surface running optical radiation receiver (1), which may be formed for example by a photodiode with a relatively large entrance window.

In front of the light entry window of the radiation receiver (1), an optical body (2) is arranged, in which a surface area substantially parallel to the radiation receiver (1) forms a facet structure. The facet structure is formed by a series of similar, respectively asymmetrically formed saw teeth. The sawtooth structure (3) is formed in this example on the radiation receiver (1) facing the underside of the optical body (2). Alternatively, the sawtooth structure (3) can also be arranged on the upper side or at the same time on the lower and upper side of the optical body (2).

The sawtooth structure (3) can consist of a plurality of individual teeth or, in the extreme case, even of a single tooth, which forms a single, with respect to the entrance surface of the radiation receiver (1), oblique edge.

As FIG. 1 shows, the sawtooth structure (3) of the optical body (2) already produces a clear directional characteristic with respect to the radiation intensity reaching the radiation receiver (1). If a light beam strikes a long flank (4) of a saw tooth (light path a) lying at an acute angle to the surface of the radiation receiver (1), the largest portion of the incident light is transmitted in the direction of the radiation receiver (1)

If, on the other hand, light falls on one of the shorter flanks (5) of a sawtooth, approximately perpendicular to the surface of the radiation receiver (1), represented by the light path b, the largest portion of the incident light is directed past the radiation receiver (1). Only a relatively small one Proportion of the grazing light striking a longer flank (4) is directed in the direction of the radiation receiver (1).

Accordingly, light incident flat from the left side is directed to a greater part onto the radiation receiver (1) than light incident at an equal angular distance from the right.

The sawtooth structure (3) thus forms a directional characteristic for incident light, which favors frontally opposite side incident light and also prefers the left before the sun sensor half-space in front of the right half space. This emphasis can be further increased by the fact that the longer edges (4) of the sawtooth structure (3), for example by a coating, an optically diffuse surface (6) and the narrow edges (5) have an optically absorbing or reflective effect.

To determine an absolute radiation intensity or to a more accurate angular resolution, a plurality of sun sensors arranged offset relative to one another can be provided, the measurement results of which can be evaluated by a ratio formation.

It is advantageous, for example, to arrange the sensors such that their sawtooth structures (3a, 3b) are offset from each other by an angle α. Such an arrangement is indicated schematically in FIG. The position of the sawtooth structure (3a, 3b) is represented here by the hatching of the optical bodies (2a, 2b). LIST OF REFERENCE NUMBERS

1 radiation receiver

2, 2a, 2b optical body 3, 3a, 3b sawtooth structure

4 longer flank

5 shorter edge

6 diffuse surface a, b light paths

Claims

claims

1. Sun sensor for a motor vehicle with one of the

Irradiation direction dependent sensitivity, with a radiation receiver (1) and one in front of the entrance window of the

Radiation receiver (1) arranged optical body (2, 2a, 2b),

characterized,

the optical body (2, 2a, 2b) has a facet structure.

2. Sun sensor according to claim 1, characterized in that the radiation receiver (1) is formed flat.

3. Sun sensor according to claim 1, characterized in that the optical body (2, 2 a, 2 b) is a plastic injection molded part.

4. Sun sensor according to claim 1, characterized in that the facet structure is formed spatially asymmetrical.

5. Sun sensor according to claim 1 or 4, characterized in that the facet structure by a sawtooth-shaped structuring (3, 3a, 3b) of a surface of the optical body (2, 2a, 2b) is formed.

6. Sun sensor according to claim 1 or 4, characterized in that the optical body (2, 2a, 2b) has at least two groups of optical surfaces, each having different optical properties.

7. Sun sensor according to claim 6, characterized in that at least one group of the optical surfaces is formed diffusely scattering.

8. Sun sensor according to claim 6, characterized in that form at least one group of optical surfaces cylindrical surfaces.

9. Sun sensor according to claim 1, characterized in that the radiation receiver (1) is designed as a photodiode.

10. Sun sensor according to claim 1, characterized in that a plurality of radiation receivers each having an optical body (2 a, 2 b) are arranged side by side.

11. Sun sensor according to claim 10, characterized in that the optical body (2 a, 2 b) against each other have an angular offset.

12. Sun sensor according to claim 1, characterized in that the optical body (2, 2a, 2b) has a permeable only to infrared radiation, colored housing.