DE102015014919A1 - Test stand for a windshield and method for checking a windshield - Google Patents

Abstract

The invention relates to a test stand (10) for a windshield (12), comprising a receiving device for receiving the windscreen (12), wherein the test stand (10) at least one laser diode for emitting a laser beam directed onto the windshield (12) receivable by means of the receiving device (16) and with respect to the beam path of the laser beam (16) behind the recordable windshield (12) arranged screen (20). The invention further relates to a method for checking a windshield (12) by means of a test stand (10).

Description

The invention relates to a test stand for a windshield of the type specified in the preamble of patent claim 1. Furthermore, the invention relates to a method for checking a windshield by means of such a test stand.

When using a head-up display, a driver sees an image displayed by a display device of the head-up display, which is reflected in a windshield of the motor vehicle. This gives the driver the impression that the image in question seems to float over the hood at a certain distance, for example 1.5 meters away from him. In this case, two mirror images of the image displayed by means of the display device, a so-called double image, can arise. A goal is to use such windshields, in which the double image effect is not so strong that this can be perceived by a driver of a motor vehicle or other vehicle occupants.

To test the suitability of windscreens for head-up displays, appropriate test stands are used. The DE 10 2013 012 319 A1 shows a generic test stand for a windshield, which comprises a receiving device for receiving the windshield. In this case, test images displayed by means of a display device are photographed and compared with a desired image by means of an evaluation software, which involves a relatively high outlay on equipment. The degree of overlap of the double images is thus checked by means of the test bench. Usually, deviations in the millimeter range are to be investigated. Measurements and analyzes of these double images can be relatively error-prone.

It is therefore an object of the present invention to provide a test stand for a windshield and a method for checking a windshield, by means of which reliable checks of a windshield can be carried out with relatively little effort.

This object is achieved by a test stand for a windshield and by a method for checking a windshield having the features of the independent claims. Advantageous embodiments with expedient and non-trivial developments of the invention are specified in the dependent claims.

In order to enable a particularly simple and reliable inspection of a windshield, it is provided according to the invention that the test stand has at least one laser diode for emitting a laser beam directed onto the windshield which can be picked up by means of the receiving device and a screen arranged behind the receivable windshield relative to the beam path of the laser beam , The laser beam emanating from the laser diode thus passes through the windshield which is recorded by means of the recording device and impinges on the screen in the form of two points of light.

It is therefore provided according to the invention, for testing windshields instead of a display device of a head-up display, to use the at least one laser diode, which can transmit a laser beam through the windscreen to be tested. The canvas serves as a kind of target plate with a plane surface, which the laser beam strikes and thus becomes punctiform visible. When passing through the windshield, the laser beam is easily deflected and is multiplied by reflections within the windshield. As a result, at least two points are visible on the canvas serving as the target plate.

The distance between these points can be used to evaluate the suitability of the windshield for the use of a head-up display. The distance between the two points striking the screen, which result from the laser beam passing through the windshield, is a measure of the double image that would arise when using the tested windshield. The distance between the two points striking the screen can be detected manually or by image-capturing optical systems, such as sensors or cameras. Moreover, it is also possible to use a plurality of laser diodes instead of the at least one laser diode, so that a plurality of laser beams are transmitted, which pass through the windshield, easily deflected and multiplied by reflections within the windshield and then impinge as respective points on the screen ,

By means of the test stand according to the invention, a particularly precise measurement and inspection of windshields with regard to the formation of double images is possible. In addition, the test stand according to the invention can be constructed particularly compact, with no costly head-up display components are required. When using the test stand, it is also possible that the windshield is initially omitted, so that a transmitted laser beam without passing through the windshield, impinges on the screen. This determines a kind of zero position. Taking into account this information can also be transmittive Windshield properties are determined. By means of the test stand according to the invention, it is therefore also possible to determine double images in transmission, which are usually specified only by windscreen suppliers.

An advantageous embodiment of the invention provides that the test stand has a sensor device, in particular a camera system, for detecting a distance between at least two incident on the screen light spots, which result from the passing through the windshield laser beam. By using the sensor device, a measure of the double image of the tested windshield can be determined in a particularly exact manner.

A further advantageous embodiment of the invention provides that, in the direction of the beam path of the laser beam, at least one deflecting mirror is arranged between the screen and the windscreen which can be received by means of the receiving device. The use of the deflecting mirror extends the path of the laser beam to be traveled until it hits the screen. Even with relatively compact dimensions of the test bench so a relatively long beam path of the laser beam can be achieved. Moreover, it is also possible that instead of just one deflecting mirror, a plurality of deflecting mirrors are used, as a result of which the travel path of the laser beam can be increased even more. The base of the test stand can thus be kept relatively compact, but due to the use of at least one deflecting mirror or even a plurality of deflecting the path of the laser beam can still be very large.

In a further advantageous embodiment of the invention, it is provided that the test stand has an absorber for absorbing laser beams reflected by the windshield. This can be avoided in particular disturbing reflections during the review of the windshield.

In the method according to the invention for testing a windshield, the test stand according to the invention or an advantageous embodiment of the test stand according to the invention is used, wherein the windshield is received by means of the receiving device, a laser beam is directed onto the windshield by means of the light emitting diode and a distance between two light spots striking the screen is detected which result from the laser beam passing through the windshield. Advantageous embodiments of the test stand according to the invention are to be regarded as advantageous embodiments of the method according to the invention, wherein the test stand has in particular means for performing the method steps.

An advantageous embodiment of the method according to the invention provides that a position is determined on the screen, at which the laser beam without passing through the windshield hits the screen, and is compared with the position of the light spots on the screen, which from the through the windshield passing laser beam result. Optionally, therefore, a kind of zero position can be determined by omitting the windshield, whereby, starting from this point, respective distances to the light points occurring in the windshield arranged in the laser beam are measured.

Further advantages, features and details of the invention will become apparent from the following description of preferred embodiments and from the drawing. The features and feature combinations mentioned above in the description as well as the features and feature combinations mentioned below in the description of the figures and / or shown alone in the figures can be used not only in the respectively specified combination but also in other combinations or in isolation, without the scope of To leave invention.

The drawing shows in:

1 a schematic side view of a test stand for a windshield; and in

2 a further schematic side view of the test stand, wherein this with respect to its components in more detail than in 1 is shown.

In the figures, identical or functionally identical elements are provided with the same reference numerals.

A total with 10 designated test stand for a windshield 12 is in a schematic side view in 1 shown. The test bench 10 includes an at least one laser diode having image source 14 for emitting a laser beam 16 , The test bench 10 also includes a receiving device, not shown here for receiving the windshield 12 , In addition, the test bench includes 10 a deflecting mirror 19 , with the windshield 12 relative to the beam path of the laser beam 16 between the deflecting mirror 19 and the image source 14 is arranged. In the beam direction of the laser beam 16 behind the deflection mirror 19 There is a semi-transparent screen serving as a target plate 20 ,

Will the laser beam 16 from the at least one laser diode of the image source 14 towards the windshield 12 emitted, the laser beam enters 16 through the windshield 12 through, the laser beam 16 inside the windshield 12 reflected and multiplied. After passing out of the windshield 12 So are from the one laser beam 16 two laser beams 16 . 18 , The two laser beams 16 . 18 meet on the screen 20 in different positions.

The test bench 10 further includes a camera 22 for detecting a distance between the positions at which the two laser beams 16 . 18 on the canvas 20 incident. In 1 is also another laser beam 24 located. The laser beam 24 corresponds to the laser beam 16 when the laser beam 16 not through the windshield 12 pass through and through the deflection mirror 19 distracted as well as on the canvas 20 would strike.

For calibration and alignment of the deflection mirror 19 can the windshield 12 initially be omitted, so that the laser beam 16 in the form of the laser beam 24 without the windshield 12 to step on the screen 20 meets. The distance between the respective impact positions of the laser beams 16 . 18 when using the windshield 12 on the canvas 20 can additionally with the impact position of the laser beam 24 be compared, so with the case that the windshield 12 in the test bench 10 not been used yet.

In 2 is the test bench 10 shown again in a somewhat more detailed schematic side view. Both the image source 14 as well as the deflection mirror 19 are pivotally mounted so that their orientation to each other can be changed. The camera 22 is behind a maintenance access 26 arranged and on the semi-transparent screen 20 directed. The semi-transparent canvas 20 serves as a virtual image plane of the test bench 10 and can also be exchanged if necessary. In 2 is the beam path of several laser beams 16 through the windshield 12 , over the deflection mirror 19 until the impact on the screen 20 again schematically illustrated in the case that the image source 14 comprises a plurality of laser diodes.

Below the windshield 12 is as part of the test bench 10 another absorber 28 arranged, by means of which reflected laser beams are absorbed. The laser beams emitted from the image source 16 when passing through the windshield 12 partially reflected and duplicated, being after passing through the windshield 12 the Prüflaserstrahlen in the form of a primary and secondary transmission, ie in the form of deflected and partially reproduced laser beams 16 . 18 exist and on the canvas 20 to meet.

Instead of a deflecting mirror 19 It is also possible to provide a plurality of deflecting mirrors to the beam path of the laser beams 16 . 18 still to extend. So even with a relatively compact design of the test bench 10 can be relatively long beam paths of the laser beams 16 be realized simply by adding several of the deflecting mirrors 19 be used.

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• DE 102013012319 A1 [0003]

Claims (6)

Test bench ( 10 ) for a windshield ( 12 ), with a receptacle for receiving the windshield ( 12 ), characterized in that the test bench ( 10 ) at least one laser diode for emitting a recordable on the means of the receiving device windshield ( 12 ) directed laser beam ( 16 ) and one related to the beam path of the laser beam ( 16 ) behind the windscreen ( 12 ) arranged canvas ( 20 ) having. Test bench ( 10 ) according to claim 1, characterized in that the test bench ( 10 ) a sensor device ( 22 ), in particular a camera system, for detecting a distance between at least two on the screen ( 20 ) has incident light points, which from the through the windshield ( 12 ) passing through laser beam ( 16 ) result. Test bench ( 10 ) according to claim 1 or 2, characterized in that in the direction of the beam path of the laser beam ( 16 ) at least one deflection mirror ( 19 ) between the canvas ( 20 ) and the recordable by means of the receiving device windscreen ( 12 ) is arranged Test bench ( 10 ) according to one of the preceding claims, characterized in that the test bench ( 10 ) an absorber ( 28 ) for absorbing through the windshield ( 12 ) has reflected laser beams. Method for checking a windshield ( 12 ) by means of a test bench ( 10 ) according to one of the preceding claims, in which the windscreen ( 12 ) received by the receiving device, a laser beam ( 16 ) by means of the LED on the windshield ( 12 ) and a distance between two on the screen ( 20 ) is detected from the light passing through the windscreen ( 12 ) passing through laser beam ( 16 ) result. Method according to claim 5, characterized in that a position on the screen ( 20 ) is determined at which the laser beam ( 16 ) without the windshield ( 12 ) to step on the canvas ( 20 ), and with positions of the light spots on the screen ( 20 ), which from the through the windscreen ( 12 ) passing through laser beam ( 16 ) result.

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