WO2010026032A2

WO2010026032A2 - Display device, transparent imaging element and method for the production of a transparent imaging element

Info

Publication number: WO2010026032A2
Application number: PCT/EP2009/060544
Authority: WO
Inventors: Stefan Altmeyer; Steffen Zozgornik; Gennaro Abbati; Stefan Henze
Original assignee: G+B Pronova Gmbh; Volkswagen Aktiengesellschaft
Priority date: 2008-08-26
Filing date: 2009-08-14
Publication date: 2010-03-11
Also published as: DE102008039737A1; WO2010026032A3; EP2329310A2

Abstract

The invention relates to a display device, such as a head-up display, having a substantially transparent imaging element (10), such as a windshield. An image is generated via an imaging device (18), such as an LCD, and radiated into the direction of the imaging element (10). According to the invention a reflection of the image occurs via a layer (14) connected to a carrier element (12) of the imaging element (10). The layer (14) has at least one holographic-optical element for reflecting an image. The invention further relates to a transparent imaging element, such as a windshield, and a method for the production of a transparent imaging element.

Description

Display device, transparent coating system and process for the production of a transparent imaging element

The invention relates to a Anzeigeeiπrichtung, in particular a head-up Dispiay, which is used for information display in motor vehicle windshields. Furthermore, the invention relates to a transparent imaging element and a method for producing a transparent imaging element, which is particularly suitable for a display device, such as a head-up display.

A transparent imaging element is, for example, a transparent pane made of, for example, glass or plastic, it being possible to image an image with the aid of the pane. For this purpose, the transparent imaging element has a carrier element, such as the disc itself. To form the imaging element, the carrier element is provided with holographic-optical elements reflective layer. Such transparent imaging elements are used in display devices, such as head-up displays. In a head-up display, the transparent figurative element is the windshield of a motor vehicle. With the help of an imaging device, such as a projector, an image is deflected by means of optical elements, such as lenses and mirrors, in the direction of the windshield. Starting from the imaging device mounted in the dashboard, the beam path passes through a complex optical system of lenses and mirrors, which also in the Depending on the optical system, the viewer sees the image at a suitable distance outside the windshield, In order to avoid that the dashboard is arranged and is thereby deflected in the direction of the windshield on the inside of the windshield Radiation is also reflected to the observer disturbing on the outside of the windshield and the observer thus doubly sees the BMd slightly offset, it is known to attach a Keiifoiie between the layers of the laminated glass.

Another disadvantage is that due to the provision of a reflective layer, the angle of incidence is identical to the Ausfaüswinkel and therefore the position of the projector is fixed.

A major problem with known head-up displays is the curvature of the windshield. It is necessary to compensate for the curvature of the windshield by the optical system. Due to the manufacturing process of the windscreens, however, they do not have exactly the same curvatures. This has the consequence that the optical system must be adapted to the curvature of the respective windshield. For this purpose, the windshields are extensively measured and sorted into categories or lots of similar curvatures. Tuned to this are several optical systems that must be assigned to the windshield of the corresponding curvature. For example, it is also problematic to replace the windshield, as this may result in a distortion of the image due to the changed curvature. Accordingly, the optical system must be readjusted or even replaced if necessary. Another problem is that the curvature of the windshield often changes during installation, which in turn can cause distortions. The above problem is not only with windshields but also with any other curved support elements that are used as an imaging element for an imaging system.

The object of the invention is to provide an improved display device that can be operated in particular with simpler and therefore less expensive imaging devices. It is another object of the invention to provide an improved transparent imaging element and a corresponding production method.

The object is achieved by a display device according to claim 1, a transparent imaging element according to claim 7 and a method for producing a transparent Abbiidungselements according to claim 21.

The transparent imaging element according to the invention, which is particularly suitable for display devices, such as head-up displays and the like, has a transparent carrier element. The transparent carrier element is, for example, a glass, plastic, composite pane or the like. A layer is connected to the transparent carrier element for reflection of an image. According to the invention, the layer is an exposed layer, wherein an at least one holographic-optical element is formed by the exposure. The layer exposed for this purpose is photosensitive, wherein an exposure takes place for example with a laser. The exposure forms the at least one holographic-optical element. Depending on the type of exposure, in particular the orientation, the shape, the number and / or the spectral compositions of the exposed sources, an interference pattern is generated in the layer. The holographic-optical elements can also be formed by other methods, such as embossing or electron beam lithography , After the optionally required fixing or curing of the layer, a holographic-optical element is formed which reflects light incident on the layer in a defined wavelength and angular range. According to the invention, the carrier element can be curved together with the not yet exposed layer or a not yet exposed layer can be applied to a curved carrier element, wherein the exposure of the layer takes place in a curved position. This has the consequence that regardless of the curvature, in particular also unevenness of the carrier element, a suitable interference pattern is generated by the Beuchten. In this case, the generated interference pattern thus has the same optical imaging properties, in particular even with local changes in curvature and unevenness.

The carrier element may also be a film, which is then applied to the pane, in particular glued, after the coating has been applied to complete the imaging element, for example. In this case, the film is exposed in a curvature corresponding to the curvature of the disk or dgh to which the film is applied. Since it is necessary in this case to know the exact curvature of the disc or the like, it is particularly preferred that the layer to be exposed is arranged directly on a surface of the carrier element, wherein the carrier element in particular to the essential element, such as Slice of picture element itself, trades.

The exposure of the layer is preferably such that the layer reflects the incident light Weilenlängen- and / or angle specific. In particular, the layer may be formed as a holographic mirror, as a hollow or Wöibspiege! acts, which preferably has magnifying properties. To form a holographic mirror, the layer is exposed with two opposing point light sources, each generating a spherical wave. The layer to be exposed is thus arranged between the two light sources. Possibly. can the two Point light sources are arranged at different angles to the normal of the carrier, ie to produce an independent of the Oberfiächenreflex angle-specific Refiektion. These are then an off-axis concave mirror or an off-axis mirror.

It is essential to the invention that the imaging element of the display device according to the invention has a holographic-optical element which at the same time reflects and images the image in the direction of a viewer. As a result, the image plane for the viewer is preferably clearly outside the support element of the holographic-optical element, i. especially clear outside the windshield. Depending on the design of the holographic-optical element, an image within, i. related to the viewer in front of the support element, such as the windshield done. For this purpose, according to the invention, the at least one holographic-optical element additionally has imaging properties. This is preferably a magnifying image.

In the case of curved support elements, it is particularly preferred to prevent the formation, preferably exposure of the layer, only after completion of the support element, i. when the carrier element is in its final curved position. If the transparent imaging element is a windshield for a head-up display, it is therefore particularly preferable to carry out the exposure only after the windshield has been installed in the motor vehicle.

In particular, it is preferably possible by a corresponding exposure of the layer to integrate a holographic lens in the holographic element. This is advantageous, in particular, when using the transparent imaging element in a marking device, since in this way one between the imaging device and the imaging device provided optical system can be simplified or possibly even completely eliminated.

It is particularly preferred to arrange the layer to be exposed within the carrier element, in particular as an intermediate layer of a laminated glass or the like. This has the advantage that the layer is particularly protected against mechanical damage. In particular, when arranging the layer within the carrier element, it is preferable to use a material for the layer which can be fixed without contact after the inspection. The fixation of such material takes place for example by heat. Furthermore, it is particularly preferred to use a material that does not need to be fixed after exposure. For example, the use of photopolymers is suitable here.

A depiction device according to the invention, which is in particular a head-up display for motor vehicles, has a substantially transparent imaging element. Furthermore, the display device has a biology device, which is in particular a display, such as an LC, LED or OLED display. With the aid of the imaging device, an image is generated, which is preferably emitted in the direction of the transparent imaging element or in the direction of the coated region of the carrier element. In the basic, simplest embodiment of the display device according to the invention, at least one holographic-optical element is connected to the imaging element. This serves to reflect the image in the direction of a viewer. The imaging element preferably has a transparent carrier element which is connected to an exposed layer for forming the at least one holographic-optical element. In this case, the imaging element is advantageously developed in particular as described above. Between the imaging element and the imaging element, a holographic lens may be arranged to enlarge the image. According to the invention, it is preferred that no optical system, in particular no optical mirrors or optical lenses, is provided between the imaging device and the imaging element. Due to the inventively designed transparent imaging element, a simply constructed display device can be realized. In particular, it is possible for the imaging device, such as the LCD, to be arranged laterally offset from the region of the transparent imaging element in which imaging takes place. The lateral offset can be compensated by a corresponding embodiment of the interference pattern. The arrangement of the imaging device is thus much more flexible, so that the construction of the dashboard is easier.

A further significant advantage of the imaging element according to the invention is that it can be defined, in particular within narrow limits, which wavelength range is reflected and transcribed. This ensures that in the corresponding wavelength range, the incident light is reflected to a large extent. This has the advantage that the imaging device can be illuminated by a weaker illumination device compared to known head-up displays and dg. As a result, the energy consumption of the display device can be significantly reduced. This is particularly advantageous in the construction of head-up displays for motor vehicles. It is also possible to define that multiple wavelength ranges are reflected.

According to the inventive method for producing a transparent imaging element, in particular an imaging element as described above, a layer with a transparent support member, such as a glass, plastic or composite disc or a corresponding film, connected, the layer is used to form a holographic-optical element. This can be done, for example, by exposure, Embossing or electron beam lithography done. Preference is given to the production of the holographic-optical element by exposure of a photosensitive layer. Subsequently, the carrier element can be curved or the layer can be applied to the already curved carrier element. According to the invention, the formation of the layer for forming holographic-optical elements in a curved state of the carrier element can take place. In this way, according to the invention, a diffractive structure can be produced in the layer whose optical properties are independent of the curvature of the support element.

Preferably, the support element is brought together with the layer to be exposed before exposure in its final form, in particular installed. This is particularly advantageous if the support element undergoes a further bend during installation, as is the case, for example, with windshields. The exposure of the layer is preferably carried out, as described above, with the aid of a plurality of interfering light sources for generating an interference pattern. This may be wavelength and / or angle specific, so that only light in a corresponding wavelength and / or angular range is reflected.

The material used may preferably be fixed without contact and, in a particularly preferred embodiment, self-fixing after exposure, so that an additional fixing step is eliminated. Preferably, the material comprises photopolymers.

The invention will be explained in more detail with reference to a preferred embodiment with reference to the accompanying drawings.

Show it :

Fig. 1 is a schematic diagram of a display device according to the invention, and Fig.2 u. 3 schematic representations for the production of holographic-optical elements in a photosensitive layer.

In the display device shown schematically in Fig. 1 is a head-up display for motor vehicles. The display device has an imaging element 10, which is a windshield in the illustrated embodiment. The windshield made of laminated glass is thus the support element 12 of the imaging element 10. In the illustrated embodiment, a layer 14 is disposed within the support member 12. Although the layer 14 is arranged in reality so that it runs parallel to an inner side 16 of the disk 12, the layer 14 is shown curved in Fig. 1 for clarity. This indicates that the at least one holographic-optical element is formed in the layer in such a way that it acts as a concave mirror, so that an enlargement of the image is achieved.

The image is generated by an imaging device 18, which in the illustrated embodiment is an LCD. The LCD 18 emits the image, as indicated by the beam path 20, in the direction of the at least one holographic-optical element formed by the layer 14. Due to the at least one holographic-optical element 14, the incident radiation 20 is reflected in the direction of an observer 24 in accordance with an indicated radiation 22. The observer 24, such as the motor vehicle handlebar, sees at freely adjustable distance from the windshield, for example within or outside the windshield 12, the image generated by the LCD 18.

In order to generate an interference pattern in the layer 14, two point light sources 28, 30 can be provided to form a hollow mirror according to FIG. 2. The two point light sources are arranged opposite to each other in the illustrated embodiment, so that the Layer 14, in which the interference pattern is generated, between the two point light sources 28, 30 is arranged. In the embodiment shown in FIG. 2, it is the design of a regular concave mirror, so that the two point light sources 28, 30 are arranged on a common axis 32 and the axis 32 is perpendicular to the layer 14.

It is also possible to form a, as shown in Fig. 3, Qff-axis concave mirror. In this case, the two Punktlichtquelien 28, 30 are not arranged on the axis 32. As a result, the interference pattern indicated in the layer 14 shown in FIG. 3 is formed.

Due to the formation of an off-axis concave mirror, it is possible to arrange the LCD 18 in a head-up display laterally offset from the area in which the layer 14 is provided.

By arranging the point light sources 28, 30 at an angle to each other, it is possible to form an angle-selective hologram. By such a hologram, light incident on the hologram is reflected only in a predetermined angular range. Likewise, by selecting corresponding wavelength ranges of the point light sources 28, 30, it is possible to form a wavelength-selective concave mirror. Such a hologram then only reflects light in a defined, predetermined wavelength range. Furthermore, it is possible to define a plurality of angular and wavelength ranges. In particular, by the definition of multiple wavelength ranges, it is possible to provide the viewer with multicolor information.

Claims

claims

1, display device, in particular head-up display, with

a substantially transparent imaging element (10), and

an imaging device (18) for generating an image emitted in the direction of the imaging element (10),

d a d u r c h e c e n c i n e s that

at least one holographic-optical element for reflection and simultaneous imaging of the image in the direction of a viewer (24) is connected to the imaging element (10).

2. Display device according to claim 1, characterized in that a holographic lens is integrated in the at least one holographic-optical element,

3, display device according to claim 1 or 2, characterized in that the imaging element (10) comprises a transparent support member (12) which is connected to form the holographic-optical element with a layer (14), wherein the holographic-optical element in the layer (14) is preferably formed by exposure or embossing,

4. Display device according to one of claims 1 to 3, characterized in that between the imaging device (18) and the imaging element (10) in the beam path further optical elements, such as lenses, mirrors or holographic lenses or holographic mirror! are arranged.

5. Display device according to one of claims 1 to 4, characterized in that the image of the inducing device (18) directly without interposition of optical elements to the imaging element (10).

6, display device according to one of claims 1 to 5, characterized in that the biology device (18) comprises a display, in particular an LC, an LED or an OLED display,

7. Transparent imaging element, in particular for a display device, such as a head-up display, with

a transparent support member (12), and

an exposed layer (14) connected to the carrier element (12) for forming at least one holographic-optical element for reflection and simultaneous imaging of an image, whereby the carrier element (12) and the layer (14) can be curved.

8. A display device or transparent imaging element according to claim 7, wherein a holographic lens is integrated in the at least one holographic-optical element,

9, display device or transparent imaging element according to one of claims 2 to 8, characterized in that the layer (14) has a curvature of the carrier element (12) substantially corresponding curvature,

10, display device or transparent imaging element according to one of claims 2 to 9, characterized in that the layer (14) is arranged directly on a surface (16) of the carrier element.

11. Display device or transparent imaging element according to one of claims 2 to 9, characterized in that the layer (14) is designed such that it reflects light wavelength-specific and / or winkeispezifisch.

12. Display device or transparent imaging element according to one of claims 2 to 11, characterized in that the training, in particular the exposure of the layer (14) after completion, in particular after the installation of the imaging element (10).

13. Display device or transparent imaging element according to one of claims 2 to 12, characterized in that the layer (14) has a diffractive structure generated in particular by an exposure.

14. Display device or transparent imaging element according to claim 13, characterized in that a reflected wavelength range and / or angular range is defined by the diffractive structure.

15. Display device or transparent imaging element according to claim 11 or 14, characterized in that the diffractive structure is formed such that the image distortion leading unevenness of the support element (12) are substantially balanced.

16. Display device or transparent imaging element according to one of claims 1 to 15, characterized in that the holographic-optical element has magnifying properties.

17. Display device or transparent Abbifdungselement according to any one of claims 2 to 16, characterized in that the layer (14) is arranged within the carrier element (12),

18. Display device or transparent Bildernernentent according to one of claims 2 to 7, characterized in that the layer (14) consists of a material in which the fixation of the exposure takes place without contact.

19. Display device or transparent AbbÜduπgselement according to one of claims 2 to 18, characterized in that the layer (14) consists of a material in which no fixation is required after the exposure,

20. Display device or transparent imaging element according to one of claims 2 to 19, characterized in that the layer (14) comprises photopolymers.

21. A process for producing a transparent imaging element, in particular according to one of claims 7 to 20, in which

a photosensitive layer (14) is connected to a transparent support element (12),

the carrier element (12) is curved before and / or after connection to the layer (14), and

the at least one holographic-optical element is formed when the carrier element (12) is curved together with the curved layer (14).

22. The method of claim 21, wherein the support member (12) together with the layer (14) before the formation of the holographic-optical element, in particular by exposure to its final shape brought, in particular installed,

23. The method of claim 19 or 21, wherein the layer (14) is formed, in particular exposed, that light wavelength-specific and / or angle-specific reflected.

24. The method according to any one of claims 19 to 23, wherein the layer (14) after forming, in particular exposure is preferably fixed without contact.

25. The method according to any one of claims 19 to 24, wherein the layer (14) comprises a self-fixing material.

26. The method according to any one of claims 19 to 25, wherein the layer (14) for generating an interference pattern is illuminated with interfering light sources.