A cover panel, for at least partially transparently covering at least one display instrument in a vehicle, has a microstructure applied on at least one surface. The microstructure is suitable for scattering visible light which is incident on the cover panel. The at least one window region of the cover panel is cutout from the microstructure. A method for manufacturing such a cover panel uses a molding tool with an applied microstructure matrix for forming a microstructure on a part of the molding tool which is assigned to a surface of a molded cover panel. The parts of the molding tool which are assigned to window regions are cut out from the microstructure matrix.

In a head-up display, a cover member includes a first transmissive member and a second transmissive member that transmit a light beam including an image generated by an image generation unit. The first transmissive member is formed to face upward from a front end to a rear end. Likewise, the second transmissive member is formed to face upward from a front end to a rear end. The rear end of the first transmissive member is offset to an upper side from the front end of the second transmissive member.

The present invention provides a display apparatus for use in a vehicle that prevents reduction in driver visibility and adds no constrains to vehicle interior design. The display apparatus includes an indicator unit and a reflection receiving surface. The indicator unit includes a housing, an indicator accommodated in the housing, and a face glass sheet attached to the housing in such a manner that the indicator is visible. The reflection receiving surface receives light traveling from an eye range and reflecting off the face glass sheet. the face glass sheet is formed into a cross-sectional concavity depressed toward the indicator. The concavity provides a curved surface that reflects the light from the eye range to the reflection receiving surface. The reflection receiving surface is a back surface of a vehicle structure placed at a position at which there is space between the reflection receiving surface and the face glass sheet.

The invention relates to a display device comprising a display plane, on which one or more planar display regions 10, 11 are arranged, said planar regions 10, 11 being covered by transparent coverings. A single transparent covering 3 covers all the planar display regions 10, 11 of the display device, is formed three-dimensionally on the viewer's side by regions of differing thicknesses and is connected on the side facing away from the viewer to the planar display regions 10, 11 by means of optical bonding. The refractive index of the material of the covering 3 corresponds to the refractive index of the optical-bonding material 8.

A display module and a vehicle-mounted display device are disclosed. The display module includes a middle frame, a display panel and an elastic adhesive body; the middle frame includes a first frame body, being arranged around an opening region and having a bearing surface; the display panel includes a middle portion and an edge portion; the adhesive body is located between the bearing surface and the edge portion; the middle frame further includes a second frame body, located at an edge of the first frame body and, the second frame body is located at a side of the first frame body away from the display panel, and an orthographic projection of the edge portion on a plane where the bearing surface is located at least partially overlaps with an orthographic projection of the second frame body on the plane where the bearing surface is located.

Provided is a vehicle display device which exhibits high visibility, and which has an attractive external appearance. A vehicle display device according to the present invention is provided with: pointer-type instruments (a speedometer and an engine tachometer; a display disposed next to the pointer-type instruments; and a planar protective plate which has, formed on the front surface thereof, a first reflected-light suppression layer. The protective plate is disposed so as to cover the front surfaces of the display and the pointer-type instruments. Furthermore, in the protective plate, light-blocking layers for concealing spaces between the display and the pointer-type instruments are formed. Moreover, a light-transmitting bonding layer, which covers and bonds a display surface of the display, and second reflected-light suppression layers, which cover the front surfaces of the pointer-type instruments, are formed on the rear surface of the protective plate so as to not overlie each other.

A dial plate is provided with a mark layer having translucency, the mark layer including numbers of linear grooves formed on a surface of the mark layer, and a reflective layer that is arranged on a back face side of the mark layer, and reflects light incident from the mark layer side. The reflective layer includes a light transmission area that allows the light emitted from a light source arranged on the back face side to transmit therethrough to a front face side, and displays a display design by the light transmitting through the light transmission area when the light source is turned on. In the reflective layer, at least the light transmission area is composed of pearl ink.

A display-system includes a transparent-display-body having a first-surface and a second-surface opposite to the first-surface, a sensor to detect a brightness of the transparent-display-body or a brightness around the transparent-display-body, an arithmetic-unit configured to derive, based on the brightness detected by the sensor, a background luminance caused by outside-light as when the transparent-display-body is viewed from a side of the second-surface, and a controller to cause video to be displayed on the first-surface, wherein where rear-show-through-luminance that is a luminance of the video that occurs on the side of the second-surface is denoted as BB and the background luminance is denoted as SB, the controller controls a video luminance in accordance with the background luminance derived by the arithmetic-unit such that (BB/SB) is less than or equal to a predetermined-contrast-value, the video luminance being a luminance at which the video is to be displayed on the first-surface.

A vehicle display device includes a housing mounted in a vehicle and having a light-shielding outer wall that forms an accommodation space, a slit being formed in the outer wall, a three-dimensional display surface disposed in the accommodation space and on which a real image is formed by display light, a projector disposed in the housing and configured to project the display light onto the display surface, and a reflector disposed outside the housing and having a reflection surface configured to reflect the real image toward an eyepoint in the vehicle. The shape of the reflection surface is a recessed shape such that light rays of the real image intersect in an optical path extending from the display surface to the reflection surface through the slit.

A refractive optical system is disposed in an optical path from a display surface to a viewing area and between a projection optical system and the viewing area. A housing receives a display device, the projection optical system, and the refractive optical system, and is provided with an opening. An opening cover has at least partially a curved portion, and is disposed in the opening so that light emitted from the display surface is incident on a convex side of the curved portion. When a light beam that is emitted from a center of the display surface and reaches a center of the viewing area is referred to as a reference light beam, a head-up display satisfies the following condition (1):

L2≦L1  (1)

where

L1 is a distance from an end on the anterior side of the observer of the refractive optical system to the opening cover, and

L2 is a distance from a position at which the reference light beam passes through the refractive optical system to the opening cover.