A DISPLAY DEVICE

Abstract

The present invention provides for a display device, which is applied to rear projection system. The device includes a screen, which is curved with incident rays penetrating into a concave side of the screen, and then being transmitted by the screen to form parallel rays to be emitted out from the convex side of the screen. The device also includes a projecting unit, configured to project rays of an image to the screen, the image including a valid area and an invalid area. The device yet further includes a covering plank, located between the screen and the projecting unit, and configured to cover the invalid area of the image for getting the light of the valid area of the image emitted by the projecting unit to project to the screen.

Claims

1. A display device, applied to a rear projection system, comprising: a screen, which is curved, the screen permitting incident rays to penetrate into a concave side of the screen, and then be transmitted by the screen to form parallel rays emitted from a convex side of the screen; a projecting unit, configured to project rays of an image to the screen, the image including a valid area and an invalid area; and a covering plank, located between the screen and the projecting unit, the plank being configured to cover the invalid area of the image so as to permit the light of the valid area of the image to be emitted by the projecting unit onto the screen.

2. The display device as claimed in claim 1, wherein the screen is made from translucent resin.

3. The display device as claimed in claim 1, wherein the projecting unit is a silicon based liquid crystal projecting unit or a digital light procession projecting unit.

4. The display device as claimed in claim 1, further comprising a plurality of covers, arranged between the projecting unit and the screen in parallel and in sequence, with an orientation along a direction of emitting light of the image emitted by the projecting unit, for covering the invalid area of the image.

5. The display device as claimed in claim 4, wherein center area of each of the covering planks is a hollow area, and the plurality of covers with increasing size of the hollow areas in sequence, are positioned between the projecting unit and the screen equidistantly so as to eliminate the invalid area of the image.

6. The display device as claimed in claim 1, wherein the projecting unit comprises: a receiver module, for receiving projected images; and a projector module, connecting to the receiver module, and configured to project lights of the projected images to the screen.

Description

BRIEF DESCRIPTIONS OF THE DRAWINGS

[0007] FIG. 1 is a diagrammatic drawing of light spot ghost shadow of a projection light source of a rear projection screen in the art;

[0008] FIG. 2 is a structural schematic drawing of a display device of an embodiment according to the invention;

[0009] FIG. 3 is a schematic drawing of rays casting of a screen made from translucent resin of an embodiment according to the invention;

[0010] FIG. 4a is a frame schematic drawing of the elliptical valid area of projected image of an embodiment according to the invention;

[0011] FIG. 4b is a frame schematic drawing of the rectangular valid area of a projected image of an embodiment according to the invention;

[0012] FIG. 4c is a frame schematic drawing of the polygonal valid area of a projected image of an embodiment according to the invention.

DETAILED DESCRIPTIONS

[0013] As shown in FIG. 2-4, a display device, applied to the rear projection system, includes: a screen 1, a cover 2 and a projecting unit 3, wherein the screen 1 is curved, configured to make incident rays penetrate into the concave side of the screen 1 and to then transmit from the convex side of the screen 1, projecting out in the form of parallel rays 4; the projecting unit 3 is configured to project rays of an image to the screen 1, and the image includes a valid area A and an invalid area B; the cover 2 is located between the screen 1 and the projecting unit 3, configured to cover the invalid area B of the image for getting the light of the valid area A of the image emitted by the projecting unit 3 to project to the screen 1.

[0014] In this embodiment, the display device is applied to the rear projection system, which eliminates the fuzzy borders of projected images with the use of the cover 2, this not only improves the contrast of projected images, but also eliminates the light spot ghost shadow 6 (see FIG. 1 and FIG. 3), with the use of the screen 1, which is able to let incident rays penetrate through itself and form parallel rays 4, increasing the utilization rate of light source. Moreover, the use of the curved screen 1 highlights the layering of images, thus promoting sensual experience of viewers.

[0015] In a preferable embodiment, the screen 1 is made from translucent resin. Furthermore, the screen 1 can use curved Fresnel lens whose surface is covered by a semi-transparent layer. Fresnel lens is a sheet lens which is made from polyolefin resin using injection molding, one side of its lens surface is a mirror side, the other side of that is engraved with concentric circles placed in sequence from small to large, which is able to let incident rays penetrate through the lens and emit out parallel rays, thus improving the contrast of images, more uniformly, and eliminating the light spot ghost shadow of projected images.

[0016] In a preferred embodiment, the projecting unit 3 is a silicon based liquid crystal projecting unit or a digital light procession projecting unit.

[0017] Liquid Crystal on Silicon (LCOS) uses a reflex process to form images, with 40% of utilization efficiency. Compared with other projection technology, a remarkable advantage of LCOS technology is high resolution, and projecting units with LCOS technology have further advantages such as high efficiency of the light utilization, small size, high aperture ratio and so on.

[0018] Digital Light Procession (DLP) has a technology core based on a digital microscope system consisting of tens of thousands of lenses, with a distance of less than 1 μm between each lens, thereby achieving extremely high-duty factor. Reducing the distance among pixels of the projected images to the limit could generate seamless digital pictures, which can keep good image sharpness at any size, without any pixel scar or sieve pore caused by other technologies, thus achieving the level of high-definition LCD in displayed images. DLP projecting technology can promote black layer and shadow effect. When a movie is played, DLP movie theatre technology can display 350 trillion colors, which are more than 8 times over the movie.

[0019] In a preferable embodiment, there are more than one of the covers 2, a number of the covers are arranged between the projecting unit 3 and the screen 1 in parallel and in sequence, with an orientation along a direction of emitting light of the image emitted by the projecting unit 3, for covering the invalid area B of the projected image.

[0020] As shown in FIGS. 3-4, in a preferable embodiment, center areas of the covers 2 are hollow areas, and the plurality of covers with increasing size of hollow areas in sequence, positioned between the projecting unit 3 and the screen 1 equidistantly for eliminating the invalid area B (fuzzy borders) of the projected image, thus displaying the valid area A, which is elliptical, rectangular, polygonal (see FIG. 4a-4c) or in other shapes.

[0021] In a preferable embodiment, the projecting unit 3 comprises: a receiver module and a projector module, wherein the receiver module is configured to receive projected images; wherein the projector module, connected to the receiver module, is configured to project lights of the projected images to the screen 1.

[0022] When it is used, a video interface could be set in the projecting unit 3, such as HDMI, MIPI or RGB interface, and the projecting unit 3 is connected with an external control chip through the video interface. When the video interface of the projecting unit 3 have been connected with that of the control chip, the projecting unit 3 can receive video signals transmitted by the control chip, and with the use of the cover 2, the projecting unit 3 can project the valid area A of the received image to the curved screen 1 made from resin material, finally displaying the valid area A of the image on the curved screen 1 of a robot.

[0023] The above description is referred only to the preferred embodiments of the invention, and it does not limit the implement method and the protecting scope of the invention. It is obvious for the skilled in the art that the changing and variation made by the specification and drawings of the invention should fall into the scope of the invention.