KR0182453B1 - Rear Projection Screen for Rear Projection Television - Google Patents

Abstract

The present invention can reduce the production cost by simplifying the structure compared to the screen of the conventional rear projection television, and radiated from the projection lens 30 to provide a rear projection screen for the rear projection television that can have a higher resolution. The first sheet 31 that focuses the image beam and the second sheet 32 which is installed in front of the first sheet 31 at regular intervals to disperse the image beam passing through the first sheet 31. In the rear projection television screen comprising a vertical component and a horizontal component of the image beam emitted from the projection lens (30) to proceed in parallel to the observer side, respectively, or to have a certain convergence, divergence angle The horizontal lenticular Fresnel lens layer 31a and the vertical lenticular Fresnel lens layer 31b constitute the screen 40. The lenticular lens layer 32a and the anti-reflective dispersant layer 32b in the vertical direction are respectively formed on both surfaces of the first sheet 31 and formed on both surfaces of the second sheet 32 positioned on the viewer side. will be.

Description

Rear Projection Screen for Rear Projection Television

1 is a perspective view showing the structure of a rear projection screen for a conventional rear projection television.

2 is a perspective view showing the configuration of a rear projection screen for a rear projection television according to the present invention.

* Explanation of symbols for main parts of the drawings

30 projection lens 31 first sheet

31a: Horizontal lenticular-Fresnel lens layer

31b: Vertical lenticular-Fresnel lens layer

32: second sheet 32a: vertical lenticular lens layer

32b: antireflective dispersion layer 40: screen

The present invention relates to a rear projection screen for a rear projection television, and in particular, by widening the left and right widths of the image beams projected on the screen, providing a wide screen similar to that of a movie screen at a low price to the user and at the same time fundamentally generating moire patterns. The present invention relates to a rear projection screen for rear projection television which can be suppressed.

Image display apparatuses are roughly classified into direct view image display apparatuses and projection image display apparatuses according to their display methods.

The electronic direct view type image display device includes a CRT (Cathode Ray Tube), which has good image quality, but as the screen is enlarged, problems such as weight and thickness of the CRT increase and manufacturing cost increase, resulting in a large screen. Not suitable for production.

In addition, the latter projection image display device (projector) includes a liquid crystal display device (hereinafter referred to as an LCD), and such an LCD can be thinned, and has an advantage in that the weight can be reduced even when composed of a large screen. In this case, the light loss caused by the polarizing plate is large, and a thin film transistor for driving the LCD is formed for each pixel, and thus there is a limit in increasing the aperture ratio (light transmission area).

Therefore, a projector using Actuated Mirror Arrays (hereinafter referred to as AMA) has been developed by Aura, United States. The AMA arranges the warping elements corresponding to the pixels in a rectangle or a square on the substrate, and arranges the fine mirrors on the top of the warping elements in a checkerboard shape to change the tilt of the mirror at high speed by individually controlling each warping element. These AMAs consist of three sets, reflecting blue, green, and red light to the screen's point of view.

Also, projectors using AMA are distinguished from using one-dimensional AMA and two-dimensional AMA. The one-dimensional AMA has mirror surfaces arranged in an M × 1 array, and the two-dimensional AMA has mirror surfaces arranged in an M × N array. The projector using the 1D AMA pre-scans M x 1 rays using a scanning mirror, and the projector using the 2D AMA projects M x N rays to display an image having an array of M x N pixels.

1 is a perspective view showing a rear projection screen for a conventional rear projection television. As shown therein, the screen 8 is an image in which an observer can see an image-beam emitted from the projection lens 2. It consists of the 1st sheet 4 and the 2nd sheet 6 largely. A fresnel lens 4a is formed in the first sheet 4 so that the image beam projected from the projection lens 2 in parallel with the projection lens 2 is located in front of the projection lens 2. Alternatively, a function of focusing toward one point may be provided, and the projection image beam in the horizontal direction may be further distributed from side to side on both surfaces of the second sheet 6 positioned at a predetermined distance from the first sheet 4. The lenticular layers 6a and 6b are formed, and a black stripe layer 7 for absorbing external light is formed on the surface of the second sheet 6 located on the observer side to increase the contrast.

Inside the screen 8 as above, SiO ₂ , CaCO ₃ , TiO ₃ , BaSO ₄ , ZnO, Al (OH) ₃ , fine powdered glass so that the projected image beam passing through this area is distributed in some vertical direction. A dispersant such as) may be added, or a fine-mat-surface may be formed on the surface of the screen 8, or a dispersant may be added in parallel with the dispersing layer. The degree of dispersion by the dispersant or the dispersion layer depends on the control of the concentration or thickness of the dispersant or the dispersion layer, and the black stripe layer 7 of the second sheet 6 reduces the reflection of the external light on the screen surface (that is, The black stripe layer is absorbed and used to increase the contrast.

However, as described above, the rear projection screen for a projection television requires a high level of technology for processing a mold for forming the Fresnel lens 4a, and thus has a problem in that the manufacturing cost increases due to the burden of mold production cost. .

In addition, in order to increase the resolution of the screen 8, the width of the black stripe layer 7 and the distance between the black stripe layer 7 must be simultaneously reduced, which has a problem of some limitation, and the black stripe layer ( 7) and the projected image information interfere with each other, moire interference pattern is generated, and the quality of the screen is deteriorated.

The present invention has been made to solve the above problems, and compared to the screen of the conventional rear projection television, the structure can be simplified to reduce the production cost, it is possible to have a higher resolution rear projection television rear projection The purpose is to provide a screen.

In order to achieve the object of the present invention, the first sheet for focusing the image beam radiated from the projection lens, and the first sheet is provided so as to be spaced apart at regular intervals in front of the first sheet for dispersing the image beam passing through the first sheet In the rear projection television screen composed of two sheets, the vertical and horizontal components of the image beam emitted from the projection lens are allowed to proceed in parallel to the observer direction or to be focused with a certain convergence and divergence angle. A horizontal lenticular Fresnel lens layer and a vertical lenticular Fresnel lens layer are formed on both surfaces of the first sheet constituting the screen, and the lenticular lens layers in the vertical direction are formed on both surfaces of the second sheet located on the observer's side. Back-projection for rear projection television with anti-reflective dispersant layer The screen is provided.

Hereinafter, an embodiment of a rear projection screen for a rear projection television according to the present invention will be described in detail with reference to the accompanying drawings.

2 is a view illustrating a configuration of a rear projection screen for a rear projection television according to the present invention. As shown in FIG. 2, a first sheet 31 for focusing an image beam radiated from the projection lens 30 and the first sheet 31 are arranged. It is installed in front of the first sheet 31 at regular intervals and has a conventional structure consisting of a second sheet 32 for dispersing the image beams passing through the first sheet 31, the screen 40 is large The first sheet 31 and the second sheet 32 are formed as described above.

The horizontal lenticular Fresnel lens layer 31a for vertically and horizontally moving the vertical and horizontal components of the image beam emitted from the projection lens 30 toward the observer side or focusing with a certain convergence or divergence angle. ) And a vertical lenticular Fresnel lens layer 31b are formed on both surfaces of the first sheet 31 constituting the screen 40, respectively, and on both surfaces of the second sheet 32 located on the viewer side. Each was formed by forming a lenticular lens layer and an antireflective dispersant layer 32b in the vertical direction.

The horizontal lenticular Fresnel lens layer 31a and the vertical lenticular Fresnel lens layer 31b may be formed of, for example, a plurality of stepped convex cylinder lenses having the same arc center.

The vertical lenticular Fresnel lens layer 31b is composed of a horizontal array of convex cylinder lenses. The vertical lenticular Fresnel lens layer 31b focuses a horizontal component of the beam incident thereto, thereby increasing the divergence angle of the beam.

The anti-reflective dispersant layer 32b may be formed so as to form a layer different from the second sheet 32 on the surface of the second sheet 32 viewed from the viewer side, as shown in the example shown in FIG. It can be formed with a constant thickness.

The antireflective dispersant layer 32b is subjected to an antireflection coating or matte treatment to suppress reflection of external light to improve contrast of the image beam. In addition, a slightly blue pigment may be added to reflect only the reflected light of the blue system among the external lights, thereby increasing the contrast with respect to the external light of the image beam.

With reference to the accompanying drawings, the operation and effect according to the embodiment of the present invention as described above will be described in detail.

As shown in FIG. 2, when the image beam is projected from the projection lens 30 toward the screen 40, first, the first beam 31 is formed on the rear surface of the first sheet 31 constituting the screen 40. In the horizontal lenticular Fresnel lens layer 31a, the vertical component is focused toward the observer side, so that the image beam is focused on the upper and lower widths than the image beam emitted from the projection lens 30. One image beam is an image that is first radiated from the projection lens 30 by focusing the horizontal component toward the observer side in the vertical lenticular Fresnel lens layer 31b formed on the front surface of the first sheet 31. The image beam is focused on the left and right widths of the beam, and the top, bottom, left and right widths are focused.

In this state, the image beam passing through the first sheet 31 passes through the second sheet 32 and passes through the vertical lenticular Fresnel lens layer 31a formed in the second sheet 32. When the components in the horizontal direction are focused more and penetrate the antireflective dispersant layer 32b, the observer can observe the image of the image beam in a wide range in the horizontal direction, which is dispersed and further dispersed by the vertical direction and the vertical lenticular Fresnel lens layer. Of course, since the left and right width of the image beam is wider, it can be applied to a wide projector.

The effect of the present invention as described above is to form a non-reflective dispersant layer having a flat surface on the surface of the second sheet constituting the screen to distribute the image beam passing through this place in the vertical direction and the horizontal direction, The band that caused moire interference pattern as well as the effect of removing the functional limitation for improving the resolution, which has been pointed out as a limitation when forming the stripe-shaped black stripe layer, was formed. Since the formation of the shape of the black stripe layer is excluded, it is possible to fundamentally suppress the generation of moiré interference, thereby improving the screen resolution.

In addition, since the shape of the horizontal lenticular Fresnel lens layer and the vertical lenticular Fresnel lens of the first sheet constituting the screen is a monotonous shape, it is possible to easily process the molding mold for this, as well as to manufacture the mold As the difficulty of the mold can be lowered, it is expected to reduce the overall manufacturing cost in addition to the mold manufacturing cost.

Claims (3)

The first sheet 31 focusing the image beam radiated from the projection lens 30 and the image beam passing through the first sheet 31 to be spaced apart at regular intervals in front of the first sheet 31 In a rear projection television screen composed of a second sheet 32 to be dispersed, a vertical component and a horizontal component of the image beam emitted from the projection lens 30 are allowed to proceed in parallel to the observer side or to some extent. A horizontal lenticular Fresnel lens layer 31a and a vertical Lenticular Fresnel lens layer 31b for connecting with convergence and divergence angles of the first sheet 31 constituting the screen 40, respectively. And a lenticular lens layer 32a and an antireflective dispersant layer 32b formed on both sides of the second sheet 32 positioned on the observer's side, respectively. Projection television rear projection screen for. The rear projection screen according to claim 1, wherein the first sheet (31) is arranged in the order of the vertical lenticular Fresnel lens layer (31b), the horizontal lenticular Fresnel lens layer (31a). The rear projection screen according to claim 1, wherein the antireflective dispersant layer (32b) of the second sheet (32) is colored in order to prevent a decrease in contrast caused by external light.