JPH0473133B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION (Field of Industrial Application) The present invention relates to a rear projection screen used in video projection televisions and the like.

In principle, a rear projection device such as a video projection television, as shown in Figure 1,
Light emitted from a light source P such as a CRT is appropriately magnified by a lens system L, projected from the back side of a screen S, and observed from the opposite side of the screen S. However, increasing the distance from the light source P to the screen S in this way increases the size of the projection device, so in reality, the distance from the light source P to the screen S increases.
As shown in B and C, a method is adopted in which one to three mirrors M are combined and the light is reflected once and then projected. However, in the method shown in FIG. 1A, the height of the device increases, and in the case of methods B and C, it cannot be said that the device has been miniaturized in terms of height and depth.

In addition, many of the screens used in such projection devices are equipped with a circular Fresnel lens on the incident side, which allows every corner of the screen to be seen brightly.
In this circular Fresnel lens, as shown in Figure 3, lens surface A is continuous through non-lens surface B, so that the incident light on non-lens surface B shown with diagonal lines is not condensed. Reduces Fresnel efficiency,
Additionally, there is a drawback that it has a negative effect on resolution. In order to prevent this problem, some methods have been used to reverse the lens surface of the Fresnel lens so that the light enters from a flat surface, and to combine it with another lenticular lens. Using a screen not only complicates assembly, but also tends to cause the screen to become blurred due to light flare between the two screens, and to reduce light utilization efficiency.

In addition, as a screen device that can reduce the depth of the projection device, Japanese Patent Application Laid-Open No. 58-57120 and Japanese Patent Application Laid-Open No. 59-9649 are known, in which the projection device is projected by making the light incident on the screen from an oblique direction. It has been proposed to reduce the depth of the system, but since these utilize lens refraction, there is a limit to increasing the angle of incidence.

In order to improve these points, the present inventors proposed a screen that allows light to enter at a steep angle from the back side and observe an image, and provided a large number of prism groups parallel to this plane of incidence, and We have already proposed a rear projection screen in which each prism constituting a group is provided with a total reflection surface so that the incident light is totally reflected on the total reflection surface and exits to the viewing side (Japanese Patent Application Laid-Open No. 1989-1999). No. 173533 and JP-A-61-
No. 208041).

(Problems to be Solved by the Invention) Our above proposal has made it possible to miniaturize the device by reducing the dimensions in the depth and height directions, and to provide a bright rear projection screen that does not reduce resolution. The present invention was completed as a result of studies aimed at further improving the resolution and at the same time obtaining clear images without image blur.

(Means for Solving the Problems) That is, the present invention has been made to achieve the above object, and its gist is to provide a screen for observing an image by allowing light to enter from the back side at a steep angle. A large number of prism groups extending linearly or arcuately are formed on this incident surface, and the incident light is totally reflected on the total reflection surface of each prism making up this prism group. A total reflection surface is formed that emits light to the observation surface.
Moreover, the rear projection screen is characterized in that a curved surface is formed on the opposite side of the total reflection surface so that the luminous flux after total reflection is smaller than the luminous flux of light incident from the opposite side of the total reflection surface.

The present invention will be described below with reference to drawings of embodiments.

FIG. 4 is a schematic diagram for explaining the basic configuration of the rear projection screen of the present invention, where P is a light source such as a CRT, L is a lens system, and S is a rear projection screen. Rear projection screen S
It is designed to be incident on the back at a steep angle. Here, the angle θ when incident on the rear projection screen S
is approximately 40 to 75°. The distance l from the light source P to the rear projection screen S at this time is the same as in the conventional method, but since the light source P is located diagonally downward, the distance l' in the depth direction is l' = lcosθ, which is smaller than l. It can be made extremely small.

However, this does not necessarily mean that the height is small, so it is actually desirable to use one mirror _M1 as shown in Figure 5A to reduce the height and length in the depth direction. . In addition, in order to further reduce the height and overall size, two mirrors M ₂ and M ₃ are used as shown in FIG. 5B.
, the light source P is connected to the rear projection screen S and the first
It is best to place it between the mirrors M ₂ of , reflect it twice, and then project it.

FIG. 6 shows a part of the rear projection screen of the present invention, and in this example, a large number of prism groups having the same shape are provided on the rear side of the rear projection screen. In other words, this prism group is composed of a large number of prisms 1 arranged in a straight line or an arc shape, and each prism 1 has a structure such that the incident light is totally reflected on the total reflection surface and exits to the observation side. It is composed of a total reflection surface 1A and a facing surface 1B which is an outwardly convex curved surface and corresponds to this entrance surface. Therefore, the light incident on the prism 1 is once focused 1C since the facing surface 1B is a curved surface convex to the outside. Once the light is focused,
It expands as it progresses further.

7 and 8 explain in more detail the light rays incident on the prism 1 according to the present invention. FIG. 7 is an enlarged view of a portion where the incident angle θ ₁ is relatively large, and FIG. 8 is an enlarged view of a portion where the incident angle θ 1 is relatively large. It is an enlarged view of a location where θ ₂ is relatively small. In FIGS. 7 and 8, the light incident on the facing surface 1B is condensed 1C because this surface is an outwardly convex curved surface, and the luminous flux B after total reflection is larger than the incident luminous flux A. becomes smaller. In addition, when the incident angle θ1 is relatively large as shown in FIG. 7, all of the light rays incident on the facing surface 1B are totally reflected on the total reflection surface 1A and emitted to the observation side.
When the incident angle θ2 is relatively small as shown in Fig. 8, a part of the light incident on the facing surface 1B leaves the total reflection surface and becomes straight light, so there are two types of light: the totally reflected light and the straight light. This causes image blurring and loss of brightness. However, by forming the facing surface 1B with an outwardly convex curved surface, the incident light is condensed on the total reflection surface side, which reduces the straight light that causes image blur, thereby improving the image quality. You can improve your performance.

The prism group in the present invention may be one in which a large number of linearly extending prisms are arranged in parallel, but in this case, although it is possible to regulate light in one axis direction, for example, in the vertical direction, it is also possible to regulate light in the horizontal direction. There was something about it that I couldn't do. To improve this,
It is preferable that the prisms are arranged in an arc shape as shown in FIG.

In other words, if P is a light source such as a CRT for projection, and O is the center of an arc on a plane F that includes a screen S, and if this line segment OP is perpendicular to the plane F, each arc on the same arc Since all the points are equidistant from the light source P, by making the cross sections of the prism 1 on this circular arc equal, the emission angles on the prism cross sections become equal, which not only simplifies the design, but also reduces the light in the vertical direction. A well-balanced screen S can be realized by regulating the light in the left and right directions as well.

Assume that the position of the light source P is x behind the screen S and y downward from the center of the screen S as shown in FIG. If the apex angle of the prism at the point is θ ₁ and the inclination of the prism entrance surface is θ ₂ , then
θ ₂ in the case of parallel emission can be determined by the following formula (n is the refractive index of the base material).

When the cross-sectional shape of the prism 1 is set to the shape expressed by the above formula, all light rays emitted from the screen S surface become parallel lights perpendicular to the screen S. This makes it possible to obtain a screen that is more compact and has more uniform brightness than a screen equipped with a conventional Fresnel lens.

10 to 15 show parts of an embodiment of the present invention, and FIG. 10 shows the most basic rear projection screen, with a total reflection surface 1A on the projection side.
A large number of prisms 1 are formed, each having a facing surface 1B. FIG. 11 shows the example shown in FIG. 10 above, in which a lenticular lens surface 1D extending vertically on the observation side is formed, and this lenticular lens surface 1D imparts light diffusivity in the horizontal direction. . 12 and 13 similarly have lenticular lens surfaces 1E and 1F with total reflection surfaces 1E ₁ and 1G ₁ formed on the projection side, which results in even greater horizontal light diffusion. In other words, the viewing angle is obtained. The structure and operation of the lenticular lens surfaces 1E and 1F having total reflection surfaces in FIGS. 12 and 13 are described in Japanese Patent Application Laid-Open Nos. 57-165830 and 1983, filed by the same applicant.
No. 57-205727, JP-A-57-207235, JP-A-58-
No. 114026, JP-A No. 145933, JP-A-58-
Since it is detailed in No. 176628, the explanation here will be omitted.

14 and 15 show an example in which a separate sheet 2 is further combined on the viewing side of the rear projection screen in FIG. 10, and FIG. 14 shows a lenticular lens extending horizontally on the projection side. Surface 2A is
In addition, a separate sheet 2 on which a vertical lenticular lens surface 2B having a total reflection surface _2B1 similar to that shown in FIG. A rear projection screen can also be provided with diffusing properties. Further, FIG. 15 shows a combination of separate sheets 2 in which a lenticular lens surface 2C extending perpendicularly to the projection side is formed, and a concave lenticular lens surface 2D and an external light absorption layer 2E are formed on the observation side. This makes it possible to improve horizontal light diffusivity and contrast.

In the above embodiment, the first group of prisms is arranged in series so as to extend in the horizontal direction, but this is arranged at a 90° angle.
It may also be configured to be converted and extend in the vertical direction. Of course, in this case, the projector will be installed horizontally.

Furthermore, in the above example, an outwardly convex curved surface is formed on the facing surface 1B so that the luminous flux after total reflection is smaller than the luminous flux of the light incident from the facing surface 1B. An outwardly convex curved surface may be formed on 1A and provided on both surfaces 1A and 1B.

When the rear projection screen of the present invention projects an image obliquely from behind, the image on the screen is distorted and blurred, but these problems can be solved by the following measures of the projection system. In other words, regarding image distortion, the CRT
This can be corrected using an electric circuit. Also, the blur of the image is
This is caused by the difference in distance from the lens system to the screen, so the image incident on the lens system from the CRT is
What is necessary is to make a constant angle with respect to the optical axis so that the focal length is the same on the screen.

Acrylic resin is the most suitable material for the rear projection screen of the present invention.
This is because acrylic resins are particularly excellent in terms of optical properties and moldability. However, it is also possible to use vinyl chloride resin, polycarbonate resin, olefin resin, styrene resin, etc. instead, and when these synthetic resin materials are used, they can be molded by extrusion molding, hot pressing, or injection molding. A rear projection screen according to the invention can be manufactured.

Further, it is preferable to provide a light diffusing means for further improving light diffusing properties on the base material or separate sheet constituting the rear projection screen of the present invention. As this light diffusion means, SiO ₂ , CaCO ₃ , Al ₂ O ₃ ,
One or two types of diffusing substances that do not melt or chemically change in the liquid synthetic resin medium, such as TiO ₃ , BaSO ₄ , ZnO, Al(OH) ₂ , glass fine powder, or organic diffusing agents.
It is preferable to uniformly mix and disperse one or more additives in the medium, or to form a layer containing these diffusion substances. It is also effective to form a fine matte surface on the projection side surface and/or the observation side surface. If such a means for imparting light diffusivity is taken, the diffusivity of the screen in the horizontal and vertical directions is compensated for and uniformity can be improved.

(Effects of the Invention) The present invention has the configuration as described in detail above, and the relative position of the projector serving as the light source is positioned diagonally to the rear, making it possible to downsize the entire projection device and reducing stray light. This has the advantage that a clear image without image blur can be obtained, and that a rear projection screen that is uniform, bright, and has excellent resolution can be easily provided.

[Brief explanation of the drawing]

Figures 1 and 2 are explanatory diagrams of the optical path from a projector to a conventional rear projection screen;
Figure 3 is a partial side view of a Fresnel lens used in a conventional rear projection screen, Figures 4 and 5.
The figure is an explanatory diagram of the light path from the projector when the rear projection screen of the present invention is used, FIG. FIG. 8 is an enlarged view for explaining in more detail, FIG. 9 is a perspective view showing another example of the present invention, and FIGS. 10 to 15 are partial perspective views showing an embodiment of the present invention. S...screen, P...CRT, L...lens system, _M1 , _M2 , _M3 ...mirror, 1...prism, 1A...total reflection surface, 1B...facing.

Claims (1)

[Claims] 1. A screen for observing an image by allowing light to enter from the rear side at a steep angle, in which a large number of prism groups extending in a straight line or an arc shape are formed on the incident surface, and Each prism that makes up this prism group is formed with a total reflection surface that totally reflects the incident light and emits it to the observation surface, and the luminous flux of the light that enters from the opposite side of the total reflection surface is smaller than the total reflection surface. A rear projection screen characterized by forming curved surfaces on opposite sides so that the luminous flux after total reflection is reduced. 2. The rear projection screen according to claim 1, further comprising a lenticular lens surface extending vertically on the viewing side. 3. The rear projection screen according to claim 2, characterized in that a lenticular lens surface having a total reflection surface is formed. 4. Claim 1, characterized in that a circular Fresnel lens is formed on the observation surface.
Rear projection screen according to item 2 or 3. 5. The rear projection screen according to claim 1, 2, 3, or 4, characterized in that a base material constituting the screen is provided with a light diffusion means. 6. The rear projection screen according to claim 1, 2, 3, 4, or 5, characterized in that it is combined with a separate sheet having a lenticular lens surface. 7. The rear projection screen according to claim 6, characterized in that a light diffusing means is provided on a separate sheet.