JPS5968727A - rear projection screen - Google Patents

Abstract

PURPOSE:To further widen a visual field by setting differently the inclined angles of surfaces of total reflection installed to both surfaces of a lens element having a total reflection body constituting a longitudinal lenticular. CONSTITUTION:This screen is mainly composed of lens elements 11 equipped with surfaces of total reflection T, by which a light arriving as a lenticular at the surface A of the observing side is irradiated by transmitting through a crest surface P after it is totally reflected once, and cylindrical lens elements 12 having a circular or noncircular cross section are combined to the lens elements 11. Moreover, the lens elements 11 are constituted in such a way that the inclined angles of the surfaces of total reflection installed to both sides of the element 11 are differently set and lights irradiated from the surfaces of total reflection are totally balanced. By using such an arrangement, the irradiating range of the lens elements can be controlled appropriately and the visual field can be widened further.

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention relates to a rear projection screen that allows an extremely wide viewing range in the horizontal direction.

Rear projection screens used in video projection televisions and the like must have high brightness and be able to view images over a wide range.

For this reason, various measures have been taken in the past, such as forming lenticules on the screen substrate, but the limit is that the viewing angle can be expanded to around 30 degrees in the horizontal direction from the center, and improvements to this are desired. Ta.

Therefore, the applicant investigated ways to widen the viewing angle in the horizontal direction, and as a result, a portion of the light incident on the screen from the light source is totally reflected by a portion of the vertical lenticular lens and emitted to the viewing side. It was proposed to widen the eave angle at a glance by
fA and Japanese Patent Application No. 37-1991-12). By using a lenticular lens with such a unique lens shape, the field of view can be expanded to a β value of 30 to lθ on one side or even more. There are demands for screens.

The present invention was developed in light of the above circumstances, and as a result of the above-mentioned lenticular lens made of a lens having a total reflection surface, there is a certain limit. The aim is to provide a screen with an extremely high viewing angle by arranging lenticules so that the light emitted from total reflection surfaces having different angles of inclination is balanced as a whole. In other words, the gist of the present invention is a rear projection screen in which vertical lenticules are formed on the viewing side, and the lenticules are such that the incident light is once totally reflected and then transmitted through the top surface to be emitted. It is mainly composed of a lens with a total reflection surface such as
Furthermore, the lens element is constructed so that the total reflection surfaces provided on both sides have different inclination angles, and are arranged so that the light emitted from the total reflection surfaces with different inclination angles is balanced as a whole. Features a rear projection screen.

Hereinafter, the present invention will be described in detail with reference to drawings of embodiments.

tyB is a schematic explanatory diagram showing the projection system of the rear projection screen of the present invention, in which LP) is a projector, (S) is a rear projection screen, and (B) is an observer. Generally, with a rear projection screen, the image projected from the back of the screen is viewed from the opposite side of the screen, as shown in the figure, but it is viewed not only from directly in front of the screen but also from a wide angle in the horizontal direction. It is hoped that this will be possible.

In the examples shown in Figures 1 and 2, a vertical lenticule is formed on the observation side (serum), and a circular Fresnel lens (, 2) is formed on the projection side (LB). ing. Providing such a Fresnel lens (c) is effective because it can uniformly brighten up to the corners of the screen t8), but of course it can also be omitted. In the present invention, the lens is equipped with a lenticule (/l is a total reflection surface IT) on the observation side facing surface (IT) such that the incident light is once totally reflected and then transmitted through the top surface IP) and exits. The element (//) is the main body,
In addition, a cylindrical lens element (l) with a circular or non-circular cross section
A combination of these is formed.

The cylindrical lens element (l) used in the present invention is
Lenses with a circular or non-circular cross section are used; circular refers to a lens that is made up of a part of a circle, and non-circular refers to a lens that is made up of a combination of parabolas or other non-circular lens shapes. 〇 First, based on Figure 3, we will explain the characteristics of a lens equipped with such a total internal reflection 0, that is, total internal reflection IT1]
Parallel light (X+) (Y, ) and (X,) − (Y
, ) are totally reflected by the total reflection surface tT), and each (ψ)
The range is emitted from the convex lens (//a) on the top surface.

The light in this (ψ) range will be emitted as strong light (bl) at a location where the bending angle is large, as shown in Figure 7.
(X,) −(
The light of X,) is emitted in the range of (ω) as (X,')-<x;). Similarly, the light (Z, ) −(Z,) incident on the cylindrical lens element (7, 2) is also (Z,′) −
<2;) and emits within the range of (φ). This 9) and (
The sum of the elements φ) is emitted as the light (a) at the 4th<liJ. Note that in the figure, the brightness ratio is the ratio of the gain at each bending angle, when the maximum gain (peak gain) when the bending angle is 00 is l. The inclination angle of the lens element (//) having such a total reflection surface tT is determined by the refractive index n of the material and Snell's equation. For example, if n is an acrylic resin with an IQ of 9.1, When using the above formula, ( is approximately A9° or more, but considering practicality, it is selected in the range of 0 to 0.

In this way, the lens element (ll) having the total reflection surface σ) plays the role of widening the viewing angle, but it is possible to use only the lens element (ll) as shown in Fig. 3 or with the cylindrical lens element (/2). When a lenticular is constructed by combining them, the range of emission is determined by the inclination angle of the total reflection surface (T). As mentioned above, this inclination angle (θ) is selected in the range of 70 to SO. However, the range of light emitted naturally differs depending on this angle.The present invention uses such a total reflection surface (tT)L.
The inclination angle of the total reflection surfaces σ) on both sides of the light beam 1) is changed to change the range of light emitted by the total reflection surfaces, thereby transmitting light over a wider range.

That is, to explain this point using Figure S, in this example, the inclination angle (θI) of one total reflection surface (T, ) of the lens element (ll) having a total reflection surface is ? 230, the lenticules arranged so that the cylindrical lens element (12) is located between the other total reflection surface (T inclination angle (θ2) is set to S0, and these lens elements (7)) are made of acrylic resin. It was manufactured by. At this time, on the projection side surface tB), Q! A Fresnel lens with a width of mm was formed. Note that in this example, (P, ) and (P, ) are 06, (P,
) is θl, 2, (P4) is 0. J mm −(Ps
) is 0. / l: m, (γ) is Q, 7 M (
! :did. Total reflection surface (T,), (T,) in the present invention
The lens element (ll) having a cylindrical lens element (ll) is constructed as described above, but the total reflection surfaces of adjacent lens elements (//) with or without a cylindrical lens element (saw) are the same. [Sometimes with a cylindrical lens interposed].

That is, in FIG. Let's be S0. Conversely, one total reflection surface (T, ) and the total reflection surfaces (T, ) adjacent to each other via the cylindrical lens element (saw) are assumed to be the same. By positioning the total reflection directions (T,) and (T,) in this way, the transmission of light can be balanced.

As mentioned above, arranging the light emitted from total reflection directions with different inclination angles so that they are balanced as a whole means arranging the same total reflection surfaces with different inclination angles next to each other. Alternatively, it is also possible to arrange this arrangement unit every second, and the point is to balance the light from the total reflection surface as a whole screen.

FIG. 3 shows the transmission characteristics of the rear projection screen constructed as described above. Assuming a unique lenticular (1) shape as shown in Fig. S, first the cylindrical lens element (7
, 2) and the parallel light incident on the convex lens (//a) on the top surface exits as light (a).

The light from one total reflection surface (T, ) is output as (1)), and the light from the other total reflection surface (T, ) is output as to). The summation of these lights therefore provides a rear projection screen with an extremely sieve field that allows viewing even at bending angles of more than 400 degrees. Note that in this example, a lens element (/
/) and cylindrical lens elements (12) are arranged alternately, +a
) and tb) are made smaller, but
It is also possible to omit the cylindrical lens element (/:1)t.

7 to 3 are cross-sectional views showing other examples of the present invention, and FIG. 7 is a convex lens (// FIG. 3 shows a configuration in which a) is replaced with a concave lens, and FIG. 3 shows a configuration in which a segmented convex lens is formed on the top surface of the lens element (ii) having a total reflection surface.

The media used for the rear projection screen of the present invention include:
In the above example, acrylic resin was used for explanation, but this is because acrylic resin is particularly excellent in terms of optical properties and moldability. However, instead of this, vinyl chloride resin, polycarbonate resin, olefin thread resin, styrene thread resin, etc. can also be used, and when a fatty material is used in the synthesis of these materials, extrusion molding, hot pressing, or injection molding can be used. , a rear projection screen according to the present invention can be manufactured. Also, the rear projection screen of the present invention may be constructed from a transparent material, but a diffusing agent may be used as a complement. That is, it is effective to mix the diffusing agent uniformly into the screen, but in this case, the diffusing agent may be, for example, 5 to 2. caco.

Al, 03. Tie, , Ba5O,, zno,
An inorganic diffusing agent such as glass fine powder or an organic diffusing agent can be used. Furthermore, in order to reduce specular reflection on the surface and improve contrast, it is also effective to form fine irregularities on the viewing side surface tB) and/or the throwing side surface tA).

The present invention has the configuration as described in detail above, and is configured so that the inclination directions of the total reflection surfaces provided on both sides of the lens element having the total reflection direction constituting the vertical lenticular are different from each other ( 1/) (2) Since it is made of Tofresnel lenses, it has the advantage that the output range of these lens elements can be appropriately regulated to provide a rear projection screen with a wider viewing range.

[Brief explanation of the drawing]

The drawings show an embodiment of the present invention, in which Fig. 1 is an explanatory diagram of a projection system of a rear projection screen, Fig. 2 is a perspective view of the rear projection screen, and Fig. 3 is a transmission state of a lens having a total reflection direction. Fig. 4 is a cross-sectional view showing the transmission state of the lenticule with the lens element of the invention removed, Fig. 4 is its graph, Fig. 7 and Fig. FIG. 2 is a cross-sectional view showing an embodiment of a rear projection screen. ]...observation side surface LB)...projection side surface (1)...vertical lenticular (//)...lens element (l) having a total reflection surface...
...Cylindrical lens element (T), (T,), (T,)...Total reflection surface (
θ), (θI), (θ, )...Inclination angle (lko) Pit/Figure (13) -Rin@shiki-kei@tada

Claims (1)

[Scope of Claims] l A rear projection screen in which vertical lenticules are formed on the observation side surface, and the lenticules are such that the incident light is once totally reflected and then transmitted through the top surface and emitted. It is mainly composed of a lens equipped with a total reflection surface, and the lens element is constructed such that the total reflection surfaces provided on both sides have different inclination angles, and the light is emitted from the total reflection surfaces with different inclination angles. A rear projection screen characterized in that the originals are arranged so as to be balanced as a whole. 2. The rear projection screen according to claim 1, wherein a Fresnel lens is formed on the projection side surface. 3 Patent (1) characterized in that a diffusing agent is added Rear projection screen according to claim @1 or 1. H. The rear projection screen according to claim 7, 2 or 3, wherein fine irregularities are formed on the observation side surface and/or the projection side li.