JP2536634Y2 - LCD projector - Google Patents

Description

[Detailed description of the invention] (A) Industrial application field The invention relates to a liquid crystal projector. In particular, it relates to the arrangement position of the light shielding plate.

(B) Conventional technology Projection devices for projecting and enlarging a cathode ray tube image from a lens group onto a screen are well known. In these projection apparatuses, it is known to use a light-shielding body (light-shielding paint) that cuts off unnecessary light near the periphery (Japanese Patent Application Laid-Open No. Sho 60/1985).
-96082, H04N5 / 74, JP-A-58-75395, H04N9 / 31).

However, a cathode ray tube type projector has a large shape and is unacceptable as a home projector, and there is also a problem such as a deviation of convergence due to the influence of geomagnetism which varies depending on an area or an arrangement direction.

By the way, the technical progress of the liquid crystal panel is remarkable, and it is considered that the liquid crystal panel is used as a light valve to form a video projector (Japanese Patent Application Laid-Open No. 61-150487).
H04N9 / 31).

The video projector is small and light and is effective not only as a home video theater entertainment video device but also as a large terminal display such as a personal computer by having a personal computer input.

This liquid crystal projector is shown in FIG. In the figure,
(10) is a projection light source, (12), (14), (16), and (18) are dichroic mirrors, and (20), (22), and (24) are reflection mirrors.

(26B), (26G), and (26R) are first to third liquid crystal units including active matrix liquid crystal display panels for blue, green, and red, respectively.

(30) is a projection lens, and (32) is a screen.
(34) is a heat ray ultraviolet ray cut filter.

In this projector, light from a light source (10) is color-separated into light of three primary colors of blue light, green light and red light by a first dichroic mirror (12) and a second dichroic mirror (14). The light is reflected by one reflection mirror (24).
The light of each color that has been color-separated is modulated by image information in the first to third liquid crystal units (26B), (26G), and (26R), respectively, and the red light is reflected by the reflection mirror (22). After that, the light of each color is applied to the third and fourth dichroic mirrors (1
6) The images are combined again by (18), and an image is projected on the screen (32) via the projection lens (10).

(C) Problems to be Solved by the Invention In this liquid crystal projector, partial unevenness in contrast and partial unevenness in color have occurred.

In addition, several fans having a large air volume are provided to suppress a rise in the temperature of the liquid crystal panel, and the fan noise is large.

The present invention proposes a liquid crystal projector in which a light-shielding plate is arranged so as to block unnecessary light which causes the above-mentioned defect, and the above-mentioned defect is improved.

(D) Means for Solving the Problems The liquid crystal projector according to the present invention includes an opening () on the optical path between the light source (10) and the color separation means (first and second dichroic mirrors (12) and (14)). 36a) is characterized in that a light-shielding plate (36) smaller than the reflector (10a) is arranged, thereby removing anisotropic light components other than components parallel to the optical axis. In addition to improving display quality such as contrast and color shading, by removing light components that do not contribute to the screen brightness without being illuminated on the LCD panel display (26d), the temperature rise of the LCD panel is suppressed and color separation is further improved. This eliminates stray light that does not enter the means and is repeatedly reflected in the housing in a state where color separation is not performed.

(E) Function First, the reason why an anisotropic light component is generated will be described.

As shown in FIG. 6, the reflector (10a) has a parabolic shape, and a lamp (10b) is installed at the focal point to obtain a component parallel to the optical axis. An anisotropic light component that is not parallel to the optical axis is included.

This is because the light emitting portion (arc portion) of the lamp has a finite size, the processing accuracy of the parabolic curved surface of the reflector varies, and an assembly error between the reflector and the lamp is caused.

In general, a liquid crystal projector uses a reflector having a diameter larger than the diagonal dimension of the display unit of the liquid crystal panel, but not all of the light from the light source is applied to the liquid crystal panel. There is also a great deal of light that is illuminated.

These unnecessary light components irradiate a shield case or the like of a driver section of the liquid crystal panel, or irradiate an optical component near the liquid crystal panel, and ultimately raise the temperature of the liquid crystal panel.

Next, the reason why display quality such as improvement of contrast and reduction of color unevenness is improved by removing the anisotropic component will be described.

The liquid crystal panel has a characteristic generally called viewing angle characteristic, in which the contrast changes depending on the incident angle of light to the liquid crystal panel. This characteristic is such that in a normally white display mode panel generally used for a liquid crystal projector, a change in contrast with respect to a light incident angle is sharp. Therefore, when there is an anisotropic light component other than the light component parallel to the optical axis, the contrast of the displayed image is reduced.

Next, color shading will be described. Generally, in an optical system that uses three liquid crystal panels and uses a dichroic mirror or a dichroic prism for color separation and color synthesis of R, G, and B light, color separation is performed if the angle of incidence on the mirror surface is different. Then, the threshold characteristic of the wavelength of color synthesis changes. Therefore, when there is a light component that is not parallel to the optical axis, it appears as color unevenness on the screen.

Further, among the light emitted from the light source, there is stray light which does not enter the dichroic mirror and is repeatedly reflected in the housing of the liquid crystal projector in a state where the light is not color-separated. Then, even if the stray light that has not been color-separated enters the liquid crystal panel, color unevenness also occurs.

Therefore, in the present invention, of the light emitted from the light source,
By removing light components that do not contribute to the display brightness on the screen and stray light that does not enter the color separation means and is not color-separated by the light-shielding plate (36), the temperature of the liquid crystal panel increases, and the contrast of the display image decreases. Reduction, color unevenness due to color shading, and color unevenness due to stray light can be suppressed.

(F) Embodiment FIG. 1 shows the principle of the liquid crystal projector of the present invention.

(36) is a light shielding plate, and this light shielding plate (36) is a light source (1).
0) is provided in the light path on the light exit side. (36a) is a square-shaped light transmitting portion.

As is clear from the figure, unnecessary light having an anisotropic light component that is not parallel to the optical axis, unnecessary light having a light component that does not contribute to the brightness of the display image, and unnecessary light having a light component outside the center of the light source are shielded. It can be seen that (36) can be removed.

The shape of the light shielding plate (36) may be such that the light transmitting portion (36a) has a square shape as shown in FIG. 2 or a shape according to the square shape as shown in FIG.

FIG. 4 shows an embodiment in which the present invention is applied to a liquid crystal projector using three liquid crystal units. The same parts as those in FIG. 5 are denoted by the same reference numerals, and description thereof will be omitted.

In this embodiment, a light-shielding plate (36) is provided in the optical path between the light source (10) and the first dichroic mirror (12), and the opening (36a) of the light-shielding plate (36) is connected to the reflector (10).
a) smaller than the diameter.

The unnecessary light (1) emitted from the light source (10) is
Removed in 6), emitted from the light source (10) and a light shielding plate (36)
And the light reflected by the reflection mirror (20)
The light enters the dichroic mirror (12). Therefore, the unnecessary light does not enter the first and second dichroic mirrors (12) and (14) and the liquid crystal units (26B) (26G) and (26R).

Therefore, the temperature rise of the liquid crystal panel is small, and it is possible to suppress a decrease in contrast of a displayed image and color unevenness due to curl shading.

The first and second dichroic mirrors (12) and (14)
The stray light that does not enter the liquid crystal and is repeatedly reflected in the housing without being color-separated is eliminated, and the color-separated light always enters each liquid crystal unit. Therefore, color unevenness due to stray light is also eliminated.

Further, since the light-shielding plate (36) is arranged between the light source (10) and the first dichroic mirror (12), one light-shielding plate exerts an effect on three liquid crystal panels.

In addition, as a material of the light shielding plate, a metal material is generally considered, but any material such as a resin and a ceramic is effective as long as the material reflects or absorbs light.

(G) Effect of the Invention In the present invention, since the light shielding plate is disposed between the light source and the color separation means, unnecessary light does not enter the liquid crystal panel, and the performance against heat generation, color shading, and contrast is improved. In addition, stray light that is not color-separated by the color separating means is eliminated, and color unevenness due to stray light is also improved.

[Brief description of the drawings]

FIG. 1 is a view for explaining the principle of the present invention, FIGS. 2 and 3 are views showing the structure of a light shielding plate, and FIG. 4 is a view showing an embodiment of the present invention. FIG. 5 and FIG. 6 each show a conventional example. (10) Light source, (12) (14) First and second dichroic mirrors (color separation means), (16) (18) Third
Fourth dichroic mirror (color combining means), (26) (26)
R) (26G) (26B): Liquid crystal unit (liquid crystal panel),
(26d): Display, (30) (30 ') ... Projection lens,
(36) ... Light shield plate (light shield frame), (36d) ... Light transmitting part

Claims (1)

(57) [Scope of request for utility model registration] A light source provided with a reflector; color separation means for separating light from the light source into blue light, green light, and red light; and light of each color separated by the color separation means is converted into image information. First, second, and third liquid crystal units that are modulated and transmitted by the first liquid crystal unit, color synthesizing means that synthesizes light of each color transmitted through the first, second, and third liquid crystal units, and color synthesizing means. In a liquid crystal projector comprising a projection lens for projecting the synthesized light to project an image on a screen, a light shielding plate having an opening smaller than the reflector is provided on an optical path between the light source and the color separation means. A liquid crystal projector characterized by being arranged.