JPH03249639A - Liquid crystal projector - Google Patents

Abstract

PURPOSE:To make a device small in size and light in weight by disposing a beam splitting means for each primary color in common, arranging liquid crystal panel means so that the light receiving surfaces may face each other, arranging a color light separating means in a space which is surrounded by the light receiving surfaces, performing the synthesis of the modulated light colors and projecting by an optical projecting means which is used for each color light in common. CONSTITUTION:The light outputted from a light source 50 is separated into the color lights by the color light separating means 58, and each of the color light is modulated by corresponding liquid crystal panel means 60, 62 and 64, and then, the projection is performed by the optical projecting means 66. And the beam splitting means 56 is disposed for each color light in common, and also, the light incident surfaces of respective liquid crystal panel means 60, 62 and 64 are arranged so as to face each other, and the color light separating means 58 is arranged in the space which is surrounded by the light incident surfaces so as to perform the color separation of the light. And also each optical color image is synthesized so as to be projected by a single projection lens 66. Thus, the entire projector device can be made small in size, light in weight and low in price.

Description

[Detailed Description of the Invention] [Industrial Application Field] The present invention relates to a liquid crystal projector that performs color display, and particularly relates to an improvement in the arrangement of various parts in a liquid crystal projector that uses a reflective liquid crystal panel. It is.

[Prior art] As a liquid crystal projector that displays color images, R
A transmissive liquid crystal projector that irradiates three TN-type liquid crystal panels with light of the three primary colors of , G, and H to generate R, G, and H images, and then combines these images and projects them onto a screen. It has been known.

In this transmission type projector, the aperture ratio of the liquid crystal panel is approximately 30 to 50% because incident light is blocked by the active matrix TFT (i-film transition 2, 2) and black stripe portion of the liquid crystal panel.

By the way, there is a trend toward higher quality television broadcasts such as high-definition and clear vision, and in response to this trend, LCD projectors are also becoming higher resolution.

High brightness is required. However, the aperture ratio of a transmissive liquid crystal panel is 30 to 50%, as described above, and does not meet this requirement.

On the other hand, in a reflective liquid crystal panel, by forming a reflective potential on the active matrix TPT, all parts other than the signal lines and scanning lines can be used as light reflecting surfaces. Therefore, the aperture ratio can be increased more than that of the transmissive type, and the demands for higher resolution and higher brightness can be met. For this reason, reflective type liquid crystal projectors have recently been developed.

FIG. 4 shows an example of such a reflective liquid crystal projector. This conventional example was announced at the 1989 Autumn National Conference of the Institute of Electronics, Information and Communication Engineers. In the figure, light output from a light source 10 first enters a blue reflective mirror 12, where B (blue) light is separated. The light transmitted through the blue reflecting dichroic mirror 12 enters the green reflecting dichroic mirror 14, where G (green) light is separated. The light transmitted through the green reflective dichroic mirror 14 is transmitted to the red reflective dichroic mirror 16.
The R (red) light is separated here.

The separated B, G, and R lights each enter a polarizing beam subric 18, 20, and 22, where their respective optical paths are changed, and each enters a reflective liquid crystal panel 24, 26, and 28. Each liquid crystal panel 24, 26, 28 has B, G,
Each image signal of H is input, and these
, H are modulated to generate an optical image.

These optical images are reflected by the liquid crystal panel 24, 26, 28 and output again to the polarized beam block 18° 20.22
are incident on each. The R, G, and B lights transmitted through these polarizing beam splitters 18, 20, and 22 are as follows.
Furthermore, a projection lens 30°32.34 and a mirror (not shown)
The light reaches a screen (not shown) through the lens, and the R, G, and B optical images are enlarged and projected.

Problems to be Solved by the Invention] However, the above-described conventional techniques have the following disadvantages.

+l) Change beam splitter and projection lens to R9G, B
Since the device is provided for each primary color light, the device becomes expensive, and also increases in weight and volume.

(21 Since each R, G, and B optical image is projected onto the screen by an independent projection lens, convergence adjustment on the projection screen becomes a problem6. In particular, when using the front method, the single projection lens method The advantage is “
There is no need for the user to make convergence adjustments (and the advantages of being able to easily install a projector anywhere and enjoy a large screen image) are lost.6 The present invention has been made in consideration of these points.

Small size and weighing, using reflective LCD panel means.

The object is to provide an inexpensive liquid crystal projector that does not require convergence adjustment by the user.

[Means for Solving the Problems] In the present invention, a light source one-color light separating means 1 a reflective liquid crystal panel means and a projection optical means are disposed on the optical path of the input and output light of the beam splitting means, and the light output from the light source is In the liquid crystal projector, the beam splitting means and the projection optical means are used in common for each color light, in which the light is separated into color lights by a color light separation means, modulated by corresponding liquid crystal panel means, and projected by a projection optical means. At the same time, the liquid crystal panel means are arranged so that their light-receiving surfaces face each other, the color light separation means is arranged in the space surrounded by the liquid crystal panel means, and images of each color light are placed on the color light incident side of the projection optical means. It is characterized by being provided with a color light combining means for combining.

[Function] According to the present invention, the beam splitting means is provided in common for each primary color light, the liquid crystal panel means is arranged so that the light receiving surfaces face each other, and the color light separating means is arranged in the space surrounded by the liquid crystal panel means. Therefore, the optical paths of each color from color separation to modulation of the light output from the light source share a common space, and the device is constructed to be small, lightweight, and inexpensive.

Furthermore, the modulated colored lights are combined and projected by a projection optical means provided in common for each colored light. This also allows the device to be made smaller and lighter. Further, there is no need for special convergence adjustment.

[Example] Hereinafter, an example of the liquid crystal projector according to the present invention will be described with reference to the accompanying drawings.
A perspective view of the main parts of the liquid crystal projector in this embodiment is shown, and FIG. 2 shows a plan view of the device shown in FIG. 1.

In these figures, a light source 50 that outputs light for illumination is provided with a beam splitter 52 in order to effectively utilize the light. As this light source 50, for example, a metal halide lamp, a xenon lamp, or a tungsten halogen lamp is used.

A cold filter 54 is provided on the light output side of the light source 50, which blocks infrared rays to prevent unnecessary temperature rise and overheating.

Next, the light transmitted through the cold filter 54 is as follows.

The light is incident on the polarizing beam brick 56 as shown by arrow F1. This polarizing beam splitter 56
is for separating incident light into transmitted light of P-component linearly polarized light and reflected light of S-component linearly polarized light. Of these, the reflected light is incident on an X-shaped dichroic mirror 58. This dichroic mirror 58 separates the incident light into three primary colors of R, G, and H.

The separated R, G, and B portions are made to enter the R, G, and B reflective liquid crystal panels 60, 62, and 64, respectively.

Next, the R, G, and B lights reflected and output from each liquid crystal panel 60, 62, and 64 respectively enter a dichroic mirror 58 and are combined there, so that the combined light returns to the polarizing beam splitter 56. It has become. A projection lens 66 is provided on the transmitted light output side of the polarizing beam splitter 56.
is provided so that a color image is projected onto a screen (not shown).

Among the above-mentioned parts, the liquid crystal panel 62 functions as shown in FIG. The same applies to the liquid crystal panel 60.degree. 64, and the dichroic mirror 58 is omitted. A detailed explanation was presented at the 1989 Institute of Electronics, Information and Communication Engineers Autumn National Conference, so an outline will be provided.

First, the case of roFFJ in which no driving voltage is applied to the pixel cells of the liquid crystal panel 62 will be described with reference to fAl in the same figure. The light from the light source 50 is separated by the polarizing beam splitter 56 into transmitted light and reflected light based on its polarization components. That is, the P component linearly polarized light (hereinafter simply referred to as "P component") travels straight, and the S component linearly polarized light (hereinafter simply referred to as "S component") is reflected and passes through the liquid crystal panel 62.
incident on .

At the drive voltage roFFJ, the light reflected by the reflective surface 62R of the corresponding cell of the liquid crystal panel 62 still remains the S component. Therefore, the light will be reflected again by the polarizing beam splitter 56 and will not be output to the projection lens 66 side.

Next, the "ON" case where the driving voltage is applied to the pixel cells of the liquid crystal panel 62 will be described with reference to FIG. Similarly, the light from the light source 50 is separated by the polarizing beam splitter 56 into transmitted light and reflected light based on its polarization components, and the S component light enters the liquid crystal panel 62.

When the drive voltage is "ON", the light reflected by the reflective surface 62R of the corresponding cell of the liquid crystal panel 62 contains a P component depending on the level of the drive voltage.

When this light enters the polarizing beam splitter 56, the P component is transmitted and output to the projection lens 66 side. Therefore, in this case, G light is projected onto the screen. The same applies to the R and H lights in the liquid crystal panels 60 and 64.

Next, the overall operation of the above embodiment will be explained. The light output from the light source 50 can be transmitted directly or through the splitter 52.
, and enters the cold filter 54 . Then, the light from which the infrared component has been removed is sent to a polarizing beam splitter 56, as indicated by an arrow Fl. The polarizing beam footer 56 reflects the S component of the incident light.

Ru. This S component is incident on the guichroic mirror 58 as shown by arrow F2 in FIG.

The guichroic mirror 58 separates the incident light into R9G and H primary color lights. Of these, the R light is indicated by arrow F3 in Figure 2.

As shown, the light is reflected by the dichroic mirror 58 and enters the R liquid crystal panel 60. Here, it is modulated based on the R image signal, reflected, and enters the gicroic mirror 58 again.

Next, the G light passes through the dichroic mirror 58 and reaches the G liquid crystal panel 62 as indicated by arrow F4 in the figure. Here, it is modulated based on the image signal of G and is reflected, and is reflected by the dichroic mirror 58.
incident on .

Next, the B light is reflected by the guichroic mirror 58 and enters the B liquid crystal panel 64, as indicated by arrow F5 in the figure. Here, it is modulated based on the image signal of B and is reflected again to the guichroic mirror 5.
8.

In the guichroic mirror 58, the R, G, and B light images modulated in the manner described above are combined, and the light of the combined image is incident on the polarizing beam splitter 56. Light is transmitted through the polarizing beam splitter 56 as explained in FIG. 3, and the transmitted light is projected onto a screen by a projection lens 66. As a result, a composite image is generated on the screen.

It should be noted that the present invention is not limited to the above-mentioned embodiments, and various design changes can be made so as to achieve the same effect. For example, in the above embodiment, color light separation and color light synthesis are
Although the dichroic mirror 58 of the same type is used in common, the color light separation means and the color light combination means may be configured separately.

[Effects of the Invention] As explained above, according to the liquid crystal projector according to the present invention, the beam splitting means is provided in common for each color light, and the light incident surfaces of the respective liquid crystal panel means are arranged so as to face each other. Since we decided to separate the colors of light by arranging the color light separation means in the enclosed space, the optical path of each color light occupies a common space, making the entire projector smaller, lighter, and cheaper. It has the advantage of being configurable.

Furthermore, since the optical images of each color are combined and projected using a single projection lens, there is also the advantage that there is no need to perform convergence adjustment.

[Brief explanation of drawings]

FIG. 1 is a perspective view showing an embodiment of a liquid crystal projector according to the present invention, FIG. 2 is a plan view of the embodiment, FIG. 3 is an explanatory diagram showing the operation of the main parts of the embodiment, and FIG. 4 1 is a configuration diagram showing a conventional device. 50... Light source, 54... Cold filter, 56...
...Polarizing beam splitter (beam splitting means),
58... Dichroic mirror (color light separation means 9 color light combination means), 60.62.64... Reflective liquid crystal panel (reflective liquid crystal panel means), 66... Projection lens (projection optical means)

Claims (1)

[Claims] A light source, a color light separation means, a reflective liquid crystal panel means, and a projection optical means are arranged on the optical path of the input and output light of the beam splitting means, and the light output from the light source is transmitted to the color light separation means. In a liquid crystal projector in which colored light is separated and modulated by corresponding liquid crystal panel means, and the projection optical means performs projection thereof, the beam splitting means and the projection optical means are provided in common for each color light, and each of the liquid crystal panel means are arranged so that their light-receiving surfaces face each other, the color light separation means is arranged in the space surrounded by the color light separation means, and a color light synthesis means for synthesizing images of each color light is provided on the color light incident side of the projection optical means. A liquid crystal projector characterized by: