JP2943239B2 - LCD projector - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION The liquid crystal projector of the present invention will be described in detail according to the following items.

A. Industrial application fields B. Summary of the invention C. Prior art [FIGS. 6 and 7] D. Problems to be solved by the invention E. Means to solve the problems F. Examples [1. FIGS. To 5] F-1. First Embodiment [FIGS. 1 to 3] a. Light source [FIGS. 1 and 2] b. Liquid crystal panel [FIGS. 1 and 2] c Light guide [Figs. 1 to 3] d. Others [Fig. 1] e. Function F-2. Second embodiment [Fig. 4] a. Light source b. Light guide c. Mirror, liquid crystal panel e. Function F-3. Third embodiment [Fig. 5] a. Light source b. Light guide c. Liquid crystal panel d. Others G. Effects of the invention (A. Industrial application fields) The present invention relates to a novel liquid crystal projector. More specifically, a liquid crystal projector device that projects an image displayed on a liquid crystal panel by a backlight arranged behind the liquid crystal panel and projects the image on a screen or the like in front of the liquid crystal panel, when the image displayed on the liquid crystal panel is projected on a screen. It is an object of the present invention to provide a novel liquid crystal projector device capable of improving the contrast and image quality of the image and preventing the temperature of the liquid crystal panel from rising.

(B. Summary of the Invention) The projector device of the present invention is provided with a light guide formed of a thin metal plate that allows only light having a predetermined angle out of the light emitted from the backlight, and a plurality of light guides formed on the light guide. By applying black paint to the wall surface that composes the optical path, the light incident on the liquid crystal panel can be controlled to a substantially parallel light flux, and the image displayed on the liquid crystal panel is projected and projected on the screen. The present invention can improve the contrast and image quality of an image, and can prevent a temperature rise because unnecessary light is not irradiated to a liquid crystal panel.

(C. Prior Art) [FIGS. 6 and 7] In a liquid crystal projector device, it is preferable that the light incident on the liquid crystal panel be more parallel. To create substantially parallel light.

FIG. 6 is a schematic sectional view showing an example a of a conventional liquid crystal projector of a front projection type.

In the figure, b denotes a liquid crystal panel, which is driven by a display circuit (not shown).

Reference numeral c denotes a backlight disposed behind the liquid crystal panel b. For example, a halogen bulb, a metal halide lamp, or the like is used.

Reference numeral d denotes a reflector provided with a rotating parabolic mirror, and the backlight c is disposed at the focal point of the reflector d, whereby the reflector d functions as parallel light generating means.

Then, the backlight c is turned on, and among the light emitted from the backlight c, the light reflected by the reflector d is forward as substantially parallel lights e, e,... (Shown by solid lines in the drawing). And is incident on the liquid crystal panel b. And
The substantially parallel light incident on the liquid crystal panel b projects an image displayed on the liquid crystal panel b, is enlarged through a projection lens f disposed in front of the liquid crystal panel b, and is placed on a screen placed in front of the liquid crystal projector device a. g is projected.

FIG. 7 is a schematic cross-sectional view showing an example h of a conventional rear projection type liquid crystal projector device. This conventional example h uses a surface light source as a backlight.

In the figure, reference numeral i denotes a liquid crystal panel, which is driven by a display circuit (not shown) similarly to the liquid crystal panel b of the first conventional example.

Reference numeral j denotes a light guide plate disposed substantially parallel to and behind the liquid crystal panel i. A light bulb k is disposed opposite one end of the light guide plate j. Then, when the bulb k is turned on, light enters the light guide plate j, and the light spreads over the entire surface of the light guide plate j by the edge light effect, and a reflecting portion l formed on the back surface of the light guide plate j. , L,... Are reflected forward and emitted forward of the light guide plate j.
Accordingly, the light guide plate j functions as a surface light source, and light emitted from the light guide plate j is incident on the liquid crystal panel i in front of the light as light containing a parallel light flux.

m is a condenser lens disposed in front of the liquid crystal panel i, and has a function of narrowing a parallel light beam transmitted through the liquid crystal panel i.

n is a projection lens arranged in front of the condenser lens m, o
Is a screen arranged in front of the projection lens n.

Thus, the light transmitted through the liquid crystal panel i is converged by the condenser lens m, then enlarged by the projection lens n and irradiated on the screen o. Thereby, the image displayed on the liquid crystal panel i is projected from the back of the screen o, and the image projected on the screen o can be viewed from the front of the screen o.

(D. Problems to be Solved by the Invention) However, in the above-described liquid crystal projector a, since the backlight c cannot be a strict point light source, even if the light is reflected by the reflector d, The parallelism is poor, and it contains many components that become diffused light,
Further, the light flux not reflected by the reflector d is directly incident on the liquid crystal panel b as diffused light p, p,... (Shown by a broken line in the drawing). There is a problem that the contrast of the image projected and projected on the screen is reduced to degrade the image quality, and that unnecessary light is radiated to the liquid crystal panel b to cause a rise in the temperature of the liquid crystal panel b.

Further, in another conventional liquid crystal projector h, of the light emitted from the light guide plate j, the light incident on the liquid crystal panel i as a substantially parallel light flux is viewed from the front side of the liquid crystal panel i. However, the other diffused light blurs the outline of the image projected on the screen o from the image displayed on the liquid crystal panel i, thereby lowering the contrast, and the extra light irradiates the liquid crystal panel i. Accordingly, there is a problem that the temperature of the liquid crystal panel i is unnecessarily increased.

(E. Means for Solving the Problems) In order to solve the above-described problems, the liquid crystal projector device of the present invention includes only a luminous flux having a predetermined angle out of the light emitted from the backlight toward the liquid crystal panel. A light guide formed of a thin metal plate that allows light to pass through is provided, and a wall surface that constitutes a plurality of optical paths formed in the light guide is coated with black so that a light flux incident on the liquid crystal panel is a substantially parallel light flux. Things.

Therefore, according to the liquid crystal projector of the present invention, since only substantially parallel light flux reaches the liquid crystal panel, it is possible to improve the contrast of the image when the image displayed on the liquid crystal panel is projected on the screen. Color reproducibility can be improved and image quality can be improved, and since the liquid crystal panel is not irradiated with useless light flux, the temperature of the liquid crystal panel is prevented from being excessively increased. can do.

(F. Embodiment) [FIGS. 1 to 5] Hereinafter, details of the liquid crystal projector device of the present invention will be described with reference to each embodiment shown in the accompanying drawings.

(F-1. First Embodiment) [FIGS. 1 to 3] FIGS. 1 to 3 show a first embodiment 1 of a liquid crystal projector according to the present invention.

In the first embodiment, the present invention is of a front projection type, in which a liquid crystal panel is a single-panel type, and a parallel light generating means uses a reflector having a paraboloidal reflecting surface as a parallel light generating means. Applied to the device.

(A. Light source) [FIGS. 1 and 2] Reference numeral 2 denotes a backlight as a point light source, which includes a normal incandescent lamp, a halogen lamp, a metal halide lamp,
A mercury lamp or the like may be used.

Reference numeral 3 denotes a reflector as a parallel light generating means disposed so as to surround the backlight 2 from the rear. The reflector 3 has a reflecting surface forming a paraboloid of revolution, and the backlight 2 is disposed at a focal point F thereof. Have been.

Therefore, the light emitted from the backlight 2 and directed backward is reflected by the reflecting surface of the reflector 3, and most of the light is emitted as a substantially parallel light beam to the front.

(B. Liquid crystal panel) [FIGS. 1 and 2] Reference numeral 4 denotes a liquid crystal panel disposed in front of the backlight 2 so as to be substantially perpendicular to the optical axis of the reflector 3, and is driven by a display circuit (not shown). An appropriate image is displayed on the display surface.

[C. Light Guide] [FIGS. 1 to 3] Reference numeral 5 denotes a light guide for passing only a parallel light beam among the light beams emitted from the backlight 2.

The light guide 5 includes vertical plates 6, 6,... In which thin (for example, 0.3 m / m) metal plates (for example, aluminum plates) are arranged at regular intervals in a state parallel and perpendicular to the optical axis. Horizontal plates 7, 7, in which thin metal plates similar to the vertical plates 6, 6, ... are arranged at equal intervals in a state parallel and horizontal to the optical axis.
... Each of the vertical plates 6, 6, ... and the horizontal plates 7, 7, ... has slits 6a, 6a, ..., 7a, 7a, which are approximately half the length thereof and are parallel to the optical axis. .. so that the front edge or the rear edge is reached, and each slit 6a,
.. Or 7a, 7a,... Are formed at the same intervals as the arrangement intervals of the respective plates 6, 6,. 6, 6, ... and 7,
7, and each slit 6a, 6a, ... and 7a, 7a, ...
The light guide 5 is configured by being fitted so as to engage with each other and assembled so as to form a lattice shape when viewed from the front-back direction. Therefore, in the light guide 5, a plurality of square optical paths 8, 8,... As viewed from the front-rear direction are formed parallel to the optical axis, and constitute the optical paths 8, 8,. Wall 8
The black coating is applied to a, 8a,... to form a non-reflective surface.

Incidentally, in the light guide 5 of the first embodiment, all the predetermined angles of the light beams passing through the respective optical paths 8, 8, ... are all the same, and the angles are 0 with respect to the optical axis. Are parallel to the optical axis, and the permissible angles for the predetermined angle are the same in each of the optical paths 8, 8,....

The extent of the allowable angle is included in the range of design matters. However, if the angle is too large, the contrast cannot be improved. If the angle is too narrow, the shadow of the light guide 5 may be reduced. Since the image is projected as an image, an appropriate range should be determined. The length l of each optical path 8 and the length a of one side of each optical path 8 as viewed from the front-back direction are determined depending on the allowable angle.

That is, for example, when an allowable angle of ± 10 ° is given to the optical axis, the relationship between the length 1 of the optical path 8 and the length a of one side when viewed from the front-back direction of the optical path 8 is as follows. Becomes

Thus, for example, when the length l of the optical path 8 (also the length of the light guide 5) is l = 30 m / m, the length a of one side of the optical path 8 when viewed from the front-back direction is Becomes

As described above, the allowable angle of the parallelism of the incident light with respect to the liquid crystal panel 4 and the length l of the optical path 8 and the length a of one side of the optical path 8 when viewed from the front-back direction have the above relationship. ,
In order to reduce the allowable angle, the length of the optical path 8 may be increased or the length a of one side when viewed from the front-back direction of the optical path 8 may be reduced. If the length 1 is to be reduced, the length a of one side when viewed from the front-back direction of the optical path 8 may be reduced.

Thus, most of the light emitted from the backlight 2 and reflected by the reflector 3 behind it and directed forward is a parallel light flux. However, since the backlight 2 is not a strict point light source, the diffuse component The parallel light flux and the light flux whose angle with respect to the optical axis is within a predetermined allowable angle (hereinafter, referred to as “parallel light flux”) pass through each light path 8, 8,... Of the light guide 5. Then, the light is incident on the liquid crystal panel 4 located in front of it. Further, among the light reflected by the reflector 3, a light flux whose angle with respect to the optical axis is out of a predetermined allowable angle and light emitted forward from the backlight 2 (hereinafter, referred to as "diffused light"). Even if the light enters the angular optical paths 8, 8,... Of the light guide 5, it impinges on the wall surfaces 8a, 8a,.
Since a,... are made non-reflective surfaces, they cannot be absorbed and pass through the respective optical paths 8, 8,.

Therefore, the light beam that can pass through the light guide 5 is only the parallel light beam, and this is incident on the liquid crystal panel 4.

Also, the diffused light passes through each of the optical paths 8, 8,.
Are absorbed by the wall surfaces 8a, 8a,.

(D. Others) [FIG. 1] Reference numeral 9 denotes a projection lens disposed in front of the liquid crystal panel 4, which spreads light obtained by projecting an image on the liquid crystal panel 4 to a desired angle.

Reference numeral 10 denotes a screen placed in front of the liquid crystal projector 1, which displays an image projected by the liquid crystal projector 1 as a video.

(E. Operation) As described above, the light projected from the backlight 2 is reflected forward by the reflector 3 at the rear thereof as a light beam containing more parallel light, and further, the light guide 5
As a result, light other than the predetermined allowable angle is absorbed, and only the parallel light flux reaches the liquid crystal panel 4.

Then, the image displayed on the liquid crystal panel 4 is projected by the above-mentioned parallel light flux, and the projection
Is displayed on the screen 10 via the. Further, at this time, since the light projected on the image displayed on the liquid crystal panel 4 is only a parallel light beam, the outline of the image is clearly projected, and therefore, the contrast of the image projected on the screen 10 is improved, and the color is thereby improved. Reproducibility is improved and higher image quality is achieved.

(F-2. Second Embodiment) [FIG. 4] FIG. 4 is a second embodiment of the liquid crystal projector according to the present invention.
11 shows a liquid crystal projector using the present invention as a front projection type, a so-called three-panel liquid crystal panel, and a combination of an elliptical reflecting mirror and a condensing lens as parallel light generating means. Applied to the device.

(A. Light Source) Reference numeral 12 denotes a backlight of a point light source.

Reference numeral 13 denotes a reflector arranged so as to surround the backlight 12 from the front. The reflector 13 has an elliptical reflection surface, and has a first focal point F1 at the _first focal point F1.
Is arranged.

Note that the liquid crystal projector device 11 of the second embodiment
As will be described later, a plurality of reflectors are provided, and the direction of the reflector 13 and the direction of light emitted from the device 11 are shifted from each other by approximately 180 °.

Emitted from the backlight 12, the light toward the front is the most reflected by the reflecting surface of the reflector 13 is focused on the second focal point F _2.

(B. Light guide) 14 is disposed light guide between the first focal point F ₁ and the second focal point F ₂ of the reflector 13, a plurality similarly to the optical guide 5 in the first embodiment Aluminum plate 15, 15,
Are assembled so as to form a lattice shape when viewed from the front-rear direction. The difference from the light guide 5 in the first embodiment is that the formed optical paths 16, 16,. focus
From F ₁ side is that is formed to be thinner in accordance with close to the second focal point F ₂ side. And each optical path 16, 16, ...
The light guide 5 in the first embodiment is provided on the wall constituting
In the same manner as described above, a black coating is applied to form a non-reflective surface.

In the light guide 14 of the second embodiment 11, each optical path 16
16 are different respectively are each given angle of each light beam passing through., The angle formed by the optical axis of the light beam and the reflector 13 toward the focal point F ₂ and the second by the reflection at a point with a reflector 13 , At a predetermined angle in the optical path through which the light beam passes. Therefore, the optical path 1 located at the center of the light guide 14
The predetermined angle becomes smaller as the distance becomes smaller, and the predetermined angle becomes larger as the optical paths 16 are located closer to the outer periphery.

Accordingly, emitted from the backlight 12 not exactly point source, the light reflected by the reflector 13, only light having a light or its predetermined allowable angle through the second focal point F ₂ by the light guide 14 The other light is absorbed by the walls of the optical paths 16, 16,... Of the light guide 14.
Therefore, most of the light that has passed through the light guide 14 passes through the second focus F ₂ or a position near the _second focus F ₂ and reaches a condenser lens described later, and can pass through the light guide 14. The remaining light is absorbed by the light guide 14 and is consumed here as heat energy.

(C. Condensing lens) 17 is a condensing lens arranged behind the second focal point F ₂ of the reflector 13, and the focal point of the condensing lens 17 is the same as that of the second focal point F ₂ of the reflector 13. They are arranged so that they coincide with each other and their optical axes coincide with each other. Therefore, the reflector
13 is reflected, in the light guide 5 light focused on the light flux passing through the second focal point F ₂ is passed through the second focal point F _2, the condenser lens
The light passes through 17 and is converted into a parallel light beam.

As described above, the light flux of the reflector 13 having the elliptical reflection surface is made to coincide with the optical axis of the condenser lens 17, and the second focal point of the reflector 13 is made coincident with the focal point of the condenser lens 17. Parallel light generating means is configured.

(D. Mirror, liquid crystal panel) 18 is provided behind the condenser lens 17 with the reflection surface inclined at an angle of 45 ° to the optical axis of the condenser lens 17 and facing obliquely upward and forward. A first total reflection mirror that directs light that has passed through the condenser lens 17 by the first total reflection mirror 18 into a parallel light flux substantially upward.

Reference numeral 19 denotes a second total reflection mirror disposed above the first total reflection mirror 18 with its reflection surface facing obliquely downward and forward. The light reflected upward by the total reflection mirror 18 is reflected forward.

Reference numeral 20 denotes a first half mirror disposed in front of the second total reflection mirror 19 with its reflection surface facing obliquely rearward and upward. The first half mirror 20 enters the first half mirror 20 here. Half of the light beam is reflected upward, and the other half is directly transmitted forward.

Reference numeral 21 denotes a third total reflection mirror disposed above the first half mirror 20 with its reflection surface facing obliquely downward and forward. The light flux reflected upward by the half mirror 20 is reflected forward.

Reference numeral 22 denotes a second half mirror disposed in front of the first half mirror 20 with its reflection surface facing rearward and obliquely upward. The first half mirror 22 is formed by the second half mirror 22. Of the luminous flux transmitted through 20, half is reflected upward, and the other half is directly transmitted forward.

Reference numeral 23 denotes a red liquid crystal panel disposed substantially vertically in front of the third total reflection mirror 21, and displays only a red component signal of a video signal as an image. The liquid crystal panel 23 for red light has the third total reflection mirror.
The light reflected forward at 21 is transmitted, and the image displayed here is projected and emitted forward as a red ray.

Reference numeral 24 denotes a liquid crystal panel for green which is disposed substantially horizontally above the second half mirror 22, and displays only a green component signal among video signals as an image. The liquid crystal panel 24 for green light includes the second half mirror.
The upper reflected at 22 is transmitted through, and the image displayed here is projected and emitted upward as a green ray.

Reference numeral 25 denotes a blue liquid crystal panel disposed substantially vertically in front of the second half mirror 22, and displays only a blue component signal of a video signal as an image. The blue liquid crystal panel 25 includes the second half mirror.
The light transmitted forward at 22 is transmitted, and the image displayed here is projected and emitted forward as a blue ray.

Reference numeral 26 denotes a fourth total reflection mirror arranged in front of the blue liquid crystal panel 25 with its reflection surface facing obliquely upward and rearward.
Light transmitted through 25 is reflected upward.

Reference numeral 27 denotes a first dichroic mirror disposed in front of the red liquid crystal panel 23 and above the green liquid crystal panel 24 with its reflection surface facing obliquely downward and forward. Is reflected, and light beams of other color components (red component and blue component) are transmitted through as they are. The light transmitted through the red liquid crystal panel 23 is transmitted as it is as a red ray through the first dichroic mirror 27, and the light transmitted through the green liquid crystal panel 24 is converted into a green ray as the first dichroic mirror. 27, the red and green ray rays are combined by the first dichroic mirror 27 and emitted forward.

Reference numeral 28 denotes a second dichroic mirror disposed in front of the first dichroic mirror 27 and above the fourth total reflection mirror 26 with its reflection surface facing obliquely downward and forward. Yes, it reflects blue light rays and transmits light rays of other color components (green and red components) as they are. Then, the light beam obtained by combining the red ray and the green ray by the first dichroic mirror 27 passes through the second dichroic mirror 28 as it is, and is reflected upward by the fourth total reflection mirror 26. The blue ray is reflected forward by the second dichroic mirror 28, whereby the combined ray of the red ray and the green ray and the blue ray are converted into the second dichroic mirror. The light is combined at 28 and emitted forward.

Reference numeral 29 denotes a projection lens disposed in front of the second dichroic mirror 28, and each of the liquid crystal panels 23, 24,
The light beam transmitted through each of the mirrors 25 and spread by the dichroic mirrors 27 and 28 is spread at a desired angle.

(E. Effect) Thus, the light projected from the backlight 12, many of the light beam is reflected back as light beam toward the focal point F ₂ of the second in front of the reflector 13 that, further, the light beam , other than the predetermined allowable angle by the light guide 14 is the light beam of only a light beam toward the second focal point F ₂ is absorbed.

The light beam that has passed through the second focal point F ₂ is
To the liquid crystal panel 23, 24, 25 via a number of total reflection mirrors 18, 19, 21, 26 and half mirrors 20, 22 arranged at the subsequent stage.
Is irradiated. Then, the image of each color component displayed on each of the liquid crystal panels 23, 24, and 25 is projected by the above-described parallel light flux, and the dichroic mirror 2 located in front of or above the same.
The images are synthesized by 7 and 28, and further projected as an image on a screen (not shown) via a projection lens 29 in front of them. Also, at this time, since the light for projecting the image of each color component displayed on each of the liquid crystal panels 23, 24, and 25 is only a parallel luminous flux, the outline of each image is clearly projected, and thus the contrast of the image projected on the screen is reduced. As a result, the color reproducibility is improved and higher image quality is achieved.

(F-3. Third Embodiment) [FIG. 5] FIG. 5 is a third embodiment of the liquid crystal projector according to the present invention.
30 shows a rear projection type of the present invention applied to a liquid crystal projector device using a surface light source as a light source.

(A. Light Source) Reference numeral 31 denotes a backlight which functions as a surface light source, and includes a light guide plate 32 arranged vertically and a light bulb 33 arranged to face one end face of the light guide plate 32. Then, the light emitted from the light bulb 33 enters the light guide plate 32, and the light spreads over substantially the entire surface of the light guide plate 32 by the edge light effect.
Are reflected forward by the reflecting elements 34, 34,... Formed on the rear surface of the light guide plate 32, and are emitted forward of the light guide plate 32. In this manner, light is emitted from the entire front surface of the light guide plate 32 and functions as a surface light source. The light emitted from the light guide plate 32 contains more light in a direction perpendicular to the surface of the light guide plate 32, that is, more horizontally.

(B. Light Guide) Reference numeral 35 denotes a light guide disposed in front of the light guide plate 32, and has substantially the same structure as the light guide 5 used in the liquid crystal projector 1 of the first embodiment. , Each optical path 3
Are parallel to each other and their respective optical paths 36, 36,...
The inner wall surface that constitutes (1) is formed as a non-reflective surface.

The light guide 35 is arranged such that each of the optical paths 36, 36,... Is horizontal, and therefore, of the light emitted from the backlight 31, only the parallel light flux is passed, and the other diffused light is After entering each of the optical paths 36, 36,..., The light is absorbed by each meridional surface and consumed as heat energy.

(C. Liquid Crystal Panel) Reference numeral 37 denotes a liquid crystal panel vertically disposed in front of the light guide 35. Only a parallel light beam passing through the light guide 35 enters the liquid crystal panel 37 and is displayed here. The projected image is projected.

(D. Others) Reference numeral 38 denotes a condensing lens disposed in front of the liquid crystal panel 37, and has a function of narrowing a parallel light beam transmitted through the liquid crystal panel 37.

39 is a projection lens arranged in front of the condenser lens 38, 40
Is a screen disposed in front of the projection lens 39, and the light beam converged by the condenser lens 38 is projected from the back surface of the screen 40 by the projection lens 39, and the image projected on the screen 40 is displayed on the screen 40. Can be seen from the front of the car.

(G. Effects of the Invention) As is apparent from the above description, the liquid crystal projector device of the present invention includes a liquid crystal panel for displaying an image,
A liquid crystal projector device comprising: a backlight disposed behind the liquid crystal panel; and a thin metal plate that transmits only a light beam having a predetermined angle among light beams emitted from the backlight toward the liquid crystal panel. The light guide formed by the above is provided, and a black paint is applied to a wall constituting a plurality of light paths formed in the light guide, so that a light flux incident on the liquid crystal panel is a substantially parallel light flux. .

Therefore, according to the liquid crystal projector of the present invention, since only substantially parallel light flux reaches the liquid crystal panel, it is possible to improve the contrast of the image when the image displayed on the liquid crystal panel is projected on the screen. The color reproducibility can be improved and the image quality can be improved, and the liquid crystal panel is not irradiated with useless light flux, thereby preventing the temperature of the liquid crystal panel from being excessively increased. be able to.

The light guides shown in the above embodiments are not limited to those described above. For example, the cross-section of each light path is hexagonal, and the light guide is configured to have a so-called honeycomb structure, and the wall surface is a non-reflective surface. The light guide may be formed as long as it is configured so that, when light passes through the light guide, the light becomes a light beam having a predetermined angle.

When the parallel light generating means is used as in the first embodiment and the second embodiment, the present invention is not limited to such a combination of a paraboloid of revolution or an elliptical reflecting surface and a condensing lens. Known technical means such as a Fresnel lens are conceivable.

Further, the specific configuration shown in each of the above embodiments is:
The embodiment of the liquid crystal projector of the present invention is merely an example, and the technical scope of the present invention should not be interpreted in a limited manner.

[Brief description of the drawings]

1 to 3 show the first embodiment of the liquid crystal projector of the present invention.
FIG. 1 is a schematic cross-sectional view of FIG.
FIG. 3 is a schematic perspective view, FIG. 3 is an exploded perspective view of a light guide, FIG.
FIG. 5 is a schematic sectional view showing a second embodiment of the liquid crystal projector of the present invention, FIG. 5 is a schematic sectional view showing a third embodiment of the liquid crystal projector of the present invention, and FIG. FIG. 7 is a schematic sectional view showing another example of a conventional liquid crystal projector device. DESCRIPTION OF SYMBOLS 1 ... Liquid crystal projector device 2 ... Backlight 4 ... Liquid crystal panel 5 ... Light guide 6, 7 ... Thin metal plate, 8 ... Optical path 8a ... Wall surface, 11 ... LCD projector device, 12 backlight, 14 light guide, 15 thin metal plate, 16 optical path, 23 liquid crystal panel, 24 liquid crystal panel, 25 liquid crystal panel, 30 liquid crystal Projector device, 31 Backlight, 35 Light guide, 36 Optical path, 37 Liquid crystal panel

──────────────────────────────────────────────────続 き Continued on front page (58) Field surveyed (Int.Cl. ⁶ , DB name) G03B 21/14

Claims (1)

(57) [Claims] 1. A liquid crystal projector device comprising: a liquid crystal panel for displaying an image; and a backlight disposed behind the liquid crystal panel, wherein a light beam emitted from the backlight toward the liquid crystal panel is provided. A light guide formed of a thin metal plate that allows only a light beam having a predetermined angle to pass therethrough is provided, and a wall surface constituting a plurality of light paths formed in the light guide is coated with black, so that the light beam incident on the liquid crystal panel is A liquid crystal projector device having a substantially parallel light beam.