JPH0486737A - Liquid crystal color projection device - Google Patents

Abstract

PURPOSE:To precisely fit respective optical components without using an optical base by providing a pair of bar materials between a pair of side plates according to the optical components and closely fixing the respective components to a pair of bar materials. CONSTITUTION:The optical components are provided between a pair of side plates 35 and 36 which are opposedly arranged so as to be in parallel with an optical axis. Besides, plural pairs of holes 38a, 38b, ... and 39a, 39b, ... which are respectively paired are formed on the respective side plates according to the respective optical components and the end parts of the bar materials 40a and 40b are inserted and fixed in the holes. Then, the parallelism of both side plates 35 and 36 is maintained. Besides, the side end parts of a liquid crystal panel 7 in one direction perpendicular to the bar materials 40a and 40b at the front surface of a liquid crystal plate are closely brought into contact with the bar materials 40a and 40b and respectively fixed by a pair of fasteners 42 and 43 clamped to a panel frame body 41. Thus, the fitting angles of the whole optical components are precisely made constant and the need of the expensive optical base made of aluminum die casting is eliminated.

Description

[Detailed Description of the Invention] [Industrial Application Field] The present invention relates to a liquid crystal color projection device using a liquid crystal plate,
In particular, the present invention relates to a liquid crystal color projection device that adds and mixes and projects images displayed on black and white liquid crystal panels provided separately for R, G, and B.

[Prior art] In recent years, the progress of liquid crystal display technology has been remarkable, with the advent of liquid crystal plates with excellent contrast and color reproducibility, and the practical use of liquid crystal color projection devices that use color liquid crystal plates as image display carriers to enlarge and project images onto large screens. has been done. This type of device converges light from a light source into approximately parallel light beams using a converging optical system, irradiates the transmissive color liquid crystal panel, and then enlarges and projects the transmitted light onto a screen via a projection optical system. , of the color liquid crystal panels currently in practical use! ! The prime number is 7
The number of pixels is from 10,000 to 90,000 pixels, and - picture elements of red (R) and green (G
), blue (if the pixels in (3) are one set, the number of pixels will be two-thirds, and when projected on a large screen!!i
Since the roughness of the pixels is noticeable, it is not practical. Therefore, in order to overcome the roughness of the number of picture elements when using a liquid crystal panel, we used three black and white liquid crystal plates and connected these liquid crystal plates with a light source of all wavelengths. R, G, and B lights are incident through a color separation (dichroic) mirror that separates (spectrums) them into three color lights of , G, and B, and R images, 0 images, and 8 images are generated on each liquid crystal plate. A method has been proposed and put into practical use in which a dichroic prism (prism method) or dichroic mirror (mirror method) is used to reproduce a color image on a large screen via a projection optical system.

These conventional devices will be explained with reference to FIG.

FIG. 4 is a schematic diagram of a liquid crystal color projection device called a mirror type, which uses dichroic mirrors for color separation and mixing of light. In the figure, 1 is a light source such as a xenon lamp, and the light emitted from this light source 1 is reflected by a total reflection mirror 2, converged by a converging optical system 3, and becomes a substantially straight ray, and only blue light is separated. The light enters the blue dichroic mirror 4 that reflects it. The blue light 5 separated by the blue dichroic mirror 4 is reflected by the mirror 6 parallel to the optical axis of the converging optical system 3 and enters the transmissive liquid crystal panel 7.

A voltage is selectively supplied to the liquid crystal panel 7 according to the constituent pixels of an arbitrary image to be projected, and the blue light 5 transmitted through the liquid crystal panel 7 becomes majestic color image light 5a having a video signal.

The blue component 5 is lost in the blue dichroic mirror 4, and the light transmitted through the mirror 4 becomes yellow. The yellow light 8 is incident on a red dichroic mirror 9, the red light 10 is separated, and the remaining green light 11 is transmitted through the mirror 9. The separated red light 10 enters a transmissive liquid crystal panel 12 having the same configuration as the liquid crystal panel 7, and becomes red image light 10a.

The blue image light 5a and the red image light 10a are mixed by a mixing dichroic mirror 13 to become magenta image light 14.

On the other hand, the green light 11 also enters the transmissive liquid crystal panel 15 having the same configuration as the surface liquid crystal panel 7, and the green image light 1.1.
a, is reflected by the mirror 16, and enters the mixing dichroic mirror 17. The green image light 1.1a and the magenta color image light 14 are mixed by a dichroic mirror 17.
The light is mixed into RGB additive color mixed image light 18, which is enlarged and projected onto a large screen 20 via one projection optical system to reproduce a color image.

The prism method uses triangular prism 4 as opposed to the L mirror one method.
This method uses a dichroic prism with a color mixing film interposed on the bonded surface to combine the RGB images, and has the same function as the mixing dichroic mirrors 13 and 17 in the Mira one-way system.

By the way, in the liquid crystal color projection device having the configuration as described above, the light from the light source is divided into R, G, and B and transmitted through the liquid crystal panels 7, 12 and 15. After that, the colors are mixed and enlarged and projected onto the screen 2 Q-l, so each pixel of the liquid crystal panels 7.12 and 15 must completely overlap on the screen 20. Therefore, the dichroic mirrors 4.9. 13.17, LCD panel 7.12
．． 15 and total reflection mirrors 6 and 16, and especially the mounting angles thereof, are required to be accurate.

Therefore, these optical component parts are usually mounted on a rigid optical base 21 made of aluminum die-casting, etc., but the mounting position on this optical base 21 is set at a precision I. ! Machine pre-processed. Therefore, the manufacturing cost of the optical base 21 is high, and since the optical component is fixed to the optical base 21 with screws, the mounting position may easily shift due to the dimensional difference between the screw mounting hole and the set screw. There was a problem.

Therefore, the present invention has been made in view of the above-mentioned problems in the prior art, and its purpose is to accurately form optical components without using an expensive aluminum die-cast optical base. The installation consists in providing a liquid crystal color projection device that allows you to obtain.

[Means for Solving the Problems] The present invention has been made to achieve the above object, and the first invention is to transmit light from a light source through three transmission type dichroic mirrors for R, G, and B. In a liquid crystal color projection device that displays an image by combining R, G, and B image light obtained by passing through a liquid crystal panel and projecting it onto a screen, the dichroic mirror and the liquid crystal panel are fixed in a predetermined position. It includes at least two parallel opposing side plates provided with a plurality of pairs of holes, and rods inserted into the respective pairs of holes of the side plates, and any of the mirrors and the liquid crystal panel are attached to these rods. Both ends are fixed.

Further, in a second aspect of the present invention, in the first aspect of the present invention, the mirror and the liquid crystal panel are fixed with the incident surface of the light source in direct contact with the bar.

Furthermore, a third aspect of the present invention is that in the first or second aspect, the mirror and the liquid crystal panel are fixed to the H bar with a stopper that holds them together.

Furthermore, a fourth invention is one in which, in any one of the first, second, and third inventions, the bar is a round bar.

[Function] In the present invention, the bar inserted into the hole in the side plate forms a mounting surface for the dichroic mirror and the liquid crystal panel. The liquid crystal panel is fixed with its entrance surface in direct contact with the bar, so that the entrance surface forms the same mounting angle as the bar. The fastener clamps and fixes the bar, the dichroic mirror, and the liquid crystal panel. The rod is a round rod that makes line contact with the dichroic mirror and the liquid crystal panel.

[Example] Hereinafter, the present invention will be described in detail based on an example shown in the drawings.

1 to 3 show an embodiment of the liquid crystal color projection device according to the present invention. 5. FIG. 1 is a perspective view showing the mounting structure of the liquid crystal panel, FIG. 2 is a plan view of the same panel, and FIG. FIG. 3 is a schematic diagram of a liquid crystal color projection device. Components in the figure that are the same as those in FIG. 4 are designated by the same reference numerals, and their explanations will be omitted. Further, in FIG. 1, illustration of the converging lens is omitted.

In these figures, 30 is a reflecting mirror whose reflective surface is a paraboloid and converts the light source light into parallel light parallel to the optical axis; 31 is a mirror that totally reflects the parallel light and guides it to the dichroic mirror 4;
32, 33, 34 are liquid crystal bar book lures, 12.15 respectively
A converging lens 35.36 is a pair of side plates arranged opposite to each other so as to be parallel to the optical axis, and between these side plates there is a dichroic ink mirror 4.9.13.17 and a liquid crystal with a converging lens. The optical components of a panel 7.12.15 and a total internal reflection mirror 6.16 are arranged. Moreover, each side plate 35, 36 has a plurality of pairs of holes 38a, 38b, 39a, '39b, .
is formed corresponding to each of the above optical components, and
Ends of rods 40a and 40b made of round rods are fitted and fixed into these holes, respectively, so that both side plates 35
．． It maintains a parallelism of 36. And the liquid crystal panel 7
．． 12.15, as shown in FIGS. 1 and 2, the side edge of the front side of the liquid crystal panel in one direction (Y direction) orthogonal to the bars 40a, 40b is in close contact with the bars 40a, 40b. , and are fixed by a pair of fasteners 42 and 43 fastened to the panel frame 41, respectively. At both ends of the inner edge of each of the fittings 42 and 43, there are integrated holding parts 44 which are curved into a semi-circular arc and are fitted onto the straight bars 40a and 40b, respectively, to press the liquid crystal panel against the bars 40a and 40b. It has been extended.

In this case, the front surface of the liquid crystal panel 7 is connected to the bar 40.
Since it is in close contact with the bars 40a and 40b, the mounting angle is always parallel to the bars 40a and 40b and does not change.

As a stopper, place the front of the liquid crystal panel close to the bar! :i
It is only necessary to use a type with an i-type of 100%, and various types of i-type such as those formed in the shape of a chrysotide sandwiching a liquid crystal plate and a rod can be used.

In addition, as for the guichroic mirror 6.9.13.17 and the total reflection mirror 6.16, both ends of the incident surface thereof are connected to a pair of bar members 40a and 40b, similar to the liquid crystal panel 7.12.15 described in ■. are closely identified with each other.

Thus, in such a configuration, each optical component is closely fixed to the pair of bars 40a, 40b suspended between the side plates 35 and 36, so that the bars 40a,
40b mounting accuracy, i.e. holes 38a, 38b, 39
a, 39b = positional accuracy or mounting accuracy of the optical component, the side plates 35, 36 are parallel to the optical axis, and the bar 40a
, 40b with respect to the side plates 35, 36 are all constant, it is possible to make the attachment angles of all optical components constant. In addition, aluminum die-cast high (
It does not require a rigid optical base and is simple and easy to manufacture.

[Effects of the Invention] As explained above, the liquid crystal color projection device according to the present invention includes a pair of rods provided between at least one pair of side plates corresponding to each optical component such as a dichroic mirror and a liquid crystal panel. Since each component is closely fixed to a pair of bars, the mounting angle of the component is uniquely determined by the mounting angle of the bar to the side plate, and the components and bars are fixed using fasteners without using screws. Since it is designed to sandwich the optical base, there is no need to worry about misalignment due to screw mounting holes, and it can be mounted at a high mounting angle.Also, it does not require an aluminum die-cast optical base, and can be provided at a low cost. .

[Brief explanation of the drawing]

Fig. 1 is a perspective view showing the mounting structure of the liquid crystal panel, Fig. 2 is a plan view of the same panel, Fig. 3 is a schematic diagram showing an embodiment of the liquid crystal color projection device according to the present invention, and Figs. FIG. 2 is a schematic diagram of a conventional device. 1... Light source means, 4.9.13,] 7--Dichroic mirror, 7.12.15--Liquid all-over mirror, 20 33.34-Several tens of side plates, 38a , 38b 3 hole, 40a, 40b --- rod/frame body 5.42 , 43 --- stopper, presser part. Japan Avionics Co., Ltd. Masaki Yamakawa Crystal panel, 0,16 Screen, 32, Z, 3s, 36 9a 39b Material, 41 ・

Claims (4)

[Claims] (1) R, G,
In a liquid crystal color projection device that displays an image by combining B-separate image lights and projecting the same onto a screen, at least two mutually disposed panels are provided with a plurality of pairs of holes for fixing the dichroic mirror and the liquid crystal panel in predetermined positions. A liquid crystal color projection device comprising parallel side plates and rods fitted into the respective pairs of holes of the side plates, and arbitrary both ends of the mirror and the liquid crystal panel are fixed to these rods. Device. (2) The liquid crystal color projection device according to claim (1), wherein the mirror and the liquid crystal panel are fixed with the incident surface of the light source in direct contact with the bar member. . (3) The liquid crystal color projection device according to claim (1) or (2), wherein the mirror and the liquid crystal panel are fixed to the bar with a stopper that holds them together. Device. (4) The liquid crystal color projection device according to any one of claims (1) to (3), wherein the bar is a round bar.