KR19980052196A - Optical device of the liquid crystal projector - Google Patents

Abstract

The present invention relates to an optical device of a liquid crystal projector in which a gap generated when a plurality of liquid crystals are combined to make a high definition large screen is optically removed to obtain a clear large screen image without disconnection of the image.

The present invention provides a front projection type liquid crystal projector comprising: a plurality of condenser lenses for condensing light of a light source, a plurality of liquid crystals arranged in a plane at a rear end of the lenses, a virtual image lens system arranged on the same optical axis at a rear end of the liquid crystals, the virtual image It consists of a projection lens system for projecting light from the lens system to the screen to obtain a high quality image on the large screen.

Description

Optical device of the liquid crystal projector

The present invention relates to a liquid crystal projector capable of optically removing a gap generated when a plurality of liquid crystals are combined to make a high definition large screen, thereby obtaining a clear large screen image without disconnection of the image.

In general, in the field of display, it is very difficult to make a screen larger than 40 inches because of limitations in size and flat screen.

Therefore, what is proposed in order to overcome this limitation is a projection apparatus that projects an image formed on a small CRT or LCD through a projection lens.

On the other hand, as a result of the development of various technologies for HDTV, a high-definition display device that provides a direct image to a user is being promoted to directly view a PDP, LCD, etc. in addition to using a CRT. As a result, a multi-faceted process for liquid crystal projectors that obtain large images is underway.

The liquid crystal used here is mass-produced at VGA level (640 × 480), and higher resolution products have been produced at the laboratory level, but it still takes a long time to mass-produce HDTV (1024 × 768). It is a reality.

Therefore, the problem of the prior art is that the product of the VGA-type enlarged projection method is already on the market, and in order to obtain the HDTV-class clarity and large screen, the CRT or the liquid crystal display method is directly used, but this method is mainly used between the liquid crystals. Because of the gap between the images, the images are easily disconnected and it is very difficult to obtain a clear image.

Recently, a method of attaching four liquid crystals without a gap has been developed, or a method of attaching 48 10 inch liquid crystals with a back projection method using a micro lens and a Fresnel lens has been developed, but it is difficult to manufacture a micro lens in such a method. In addition, cost increases.

In addition, since the rear projection type can not arbitrarily adjust the size of the screen and the size of the microlens and Fresnel lens is as large as the screen size, there is a manufacturing problem.

The present invention has been made to solve the above-mentioned general drawbacks, to project a HDTV-class image using four VGA class, so that the gap between the liquid crystal is not projected to obtain a clear image by eliminating the disconnection of the image. Its purpose is to provide a liquid crystal projector.

In order to achieve the above object, the present invention provides a front projection type liquid crystal projector comprising: a plurality of condenser lenses for condensing light of a light source, a plurality of liquid crystals arranged in a plane at the rear end of the lenses, and a same optical axis at the rear end of the liquid crystals. And a projection lens system for projecting light emitted through the virtual image lens system onto the screen.

1 is a block diagram of a liquid crystal projector according to the present invention

2 is a view for explaining the principle of operation of the present invention

3 is a view for explaining the shape and arrangement of each liquid crystal of the present invention;

4 is a view for explaining the position of the optical axis of the virtual image lens system when the distance between the upper, lower, left and right liquid crystals of the present invention is the same;

Figure 5 is another first embodiment of the present invention

Figure 6 is a second embodiment of the present invention

7 is a third embodiment of the present invention

Explanation of symbols on the main parts of the drawings

1: light source 3: first condenser lens

4: second condenser lens 5: first liquid crystal

6: second liquid crystal 7: first virtual image lens

8: second virtual image lens 9: screen

10: projection lens system 18, 19, 20, 22: optical system

1 is a view for explaining the principle of the present invention, showing an optical path in the case of combining two liquid crystals.

In such a structure, the light source 1 which emits light, the reflector 2 which reflects the light emitted by the said light source 1, and the 1st, 2nd condenser lens 3 which condenses light ( 4) and the first and second liquid crystals 5 and 6 provided at the rear end of the first and second condenser lenses 3 and 4, and the rear ends of the first and second liquid crystals 5 and 6. The first and second virtual image lenses 7 and 8 having a + refractive index and an image of the first virtual image lens 7 at a lower end of the screen 9 and the second virtual image lens 8. It consists of a projection lens system 10 for converging an image on the top of the screen 9, wherein the first and second virtual image lenses 7 and 8 form one virtual image lens system.

According to the present invention configured as described above, when light is emitted from the light source 1, the light is reflected by the reflector 2 and the first and second liquid crystals 5 and 6 are provided through the first and second condenser lenses 3 and 4. The image generated from the first and second liquid crystals 5 and 6 is illuminated on the screen 9 through the first and second virtual image lenses 7 and 8 and the projection lens system 10. Projected.

In this case, the optical path ① means that the image in the center of the first liquid crystal 5 is formed at the lower middle point on the screen 9, and the optical path ② corresponds to the upper portion of the second liquid crystal 6. ) Means to be formed in the center.

In addition, the optical path ③ means that the lower part of the second liquid crystal 6 is formed at the uppermost part of the screen 9.

In FIG. 2, when the light paths of the dotted lines are connected in a straight line, for example, the light rays starting from the second liquid crystal 6 coincide with the actual light paths after passing through the second virtual image lens 8, which is the projection lens system 10. It shows that the position of the image with respect to the position of the virtual image is the same, the liquid crystal is located inside the first focus of the virtual lens system to form an enlarged image.

Meanwhile, a shielding structure is formed between the first liquid crystal 5 and the first virtual image lens 7, the second liquid crystal 6, and the second virtual image lens 8 so that light does not pass through each other.

3 shows an embodiment of the arrangement and spacing of the liquid crystals used in the present invention. In FIG. 1, only two liquid crystals 5 and 6 are illustrated, but in fact, four liquid crystals are arranged in a plane as shown in the drawing. In each case, the shape and arrangement of the liquid crystal and the size of the virtual image formed by the enlargement are shown.

This means that the length and width of the 1.3-inch liquid crystal are 19.8 mm and 26.4 mm, and the vertical and horizontal liquid crystal intervals are 1 mm, and the size of the enlarged virtual image becomes 20.8 mm and the same ratio is applied. Since the horizontal direction of the virtual image is 27.733MM, the horizontal distance of the liquid crystal should be 1.333MM apart.

That is, the interval between the upper and lower liquid crystals is 1 mm, and the interval between the left and right liquid crystals is 1.333 mm, so that when the aspect ratio of the liquid crystal is not 1: 1 but 4: 3, the vertical and horizontal gaps are also different by the ratio.

Here, the left and right liquid crystals may have a distance of 1 mm equal to the vertical gap. In this case, as shown in FIG. 4, the optical axis of the virtual image lens is slightly shifted to the side from the center of the liquid crystal so that the optical axis is out of the vertical axis from the center of the projection lens system. Just make the distance the same.

In addition, in the same manner, the distance between the liquid crystals can be adjusted depending on the conditions, and at this time, only the position of the virtual image lens optical axis needs to be slightly adjusted.

On the other hand, assuming that the virtual lens system is located at a distance of about 40MM, the distance of the diagonal of the liquid crystal is slightly larger than 1.3 inches, A = 40MM and B = MA from the imaging equation of 1 / A-1 / B = 1 / F. Since M (magnification) = 20.8 / 19.8, F = (MA) / (M-1) = 832MM and B = 42.02MM.

Here, A = distance from the liquid crystal to the first main point of the virtual image lens system, B = distance from the second main point of the virtual image lens to the virtual image, and F is the focal length of the virtual image lens system.

5 shows an embodiment in which the present invention is applied to a conventional flat panel filter type three-panel liquid crystal projector, and includes a hot mirror 11, an R mirror 12, a first mirror between the light source 1 and the projection lens 10. In arranging the second mirrors 13, 14, G1, G2 mirrors 15, 16, and B mirrors 17, a condenser lens and a liquid crystal are disposed on the first mirror 13 and the G2 mirror 16. And an optical system 18 composed of a virtual image lens system and between the second mirror 14 and the G1 mirror 15 and between the G1 mirror 15 and the G2 mirror 16, respectively, as described above. ) Is placed.

In this embodiment, the light emitted from the light source 1 is illuminated in parallel by the reflector, the red light is reflected upward by the R mirror 12, and the green and blue light are transmitted as it is.

The red light is reflected back by the first mirror 13 and then enters the projection lens system 10 through the G2 mirror 16 and the B mirror 17 through the optical system 18, where the liquid crystal is actually arranged up, down, left, and right. Although only two are visible on the drawing.

In addition, the red + blue light that has passed through the R mirror 12 as it is is reflected only from the G1 mirror 15 to the upper part of the green light, and is also reflected by the G2 mirror 16 via the optical system 20 to be projected through the B mirror 17. Incident to the lens system 10.

Meanwhile, the blue light passing through the G1 mirror 15 as it is is reflected by the second mirror 14 through the optical system 19 and reflected by the B mirror 17 again to be incident on the projection lens system 10.

The light incident on the projection lens system 10 is synthesized as white light to form an image on the screen by the projection lens system 10.

Here, the G2 mirror 16 transmits red light and reflects green light, and the B mirror 17 reflects blue light and transmits red and green light.

FIG. 6 shows another embodiment in which the present invention is applied to an existing prism type three-panel liquid crystal projector, wherein the condenser lens is disposed on three surfaces of the color synthesis prism 21 disposed between the light source 1 and the projection lens system 10. An optical system consisting of a liquid crystal and a virtual image lens system is disposed, and an operation description is made based on the same principle as the embodiment of FIG. 5.

7 shows an embodiment in which the present invention is applied to a color short panel liquid crystal projector, wherein the condenser lens, the color liquid crystal, and the virtual image lens system are described between the hot mirror 11 and the projection lens system 10 at the rear end of the light source 1. One optical system 22 is arranged and configured, and this embodiment also operates in the same principle as in the case of FIG.

As described above, the present invention can obtain HDTV-class images by using four VGA-level liquid crystals, and high-quality images can be obtained, and images can be connected up to 1/10 of the pixel size. As described above, the gap between the liquid crystals is larger than the pixel size, thereby preventing the image from being broken.

In addition, by using the front projection method can be manufactured in a small size of each lens, thereby reducing the size of the overall system.

Claims (9)

A front projection type liquid crystal projector comprising: a plurality of condenser lenses for condensing light from a light source, a plurality of liquid crystals arranged in a plane at the rear end of the lenses, a virtual image lens system arranged on the same optical axis at the rear ends of the liquid crystals, and the virtual image And an projection lens system for projecting light emitted through the lens system onto the screen. The method of claim 1, And a shielding structure between the first liquid crystal and the second liquid crystal to prevent light from passing through the first virtual lens and the second virtual lens. The method of claim 1, And the optical axis of the projection lens system is different from the optical axis of the virtual lens system and integrally formed with the center of the screen. The method of claim 1, An optical apparatus for a liquid crystal projector, characterized in that the distance between liquid crystals is equalized by adjusting the optical axis of the virtual image lens system. The method according to any one of claims 1 to 4, The virtual image lens system includes a lens system having a + refractive index, and the liquid crystal is configured to be positioned inside the first focus of the virtual lens system to form an enlarged virtual image. The method of claim 1, An optical apparatus of a liquid crystal projector, characterized in that all liquid crystals are configured to be illuminated by one light source. A front projection type liquid crystal projector comprising: an optical system comprising a condenser lens, a color liquid crystal, and a virtual image lens disposed between a hot mirror and a projection lens at a rear end of a light source. A flat panel filter type three-panel liquid crystal projector having a hot mirror, an R mirror, a first mirror, a second mirror, a G1, a G2 mirror, and a B mirror disposed between the light source and the projection lens, wherein the first mirror and the G2 mirror, and the second mirror. And an optical system comprising a condenser lens, a liquid crystal and a virtual image lens, respectively, between a mirror and a G1 mirror and between a G1 mirror and a G2 mirror. A prism-type three-panel liquid crystal projector comprising: an optical system composed of a condenser lens, a liquid crystal, and a virtual lens system on three surfaces of a color synthesizing prism disposed between a light source and a projection lens, respectively.