KR100201996B1 - Liquid crystal display projector - Google Patents

Abstract

According to the present invention, by converting the P polarization component into the S polarization component before reaching the LCD panel among the two polarization components S polarization component and P polarization component generated from the light source and directed toward the LCD panel, the polarization component that was initially the P polarization component is also linearly polarized. In order to be able to pass through the LCD panel to be used to reduce light loss, the aspherical reflector 21 reflecting in parallel the direct light emitted from the light source 20 and the aspheric reflector 21 emitted from the light source 20 Light paths 22a and 23a for reflecting a part of the light propagated to the aspherical reflector 21 and passing parallel light reflected by the aspherical reflector 21 and light emitted from the light source 20. Is formed in the center and passes through the concave elliptical ring-shaped ellipsoidal reflectors 22 and 23 and the light paths 22a and 23a formed in the center of the elliptical reflectors 22 and 23. The light filter includes a parallel light guide 24 for passing only parallel light components among the light components, an infrared filter 25 for removing hot wires of parallel light traveling through the parallel light guide 24, and the infrared filter ( The polarization component S1 reflects the polarization component S1 and the P polarization component P1 is transmitted among the polarization components included in the parallel light traveling through the light 25, and the polarization prism 26 is transmitted through the polarization prism 26. The polarization prism (26) is a polarization conversion panel (27) for converting the P polarization component (P1) into an S polarization component (S1), and the S polarization component (S1) transmitted through the polarization conversion panel (27). 45 reflects the S polarized light component S1 reflected by Reflector 28 and the polarizing prism 26 and 45 Image information is provided to the Fresnel lens 29 for condensing the S polarization component S1 reflected from the reflector 28 and the S polarization component S1 condensed through the Fresnel lens 29. The LCD panel 30 and the projection lens group 31 for projecting the light obtained by the image information while passing through the LCD panel 30 toward the screen 32.

Description

Liquid Crystal Display (LCD) Projector

1 is an optical circuit diagram showing the configuration of a projector using a conventional LCD panel.

2 is an optical circuit diagram showing a configuration of an LCD projector according to the present invention.

3 is a perspective view showing the structure of a parallel light guide according to the present invention.

4 is a plan view showing the structure of an elliptical reflector according to the present invention.

5 is a cross-sectional view showing a beam cross section before parallel light is incident on a polarizing prism in the LCD projector according to the present invention.

6 is a cross-sectional view showing a cross-sectional view of the beam converted by the parallel light through the polarizing prism in the LCD projector according to the present invention.

* Explanation of symbols for main parts of the drawings

20: light source 21: aspherical reflector

22, 23: elliptical reflector 22a, 23a: light path

24: parallel light guides 24a, 24b, 24c, , 24: tube

24x: anti-reflective coating film 25: infrared filter

26: polarization prism 27: polarization conversion panel

28: 45 Reflector 29: Fresnel Lens

30: LCD (Liquid Crystal Display) panel

31: projection lens group 32: screen

S1: S polarization component P1: P polarization component

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an LCD projector. Particularly, among the two polarization components, S polarization component and P polarization component generated from the light source and directed toward the LCD panel, P polarization component is converted into S polarization component before reaching the LCD panel, and P is initially The polarizing component, which was a polarizing component, can also be used in an LCD panel using linearly polarized light.

In the projector using the conventional LCD panel, as shown in FIG. 1 of the accompanying drawings, the light generated from the light source BS is reflected by the reflector R1 and is collected by the condenser lens CL, and the light is removed again from the heat ray. After the heat ray component is removed while passing through the infrared ray IR, the image information is acquired while passing through the LCD panel LP.

In this state, the light carrying the image information is projected onto the screen SC by the projection lens 10 to enlarge and view desired image information.

However, the projector using the conventional LCD panel uses only one flat light component among the two polarization components that cross and overlap each other in the structure of the LCD panel LP, resulting in a maximum light efficiency (Max) of only 50%.

That is, because only the P polarization component and the S polarization component that cross each other at right angles may pass through the LCD panel LP using linear polarization, the remaining P polarization component, which accounts for 50% of the light, is extinguished. Because it is thrown away.

Therefore, in the conventional configuration, since the light loss cannot be reduced to 50% or less, the light loss is large.

The present invention has been made to solve the above-mentioned problems, the S polarization component of the two polarization components that are generated from the light source toward the LCD panel and the P polarization component of the P polarization component before reaching the LCD panel as the S polarization component By converting, the purpose is to reduce the optical loss by allowing the polarization component, which was initially the P polarization component, to pass through the LCD panel using linear polarization.

An aspheric reflector reflecting the direct light emitted from the light source in parallel to achieve the object of the present invention; A light path for reflecting a part of light emitted from the light source and traveling to the aspherical reflector to the aspherical reflector is formed at the same time, and a light path through which parallel light reflected by the aspherical reflector and light emitted from the light source passes is formed at the center. An elliptical reflector having a concave elliptic ring shape; A parallel light guide for passing only parallel light components among light components passing through an optical path formed at the center of the elliptical reflector; An infrared filter for removing hot wires of the parallel light traveling through the parallel light guide; A polarizing prism reflecting the S polarization component and transmitting the P polarization component among the polarization components included in the parallel light traveling through the infrared filter; A polarization conversion panel for converting the P polarization component transmitted through the polarization prism into the S polarization component; 45 reflecting the S-polarized component converted and transmitted by the polarization converting panel to be parallel to the direction in which the S-polarized component reflected by the polarizing prism travels Reflector; 45 with the polarizing prism A Fresnel lens for condensing the S-polarized components respectively reflected from the reflector; An LCD panel for providing image information to the S-polarized component traveling through the Fresnel lens; An LCD projector is provided, which is composed of a projection lens group for projecting light, which has acquired image information, through the LCD panel toward a screen.

According to one preferred embodiment, the parallel light guides are arranged concentrically with each other and have a plurality of tubes of different lengths in a stair-shaped shape with a predetermined gap, and the central axis thereof is parallel to a direction in which parallel light passes therethrough. Can be installed and configured.

According to one preferred embodiment, the inner and outer circumferential surfaces of each tube may be formed by forming an anti-reflective coating film.

The antireflective coating film may be, for example, black.

Hereinafter, an embodiment of an LCD projector according to the present invention will be described in detail with reference to the accompanying drawings.

2 to 6 show an embodiment of the LCD projector according to the present invention, as shown therein; an aspherical reflector 21 for reflecting parallel light emitted from the light source 20 in parallel;

Parallel light reflected by the aspherical reflector 21 and the light source 20 are reflected by the aspherical reflector 21 while simultaneously reflecting a part of light emitted from the light source 20 and escaping from the aspherical reflector 21. Optical paths 22a and 23a through which light emitted from the light is passed are formed in the center, and the concave elliptical ring-shaped elliptic reflectors 22 and 23;

A parallel light guide 24 for passing only parallel light components among light components passing through the optical paths 22a and 23a formed at the center of the elliptical reflectors 22 and 23; An infrared filter (25) for removing hot wires in parallel light traveling through the parallel light guide (24); A polarizing prism 26 for reflecting S-polarized component S1 and transmitting P-polarized component P1 among polarization components included in parallel light traveling through the infrared filter 25;

A polarization conversion panel 27 for converting the P polarization component P1 transmitted through the polarization prism 26 into the S polarization component S1; 45 reflecting the S-polarized component S1 converted and transmitted by the polarization conversion panel 27 to proceed in parallel with the direction in which the S-polarized component S1 reflected by the polarizing prism 26 travels. A reflector 28;

The polarizing prism 26 and 45 A Fresnel lens 29 for condensing the S polarization components S1 reflected from the reflector 28;

An LCD panel 30 which provides image information to the S-polarized component S1 which is focused through the Fresnel lens 29; It is composed of a projection lens group 31 for projecting the light obtained by the image information while passing through the LCD panel 30 toward the screen (32).

The parallel light guide 24 has a plurality of tubes 24a, 24b, 24c,... 24n different in length from each other while being concentric with each other as shown in FIG. It arrange | positioned and comprised the center axis parallel to the direction which the parallel light which passes through this progresses.

The anti-reflective coating film 24x may be formed on the inner and outer circumferential surfaces of the respective tubes 24a, 24b, 24c,... 24n.

The antireflective coating layer 24x may be treated with, for example, a black anodizign coating.

On the other hand, Figure 4 shows the elliptical reflectors 22, 23, and the ones shown on the right side and the lower side of the elliptical ring in the drawing are the longitudinal cross-sectional shape and the transverse cross-sectional shape of the elliptical reflectors 22, 23, respectively. Each is shown for reference.

With reference to the accompanying drawings will be described in detail the operation and effect according to the embodiment of the present invention as described above.

As shown in FIGS. 2 to 6, the light emitted from the light source 20 is partially directed to the aspherical reflector 21 and the elliptical reflectors 22 and 23, while the elliptical reflector is used in the aspheric reflector 21. Light is reflected in parallel toward the light paths 22a and 23a formed at the center of the 22 and 23, and the elliptical reflectors 22 and 23 as shown in FIG. Light is reflected back toward the light.

Afterwards, the light propagating toward the light paths 22a and 23a mostly passes parallel light components by the parallel light guide 24, and the parallel light emitted through the parallel light guide 24 passes through the infrared filter 25. The heat wire is removed from the toward the polarizing prism 26.

At this time, the light toward the polarizing prism 26 has a rectangular irregular shape in which the S-polarized component S1 and the P-polarized component P1 overlap each other as shown in FIG. 5.

In the above state, the parallel light traveling toward the polarization prism 26 through the parallel light guide 24 is reflected by the polarization prism 26 among the two polarization components of the parallel light. Facing the Fresnel lens 29, the P polarization component (P1) is transmitted through the polarization prism 26, and the S polarization component (S1) is changed while passing through the flat conversion panel 27, and the changed S polarization component S1 is 45 The S-polarized component S1 reflected by the polarizing prism 26 by the reflector 28 is reflected toward the Fresnel lens 29 so as to travel in parallel with the traveling direction.

At this time, the light directed toward the Fresnel lens 29 is squarely shaped as shown in FIG. 6, while the cross-sectional area of the beam cross-section is increased by about twice as shown in FIG. Only have (S1).

In such a state, the S-polarized component S1 toward the Fresnel lens 29 is focused and directed toward the LCD panel 30, and the image information obtained from the LCD panel 30 is screened through the projection lens group 31. Lighted at (32).

As described above, the P polarization component does not overlap with the original S polarization component in the two polarization components of parallel light, and is configured to be condensed and used while being arranged in a square with the original S polarization component after being converted to the S polarization component. Therefore, the light efficiency can be expected up to 100%.

Claims (3)

An aspheric reflector 21 reflecting parallel light emitted from the light source 20 in parallel; Parallel light reflected by the aspherical reflector 21 and the light source 20 are reflected by the aspherical reflector 21 while simultaneously reflecting a part of light emitted from the light source 20 and escaping from the aspherical reflector 21. Optical paths 22a and 23a through which light emitted from the light is passed are formed in the center, and the concave elliptical ring-shaped elliptic reflectors 22 and 23; Concentric with each other, the tubes 24a, 24b, 24c, .... 24n of different lengths are arranged in a staircase shape with a predetermined gap, and the central axis thereof is an optical path of the elliptical reflectors 22, 23. A parallel light guide 24 provided in parallel with a direction in which parallel light travels so as to allow only parallel light components to pass through among the light components passing through the 22a and 23a; An infrared filter (25) for removing hot wires in parallel light traveling through the parallel light guide (24); A polarizing prism 26 for reflecting S-polarized component S1 and transmitting P-polarized component P1 among polarization components included in parallel light traveling through the infrared filter 25; A polarization conversion panel 27 for converting the P polarization component P1 transmitted through the polarization prism 26 into the S polarization component S1; 45 reflecting the S-polarized component S1 converted and transmitted by the polarization conversion panel 27 to proceed in parallel with the direction in which the S-polarized component S1 reflected by the polarizing prism 26 travels. A reflector 28; The polarizing prism 26 and 45 Image information is provided to the Fresnel lens 29 for condensing the S polarization component S1 reflected from the reflector 28 and the S polarization component S1 condensed through the Fresnel lens 29. An LCD panel 30; And a projection lens group (31) for projecting light toward the screen (32) from which the image information is acquired while passing through the LCD panel (30). The LCD projector according to claim 1, wherein an anti-reflective coating film (24x) is formed on the inner and outer circumferential surfaces of the respective tubes (24a, 24b, 24c,... 24n). The LCD projector according to claim 1, wherein said anti-rust coating layer (24x) is black.