KR200156494Y1 - Light apparatus for lcd projector - Google Patents

Abstract

The present invention relates to a lighting apparatus, and more particularly to a lighting apparatus for a liquid crystal projector to polarize the beam from the light source to efficiently use both beams. The present invention is a polarization splitting device disposed in front of the light source; A polarization conversion element for phase converting the reflected light of the polarization separation element; Reflection mirrors for reflecting the transmitted light and the reflected light of the polarization splitting device by 90 °; A liquid crystal panel which receives the beams finally; The inclined surface is formed from one end of the reflective surface closest to the liquid crystal panel along the thickness of the reflective mirror, and at least one of the reflective mirrors is covered with a coating film with a controlled reflectance to uniformly polarize the front of the liquid crystal panel. It has the effect of projecting a beam.

Description

Lighting device for liquid crystal projector

1 is a conventional lighting device for a liquid crystal projector,

2 is a lighting device for a liquid crystal projector according to an embodiment of the present invention,

3 is a lighting device for a liquid crystal projector according to another embodiment of the present invention,

4 is a lighting apparatus for a liquid crystal projector according to another embodiment of the present invention.

* Explanation of symbols for main parts of the drawings

100: light source 120: concave reflector

140: polarization separation device 160: polarization conversion device

180, 182, 184, 186, 188, 190, 192: first to seventh mirrors

200: liquid crystal panel

The present invention relates to a lighting apparatus, and more particularly, to a lighting apparatus for a liquid crystal projector to polarize the beam (Beam) from the light source to use both beams efficiently.

(A) of FIG. 1 shows a schematic light path in a conventional lighting device for a liquid crystal projector, and (b) shows nonparallel rays due to a polarization converter.

The beam of the light source 100 reaches the polarization splitter 140 as parallel light reflected by the reflector 120 installed on the rear surface of the light source. The first beam B ₁ , which is the P-polarized beam passing through the polarization splitter 140, immediately enters the liquid crystal panel 200, and the S-polarized beam reflected by the polarization splitter 140 is the polarization converting element 160. As it passes through, it is converted into a P-polarized beam. The second beam B ₂ , which is the converted P-polarized beam, is reflected by the first reflection mirror 180 and enters the liquid crystal panel 200 in parallel with the first beam. However, since the polarization conversion element 160 is positioned between the polarization separation element 140 and the first reflection mirror 180, the polarization beam reaches the center of the liquid crystal panel 200 as shown in FIG. You won't be able to. In particular, when the beam from the light source 100 is not completely parallel light, the intensity of the beam incident to the center portion of the liquid crystal panel 200 is further reduced due to total reflection in the polarization conversion element 160. Therefore, the user has a problem in that the center of the screen to see the dark image.

An object of the present invention for solving the above problems is to polarize the beam of the light source, and one of the beams are polarized conversion to make the two beams the same polarization beam and then to change the path of the polarized beams using a plurality of reflection mirrors Therefore, it is to provide an illumination device that allows the same amount of beams to enter the central portion of the liquid crystal panel.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

2 shows an optical path of the lighting apparatus according to an embodiment of the present invention. The polarization splitting element 140 positioned in front of the light source 100 has a function of separating light sources incident from the light source into P-polarized light and S-polarized light having a traveling direction perpendicular to each other. The polarization splitting element 140 is installed at an angle of 45 ° with respect to the light beam projected from the light source 100 so that the reflected light is directed downward. The first reflection mirror 180 is disposed to reflect the transmitted light of the polarization splitting element 140 at 90 °. The third reflection mirror 184 is disposed to reflect the reflected light of the polarization splitting element 140 by 90 degrees. The second reflection mirror 182 is installed on the optical path of the light rays reflected by the first reflection mirror 180 and the third reflection mirror 184. The second reflection mirror 182 is arranged to reflect the reflected light of the first reflection mirror 180 by 90 degrees. The liquid crystal panel 200 is disposed to receive the reflected light of the second reflection mirror 182 and the third reflection mirror 184. The exact arrangement of the second reflection mirror 182 is disposed so that its upper end portion is reflected from the lower portion of the third reflection mirror 184 to cover a part of the beam incident to the center of the liquid crystal panel 200.

The polarized beam is changed in path by the above-described reflection mirrors. The first beam B ₁ is incident to the lower portion of the liquid crystal panel 200, and the second beam B ₂ is incident to the upper portion of the panel 200. The boundary between the two beams incident on the panel 200 is a ray represented by a solid line in a circular dotted line. The beam passing through the upper end of the second reflecting mirror 182 of the beam of the first reflecting mirror 180 and the beam reflected from the third reflecting mirror 184 is reflected by the upper end of the second reflecting mirror 182. Incident on the liquid crystal panel 200.

Light rays represented by dotted lines are reflected at the edges of the first reflecting mirror 180 and the third reflecting mirror 184 as beams reflected at the edges of the concave reflector 120. These beams meet at the thickness mirror 182b of the second reflection mirror 182 and cause interference to reduce the amount of light at the two beam boundaries. This causes the center of the screen to be somewhat darker than the surroundings. Therefore, the light beams are formed to have an inclined surface 182c at a thickness of the reflective mirror from the upper end of the reflective surface of the second reflective mirror 182 so that the light does not reach the second reflective mirror 182.

As a result, the phenomenon that the brightness of the center portion of the screen falls slightly can be eliminated. However, when the light intensity of the two beams is different, the screen splitting still occurs. In order to solve this problem, a reflectance-adjusted coating is applied to one of the reflective mirrors.

3 shows another embodiment of the present invention. The same parts as in the above embodiment are denoted by the same reference numerals. In this example, the fourth reflection mirror 186 plays the role of the second reflection mirror 182 of FIG. 2. The fourth reflection mirror 186 is installed between the first and third reflection mirrors 180 and 184. The correct position of the fourth reflecting mirror 186 is disposed so that the lower end of the reflecting surface covers a part of the beam reflected from the upper part of the third reflecting mirror 184 and incident on the panel 200. In this manner, the upper portion of the liquid crystal panel 200 is positioned in front of the fourth reflection mirror 186. Therefore, the first beam B ₁ reflected by the fourth reflection mirror 186 is incident on the upper panel, and the second beam B ₂ is incident on the lower panel. In this case, when the beam reflected from the third reflection mirror 184 and incident to the center of the panel 200 passes through the rear surface end instead of the reflective surface end of the fourth reflection mirror 186, the two beams are divided.

Therefore, the fourth reflective mirror 186 is formed to have an inclined surface at the mirror thickness from the lower end of the reflective surface so that the boundary between the two beams is not divided. Other actions are the same as in FIG.

4 shows another embodiment of the present invention. This example is characterized by the use of multiple reflective mirrors. A fifth reflection mirror 188 that receives the light reflected from the third reflection mirror 184 and reflects the light 90 degrees again is disposed under the first reflection mirror 180. The sixth reflective mirror 190 and the seventh reflective mirror 192 are disposed in the middle of the first and fifth reflective mirrors 180 and 188. The liquid crystal panel 200 is disposed in front of the sixth and seventh reflection mirrors 190 and 192. The seventh reflection mirror 192 receives the reflected light of the fifth reflection mirror 188 and reflects the light 90 ° again to enter the liquid crystal panel 200. The sixth and seventh reflecting mirrors 190 and 192 respectively form the lower end and the upper end to have an inclined surface for the reason described in FIGS. 2 and 3. The two reflection mirrors 190 and 192 abut the inclined surfaces to form a right angle with each other. The beams incident on the liquid crystal panel 200 are beams finally reflected by the sixth and seventh reflection mirrors 190 and 192.

Light rays, shown as dashed lines, pass through the beams reflected at the edges of the first and fifth reflecting mirrors 180 and 188, respectively, without touching the reflective surfaces of the sixth and seventh reflecting mirrors 190 and 192, as shown in the circle. Throw it away. This does not affect the boundary of the two beams incident on the panel. Other functions are the same as those of the above embodiments.

As described above, the lighting apparatus for a liquid crystal projector according to the present invention has an effect of injecting a uniform polarization beam to the entire liquid crystal panel.

Claims (6)

(Correction) A lighting apparatus for a liquid crystal projector for projecting a beam from a light source to a liquid crystal panel, comprising: a polarization splitting element disposed in front of the light source for separating and transmitting the beam into P-polarized light and S-polarized light; A polarization converting element disposed on an optical path of a beam reflected by the polarization splitting element to convert and transmit a phase of the reflected beam; And optical coupling means for uniformly projecting beams transmitted from the polarization splitting element and the polarization converting element onto the liquid crystal panel. (Correction) The display apparatus according to claim 1, wherein the optical coupling means comprises: a first reflection mirror that reflects the transmitted light of the polarization splitting element by 90 degrees; A second reflection mirror reflecting the transmitted light of the polarization conversion element by 90 ° and projecting the upper portion of the liquid crystal panel; And positioned on an optical path of beams reflected from the first and second reflecting mirrors, and a beam of an upper end portion of the reflecting surface of the first reflecting mirror proceeds without reflection and transmission, and the reflecting surface of the second reflecting mirror. The lower beam forms an inclined surface according to the thickness at the upper end of the reflecting surface so as not to proceed to the liquid crystal panel, and consists of a third reflecting mirror which reflects the reflected light of the first reflecting mirror by 90 ° and projects the lower part of the liquid crystal panel. Lighting equipment for liquid crystal projectors. According to claim 1, The optical coupling means comprises: a first reflection mirror for reflecting the transmitted light of the polarization splitting device 90 °; A second reflection mirror reflecting the reflected light of the polarization conversion element by 90 °; A third reflecting mirror which reflects light reflected from the second reflecting mirror at 90 degrees; A fourth reflection mirror positioned such that the beam at the lower end of the reflective surface of the first reflection mirror proceeds without reflection and transmission, and reflects the light reflected from the first reflection mirror by 90 ° to project the light to the upper portion of the liquid crystal panel; And a fifth reflecting mirror positioned so that the beam of the upper end of the reflecting surface of the third reflecting mirror proceeds without reflection and transmission, and reflecting the light reflected from the third reflecting mirror by 90 ° to project the lower portion of the liquid crystal panel. Illumination device for a liquid crystal projector characterized in that. The illuminating device for a liquid crystal projector according to claim 3, wherein the lower end of the reflecting surface of the fourth reflecting mirror and the upper end of the reflecting surface of the fifth reflecting mirror are bonded to each other at right angles. According to claim 1, The optical coupling means comprises a first reflecting mirror for reflecting the transmitted light of the polarization splitting device 90 °; A second reflection mirror reflecting the transmitted light of the polarization conversion element by 90 ° and projecting the lower portion of the liquid crystal panel; And positioned on an optical path of beams reflected from the first and second reflecting mirrors, and a beam of a lower end portion of the reflecting surface of the first reflecting mirror proceeds without reflection and transmission, and the reflecting surface of the second reflecting mirror. The beam of the upper end is formed of a third reflecting mirror which forms an inclined surface according to the thickness at the lower end of the reflecting surface so as not to proceed to the liquid crystal panel and reflects the reflected light of the first reflecting mirror by 90 ° to project the upper part of the liquid crystal panel. Lighting equipment for liquid crystal projectors. 6. The liquid crystal projector according to any one of claims 2 to 5, wherein at least one of the reflection mirrors has a coating layer with a reflectance adjusted to adjust the polarization beams to the same light intensity. Lighting equipment.