KR100272104B1 - Reflection type projector - Google Patents

Abstract

Disclosed is a reflective project apparatus that can increase brightness of light projected on a screen by simultaneously superimposing three colors used to implement a color image in one screen configuration.

The disclosed reflective project apparatus includes a light source; First and second dichroic mirrors disposed on an optical path to transmit and reflect incident light according to a wavelength region; First, second and third image generating means for generating an image corresponding to each color from incident light; A first prism disposed on an optical path between the first dichroic mirror and the first image generating means; A second prism disposed on an optical path between the second dichroic mirror and the second image generating means; A third prism disposed on an optical path between the second dichroic mirror and the third image generating means; A dichroic beam splitter for selectively transmitting or reflecting light according to the wavelength so that light incident through the first, second, and third prisms is emitted in one direction; Correction prism installed on the light exit surface of the dichroic beam splitter such that the optical axis of light incident on the dichroic beam splitter via each of the first, second and third prisms is incident substantially perpendicular to each of the three incidence planes of the dichroic beam splitter. and; A projection lens unit which enlarges and transmits the light incident from the dichroic beam splitter side toward the screen; It is characterized by including.

Description

Reflective Project Device

The present invention relates to a reflective project apparatus using a reflective image generating means, and more particularly, to a reflective project apparatus capable of increasing the brightness of light projected on a screen by simultaneously superimposing three colors used for implementing a color image. will be.

Generally, a projector apparatus is an apparatus for providing an image by projecting an image generated by the image generating means onto a screen using a separate light source. This projector apparatus is classified into a transmission type and a reflection type according to the form of the image generating means described above.

The present applicant is a Korean Patent Application No. 97-13025 (filed date; April 19, 1997, 1997), which is a reflective project device that can realize a color screen by irradiating the screen with three colors simultaneously to increase the brightness of the screen; Reflective project device, inventor;

As shown in FIG. 1, the proposed reflective project apparatus includes a light source 110 for generating and projecting light, and first and second dichroic elements disposed on an optical path to transmit and reflect incident light according to a wavelength region thereof. First, second and third mirrors 131 and 135, first, second and third optical path converting means 140, 150 and 160 for converting the advancing path of incident light, and first, second and third generating images from the incident light. The light incident through the third image generating means (145, 155, 165) and the first, second, and third optical path changing means (140, 150, 160) is emitted in one direction. And a dichroic beam splitter 170 and a projection lens unit 180 to enlarge and project the light incident from the dichroic beam splitter 170.

Each of the first to third light path converting means 140, 150, and 160 may include first to third condensing lenses 141, 151 and 161, and first to third prisms 143 and 153. 163). The first to third prisms 143, 153, and 163 allow light to be incident at an angle greater or smaller than a critical angle, thereby transmitting the light incident from the light source 110, and transmitting the light to the first to third prisms. The light reflected by each of the three image generating means 145, 155, and 165 has first to third transmission / reflection surfaces 143a, 153a, and 163a to be totally reflected.

The dichroic beam splitter 170 has three entrance planes 171, 172, 173 and one exit plane 174. Each of the three incidence planes 171, 172, 173 faces each of the first, second, and third optical path converting means 140, 150, 160 and each of the optical path converting means 140 ( 150, the traveling path of the incident light is converted so that the incident light is directed toward the one exit surface 174. To this end, the dichroic beam splitter 170 has first and second mirror surfaces 176 and 177 for selectively transmitting or reflecting light depending on the wavelength. The first mirror surface 176 is coated so as to transmit and reflect according to the wavelength region to reflect the light incident through the first optical path converting means 140, and second and third optical path converting means 150. The light incident through the 160 is transmitted. The second mirror surface 177 is coated to transmit and reflect according to the wavelength region to transmit the light passing through the first and second optical path converting means 140 and 150 and to transmit the third optical path converting means ( The light via 160 is reflected. As described above, since the dichroic beam splitter 170 includes first and second mirror surfaces 176 and 177, the light incident from each of the three incident surfaces 171, 172, and 173 is one exit surface. 174 exits.

The projection lens unit 180 is disposed between the dichroic beam splitter 170 and a screen (not shown) to enlarge and project the light incident from the dichroic beam splitter 170 toward the screen.

In the reflective project device configured as described above, referring to FIG. 2, the first to third prisms may be implemented because the optical axis A _L and the optical axis A _P of the projection lens unit are different from each other. 143, 153, 163 and the dichroic beam splitter 170 have an optical arrangement as shown in FIG.

Here, when the illumination optical axis A _L passes through a line segment where the first and second mirror surfaces of the dichroic beam splitter 170 meet, the utilization efficiency of three colors is increased. However, in this arrangement, the first FLCD 147 of the first image generating means 145 and the second FLCD 157 of the second image generating means 155 are disposed too close to each other so that the first and second FLCD ( It is difficult to mount the convergence adjusters 149 and 159 to adjust the convergence of each of the 147 and 157. In addition, light incident through the first to third prisms 143, 153, and 163 and incident on each of the three incident surfaces 171, 172, and 173 of the dichroic beam splitter 170 is approximately incidence angle. Since the optical arrangement is not achieved by 90 °, the optical arrangement is complicated, and the occupied space of the first to third prisms 143, 153, and 163 is increased.

Accordingly, the present invention has been made to supplement the above-mentioned point, and has a correction prism to simplify the optical arrangement of the first to third prism, to minimize the occupied space and to secure the installation space of the convergence adjustment device The purpose is to provide a reflective project apparatus.

1 is a schematic view showing an optical arrangement of a reflective project device proposed by the applicant.

FIG. 2 shows the optical arrangement of the first to third prisms and the dichroic beam splitter of FIG. 1; FIG.

3 is a schematic view showing an optical arrangement of a reflective project apparatus according to an embodiment of the present invention.

<Explanation of symbols for the main parts of the drawings>

110 ... light source 131 ... first mirror

132,133,134 ... reflective mirror 135 ... Secondary mirror

140,140 '... first light path converting means 141,141' ... first condenser lens

143,143 '... first prism 145 ... first imaging means

146 ... first polarizer 147 ... first ferroelectric liquid crystal display device

148 ... 1st analyzer 150, 150 '... 2nd light path converting means

151,151 '... second condenser lens 153,153' ... second prism

155 ... Second Image Generation 156 ... Second Polarizer

157 Second ferroelectric liquid crystal display 158 Second analyzer

160,160 '... third light path converting means 161,161' ... third condenser lens

163,163 '... 3rd Prism 165 ... 3rd Image Generation Means

166 Third Polarizer 167 Third Ferroelectric Liquid Crystal Display Device

168 3rd analyzer 170,170 '... Different beam splitter

180 Projection lens unit 190 Compensation prism

In order to achieve the above object, a reflective project device according to the present invention comprises: a light source for generating and projecting light; A first dichroic mirror disposed on an optical path and transmitting and reflecting incident light according to a wavelength region; First, second and third image generating means for generating an image corresponding to each color from incident light; Disposed on an optical path between the first dichroic mirror and the first image generating means to transmit the light incident through the first dichroic mirror and totally reflect the light reflected by the first image generating means; A first prism having a first transmission / reflection surface; A second dichroic mirror for transmitting and reflecting light reflected from the first dichroic mirror according to a wavelength region; A second light beam disposed on an optical path between the second dichroic mirror and the second image generating means to transmit the light reflected by the second dichroic mirror and totally reflect the light reflected by the first image generating means A second prism having a transmission / reflection surface; A third disposed on an optical path between the second dichroic mirror and the third image generating means to transmit light transmitted through the second dichroic mirror and totally reflect the light reflected by the third image generating means A third prism having a transmission / reflection surface; A dichroic beam splitter having first and second mirror surfaces selectively transmitting or reflecting light according to a wavelength such that light incident through the first, second and third prisms is emitted in one direction; An optical axis of light incident on the light exit surface of the dichroic beam splitter and incident on the dichroic beam splitter via each of the first, second, and third prisms is incident substantially perpendicular to each of the three incident surfaces of the dichroic beam splitter; A correction prism to make it possible; A projection lens unit for extending and transmitting the light incident from the dichroic beam splitter toward the screen; It is characterized by including.

Hereinafter, exemplary embodiments of a reflective project apparatus according to the present invention will be described in detail with reference to the accompanying drawings.

3 is a schematic diagram showing an optical arrangement of a reflective project apparatus according to an embodiment of the present invention.

As shown, the reflective project device of the present invention includes a light source 110 for generating and projecting light, and first and second dichroic mirrors 131 disposed on an optical path to transmit and reflect incident light according to a wavelength region thereof. 135, the first, second and third light path converting means 140 ', 150' and 160 'for converting the traveling path of the incident light and the first, second and second generating images from the incident light. Light incident through the third image generating means 145, 155, 165 and the first, second, and third optical path changing means 140 ′, 150 ′, 160 ′ is oriented in one direction. A dichroic beam splitter 170 'for outputting and a correction prism 190 for causing an illumination optical axis incident on the dichroic beam splitter 170' to be incident substantially perpendicular to each of three incidence planes of the dichroic beam splitter 170 '. And a projection lens unit 180 for expanding and projecting the light incident from the dichroic beam splitter 170 '.

Here, the members using the same reference numerals as in the drawings shown in FIGS. 1 and 2 are the same members having the same functions, and thus detailed description thereof will be omitted.

The first optical path converting means 140 ′ converts a traveling path of the light incident through the first dichroic mirror 131. The first light path converting means 140 'includes a first condensing lens 141' and a first prism 143 '. The first condenser lens 141 ′ focuses incident divergent light to become parallel light. The first prism 143 ′ is configured to transmit light incident from the first condenser lens 141 ′ and to totally reflect light reflected by the first image generating means 145. Has

The second optical path converting means 150 ′ is disposed on an optical path between the second dichroic mirror 135 and the dichroic beam splitter 170 ′ to reflect light reflected from the second dichroic mirror 135. And a second condensing lens 151 'and a second prism 153' to convert the traveling path of the light. Here, the role and optical arrangement of each of the second condensing lens 151 'and the second prism 153' is substantially the same as that of each of the first condensing lens 141 'and the first prism 143'. Detailed description will be omitted.

The third optical path converting means 160 ′ is disposed on an optical path between the second dichroic mirror 135 and the dichroic beam splitter 170 and transmits light transmitted through the second dichroic mirror 135. A third condenser lens 161 ′ and a third prism 163 ′ are included to convert the traveling path of the light. Here, the role and optical arrangement of each of the third condenser lens 161 ′ and the third prism 163 ′ are substantially the same as that of each of the first condenser lens 141 ′ and the first prism 143 ′. Detailed description will be omitted.

The dichroic beam splitter 170 'has three incident surfaces 171', 172 'and 173' and one exit surface 174 '. Each of the three incident surfaces 171 ', 172', and 173 'faces each of the first, second, and third optical path converting means 140', 150 ', 160' and each optical path The traveling path of the incident light is converted so that the light incident through the converting means 140 ', 150', 160 'is directed toward the one exit surface 174'. To this end, the dichroic beam splitter 170 'has first and second mirror surfaces 176' and 177 'for selectively transmitting or reflecting light depending on the wavelength. The first mirror surface 176 'is coated to transmit and reflect along the wavelength region to reflect the light incident through the first optical path converting means 140', and the second and third optical path converting means. Light incident through (150 ') and 160' is transmitted. The second mirror surface 177 'is coated to transmit and reflect along the wavelength region so that light passing through the first and second optical path converting means 140' and 150 'is transmitted and the third optical path is transmitted. The light passing through the conversion means 160 ′ is reflected. As described above, since the dichroic beam splitter 170 'includes first and second mirror surfaces 176' and 177 ', incident on each of the three incident surfaces 171', 172 'and 173'. The emitted light is emitted through the one exit surface 174 '.

The correction prism 190 takes into account the optical arrangement and optical aberration of the dichroic beam splitter 170 'and the first to third prisms 143', 153 ', and 163', and thus the dichroic beam splitter ( 170 ') between the exit surface 174' and the projection lens unit 180 is preferably provided. The correction prism 190 is preferably formed by joining one surface to the exit surface 174 'of the dichroic beam splitter 170' in a wedge shape. In addition, the correction prism 190 may be integrally provided with the dichroic beam splitter 170 ′.

Since the aberration, in particular chromatic aberration and distortion caused by the optical arrangement change of the first to third prisms 143 ', 153' and 163 'can be corrected by the correction prism 190, the first to third The optical axis A _L of the incident light incident through the three prisms 143 ', 153' and 163 'has three incident surfaces 171', 172 'and 173' of the dichroic beam splitter 170 '. ), And the installation space of the convergence adjusting device of the image generating means as described above is secured. In addition, the first to third prism 143 ′ such that the optical axis A _L of the incident light passes through portions where the first and second mirror surfaces 176 ′ and 177 ′ of the dichroic beam splitter 170 ′ meet. 153 'and 163' can be arranged.

As described above, the reflective project device according to the present invention can increase the brightness of the light projected on the screen by simultaneously superimposing three colors used for color image implementation. In addition, by changing the optical structure of the first, second and third prism by the correction prism, the optical axis of the incident light is the first of the dichroic beam splitter when the non-axis optical system is designed to shift the optical axis of the incident light and the optical axis of the projection lens unit. And it is easy to arrange so as to transmit the portion where the second mirror surface meets.

Claims (3)

A light source for generating and projecting light; A first dichroic mirror disposed on an optical path and transmitting and reflecting incident light according to a wavelength region; First, second and third image generating means for generating an image corresponding to each color from incident light; Disposed on an optical path between the first dichroic mirror and the first image generating means to transmit the light incident through the first dichroic mirror and totally reflect the light reflected by the first image generating means; A first prism having a first transmission / reflection surface; A second dichroic mirror for transmitting and reflecting light reflected from the first dichroic mirror according to a wavelength region; A second light beam disposed on an optical path between the second dichroic mirror and the second image generating means to transmit the light reflected by the second dichroic mirror and totally reflect the light reflected by the first image generating means A second prism having a transmission / reflection surface; A third disposed on an optical path between the second dichroic mirror and the third image generating means to transmit light transmitted through the second dichroic mirror and totally reflect the light reflected by the third image generating means A third prism having a transmission / reflection surface; A dichroic beam splitter having first and second mirror surfaces selectively transmitting or reflecting light according to a wavelength such that light incident through the first, second and third prisms is emitted in one direction; An optical axis of light incident on the light exit surface of the dichroic beam splitter and incident on the dichroic beam splitter via each of the first, second, and third prisms is incident substantially perpendicular to each of the three incident surfaces of the dichroic beam splitter; A correction prism to make it possible; A projection lens unit for extending and transmitting the light incident from the dichroic beam splitter toward the screen; Reflective project device comprising a. The reflective project apparatus according to claim 1, wherein the correction prism has a wedge shape and one surface thereof is coupled to the light exit surface of the dichroic beam splitter. The reflective project apparatus according to claim 1, wherein the correction prism is formed integrally with the dichroic beam splitter.