KR100219640B1 - Lcd projector - Google Patents

Abstract

First and second dichroic filters disposed to transmit the light emitted from the light source according to the wavelength region and to transmit the light or to change the light at a predetermined angle; First and second liquid crystal display elements disposed on paths of light for each wavelength region reflected by the first and second dichroic filters, respectively, and arranged to reflect and change light in each wavelength region by a predetermined angle path; A third liquid crystal display device disposed on a path of the wavelength region light that has passed through the first and second dichroic filters and disposed to reflect the light of the wavelength region by changing a predetermined angle path; The light of the wavelength region reflected by the first liquid crystal display device and provided on the path of the wavelength region light reflected by each of the first and second liquid crystal display elements is changed by reflecting the light of the wavelength region by a predetermined angle path. Third and fourth dichroic filters disposed side by side on the same optical path to transmit; Disclosed is a reflective liquid crystal project apparatus comprising a projection lens through which light for each wavelength region transmitted and reflected by the third liquid crystal display device and the third and fourth dichroic filters is transmitted.

Description

Reflective Liquid Crystal Project Device

The present invention relates to a project device using a liquid crystal display device, and more particularly, to a reflective liquid crystal projection device using three reflective liquid crystal display devices.

The project device is an image projection system that generates an image by means of image generating means such as a small cathode ray tube (CRT) or a liquid crystal display device (LCD), which is specially manufactured, and then magnifies the image through a projection lens and projects it on a large screen. In recent years, the demand is increasing due to the advantage of obtaining a large screen that can satisfy the needs of consumers. Such a project apparatus is classified into a transmissive type and a reflective type according to the shape of the image generating means. FIG. 1 schematically illustrates an optical arrangement of a conventional reflective liquid crystal project apparatus. Referring to FIG. 1, a conventional reflective liquid crystal projection apparatus includes a light source 10 having a lamp 10a and a reflector 10b to generate light and project light in one direction, and a path of light emitted from the light source 10. A polarizing beam splitter (PBS) 20 is disposed on the light beam to transmit and reflect incident light according to a polarization component to convert a light traveling path, and a first mirror surface on the light exit surface side of the polarizing beam splitter 20. A dichroic prism 30 having a 31 and a second mirror surface 32 is disposed adjacent to each other to transmit and reflect incident light according to the wavelength. The first liquid crystal display element 41, the second liquid crystal display element 42, and the third liquid crystal display element 43 are disposed adjacent to each other on the light exit surface of the dichroic prism 30. By reflecting the light of each wavelength region emitted from the Ik prism 30 so that the light routed by the dichroic prism 30 is projected on the screen (not shown) through the projection lens 50 to display an image Consists of.

In the conventional reflective liquid crystal projector device having the above configuration, it is difficult to precisely manufacture the polarizing beam splitter 20 for transmitting and reflecting the incident light according to the polarization component, thus making it difficult to secure performance and mass productivity. . In addition, since the dichroic prism 30 for transmitting and reflecting the incident light according to the wavelength has to be processed and bonded by four prisms as shown, manufacturing cost increases.

The technical problem to be achieved by the present invention is to improve the problems of the conventional reflective liquid crystal project device as described above, the solution for achieving the technical problem is to separate the incident light by a dichroic filter to transmit and By reflecting, the performance and mass productivity of the reflective liquid crystal project apparatus are ensured and the manufacturing cost is reduced. Accordingly, an object of the present invention is to provide a reflective liquid crystal project apparatus which can be easily produced at low cost by achieving the above technical problem.

1 is a schematic view showing an optical arrangement of a conventional reflective liquid crystal projector device,

2 is a schematic view showing an optical arrangement of the reflective liquid crystal projector according to the present invention.

Explanation of symbols for the main parts of the drawings

100.Light 110.Lamp

120 ... 210 reflectors ... 1 dichroic filter

220 second dichroic filter 230 third dichroic filter

240 fourth dichroic filter 310 first liquid crystal display element

320 ... second liquid crystal display element 330 ... third liquid crystal display element

400 ... projection lens

In order to achieve the above object, a reflective liquid crystal project device according to the present invention comprises: a light source configured to generate light and project in one direction; A first dichroic filter and a second dichroic filter disposed side by side on a path of light emitted from the light source and arranged to separate incident light according to a wavelength region, and to change the path by a predetermined angle and reflect the incident light; The first liquid crystal display device and the second liquid crystal provided on the path of the light for each wavelength region reflected by the first dichroic filter and the second dichroic filter, respectively, so as to reflect the light for each wavelength region by changing a predetermined angle path. A display element; A third liquid crystal display device disposed on a path of light for each wavelength region that has passed through the first dichroic filter and the second dichroic filter and disposed so as to reflect the light of the wavelength region by changing a predetermined angle path; A wavelength region which is provided on the path of the wavelength region light reflected by the first liquid crystal display element and the second liquid crystal display element, respectively, by changing a predetermined angle path of the wavelength region and reflecting the same; A third dichroic filter and a fourth dichroic filter disposed side by side on the same optical path so as to transmit light; And a projection lens through which light for each wavelength region transmitted and reflected by the third liquid crystal display device, the third dichroic filter, and the fourth dichroic filter is transmitted.

In the reflective liquid crystal project device according to the present invention, in particular, the first liquid crystal display element, the second liquid crystal display element, and the third liquid crystal display element are disposed in parallel with each other between the light source and the projection lens, A dichroic filter and a fourth dichroic filter are disposed in parallel with the second liquid crystal display device, and the second dichroic filter and the third dichroic filter are arranged with the second liquid crystal display device and the third liquid crystal display. It is preferable that the display elements are arranged in parallel with each other.

Hereinafter, a reflective liquid crystal projector apparatus according to a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings.

Referring to FIG. 2, the reflective liquid crystal project apparatus according to the present invention is provided side by side on the light source 100 and the path of the light emitted from the light source 100 to generate light and project it in one direction. The first dichroic filter 210 and the second dichroic filter 220, and the first dichroic filter 210 and the second dike, which are arranged to be separated to transmit and change the path at a predetermined angle, and are reflected. The first liquid crystal display device 310 and the second liquid crystal display device 320, which are provided on the paths of the wavelength region light respectively reflected by the roic filter 220, are arranged to reflect the light of each wavelength region by changing a predetermined angle path. And a third provided on the path of the light in the wavelength region that has passed through the first dichroic filter 210 and the second dichroic filter 220 and arranged to change and reflect the light in the wavelength region by a predetermined angle path. Liquid crystal display device 330 and the first liquid crystal It is provided on the path of the wavelength region light reflected by the viewing element 310 and the second liquid crystal display element 320, respectively, and the light of the wavelength region is changed by a predetermined angle path and reflected on the third liquid crystal display element 330. The third dichroic filter 230 and the fourth dichroic filter 240 disposed side by side on the same optical path so as to transmit the light in the wavelength region reflected by the light, and the third liquid crystal display device 330 And the projection lens 400 through which the light of the wavelength region reflected and transmitted by the third dichroic filter 230 and the fourth dichroic filter 240 is transmitted.

In the above configuration, the light source 100 includes a lamp 110 for generating light and a reflector 120 for reflecting the light emitted from the lamp 110 to guide the traveling path in one direction. The reflector 120 may be an ellipsoid having a different focus at a point where light is focused with the position of the lamp 110 as one focal point, or the lamp 110 with the position of the lamp 110 as one focal point. A parabolic mirror that reflects light emitted from the light beam and becomes parallel light can be used.

The first liquid crystal display device 310, the second liquid crystal display device 320, and the third liquid crystal display device 330 are disposed in parallel with each other between the light source 100 and the projection lens 400. In addition, the first dichroic filter 210 and the fourth dichroic filter 240 are disposed in parallel with the second liquid crystal display device 320. In addition, the second dichroic filter 220 and the third dichroic filter 230 may be disposed in parallel with each other to be positioned between the second liquid crystal display device 320 and the third liquid crystal display device 330. do. That is, the overall optical arrangement except for the light source 100 and the projection lens 400 is preferably arranged in a rhombus or diamond shape, and the optical arrangement is in the form of an entire optical path according to the size of the light source and the liquid crystal display. Can be arranged to be changed as appropriate.

The first dichroic filter 210 reflects, for example, red (R) light and transmits light of a different wavelength range according to the wavelength region of the incident light, and the second dichroic filter 220 is green. (G) Reflects light and transmits light in other wavelength ranges. In addition, the third dichroic filter 230 and the fourth dichroic filter 240 transmit, for example, blue (B) light and reflect light of another wavelength range.

The first liquid crystal display device 310, the second liquid crystal display device 320, and the third liquid crystal display device 310 are configured to rotate and reflect the polarization direction of incident light by a signal applied to each pixel. The light of the wavelength region reflected or transmitted by the first dichroic filter 210 and the second dichroic filter 220 is disposed to correspond to the incident and reflected light at a predetermined angle.

Looking at the operation of the reflective liquid crystal project device according to the present invention having the above configuration as follows.

Light emitted from the light source 100 is reflected by the wavelength region, for example, red (R) light is reflected by the first dichroic filter 210 is incident on the first liquid crystal display device 310 at a constant angle of incidence do. In addition, light of a different wavelength range passes through the first dichroic filter 210, and for example, green (R) light is reflected by the second dichroic filter 220 and the second liquid crystal has a constant incident angle. While incident on the display element 310, blue (B) light passes through the second dichroic filter 220 and is incident on the second liquid crystal display element 310 at a predetermined incident angle.

Light for each wavelength region incident on the first liquid crystal display device 310 and the second liquid crystal display device 320 is constant by the third dichroic filter 230 and the fourth dichroic filter 240, respectively. At the same time, the wavelength range light incident on the third liquid crystal display device 330 is transmitted through the third dichroic filter 230 and the fourth dichroic filter 240. As a result, each wavelength of light reflected and transmitted by the third dichroic filter 230 and the fourth dichroic filter 240 is projected on a screen (not shown) through the projection lens 400 to display an image. Is displayed.

As described above, the reflective liquid crystal project device according to the present invention is configured to transmit and reflect the light emitted from the light source for each wavelength region by a dichroic filter, thereby ensuring performance and mass production while simultaneously manufacturing cost. Can be reduced. Therefore, according to the present invention, it is possible to provide a reflective liquid crystal project device that can be easily produced at low cost.

Claims (4)

A light source configured to generate light and project it in one direction; A first dichroic filter and a second dichroic filter disposed side by side on a path of light emitted from the light source and arranged to separate incident light according to a wavelength region, and to change the path by a predetermined angle and reflect the incident light; A first liquid crystal display device and a second liquid crystal disposed on a path of light for each wavelength region reflected by the first dichroic filter and the second dichroic filter, respectively, and arranged to reflect the light of each wavelength region by changing a predetermined angle path; A display element; A third liquid crystal display device disposed on a path of light for each wavelength region that has passed through the first dichroic filter and the second dichroic filter and disposed so as to reflect the light of the wavelength region by changing a predetermined angle path; A wavelength provided on the path of light for each wavelength region reflected by the first liquid crystal display device and the second liquid crystal display device, respectively, by changing a predetermined angle path to reflect the light in the wavelength region and reflecting the light reflected by the third liquid crystal display device; A third dichroic filter and a fourth dichroic filter disposed side by side on the same optical path to transmit light in the region; And And a projection lens through which light for each wavelength region transmitted and reflected by the third liquid crystal display device, the third dichroic filter, and the fourth dichroic filter is transmitted. . The method of claim 1, And the first liquid crystal display element, the second liquid crystal display element, and the third liquid crystal display element are arranged in parallel with each other between the light source and the projection lens. The method of claim 1, And the first dichroic filter and the fourth dichroic filter are arranged in parallel with the second liquid crystal display device. The method of claim 1, And the second dichroic filter and the third dichroic filter are disposed in parallel with each other between the second liquid crystal display element and the third liquid crystal display element.

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