KR100283762B1 - Jig for making optical prism and method for making optical prism by using jig - Google Patents

Abstract

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an optical prism for synthesizing RGB light separated by color separation means in a liquid crystal projector optical system. More specifically, a jig for manufacturing an optical prism that can improve productivity by manufacturing an optical prism in a good yield. And an optical prism manufacturing method using a jig.

According to an aspect of the present invention, there is provided a method of manufacturing an optical prism, comprising: manufacturing a first adhesive prism by bonding respective B reflection surfaces to each other in a state where the first and second triangular prisms are placed on a mounting groove of a jig; Manufacturing a second adhesive prism by bonding the respective B reflection surfaces to each other with the third and fourth triangular prisms mounted on the mounting grooves of the jig; While the first adhesive prism is positioned so that the R reflective surface of the first adhesive prism is in contact with the R reflective surface of the second adhesive prism, the B reflective surfaces of the first and second adhesive prisms are formed using an auto collimator. And bonding the first and second adhesive prisms after matching, thereby facilitating the process of adhering two triangular prisms to form an adhesive prism and the process of adhering two adhesive prisms to form an optical prism. It is possible to improve the yield and productivity of the product.

Description

Jig for manufacturing optical prism and method for manufacturing optical prism using jig {JIG FOR MAKING OPTICAL PRISM AND METHOD FOR MAKING OPTICAL PRISM BY USING JIG}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an optical prism for synthesizing RGB light separated by color separation means in a liquid crystal projector optical system. More specifically, a jig for manufacturing an optical prism that can improve productivity by manufacturing an optical prism in a good yield. And an optical prism manufacturing method using a jig.

Today, with the development of the information industry, the demand for image display means having a larger screen has been increasing. However, the conventional direct view cathode ray tube, which is a conventional image display means, has to manufacture the cathode ray tube itself in large size in order to enlarge the screen. Due to various realistic constraints, there was a limit to the degree of enlargement.

In addition, even if it is possible to produce a large-sized cathode ray tube to some extent by overcoming the technical difficulties described above, another increase in the production of a television set having a large cathode ray tube on the screen due to the increase in the load of the cathode ray tube Due to technical difficulties due to constraints and the like, there was no limit to the production of a television having a large cathode ray tube as a screen.

Under such a background, an image projection system such as a projection television or a video projector has been developed and put into practical use to overcome the difficulties of various technical factors and obtain a larger screen.

Such an image projection system generates an image using image display means such as a specially made small cathode ray tube (CRT) or a liquid crystal display element (hereinafter referred to as LCD), and enlarges the image through an optical lens to enlarge a large screen. As a system of projecting on a projector, a projector using an LCD (hereinafter referred to as a liquid crystal projector) has a very simple optical structure and can be made lighter and shorter than a CRT projector. It is widely used as a display device for HDTV) and video conference.

Liquid crystal panels used in liquid crystal projectors are commonly known as matrix type liquid crystal plates, in which pixels are arranged in a matrix in two directions perpendicular to each other, and are driven individually by a driving voltage. Change the optical properties.

The driving voltage can be applied to the individual pixels by a simple matrix system, and a non-linear two-terminal element such as a metal insulating metal (MIM) or a three-terminal switching element such as a TFT (thin film transistor) is disposed for each pixel. It can be applied to each pixel alternately by an active matrix system.

The optical system of the liquid crystal projector described above will be described with reference to FIG. 1.

As shown, the optical system is a lamp 102 for emitting light and its transmittance is changed in accordance with the applied image signal to transmit or block the red light (R), green light (G), blue light (B). First to third liquid crystal plates 110a, 110b and 110c, first and second dichroic filters 106a and 106b for selectively passing light by wavelength, and first to third reflection mirrors 108a and 108b. 108c), the first to third field lenses 112a, 112b and 112c, the first and second condenser lenses 114a and 114b, and the optical prism 120.

The optical prism 120 reflects the red light (R) and the blue light (B) incident on three surfaces perpendicular to each other and transmits the green light (G) as it is, thereby synthesizing the three color light beams to form the projection lens 118. The optical prism 120 is provided with two reflecting surfaces (R reflecting surface and B reflecting surface) for reflecting red light and blue light.

Accordingly, the white light emitted from the halogen metal lamp 102 is irradiated to the first dichroic filter 106a, and among the white light, the green light G and the blue light B pass through the first dichroic filter 106a. On the other hand, the red light R is reflected by the first dichroic filter 106a, and the reflected red light is reflected by the first mirror 108a to pass through the first field lens 112a to the first liquid crystal plate 110a. ) Is incident.

The red light incident on the first liquid crystal plate 110a passes through the first liquid crystal plate 110a and enters the optical prism 120 as the transmittance of the first liquid crystal plate 110a changes. Reflected from the reflecting surface is to enter the projection lens 118.

On the other hand, the green light (G) and blue light (B) transmitted by the first dichroic filter (106a) is irradiated to the second dichroic filter (106b), the green light of the light is the second dichroic filter While reflected by the 106b, blue light is transmitted, and the green light transmitted through the second dichroic filter 106b is incident on the second liquid crystal plate 110b through the second field lens 112b, and then the second light is transmitted. As the transmittance of the liquid crystal plate 110b changes, the liquid crystal plate 110b passes through the second liquid crystal plate 110b.

Subsequently, the green light passing through the second liquid crystal plate 110b passes through the optical prism 120 as it is and enters the projection lens 118.

The blue light transmitted through the second dichroic filter 106b passes through the first condenser lens 114a and then is reflected by the second reflecting mirror 108b to be incident on the second condenser lens 114b. The blue light passing through the two condenser lenses 114b is reflected by the third reflection mirror 108c and is incident on the third liquid crystal plate 110c through the third field lens 112c and enters the third liquid crystal plate 110c. The incident blue light passes through the third liquid crystal plate 110c and enters the optical prism 120 as the transmittance of the third liquid crystal plate changes, and is then reflected by the B reflection surface in the optical prism 120 to reflect the projection lens 118. To enter.

In this way, the optical prism 120 combines three rays, ie red, green and blue rays, and the projection lens 118 projects the synthesized rays L on a screen, not shown.

A jig for manufacturing an optical prism having the above function and a method of manufacturing an optical prism using the jig will be described with reference to FIGS. 2 and 3.

2 is a flowchart illustrating a process of manufacturing an optical prism using a jig according to the related art.

The optical prism 120 includes first to fourth triangular prisms 120a, 120b, and 120c each having an R reflecting surface for red light R, a B reflecting surface for blue light B, and a light incident / emitting surface, respectively. 120d), one prism of the triangular prisms may be made of a special prism for refracting light at a predetermined angle.

When manufacturing the optical prism 120 using the jig 200 according to the prior art, first, the first and second triangular prism (120a, 120b) on the upper surface 210 of the jig 200 is placed (FIG. 2A) Each B reflective surface is bonded to each other to prepare a first adhesive prism (FIG. 2B), and then a second adhesive prism is produced by using the third and fourth triangular prisms in the same manner as above.

After the first and second adhesive prisms are manufactured as described above, the adhesive prisms are erected to the microscope, and in this state, the B reflecting surface of the first adhesive prism and the B reflecting surface of the second adhesive prism are aligned through the microscope. While visually observing, the R reflecting surfaces of each prism are bonded to each other to prepare an optical prism 120 (FIG. 2C).

In the manufacturing process of the above optical prism, an epoxy resin is used normally as an adhesive agent.

By the way, according to the conventional manufacturing method and apparatus as described above, since the work of matching the B reflecting surfaces of each prism at the time of bonding the first adhesive prism and the second adhesive prism has been performed by visual observation through a microscope, It was difficult to exactly match the B reflecting surface of the adhesive prism, which caused problems such as lowering productivity and increasing defective rate.

The present invention has been made to solve the above problems, and an object of the present invention is to provide a jig for manufacturing an optical prism capable of improving productivity by producing an optical prism in a good yield.

Another object of the present invention is to provide an optical prism manufacturing method using the jig.

1 is a view schematically showing the configuration of a liquid crystal projector optical system using LCD among a general image projection system.

2 is a process flow diagram at the time of manufacturing the optical prism using a jig according to the prior art.

Figure 3 is a process flow diagram at the time of manufacturing the optical prism using the jig for manufacturing the optical prism according to the present invention.

<Explanation of symbols for main parts of the drawings>

120: optical prism 300: jig

320: Wit Home 400: Auto Collimator

In the jig for manufacturing an optical prism according to the present invention for achieving the above object, the first to fourth having the R reflection surface for the red light (R), the B reflection surface for the blue light (B) and the light incident / exit surface, respectively 'V' shape so that each light incidence / emission surface can maintain a predetermined angle with respect to the top surface of the jig when two triangular prisms are mounted at the same time to bond the R reflecting surface or the B reflecting surface among Characterized in that the mounting groove is provided.

According to a preferred aspect of the present invention, in the method of manufacturing an optical prism using the jig, each of the B reflecting surfaces is bonded to each other in a state where the first and second triangular prisms are placed on the mounting groove of the jig to form a first adhesive prism. Manufacturing step; Manufacturing a second adhesive prism by bonding the respective B reflection surfaces to each other with the third and fourth triangular prisms mounted on the mounting grooves of the jig; While the first adhesive prism is positioned so that the R reflective surface of the first adhesive prism is in contact with the R reflective surface of the second adhesive prism, the B reflective surfaces of the first and second adhesive prisms are formed using an auto collimator. And adhering the first and second adhesive prisms after matching.

Hereinafter, an optical prism manufacturing jig and a method of manufacturing an optical prism using the jig according to a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings.

3 is a flowchart illustrating a process of manufacturing an optical prism using a jig according to the present invention.

As shown, in the optical prism manufacturing jig 300 according to the present invention, when two triangular prisms are mounted at the same time to bond the R reflecting surface or the B reflecting surface, each light incident / emitting surface has a jig 300. A 'V' shaped mounting groove 320 is provided to maintain a predetermined angle with respect to the upper surface 310 of the jig 300, and the jig 300 is formed of an optical material having the same material as that of the prism.

Here, the jig 300 is formed of an optical material to increase the convenience of use by not limiting the position of the auto collimator, which will be described later.

When manufacturing the optical prism using the jig formed as described above, the first and second triangular prism 120a, 120b is first placed on the mounting groove 320 of the jig 300, and the respective B reflection surfaces are bonded to each other. To prepare a first adhesive prism (FIGS. 3A and 3B), remove the first adhesive prism from the mounting groove 320, and then manufacture the second adhesive prism using the third and fourth triangular prisms in the same manner as described above. do.

Thereafter, the B reflective surfaces of the first and second adhesive prisms are formed using the auto collimator 400 while the first adhesive prism is positioned so that the R reflective surface of the first adhesive prism is in contact with the R reflective surface of the second adhesive prism. After matching, the first and second adhesive prisms are adhered to prepare an optical prism (FIG. 3C).

As described above, the auto collimator 400 is a device for easily matching the reflective surfaces of the optical prism, and when the B reflective surfaces of the first and second adhesive prisms do not coincide with each other, the optical prism ( While the light reflected by 120 is displayed as two points, when the B reflection surfaces of the first and second adhesive prisms coincide with each other, the light reflected by the optical prism 120 is displayed by one point. have.

In addition, since the jig is formed of an optical material, the auto collimator can be used at a user-friendly position.

According to the jig and the manufacturing method according to the present invention, the yield of the optical prism can be improved by about 30% compared to the conventional.

The present invention is not limited to the above embodiments, but may be modified and changed by those skilled in the art within the spirit and scope of the appended claims.

As described above, according to the present invention, a process of forming an adhesive prism by adhering two triangular prisms and a process of forming an optical prism by adhering two adhesive prisms can be easily performed. And productivity can be improved.

Claims (2)

The first to fourth triangular prisms having the R reflecting surface for the red light R, the B reflecting surface for the blue light B, and the light incidence / emission surface, respectively, may be mutually bonded to the reflecting surfaces for the light of the same color. In the jig for manufacturing an optical prism, The jig has a 'V' shape so that each light incidence / emission surface can maintain a predetermined angle with respect to the top surface of the jig when two triangular prisms are simultaneously mounted to adhere the R reflecting surface or the B reflecting surface. Jig for manufacturing an optical prism, characterized in that the mounting groove is provided. The first to fourth triangular prisms having the R reflecting surface for the red light R, the B reflecting surface for the blue light B, and the light incidence / emission surface, respectively, are bonded to each other by mutually bonding the reflecting surfaces for the light of the same color. In the method for manufacturing an optical prism, Bonding each of the B reflecting surfaces to each other in a state in which the first and second triangular prisms are placed on the mounting groove of the jig, thereby manufacturing a first adhesive prism; Manufacturing a second adhesive prism by bonding the respective B reflection surfaces to each other with the third and fourth triangular prisms mounted on the mounting grooves of the jig; While the first adhesive prism is positioned so that the R reflective surface of the first adhesive prism is in contact with the R reflective surface of the second adhesive prism, the B reflective surfaces of the first and second adhesive prisms are formed using an auto collimator. Matching and then bonding them; Method for producing an optical prism comprising a.