KR100484431B1 - Method for assembling a prizm for a LCD Projector - Google Patents

Abstract

The present invention relates to a liquid crystal projection device, and more particularly, to a device for fixing a prism of a synthetic system, and provides a method for bonding a synthetic system of rice bread that is easy to assemble and does not cause deformation of the prism after assembly. The synthetic system of the present invention provides a prism fixing device and a fixing method capable of irradiating and curing UV light uniformly and quickly through the wall of the prism.

Description

Method for fixing prism of LCD projecting device {Method for assembling a prizm for a LCD Projector}

The proportion of liquid crystal projection TVs and projection apparatuses that implement a large screen using a liquid crystal display device is increasing in the large display implementation display market, surpassing previous projection TVs or projection device products using CRTs. This is due to the advantage that the size of the device can be reduced because the size of the liquid crystal display device itself is advantageous compared to the CRT.

The liquid crystal projection apparatus is configured to implement a screen on a large screen by magnifying and projecting particles of an image formed in the liquid crystal panel through a projection lens, using light generated from a lamp as a light source as a light source. 1 shows a schematic diagram of a simple three-plate liquid crystal projection apparatus. A lamp assembly comprising a lamp 3, a reflector 2, and an arc protector 4, and a light source unit composed of a fan 5 as a cooling device, and several mirrors 6 for projecting and enlarging the light generated from the light source unit. ), A projection optical system, which is an optical system composed of a prism (7), a lens, and the like, and a screen (1) for forming the projected light on a screen.

In the conventional three-plate type liquid crystal projection apparatus, a synthesis system using the prism 7 is configured to synthesize phases of R, G, and B liquid crystals which are color components formed separately. In the synthesis system, an alignment device, a liquid crystal, and a prism for proper alignment of each phase are used, which is collectively called a synthesis system. Each part of the composite system is a complex configuration with a configuration sensitive to alignment tolerances.

Figure 2 shows the rest of the prism configuration except the liquid crystal in the synthesis system. Since the prism 22 must be properly fixed, the synthetic system is provided with a fixing part (23 or less prism base) for fixing the prism 22 to the light tube, the prism 22, and an aligner for aligning the liquid crystal. It consists of upper fixing parts (less than 21 prism towers), respectively.

The prism tower 21 and the prism base 23 should be firmly fixed to each other with the prism 22 interposed therebetween, and the deformation of the prism tower 21 and the prism base 23 should be small. In addition, workability should be good when fixed.

In order to satisfy this requirement, a bonding method is conventionally used to fix a synthetic system. In other words, the ultraviolet curable adhesive is administered to the adhesive surface 24 at the position where the prism 22 is attached to the prism base 23, and irradiated with ultraviolet rays to cure the adhesive.

The prism tower 21 is similarly formed.

The hardenability of the ultraviolet curable adhesive used at this time is a function of the amount of ultraviolet radiation and time. That is, the prism 22 is mechanically fixed to the prism base 23 and the prism top 21, respectively, so that the amount and irradiation time of the ultraviolet curing adhesive must be appropriate to have the desired mechanical properties. If there is an abnormality such as a shadow or the like at the irradiation part, the adhesive of the part is not cured and the fixing part is weakened.

3 is a bonding method of a conventional synthetic system. A representative feature of this method is that it irradiates ultraviolet light through the sides of the prism 31. In order to implement this, the illumination system 32 which controls the ultraviolet rays to irradiate the ultraviolet rays to both the adhesive surface of the prism base or the prism tower 33 is used.

3 is an optical path of ultraviolet light emitted from the illumination system. In this case, the irradiation distance is different because the distance from the light source to the adhesive surface on which the adhesive is formed is different as shown in the figure. Therefore, since the curing rate of the ultraviolet adhesive varies depending on the position, this causes shrinkage in the adhesive, and thus the residual stress is a problem of lowering the adhesive strength and precision. In addition, residual stress causes deformation of the prism during or after assembly, which causes problems in product reliability.

The present invention is to improve the existing prism fixing device and fixing method to provide a stable prism fixing device and method that is easy to assemble and does not cause deformation of the prism during or after assembly.

The present invention is to provide a bonding method for reducing the irradiation distance of the ultraviolet light, the same distance from the ultraviolet light source to each adhesive surface to increase the irradiation dose on the adhesive surface and to make the distribution constant.

The present invention is to provide a fixing method of the prism by the optical fiber in order to solve the above conventional problems.

Hereinafter, an apparatus for fixing the prism of the synthetic system of the present invention will be described in detail with reference to FIG. The prism 42 according to the present invention is fixed by the prism base 43 and the prism top 41. In particular, at least one hole 45 for irradiating ultraviolet rays is formed in the prism tower 41. 44 of the prism base 43 indicates the adhesive surface of the prism.

With this structure, the prism bonding method of the synthetic system of the present invention will be described in detail with reference to FIG.

As shown in Fig. 5A, an ultraviolet curable adhesive is injected into the adhesive surface 56 using the dispenser 50 in the prism tower 51 having the holes 55 formed thereon. Then, as shown in FIG. 5 (b), the prism 52 is placed thereon, and then the optical fiber 57 is fixed to the prism 52 by appropriate means. When the ultraviolet light is irradiated through the fixed optical fiber 57, the prism top 51 is transmitted through the prism from the top of the prism and irradiated to the prism top 51 where the adhesive is formed. Is fixed to.

In the same manner as in the method of attaching the prism 52 to the prism base 53, the prism is applied to the adhesive surface 54 of the prism base 53 using the dispenser 50 as shown in FIG. 5 (c). When the prism 52 to which the top 51 is attached is placed, and the optical fiber 57 is fixed through the hole 55 formed in the prism top 51, and then irradiated with ultraviolet rays, the ultraviolet rays passed through the prism The adhesive formed on the prism base 53 is cured to fix the prism stably.

According to the present invention, since ultraviolet rays are directly irradiated from the upper and lower surfaces of the prism without using the wall surface of the prism, the distance from the light source to the adhesive becomes constant and close, so that the curing speed is about 30% when the longitudinal length of the prism is 47 mm. Can be improved. In addition, the amount of ultraviolet rays per unit area incident on the adhesive surface can be increased by five times or more, and the slope of the power distribution of the ultraviolet rays incident on the adhesive surface is greatly reduced, so that the bonding surface has a uniform property.

Therefore, it is possible to significantly improve the work speed of hardening and at the same time significantly lower the stress level due to shrinkage occurring during or after curing, thereby greatly improving the reliability of the product.

1 is a structural diagram of an optical system of a three-plate liquid crystal projection apparatus

Figure 2 is a conventional prism fixing device

3 is a conventional prism fixing method

Figure 4 is a prism fixing device according to the present invention

Figure 5 is a fixing method of the prism according to the present invention

21,41, 51: Prism Tower 22, 42, 52: Prism

23,43,53: Prism Base 45,55: Hole

24, 44, 54, 56: Prism bonding position 50: dispenser 57: optical fiber

Claims (4)

A method of fixing a prism of a synthetic system of a liquid crystal projection device to a prism fixing device, comprising: forming an ultraviolet curable adhesive between the prism and the prism fixing device, and curing the ultraviolet curable adhesive by an optical fiber. Prism fixing method of liquid crystal projection device The prism fixing method of claim 1, wherein the prism fixing device comprises a first prism fixing part and a second prism fixing part respectively formed on opposite surfaces of the prism. The method of fixing the prism and the first prism fixing part of claim 1 comprises fixing an optical fiber to the prism, and then irradiating ultraviolet rays through the optical fiber to pass through the prism and formed between the prism and the first prism fixing device. Prismatic fixing method of the liquid crystal projection device characterized in that to cure the adhesive The method of fixing the first prism fixing device, the prism, and the second prism fixing part of claim 3 fixes the optical fiber through a hole formed to penetrate the first prism fixing device, and then irradiates ultraviolet rays through the optical fiber. To pass through the prism to cure the adhesive formed between the prism and the second prism fixing device, characterized in that the prism fixing method of the liquid crystal projection device