KR20070024280A - Prism fixing structure of an optical engine - Google Patents

Abstract

A prism fixing structure in an optical engine is provided to install a prism on a base in a state in which the prism is adhered to a prism attachment surface when the prism is installed in the prism fixing structure, thereby preventing an air gap occurring at the time of bonding. A prism fixing structure comprises a prism attachment surface(114) attached to a prism(70). The attachment surface(114) has holes(112) for injecting an adhesive agent to adhere the prism(70) to the attachment surface(114). The attachment surface(114) has at least two holes. An opening(118) through which light transmitted from the prism(70) is formed in the prism attachment surface(114). The holes are formed around the prism(70) attached to the attachment surface(114). A prism fixing unit(116) limits movement in a side direction of the prism(70) installed to the attachment surface(114).

Description

 Prismatic fixing structure of an optical engine

1 is an optical system structure of a typical DLP projection television.

2 is a plan view of a prism fixing structure installed in the optical engine according to the present invention.

3 is an enlarged perspective view of a prism fixing part in the prism fixing structure of FIG.

4 is a cross-sectional view of II ′ in a state in which a bond is injected into the adhesive injection groove of FIG. 3.

5 is a cross-sectional view of II ′ in a state in which a prism is coupled after a bond is injected into the adhesive injection groove of FIG. 3.

6 is a cross-sectional view of II-II 'in the state in which the prism is bonded after the bond is injected into the adhesive injection groove of FIG.

7 is a cross-sectional view of the prism coupled to the fixing structure according to the present invention.

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

100: optical engine 101: base surface

110: prism arrangement portion 112: adhesive injection groove

114: prism attachment surface 116: prism fixing portion

118: light passage and opening

The present invention relates to a DLP optical engine, and more particularly, to prevent an air gap generated between a prism and a case when bonding a TIR prism installed in the DLP optical engine to a TIR optical engine case. A prism fixing structure of a DLP optical engine.

In general, a projection television is a device for projecting an image generated by an image generator to a screen at a predetermined magnification with a lens system and a reflection mirror in order to obtain an image screen of 40 inches or more. An apparatus for projecting an image from a projection television is called an optical engine, and such a projection television includes a CRT projection, an LCD projection, and a DPL projection method according to the type of the image generating unit.

Among them, the DLP projection method is a new display method compared to an LCD (LCD) liquid crystal display (LCD) projection system, and a method of realizing high definition image quality by using a light reflecting element. More specifically, this is a technology that expresses high brightness and high resolution images by selectively reflecting light using a device in which hundreds of thousands of reflective elements are integrated on one chip, and a projector, a cathode ray tube (CRT), and a liquid crystal display (LCD) Although it is an extension of the projection screen representation technology that has been developed through the process, it has a characteristic of being reflective compared to the already available LCD projection system.

DLP-type projection television uses a digital device that determines the blocking and opening of light through a circuit board and reflects the light reflected on the surface of a number of fine digital micromirror devices (DMDs). Adjust the degree to implement the image. Therefore, there is no noise or image quality deterioration when converting a digital signal to an analog signal, and different characteristics are not corrected for each device, so that the original picture can be perfectly reproduced.

In addition, the response speed of the device is faster than the LCD and Plasma Display Pannel (PDP) methods, so it can be reproduced more smoothly and steadily in moving images, and the wide viewing angle can accommodate many viewers. It is simple and unaffected, making it easy to adjust and suitable for both front and rear projection applications.

Such an optical engine of the DLP projection television will be described based on FIG. 1. 1 is a conceptual diagram showing a general structure of an optical engine used in a DLP projection television.

Referring to FIG. 1, the optical engine of the DLP projection television includes a lamp 10 for generating light, an ultraviolet cut filter 20 for blocking ultraviolet rays from the light generated by the lamp, and the lamp 10. The integrator 30 through which the light generated by the light passes, the color wheel 40 where the white light passing through the integrator 30 is color-divided into RGB, and the light passing through the color wheel 40 are collected. A condensing lens 50, a folding mirror 60 for changing a path of light passing through the condensing lens 50, and a TIR prism 70 in which light passing through the folding mirror 60 is reflected; A DM 80 illuminates the light reflected by the TIR prism 70 on the screen, and a projection lens 90 which enlarges the light reflected by the DM 80.

At this time, the TIR prism is an important component in the optical engine that directly affects the illumination system such as the screen size and focus. Among the factors affecting the optical system, such a TIR prism is dealt with very precisely installed with an installation error of ± 0.05mm or less.

The conventional method of fixing this TIR prism to the TIR engine case has been to bond the prism to the case by injecting a bond between the prism seating surface of the TIR engine base and the prism.

However, the bond injected between the prism seating surface and the prism forms an air gap between the prism seating surface and the prism while the bond is hardened. Such an air layer has a problem of causing a fatal error in the back focal length (BFL) of the optical engine to be precise.

The present invention has been proposed to solve the above problems, and an object of the present invention is to provide a prism fixing structure of a DLP optical engine such that no air layer is generated between the prism and the prism attachment surface attached to the TIR engine case.

The prism fixing structure of the DLP optical engine according to the present invention for achieving the above object includes an attachment surface to which a prism is attached, and the attachment surface includes the attachment surface such that the prism is fixed in contact with the attachment surface. And an adhesive injection groove into which a bond for bonding the prism to the prism is injected.

By such a structure, there is an advantage that no air layer is generated between the prism and the prism attachment surface attached to the prism attachment surface.

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

2 is a plan view of a case part having a prism fixing structure according to the present invention in an optical engine.

The case of the optical engine 100 is formed of a base surface 101 to which the prism 70 is fixed and a side wall 102 surrounding the base surface 101 in all directions. One side of the side wall 102 is formed with a light inlet opening 104 for introducing the light passing through the condensing lens 50 to the inside. A case coupling hole 103 is formed at an upper end of the side wall 102 to couple the case part to other parts of the optical engine 100.

In the center of the base surface 101, a prism placement portion 110 in which a prism 70 is disposed is formed. The prism placement unit 110 is a prism attachment surface 114 to which one surface of the prism 70 is attached, and a position of the prism 70 formed around the attachment surface 114 and attached to the attachment surface 114. It is formed to include a prism fixing part 116 for fixing.

Inside the attachment surface 114 is formed a rectangular light passing opening 118 opened to the lower side of the case part l so that the light passing through the prism 70 can be directed to the DMD below the attachment surface. The prism attachment surface 114 to which the prism 70 is attached is formed around the light passing opening 118 so as to surround the light passing opening 118. The prism attachment surface 114 is formed with a plurality of adhesive injection grooves 112 into which an adhesive such as a bond for attaching the prism 70 to the prism attachment surface 114 is injected.

At this time, the case portion of the optical engine 100 shown in FIG. 2 shows only the portion where the prism 70 is installed, and the configuration related to the case portion of the optical engine 100 coupled with other components is the present invention. It does not belong to the scope of the idea of the detailed description thereof will be omitted. In the following different drawings, it will be described in more detail with respect to the prism fixing sphere according to the present invention.

 3 is a perspective view illustrating the prism fixing structure according to the present invention, and is an enlarged view of the prism disposition unit 110 of FIG. 2.

Referring to FIG. 3, a light passing opening 118 having a rectangular shape is formed at the center of the prism placement unit 110 so that light passing through the prism 70 is directed toward the DMD 80 under the base surface 101. Is formed. The prism fixing structure according to the present invention is a structure for fixing the prism 70 on the light passing opening 118, and one surface of the prism 70 fixed by the prism fixing structure according to the present invention is the light passing opening. 118 is configured to cover all of them.

In more detail, a prism attachment surface 114 is formed around the periphery of the light passage opening 118. The prism attachment surface 114 has a substantially constant width around the light passing opening 118 and is formed to surround the light passing opening 118 in a 'c' shape. Preferably, the prism attachment surface 114 is coplanar.

The outer side of the prism attachment surface 114 is formed to form an inclined surface 115 slightly inclined downward from the outer end of the prism attachment surface 114. Preferably, the width of the inclined surface 115 is approximately equal to the width of the prism attachment surface 114. Such an inclined surface 115 will be described in more detail in the following drawings.

Meanwhile, a plurality of adhesive injection grooves 112 having a predetermined depth and substantially circular are formed between the prism attachment surface 114 and the inclined surface 115. The adhesive injection groove 112 is a groove into which an adhesive such as a bond is injected, and is a component adopted in the prism fixing structure according to the present invention in order to couple the prism 70 to the prism attachment surface 114.

The adhesive injection groove is preferably formed at regular intervals along the circumference of the light passing opening 118. In addition, the adhesive injection groove 112 is more preferably formed in a plurality of pairs corresponding to each other in a row on both end sides of the surface on which the prism 70 is installed. The diameter of the adhesive injection groove 112 is preferably smaller than the combined width of the prism attachment surface 114 and the inclined surface 115.

 On the other hand, a prism fixing part 116 formed of a wall having a height higher than the prism attachment surface 114 and having a predetermined width is formed at the outermost circumference of the light passing opening 118.

In detail, the prism fixing part 116 is a component for fixing the prism 70 without moving laterally when the prism 70 is attached to the prism attachment surface 114. It is formed to surround. Accordingly, the prism attachment surface 114 and the inclined surface 115 have a shape surrounded by the prism fixing portion 116. At this time, one surface of the prism fixing part 116 formed on the light inlet opening 104 side is preferably formed to have a height lower than the other three surfaces so as not to block the path of the light flowing into the prism.

On the other hand, when the prism 70 is attached to the prism attachment surface 114, the inner surface of the prism fixing portion 116 is formed to contact the lower end of the side surface of the prism 70. In other words, the distance between the inner surfaces formed by the prism fixing portion 116 is preferably equal to the width of the prism 70.

Fixing the prism 70 to the prism fixing structure configured as described above follows the following procedure. First, an adhesive such as a bond is injected into the adhesive injection groove 112 formed in the prism attachment surface 114 by a predetermined amount. This is accomplished by placing the prism 70 inside the prism fixture 116 and in close contact with the prism attachment surface 114.

In the following, unlike the drawings, according to the prism fixing structure of the present invention, the prism 70 is in close contact with the prism attachment surface 114 without generating an air layer between the prism 70 and the prism attachment surface 114. It will be described in more detail.

4 is a cross-sectional view of a state in which a predetermined amount of bond is injected into the adhesive injection groove 112 according to the present invention. FIG. 5 is a cross-sectional view of the prism 70 attached to the prism attachment surface 114 in a state in which the bond is injected into the adhesive injection groove 112, and FIG. 6 is a cross-sectional view of FIG. 5 viewed in the vertical direction.

Referring to FIG. 4, in order to fix the prism 70 to the prism fixing part according to the present invention, a predetermined amount of bond A is first injected into the plurality of adhesive injection grooves 112. At this time, it is preferable to inject the bond A into the adhesive injection groove 112 so that the amount of the bond A is slightly higher than the height of the prism attachment surface 114. This is to allow the bond (A) to be hardened by burying the lower surface of the prism to be bonded. Therefore, the amount of bond A is injected may vary depending on the depth of the adhesive injection groove. At this time, since the adhesive, such as a bond, is a fluid having a viscosity, it forms a spherical surface without overflow when injected into the adhesive injection groove 112.

In this way, the prism is attached to the prism attachment surface 114 in the state in which the bond A is injected into the adhesive injection groove 112. The prism 70 attached to the prism attachment surface 114 may be positioned by aligning the lower ends of both sides of the prism 70 inside the prism fixing portion 116 having the same width as the prism 70.

As described above, when the prism 70 is pressed downward while the lower ends of both sides of the prism 70 are aligned with the inside of the prism fixing part 116, the bottom surface of the prism 70 comes into close contact with the prism attachment surface 114. . This state is shown in FIG.

Referring to FIG. 5, when the bottom surface of the prism 70 is in close contact with the prism attachment surface 114, an adhesive such as bond A injected into the adhesive injection groove 112 is pressed on the bottom surface of the prism so that the bond is injected into the adhesive. It will be pressed to fill the groove.

As such, the bond filled in the adhesive injection groove becomes hard after a certain time, and thus the hard bond secures the prism 70 to the base portion 101 while the prism 70 and the prism attachment surface 114 are in close contact with each other. Will be. At this time, the amount of the bond injected into the adhesive injection groove 112 is sufficient if the injection is enough to fill the adhesive injection groove 112 slightly when the bond is pressed by the prism 70.

However, when the bond is injected, the amount of bond injected may be so great that the bond overflows the adhesive injection groove 112 when the bond is pressed by the bottom surface of the prism. In contrast, the inclined surface 115 is formed on the side of the prism attachment surface.

Referring to FIG. 6, the inclined surface 115 is formed such that the height of the portion adjacent to the adhesive injection groove 112 is lower than the height of the prism attachment surface 114, and the height is lowered toward the prism fixing portion 116. Is formed. This inclined surface serves as the outlet of the adhesive. That is, when the bond is pressed by the prism, when the adhesive overflows the groove 112, the overflow portion of the bond flows down the inclined surface without penetrating into the prism attachment surface 114. Thus, the height of the bond can be limited to have a height to the underside of the prism.

As such, the inclined surface is formed so that the prism can be completely adhered to the prism attaching surface so that the air layer generated when the conventional prism is fixed to the base of the optical engine is not generated.

7 is a cross-sectional view showing a state where the prism is in close contact with and fixed to the prism attachment surface 114. Finally, the prism is installed in the prism fixing structure according to the present invention.

As described above, the prism 70 is installed in the prism fixing structure according to the present invention, so that the prism 70 is installed on the base surface 101 in close contact with the prism attaching surface 114, and at the time of conventional bonding engagement. Formation of the air layer which has occurred is prevented.

The embodiments described above are intended to describe one embodiment of the present invention, and the scope of the present invention is not limited to the above-described embodiments and may be appropriately modified within the scope of the claims. For example, the shape and structure of each component specifically shown in the embodiment of the present invention can be modified.

As described above, since the prism is installed in the prism fixing structure according to the present invention, the prism is installed in the base in close contact with the prism attaching surface, and the formation of the air layer, which has occurred during the conventional bonding bonding, is prevented.

Claims (6)

The attachment surface to which the prism is attached is included, Prismatic fixing structure of the DLP optical engine has an adhesive injection groove is formed in the attachment surface is injected with the adhesive to bond the attachment surface and the prism so that the prism is fixed in contact with the attachment surface. The method of claim 1, A prism fixing structure having a light passage and an opening through which light passing through the prism passes through the prism attachment surface. The method of claim 1, The adhesive injection groove is a prism fixing structure formed around the inner circumference of the prism attached to the attachment surface. The method of claim 1, An adhesive discharge part is formed on an upper side of the adhesive injection groove, and a prism fixing structure configured to allow the adhesive injected into the adhesive injection groove to flow out toward the adhesive discharge part. The method of claim 1, And a prism fixing portion for limiting lateral movement of the prism installed on the attachment surface. The method of claim 1, At least two adhesive injection grooves formed on the attachment surface.

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