KR20070117864A - Lenz assembly for optical engine - Google Patents

Abstract

A lens assembly for an optical engine is provided to install a lens to a lens mount stably by installing an elastic fastening member between the lens mount and a lens. A lens assembly for an optical engine comprises an optical engine case(110), a lens(130), a lens mount(120), and a fastening member(140). Various components are mounted in the optical engine case. The lens refracts light. The lens mount is attached to the optical engine case and the lens is inserted in the lens mount. The fastening member fixes the lens to the lens mount. The fastening member is elastic and disposed between the lens and the lens mount.

Description

Lens assembly for optical engines

1 is a block diagram of a projection image display device according to the prior art;

FIG. 2 is an exploded perspective view illustrating the lens assembly for the optical engine in FIG. 1; FIG.

3 is a perspective view showing a lens assembly for an optical engine according to the present invention;

4 is a perspective view showing a state in which an optical engine lens is inserted according to the present invention;

5A is a perspective view of the fixing member of FIG. 3;

Figure 5b is a side view showing the fixing member of FIG.

Figure 5c is a front view showing the fixing member of FIG.

<Description of Signs of Major Parts of Drawings>

110: optical engine case 120: lens insert

130: lens 140: fixing member

142: upper portion 144: side portion

146: lower part 148: post-war government

150: handle portion

The present invention relates to an image display device, and more particularly, to improve the structure so that the lens for the optical engine can be more stably fixed.

In general, a projection type image display apparatus among image display apparatuses is an apparatus that enlarges and projects an image using a projection optical system, and includes an LCD projector, a CRT projector, and a DLP projector.

In particular, the LCD projector has a single-plate type consisting of one LCD with red, green, and blue color filters, and white light emitted from the lamp, which is a light source, is separated into red, green, and blue through a dichroic mirror, and then It is re-synthesized by a dichroic prism through the arranged mono LCD, and divided into a three-plate type in which a projection lens projects onto the screen.

Referring to Fig. 1, the overall configuration of a three-panel LCD projector will be described.

The beam emitted from the light source 1 is reflected by the parabolic mirror 2 to become parallel light, and is directed to the ultraviolet and infrared cut filter 3. At this time, the ultraviolet light, infrared cut filter 3 serves to transmit only visible light.

On the other hand, visible light passing through the ultraviolet and infrared filters 3 passes through the first fly's eye lens 4 and the second fly's eye lens 5, and the beams are incident by the fly's eye lenses 4 and 5. This distribution is even.

The evenly distributed beam passing through the fly's eye lenses 4 and 5 is polarized while passing through the flat polarizer 6.

In addition, the beam polarized while passing through the planar polarizer 6 is focused while passing through the first condenser lens 7 and proceeds to the first reflector 8, and the optical path is changed by the first reflector 8. It is directed to the second condensing lens 9, and is condensed once again while passing through the second condensing lens 9. In this case, the first and second condensing lenses 7 and 9 serve to increase the beam utilization efficiency of the entire optical system.

On the other hand, the beam passing through the second condenser lens 8 passes through the first dichroic mirror 10, and the first dichroic mirror 10 transmits only the beam in the blue region. Subsequently, the beam of the blue region passing through the first dichroic mirror 10 changes the optical path by the second reflector 12 and enters the blue polarization separator 17 through the polarizer 14. In this case, the polarizer 14 serves to filter out beam components that are not polarized while passing through the plate-type polarizer 6, and the blue polarizer 17 is applied to the polarization state of the incident beam. Accordingly, as a means for reflecting or transmitting the beam, the incident beam has a function of transmitting when the polarization state is P wave and reflecting when S wave.

Therefore, among the beams incident on the blue polarization separator 17, a beam whose S polarization state is S is reflected on the oblique plane of the blue polarization separator 17 and is incident on the blue reflective LCD 20, and the incident beam is the blue light. The polarization state is controlled according to the image electric signal applied to the reflective LCD 20.

That is, when voltage is applied to the blue reflective LCD 20, the beam having the polarization state of S wave is converted into the P wave, and the beam converted into the P wave is incident again to the blue polarization separator 17. At this time, the blue polarization separator 17 transmits a P-wave beam, and thus, the beam transmitted through the blue polarization separator 17 is incident to the dichroic prism 22.

On the other hand, of the beams irradiated from the light source along the optical path configured by the existing optical system, the green and red beams reflected by the first dichroic mirror 10 enter the second dichroic mirror 11. The second dichroic mirror 11 reflects the beam of the green region and transmits the beam of the red region.

Thereafter, the beam of the green region and the beam of the red region separated by the second dichroic mirror 11 are incident on the dichroic prism controlled according to the same process as controlling the beam of the blue region. That is, the beam of the green region reflected by the second dichroic mirror 11 passes through the polarizer 13, the green polarization separator 16, and the green reflective LCD 19, and the dichroic prism 22. The beam of the red region incident to the second dichroic mirror 11 and transmitted through the dichroic prism 22 passes through the polarizer 15, the red polarization separator 18, and the red reflective LCD 21. Incident).

On the other hand, the beam of the green area incident on the dichroic prism 22 passes through the dichroic prism as it is and enters the projection lens 23, and the beams of the blue and red areas are reflected to reflect the projection lens 23. Incident).

However, the blue, green, and red beams emitted through the projection lens 23 are projected on a screen (not shown) according to the above-described process.

The LCDs 19, 20, and 21 may each be made of LCoS in which lower glass is replaced with a silicon wafer and a circuit is formed thereon.

Next, the installation structure of the lens used in the optical engine will be described with reference to FIG.

The lens used in the conventional optical engine is composed of an optical engine case 110, the lens insertion unit 120, the lens 130.

The lens insertion unit 120 is formed to protrude from the optical engine case 110, the middle portion has a shape corresponding to the outer peripheral surface of the lens 130, the groove is inserted into the lens 130 is provided. .

However, the conventional optical engine has a structure in which the lens 130 is simply inserted into the lens insertion unit 120 of the optical engine case 110 when the lens 130 is inserted, and thus cannot secure a stable fixing of the lens 130.

That is, the position of the lens 130 may be inserted in a wrong position depending on the ejection state of the optical engine case 110, and the lens may be separated by the distance between the lens 130 and the lens insertion unit 120. 130) can not be prevented from shaking. If the lens 130 is inserted in such a state, there is a problem that the optical performance is significantly lowered even in a small impact.

In order to solve the above problems, the object of the present invention is to improve the optical performance by improving the structure of the lens assembly for an optical engine and stably fixing the lens to the lens insert.

In order to achieve the above object, the present invention provides an optical engine case, various lenses are installed, a lens for refracting light, a lens insertion hole provided in the optical engine case is inserted into the lens, and the lens insertion unit It provides a lens assembly for an optical engine comprising a fixing member fixed to.

Preferably, the fixing member uses a material having elasticity. And the fixing member is preferably provided between the lens and the lens insert.

Furthermore, the fixing member preferably includes an upper portion for fixing the lens from the top down and a side portion for fixing the lens from the side.

In addition, the fixing member may further include a handle portion for fixing at least one of the front or rear surface of the lens as a reference surface.

The configuration and operation of the embodiments of the present invention will be described in detail with reference to the accompanying drawings.

For reference, prior to describing the configuration of the embodiment of the present invention, in order to avoid duplication of description of the prior art reference to the same reference numerals will be referred to.

3 and 4, the basic configuration of the lens assembly for an optical engine according to the present invention will be described.

The lens assembly for an optical engine according to the present embodiment includes an optical engine case 110, a lens 130, a lens insertion unit 120, and a fixing member 140.

The optical engine case 110 serves to install various components constituting the optical engine.

The optical engine case 110 is usually manufactured by injection molding integrally with the lens insert 120.

The lens insertion unit 120 is provided inside the optical engine case 110 and includes a protrusion 124 and an insertion groove 122.

Since the insertion groove 122 is a portion into which the lens 130 is inserted, the insertion groove 122 is preferably provided in a shape corresponding to the outer surface of the lens 130.

In the present embodiment, since the lens 130 is circular, the insertion groove 122 is provided in a circular shape.

Since the lens 130 is easily inserted into the insertion groove 122 and is to be inserted into the insertion groove 122 to be fixed, the thickness of the insertion groove 122 is the thickness of the lens 130 It is preferred to be made slightly larger than the thickness.

The protrusion 124 is preferably manufactured in the same shape as the insertion groove 122 so that the light does not block the portion passing through the lens 130.

The lens 130 serves to refract light. Specifically, in the optical engine, the lens 130 serves to evenly distribute the incident light or to condense the light to increase the light utilization efficiency of the entire optical system.

The fixing member 140 complements the fixed state of the incomplete lens 130.

Referring to Figure 5a, 5b, 5c the configuration of the fixing member 140 is as follows.

In the present embodiment, the fixing member 140 is provided between the lens 130 and the lens insertion unit 120.

The fixing member 140 may be provided at one side of the lens 130 or may be provided at both sides.

Since the lens 130 and the lens insertion unit 120 have a slight gap, the lens 130 may be shaken when the optical engine is driven. At this time, the fixing member 140 is inserted in the gap between the lens 130 and the lens insert 120 to prevent the shake of the lens 130.

In addition, the fixing member 140 is preferably made of a material having elasticity.

The fixing member 140 not only serves to fill a gap between the lens 130 and the lens insert 120, but also elastically deformed to facilitate the insertion of the lens 130 and the lens. It is possible to fix the 130 more strongly.

In this embodiment, the fixing member 140 is provided with a leaf spring.

In addition, in the present embodiment, the fixing member 140 includes an upper part 142, a side part 144, a lower part 146, a front and rear fixing part 148, and a handle part 150.

The upper part 142 serves to adhere the lens 130 to the bottom reference plane by pressing the lens 130 from the top to the bottom.

The side portion 144 serves to keep the lens 130 in close contact with the side.

In addition, the front and rear fixing portion 148 extends from the side portion 144 and serves to closely contact the lens 130 to the front or rear reference plane.

The handle portion 150 is provided in a form bent from the front and rear fixing portion 148 serves to press by the hand when the fixing member 140 is inserted.

The lower part 146 serves to fix the fixing part to the lens inserting part 120.

In the present embodiment, the lens 130 contacts all of the upper part 142, the side part 144, and the lower part 146 of the fixing member 140.

Thus, the lens 130 is firmly fixed to the position designed by the fixing member 140.

Next, the installation process of the lens assembly for an optical engine according to the present embodiment is as follows.

The lens 130 is inserted into the lens insertion unit 120, and the fixing member 140 is pushed downward from the top between the lens insertion unit 120 and the lens 130 to insert the fixing member. do.

The fixing member 140 is provided with a handle portion 150 to easily insert the fixing member 140 down.

Since the fixing member 140 is elastically deformed and inserted when inserted, the fixing member 140 is firmly fixed to the lens 130 by the elastic force after the insertion is completed.

Lens assembly for an optical engine according to the present invention having the above configuration has the following effects.

First, there is an advantage to improve the optical performance by fixing the lens to the reference plane in a simple way by inserting a fixing member.

Second, there is an advantage that the lens is firmly fixed to improve the durability of the optical engine.

Claims (5)

An optical engine case in which various components are installed; Lenses for refracting light; A lens insertion unit provided in the optical engine case and into which the lens is inserted; And Lens assembly for an optical engine comprising a fixing member for fixing the lens to the lens insert. The method of claim 1, Lens assembly for an optical engine, characterized in that the fixing member has an elasticity. The method of claim 1, The fixing member is an optical engine lens assembly, characterized in that provided between the lens and the lens insert. The method of claim 1, The fixing member, An upper part which fixes the lens from top to bottom, Lens assembly for an optical engine, characterized in that it comprises a side portion for fixing the lens from the side. The method of claim 1, The fixing member includes a front and rear fixing unit for fixing at least one of the front or rear surface of the lens as a reference plane.

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