KR0136545Y1 - Control device of intensity of laser radiation for using tilting mirror - Google Patents

Abstract

The present invention is to install a focusing lens and a tilting mirror to adjust the amount of laser light to increase the response speed, increase the light efficiency and also to reduce the noise of the focused light through the prism to adjust the laser light amount control device The configuration includes a laser scanning means (11) for scanning light having a certain area, and first and second transmission holes (14a, 14b) for transmitting the light scanned from the laser scanning means (11). The focusing lens 14 is reflected by the tilting mirror 12 and the tilting mirror 12 that reflects light passing through the first through hole 14a of the focusing lens 14, and the focusing lens 14. It consists of a prism 16 for reflecting the light passing through the second transmission hole (14b) of the) to be able to adjust the amount of light of the beam scanned from the laser scanning means (11).

Description

Laser light amount control device using tilting mirror

1 is a view schematically showing a laser light amount control device using a tilting mirror according to the present invention.

2 (a) and 2 (b) show the focusing lens and prism in FIG.

* Explanation of symbols for main parts of the drawings

10: laser light amount control device 11: laser scanning means

12: tilting mirror 14: focusing lens

16: Prism

The present invention relates to a laser light quantity control device using a tilting mirror, and more particularly, by installing a focusing lens and a tilting mirror to adjust the amount of laser light to increase the response speed, increase the light efficiency, and also focus through a prism. It relates to a laser light amount control device using a tilting mirror that can reduce the noise of light.

In general, in a large liquid crystal display (hereinafter referred to as LCD), a laser beam scanned from a laser scanning means as a light source is projected through an LCD shutter, which uses polarized light, and thus response speed to image information is increased. There was a problem that the LCD is slow, and such an LCD has a high light loss due to a polarizing plate, and thin film transistors for driving the LCD are formed for each pixel, which limits the opening ratio (light transmission area).

Thus, Actuated Mirror Arrays (hereinafter referred to as AMA) was developed by Aura, United States, which distinguishes between using one-dimensional AMA and two-dimensional AMA. The one-dimensional AMA has mirror surfaces arranged in an M × 1 array, and the two-dimensional AMA has mirror surfaces arranged in an M × N array. Therefore, a projection image display device using a one-dimensional AMA pre-scans M × 1 rays using a scanning mirror, and a projection image display device using a two-dimensional AMA projects M × N beams to produce an array of M × N pixels. Branches represent images.

The present invention can solve the problems of lowering the response speed and lowering the light efficiency caused by adjusting the amount of light by using the LCD shutter or mechanical shutter using the polarization phenomenon of the light amount of the beam scanned from the conventional laser scanning means as described above It is an object of the present invention to provide a laser light quantity control device using a tilting mirror.

According to a preferred embodiment of the present invention to achieve the above object, the laser scanning means for scanning the light having a certain area, and the first and second transmission hole for transmitting the light scanned from the laser scanning means And a prism for reflecting the light passing through the second transmission hole of the focusing lens, and a tilting mirror for reflecting light passing through the first transmission hole of the focusing lens. Provided is a laser light amount adjusting device using a tilting mirror, characterized in that the amount of light of the beam scanned from the laser scanning means can be adjusted.

The focusing lens is preferably one side of the convex lens shape and the other side of the focusing mirror, the first and second through-holes are formed in the plane, and is coated with chrome or the like around the first and second through-holes. have.

The prism has third and fourth through holes formed on the incident surface and the transmissive surface.

According to the embodiment, the laser beam scanned from the laser scanning means is reflected by the tilting mirror through the first transmission hole of the focusing lens, and then the amount of light is adjusted while passing through the second transmission hole of the focusing lens, and the third and A beam of a certain amount of light is projected through the fourth through hole.

Hereinafter, a laser light quantity adjusting device using a tilting mirror according to the present invention will be described in detail with reference to the accompanying drawings.

FIG. 1 is a plan view schematically showing a laser light amount adjusting device using a tilting mirror according to the present invention, and FIGS. 2 (a) and (b) are front views showing the focusing lens and prism of FIG. As shown in the drawing, the laser light amount adjusting device 10 includes a laser scanning means 11, a tilting mirror 12, a focusing lens 14, and a prism 16.

The tilting mirror 12 is to be tilted at a predetermined angle by an applied driving voltage.

The focusing lens 14 focuses the laser beam scanned from the laser scanning means 11 on one side thereof with a convex lens shape, and the first and second transmission holes 14a and 14b are formed on the other side thereof in a planar shape. It is.

The prism 16 includes an incident surface, a reflective surface, and a projection surface, and third and fourth transmission holes 16a and 16b are formed in the entrance surface and the projection surface, respectively.

The circumferences of the first through fourth through holes 14a, 14b, 16a, and 16b of the focusing lens 14 and the prism 16 are coated with a material such as chromium (Cr), respectively.

The second through third through holes 14b, 16a, and 16b have the same size.

Referring to the operation of the laser light amount control device using a tilting mirror according to the present invention configured as described above are as follows.

First, a laser beam having a predetermined area is scanned from the laser scanning means 11, and the laser beam passes through the first transmission hole 14a of the focusing lens 14 and reaches the tilting mirror 12 to be reflected. Thereafter, the second through hole 14b of the focusing lens 14 is transmitted. Thereafter, the beam passing through the second through hole 14b is transmitted through the third through hole 16a of the prism 16 to be reflected at the reflection surface, and then the light is adjusted and scanned through the fourth through hole 16b. will be.

As described in the above embodiment, the laser light amount adjusting device using the tilting mirror according to the present invention is the response speed because the light passing through the focusing lens is reflected by the tilting mirror and passed through the transmission hole of the focusing lens to adjust the response speed Compared to the related art, the light efficiency is much faster and the light efficiency is increased, and a constant amount of light is passed through the prism, thereby reducing the noise of the light.

While the present invention has been described and illustrated with reference to the preferred embodiments, those skilled in the art will be able to perform various modifications without departing from the gist of the present invention.

Claims (4)

A focusing lens 14 having laser scanning means 11 for scanning light having a predetermined area, and first and second transmission holes 14a, 14b for transmitting the light injected from the laser scanning means 11; And a tilting mirror 12 reflecting light passing through the first transmission hole 14a of the focusing lens 14 and the second projection hole reflected by the tilting mirror 12. And a prism (16) for reflecting the light passing through the (14b) to adjust the amount of light of the beam scanned from the laser scanning means (11). The apparatus of claim 1, wherein the prism (16) has third and fourth through holes (16a, 16b) formed on the incident surface and the transmission surface. The apparatus of claim 1, wherein chromium (Cr) is coated around the focusing lens (14) of the first and second projection holes (14a, 14b). The apparatus of claim 1, wherein the circumferences of the third and fourth through holes (16a, 16b) of the prism (16) are coated with chromium (Cr).