KR100811178B1 - Image display apparatus - Google Patents

Abstract

An image projection apparatus is disclosed. The image projection apparatus enlarges a first mirror that changes an optical path of an enlarged image, an image changed by an optical path by the first mirror, and reflects the image changed by the optical path by the second mirror to the screen. And a third mirror. As a result, an ultra-thin design can be realized by reducing the thickness of the image projector and reducing the height thereof, and image quality is improved due to the prevention of warpage.

Projection, projection, thickness

Description

Image projection apparatus

1 schematically shows a conventional image projection apparatus;

2 is a view showing an image projection apparatus according to an embodiment of the present invention, and

3 is a diagram showing an image projector according to another embodiment of the present invention.

Explanation of symbols on the main parts of the drawings

210: projection lens 220: first mirror

230: second mirror 240: third mirror

250: screen

The present invention relates to an image projection apparatus using a micro display element, and more particularly, to an image projection apparatus to reduce the thickness of the image projection apparatus to be slimmer.

An image projector such as a projection television is a device that generates an image using a micro display element, and magnifies the image through a projection optical system to project it on a large screen. In recent years, demand is increasing day by day because of the advantage that large screens can be satisfied to meet consumer needs.

1 is a diagram schematically showing a conventional image projection apparatus.

Referring to FIG. 1, a conventional image projection apparatus includes a projection lens 110, a mirror 120, and a screen 130.

Specifically, the image projected on the screen 130 is imaged by projecting the light having information through the panel, that is, the image, on the screen 130, through the projection lens 110.

In this case, the mirror 120 is positioned at a position inclined to the screen 130 to change the optical path in order to bring the optical axis to the center of the screen 130. That is, the image enlarged and projected through the projection lens 110 is reflected by the mirror 120 to form an image on the screen 130.

However, such an image projection apparatus needs a space for projection using the projection lens 110 and the mirror 120 to project an image. In particular, since the mirror 120 must have a certain inclination, it requires a lot of rear space of the image projection apparatus. For this reason, when a flat screen display device such as an LCD (Liquid Crystal Display) or a plasma display panel (PDP) has the same screen size, the image projection device is bulkier than the flat display device.

Therefore, the conventional image projection apparatus has a disadvantage that not only the appearance design is disadvantageous but also occupies a lot of installation space. In addition, not only warpage may occur due to the mirror weight, but also a problem of deterioration in image quality due to the warpage may occur.

Accordingly, an object of the present invention is to provide an image projection apparatus capable of realizing an ultra thin design by reducing the thickness of the image projection apparatus and making it slim.

Another object of the present invention is to provide an image projection apparatus capable of preventing a deterioration of image quality due to warpage.

An image projection apparatus according to the present invention for achieving the above object comprises: a first mirror for changing an optical path of an enlarged image, a second mirror for changing an optical path by enlarging an image changed by the first mirror, and the first mirror; And a third mirror for reflecting the image changed in the optical path by the two mirrors to the screen.

The second mirror is preferably any one of an aspherical mirror and a free curved mirror.

The third mirror is preferably positioned in parallel with the upper end surface of the main body or to have a predetermined inclination.

Moreover, it is preferable that the said predetermined inclination is ± 10 degrees or less.

The third mirror may be positioned in parallel with the lower end surface of the main body or inclined at ± 10 degrees or less.

Preferably, the second mirror is located between the first mirror and the third mirror.

The first mirror is preferably located outside the optical path of the image reflected by the third mirror and formed on the screen.

Preferably, the image projection apparatus further includes a projection lens positioned on the top of the main body and applying the enlarged image to the first mirror.

In this case, the first mirror is positioned below the projection lens such that the enlarged image is projected obliquely onto the second mirror, and is located outside the optical path of the image reflected by the third mirror and formed on the screen.

The display apparatus may further include a projection lens positioned at a lower end of the main body and applying the enlarged image to the first mirror.

In this case, the first mirror is preferably located above the projection lens so that the enlarged image is projected obliquely to the second mirror.

An image projection apparatus according to an embodiment of the present invention may include: a projection lens positioned at an upper end of a main body and projecting an enlarged image; a first lens positioned below the projection lens and changing an optical path of the enlarged image; A mirror, a second mirror for changing the optical path changed by the first mirror to change the optical path, and a position parallel to the bottom surface of the main body or having a predetermined inclination, and positioned by the second mirror. And a third mirror that reflects the modified image to the screen.

Here, it is preferable that the said 2nd mirror is any one of an aspherical mirror and a free curved mirror.

The second mirror is located between the first mirror and the third mirror.

And it is preferable that the said predetermined inclination is inclination of +/- 10 degree or less.

In addition, the image projection apparatus according to another embodiment of the present invention, a projection lens which is located at the bottom of the main body, and projects the enlarged image, the first lens positioned above the projection lens, and changing the optical path of the enlarged image A mirror, a second mirror that enlarges an image changed by an optical path by the first mirror, and changes an optical path, and is positioned to be parallel to an upper end surface of the main body or to have an inclination of ± 10 degrees or less, and the second mirror And a third mirror for reflecting the image changed by the optical path to the screen.

Here, the second mirror may be any one of an aspherical mirror and a free curved mirror.

Hereinafter, with reference to the drawings will be described in detail the present invention.

2 is a diagram illustrating an image projection apparatus according to an embodiment of the present invention.

The image projection apparatus projects an image using a micro display element, and is provided with a plurality of mirrors to change the projection method, so that the thickness can be reduced and ultra-thin implementation is possible. Micro display elements used in the image projection apparatus include a digital micromirror device (DMD), a thin film transistor (TFT), and a liquid crystal on silicon (LCOS).

Referring to FIG. 2, the image projection apparatus includes a projection lens 210, a first mirror 220, a second mirror 230, a third mirror 240, and a screen 250.

The projection lens 210 is located at the top of the image projection device, and enlarges and projects the image illuminated on the micro display element. Since the projection lens 210 is positioned at the top of the image projection apparatus, a light source (not shown) and a micro display element are also positioned at the top of the image projection apparatus.

The first mirror 220 is positioned to have a predetermined inclination under the projection lens 210 so that the image is projected obliquely, and reflects the image projected by the projection lens 210 to change the optical path.

In this case, since the first mirror 220 is positioned to have a predetermined inclination, that is, a small inclination, the angle of the image enlarged by the projection lens 210 is reflected in a small state.

The second mirror 230 is positioned in parallel with the first mirror 220 and reflects the image reflected by the first mirror 220 again. Here, the second mirror 230 is at least one of an aspherical mirror and a free curved mirror. A free curved mirror is a mirror having a plane in which the reflecting plane is not optical axis symmetric but has an arbitrary height equal to the horizontal and vertical directions.

As the second mirror 230 is used as either an aspherical mirror or a free curved mirror, an image of better image quality can be obtained by correcting distortion of the image.

As the second mirror 230 is used as either an aspherical mirror or a free curved mirror, an image reflected at a small angle by the first mirror 220 is enlarged by an enlarged angle by the second mirror 230. And reflected.

The third mirror 240 is positioned to have an inclination parallel to or less than the bottom surface of the image projection device, for example, an inclination within ± 10 degrees, and reflects the image magnified and reflected by the second mirror 230 to the screen 240. do.

Here, the thickness of the image projector may be further reduced according to the inclination of the third mirror 240. Specifically, the thickness of the image projector is reduced as the inclination of the third mirror 240 approaches ± 10 degrees, compared to when the third mirror 240 is parallel to the bottom surface of the image projector.

In addition, since the third mirror 240 is located on the lower surface of the image projector, the image quality may be improved due to the prevention of warpage.

The image reflected by the third mirror 240 is imaged on the screen 250.

In this case, the first mirror 220 is positioned outside the optical path reflected by the third mirror 240 and formed on the screen 250, and the second mirror 230 is formed of the first mirror 220 and the third mirror ( 240).

Thus, not only the thickness of the image projector but also the height of the image projector can be reduced by about 35% compared with the conventional image projector. That is, as the projection lens 210, the first, the second, and the third mirrors 220, 230, and 240 are all disposed vertically, the thickness of the image projection apparatus may be reduced to the distance from the second mirror 230 to the screen 250. do. In addition, as the plurality of mirrors are arranged like the first, second, and third mirrors 220, 230, and 240, and the second mirror 230 is arranged as an aspherical mirror or a free curved mirror, the distance of the optical path is reduced, so that The height is reduced.

3 is a diagram showing an image projector according to another embodiment of the present invention.

Referring to FIG. 3, the image projection apparatus includes a projection lens 310, a first mirror 320, a second mirror 330, a third mirror 340, and a screen 350.

The projection lens 310 is located at the bottom of the image projection apparatus, and enlarges and projects the image illuminated on the micro display element. Since the projection lens 310 is positioned at the bottom of the image projection apparatus, a light source (not shown) and a micro display element are also positioned at the bottom of the image projection apparatus.

The first mirror 320 is positioned to have a predetermined inclination on the upper side of the projection lens 310 so that the image is projected obliquely, and reflects the image projected by the projection lens 310 to change the optical path.

The second mirror 330 is positioned in parallel with the first mirror 320 and reflects the image reflected by the first mirror 320 again. In this case, the second mirror 330 is at least one of an aspherical mirror and a free curved mirror.

The third mirror 340 is positioned to have an inclination parallel to or smaller than the top surface of the image projection apparatus, for example, ± 10 degrees, and reflects the image reflected by the second mirror 330 to the screen 340. .

Here, the thickness of the image projector may be further reduced according to the inclination of the third mirror 340. Specifically, the thickness of the image projector is reduced as the inclination of the third mirror 340 is closer to ± 10 degrees than when the third mirror 340 is in parallel with the bottom surface of the image projector.

The image reflected by the third mirror 340 is imaged on the screen 350.

As a result, not only the thickness of the image projecting device but also the height of the image projecting device is reduced by about 35% compared with the conventional image projecting device.

As described above, according to the present invention, the thickness of the image projection apparatus can be reduced and slim, and the height can be realized, and the ultra-thin design can be realized, and the image quality is improved due to the prevention of warpage.

In addition, although the preferred embodiment of the present invention has been shown and described above, the present invention is not limited to the specific embodiments described above, but the technical field to which the invention belongs without departing from the spirit of the invention claimed in the claims. Of course, various modifications can be made by those skilled in the art, and these modifications should not be understood from the technical spirit or the prospect of the present invention.

Claims (20)

A first mirror for changing an optical path of the enlarged image; A second mirror for changing an optical path by enlarging an image changed by an optical path by the first mirror; And And a third mirror reflecting the image changed in the optical path by the second mirror to the screen. The second mirror, And an aspheric mirror and a free-form surface mirror. delete The method of claim 1, The third mirror, An image projection device, characterized in that located in parallel with the upper surface of the main body or to have a predetermined inclination. The method of claim 3, The predetermined slope is An image projection device characterized by an inclination of ± 10 degrees or less. The method of claim 1, The third mirror, An image projection device, characterized in that it is positioned in parallel with the lower surface of the main body or have an inclination of ± 10 degrees or less. The method of claim 1, The second mirror, And an image projector positioned between the first mirror and the third mirror. The method of claim 1, The first mirror, And an optical projection apparatus positioned outside an optical path of an image reflected by the third mirror and formed on the screen. The method of claim 1, And a projection lens positioned at an upper end of the main body to apply the enlarged image to the first mirror. The method of claim 8, The first mirror, And the enlarged image is positioned below the projection lens such that the enlarged image is projected obliquely onto the second mirror. The method of claim 9, The first mirror, And an optical projection apparatus positioned outside an optical path of an image reflected by the third mirror and formed on the screen. The method of claim 8, The first mirror, And the enlarged image is positioned below the projection lens such that the enlarged image is projected obliquely to the second mirror, and is located outside the optical path of the image reflected by the third mirror and formed on the screen. The method of claim 11, The second mirror is any one of an aspherical mirror and a free curved mirror, And the third mirror is positioned to be parallel to the bottom surface of the main body or to have an inclination of ± 10 degrees or less. The method of claim 1, And a projection lens positioned at a lower end of the main body and applying the enlarged image to the first mirror. The method of claim 13, The first mirror, And the enlarged image is positioned above the projection lens such that the enlarged image is projected obliquely onto the second mirror. A projection lens positioned at an upper end of the main body to project an enlarged image; A first mirror positioned below the projection lens and changing an optical path of the enlarged image; A second mirror for changing an optical path by enlarging an image changed by an optical path by the first mirror; And And a third mirror positioned parallel to the bottom surface of the main body or having a predetermined inclination, and reflecting an image changed in the optical path by the second mirror to the screen. The method of claim 15, The second mirror, And an aspheric mirror and a free-form surface mirror. The method of claim 15, The second mirror, And an image projector positioned between the first mirror and the third mirror. The method of claim 15, The predetermined slope is An image projection device characterized by an inclination of ± 10 degrees or less. Located at the bottom of the main body, the projection lens for projecting an enlarged image; A first mirror positioned above the projection lens and changing an optical path of the enlarged image; A second mirror for changing an optical path by enlarging an image changed by an optical path by the first mirror; And And a third mirror positioned to be parallel to the top surface of the main body or having an inclination of ± 10 degrees or less, and reflecting an image changed by the second mirror to the screen. The second mirror, And an aspheric mirror and a free-form surface mirror. delete

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