KR100839480B1 - Image tilting device for projection - Google Patents

Abstract

An image tilting device for a projection is provided to contact and join a flange, formed slopely for a bracket, to a joining target object to mount an image tilting member slopely for a vertically disposed joining target object, thereby facilitating the assembly of the image tilting device and the rotation of a tiling portion. An image tilting device for a projection comprises an image tilting member(10,20,30,40), a bracket(60), and a flange(65). The image tilting member reflects light radiated from a laser scanning unit by a minute rotation to improve the quality of a displayed image. The bracket is joined to the image tilting member. The flange is formed slopely for the bracket. The flange is joined to a joining target object in parallel to dispose the image tilting member slopely for the joining target object. Further, the image tilting member contains a tilting part having a mirror, a support part connected with hinge, a drive unit for rotating the tilting part and the bracket.

Description

Image tilting device for projection}

1 is a schematic diagram of a typical projection system,

2 is an exploded perspective view of a conventional image tilting apparatus;

3 is a cross-sectional view of the image tilting apparatus shown in FIG.

4 is a schematic structural diagram showing a coupling structure of a conventional image tilting apparatus;

5 is a perspective view of an image tilting apparatus according to an embodiment of the present invention;

6 is an exploded perspective view of the image tilting apparatus according to the embodiment of the present invention;

7 is a side view of the image tilting apparatus according to the embodiment of the present invention;

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

10: mirror holder, 20: mirror,

30: tilting part, 40: support part,

52: coil, 55: magnet,

60: bracket, 62: support,

65: flange, 70: PCB holder,

80: PCB, 200: bonding object.

The present invention relates to an image tilting apparatus for projection, and more particularly, to an image tilting apparatus for projection that can be easily tilted to form an image tilting apparatus by forming an inclined flange on a bracket.

Projection system is for realizing a small image on a large screen using optical means. According to the type of device to implement the image, CRT (Cathod Ray Tube) projection, LCD (Liquid Crystal Display) projection and DLP (Digital Light Processing) projection Can be divided in a way.

CRT projection method is the oldest method that reflects a small high-definition CRT on a mirror and forms an image on the screen. The LCD projection method is a small LCD with a diameter of about 4 inches inside the projection TV when an external playback video signal is sent to the projection TV. The screen receives it and reproduces the image.

Subsequently, the image formed on the screen is shot with a strong light from behind the LCD screen to magnify the screen through the lens, and reflected on the mirror to project on the screen.

The DLP projection method uses a digital micromirror device (DMD) semiconductor chip integrated with hundreds of thousands of fine driving mirrors developed by Texas Instruments to operate an enlarged projection image signal from an external source.

Such DLP projection systems are disclosed in US Pat. No. 6,582,080 to Imax Corporation.

1 is a schematic diagram of a general projection system (see Patent Publication No. 10-0509956).

In the projection system 2000 as illustrated in FIG. 2, the white light generated by the light source 2100 is light of a color synchronized with an image displayed on the micro display device 2300 while passing through the color processing device 2200. Has

The image displayed on the micro display device 2300 passes through the first projection lens 2410 and then is reflected by the image tilting apparatus 1000 to which the reflection mirror 1410 is attached, thereby causing the second projection lens ( It is enlarged on the screen 2500 by 2420.

The reflective mirror 1410 is attached to the image tilting apparatus 1000 and rotated by a fine rotational movement of the image tilting apparatus 1000.

In this case, the image tilting apparatus 1000 may rotate based on a vertical or horizontal axis of the image tilting apparatus 1000 or may rotate about an oblique axis having a predetermined angle, so that the reflective mirror 1410 is attached thereto. The direction of rotation also changes.

The image rotated about the horizontal axis of rotation (H) of the image tilting device 1000 is finely moved in the vertical direction of the screen 2500, which is the same direction as the arrow shown on the screen 2500, the image displayed By superimposing this, the image quality of the image is made clear.

That is, when the image tilting apparatus 1000 is micro-reciprocated, displacement occurs in the vertical direction of the pixel by the moving direction, and the upper and lower surfaces of the pixel appear to overlap each other, so that the boundaries of all the pixels are blurred. As a result, the resolution can be increased.

FIG. 2 is an exploded perspective view of a conventional image tilting apparatus, and FIG. 3 is a cross-sectional view of the image tilting apparatus shown in FIG. 2 (see Publication No. 10-2007-0039426).

2 and 3, the conventional image tilting apparatus, the mirror 100 for reflecting the light scanned from the optical scanning device; A tilting unit 110 on which the mirror 100 is seated; Support 120; Hinge parts 130 formed to connect the support part 120 and the tilting part 110 at both ends of the center line of the surface where the tilting part 110 is tilted; It is installed in an eccentric position with respect to the middle wire, and consists of a power unit for generating power for tilting the tilting unit 110 based on the support unit 120.

The hinge portion 130 has a cross section having a shape of '+'.

The tilting unit 110 is finely tilted up and down with reference to FIG. 4 based on a center line connecting both hinge parts 130 to tilt the mirror 100.

The power unit, the magnet 150 is fixed to one side of the tilting unit 110 or the support unit 120 side; And the magnet 150 is fixed to the side of the tilting part 110 or the support part 120 that is not fixed, and receives the magnetic flux emitted from the magnet 150 when power is applied, and the tilting part 110 is tilted. It consists of a wound coil 140 for generating a driving force.

The magnetic flux of the magnet 150 passes through the coil 140 horizontally with reference to FIG. 4, and the direction of the current of the coil 140 flows horizontally while being perpendicular to the magnetic flux of the magnet 150.

Therefore, when power is supplied to the coil 140, the coil 140 and the magnet 150 generate an electromagnetic force according to Fleming's left hand law that pushes each other in the vertical direction.

Since the magnet 150 is fixed to the support part 120 side, the tilting part 110 to which the coil 140 is fixed is driven up and down.

One power unit is provided at each of the two edges with respect to the center line connecting the two hinge parts 130.

Power units on both sides are arranged to generate driving force in opposite directions, respectively, and the sum of the respective power units is transmitted to the tilting unit 110.

In addition, each power unit is further provided with a yoke 160 in which one support 162 on which the magnet 150 is supported and the other support 162 located at the center of the coil 140 are integrally formed. The magnetic flux emitted from the 150 and passed through the coil 140 is returned back to the magnet 150.

The bracket 170 is coupled to the support 120, and the bracket 170 is provided with a plurality of adjustment screws 122 for adjusting the initial setting angle of the support 120.

The bracket 170 is fixed to the yoke 160 using the second fixing screw 172.

In addition, the bracket 170 fixes the PC 180 on which the driving device 182 is mounted to control the power supplied to the coil 140.

The PC 180 is fixed to the yoke 160 using the third fixing screw 184.

Such a conventional image tilting apparatus for projection should be mounted inclined to reflect the incident light in a predetermined direction as shown in FIG.

4 is a schematic structural diagram illustrating a coupling structure of a conventional image tilting apparatus.

To this end, as shown in FIG. 4 (a), the whole image tilting apparatus 300 having the mirror 100 mounted on the upper surface of the coupling object 200 vertically formed is inclined to be easily assembled. There was a problem that the tightening force is weak.

In addition, as shown in FIG. 4 (b), the coupling object 200 may be inclined to be coupled in parallel to the coupling object 200 and the image tilting device 300, in which case the inclined coupling object 200 is formed. ) Is not easy to manufacture and must be a separate design change, there is a problem that the product is large due to the interference problem of the inclined coupling object 200 and other components.

In addition, as shown in FIG. 4C, the image tilting apparatus 300 is vertically disposed in parallel with the vertically formed coupling object 200 and includes a mirror holder or a tilting unit on which the mirror 100 is mounted. The mirror 100 itself may be inclined by varying the upper and lower thicknesses of the 300, but in this case, the upper and lower thicknesses of the image tilting apparatus 300 including the mirror holder or the tilting part are tilted due to the mirror 100. The balance of the upper and lower parts is not easy to rotate the tilting portion, and there is a problem in that the weight of the product becomes heavier as the thickness of the image tilting apparatus 300 including the mirror holder or the tilting portion.

The present invention has been made to solve the above-described problems, but the image tilting device is mounted obliquely to the existing vertically formed coupling object, the fastening force with the coupling object is easy and easy to assemble and the top and bottom balance of the tilting portion is easily rotated Its purpose is to provide an image tilting device for projection.

In order to achieve the above object, the projection image tilting apparatus of the present invention includes: an image tilting member for sharpening the image quality of the displayed image by reflecting the light scanned from the optical scanning device by a micro-rotation motion; A bracket coupled to the image tilting member; The flange is formed to be inclined to the bracket, the flange is coupled in parallel to the coupling object characterized in that the image tilting member is arranged to be inclined with respect to the coupling object.

The image tilting member may include a tilting unit mounted with a mirror for reflecting light; A support portion rotatably hinged to the tilting portion; Drive means for rotating the tilting portion; It comprises the bracket coupled to the support, the drive means, and a magnet mounted to the bracket; The coil is mounted to the tilting part and receives the magnetic flux generated from the magnet, and the coil is configured to drive the tilting part. The yoke part integrally formed with the bracket releases the magnetic flux passing from the magnet and passed through the coil back to the magnet. It is.

The flange is formed to extend on both sides of the bracket, so that the horizontal inclination length of the flange to the bracket is equal to or less than the combined thickness of the tilting portion and the bracket.

Hereinafter, with reference to the accompanying drawings will be described in detail a preferred embodiment of the present invention.

5 is a perspective view of an image tilting apparatus according to an embodiment of the present invention, Figure 6 is an exploded perspective view of the image tilting apparatus according to an embodiment of the present invention, Figure 7 is a side view of the image tilting apparatus according to an embodiment of the present invention to be.

5 to 7, the image tilting apparatus of the present invention comprises an image tilting member, a bracket 60, a flange 65 and the like.
The image tilting member includes a mirror 20, a mirror holder 10, a tilting portion 30, a support portion 40, a driving means, and the like.

The mirror 20 is for reflecting the light scanned from the optical scanning device, it is mounted on the mirror holder 10.

The mirror 20 is directly mounted on the upper surface of the tilting part 30 or a mirror holder 10 on which the mirror 20 is mounted.

The support part 40 is disposed on both sides of the tilting part 30, and the tilting part 30 is hinged rotatably with respect to the support part 40.

In detail, the tilting part 30 and the support part 40 are integrally connected by a cross-shaped hinge part.

Of course, the tilting portion 30 and the support portion 40 may be connected by other shapes in addition to the cross-shaped hinge.

The driving means for rotating the tilting unit 30 is mounted below the tilting unit 30, and the driving unit includes a coil 52 and a magnet 55.

The coil 52 is wound in a hollow cylinder shape, and fixedly coupled to the upper and lower sides of each of the two sides with respect to the center line of the tilting unit 30.

The magnet 55 is mounted to the bracket 60 to be disposed on the side of each of the coils 52.

That is, the magnetic flux of the magnet 55 passes through the coil 52 horizontally, and the direction of the current of the coil 52 flows horizontally while being perpendicular to the magnetic flux of the magnet 55.

Therefore, when a current is applied to the coil 52 coupled to the tilting unit 30, the coil 52 receives the magnetic flux emitted from the magnet 55 and is driven together with the tilting unit 30.

That is, the coil 52 and the magnet 55 generate an electromagnetic force according to Fleming's left-hand law that pushes each other in the vertical direction, and the tilting part 30 to which the coil 52 is fixed rotates up and down. .

The bracket 60 is disposed below the tilting part 30, the support part 40, and the driving means, and is coupled by the support part 40 and the fastening means.

Four support members 62 protrude upwardly from the bracket 60, and two support members 62 are disposed at the center of each of the coils 52, and the other two support members are provided in the coils 52. And adjacent to each of the magnets 55.

A yoke portion is formed in the bracket 60, and the yoke portion is disposed below the coil 52 and the magnet 55 to release the magnetic flux emitted from the magnet 55 and passed through the coil 52. It serves to return to the magnet (55).

The yoke portion may be formed separately, but preferably the support 62 serves as the yoke portion.

That is, the yoke portion refers to a portion where the support 62 is formed, and the support 62 is configured to form the yoke portion.

The flanges 65 extend on both sides of the bracket 60, and the flanges 65 are disposed on both sides of the tilting part 30.

The flange 65 is formed to be inclined with respect to the bracket 60 and the tilting portion 30, and the horizontal inclination length of the flange 65, that is, between the inclined flange 65 and the non-inclined bracket 60 The maximum distance is to be equal to or less than the combined thickness of the tilting unit 30 and the bracket 60.

By doing so, even if the inclined flange 65 is formed, the entire thickness of the image tilting apparatus can be maintained at the same thickness as in the prior art, thereby making the product slim.

By forming the inclined flange 65 on the bracket 60 as described above, by engaging the flange 65 in parallel to the coupling object 200 as shown in Figure 7, the image tilting member is vertically disposed It can be mounted obliquely to the coupling object (200).

Therefore, in order to mount the image tilting device inclined, it is not necessary to change the design of the vertically formed coupling object 200 separately, and since the flange 65 is coupled in parallel with the coupling object 200, the fastening force is strong and the assembly is easy. can do.

In addition, the upper and lower thicknesses of the tilting part 30 are the same, so that the upper and lower balances of the tilting part 30 are balanced, thereby facilitating the rotation of the tilting part 30.

On the other hand, by mounting a separate PCB holder 70 to the bracket 60, it can be mounted to the PCB (80).

Projection image tilting apparatus of the present invention is not limited to the above-described embodiment, it can be carried out in a variety of modifications within the scope of the technical idea of the present invention.

According to the projection image tilting apparatus of the present invention as described above has the following advantages.

First, by forming an inclined flange on the bracket and engaging by connecting the flange in parallel to the coupling object, the image tilting member can be mounted obliquely on the vertically arranged coupling object, the coupling object vertically formed to mount the image tilting member inclinedly. There is no need to change the design separately, and because the flange is coupled in parallel with the coupling object, the fastening force is strong and easy to assemble, and the same can be done without changing the upper and lower thicknesses of the tilting part to arrange the mirror inclinedly. Up and down balance can be matched to facilitate the rotation of the tilting portion.

Second, by forming the yoke integrally to the bracket, it is possible to reduce the number of parts can be reduced cost and improve assembly.

Third, by making the horizontal slope of the flange equal to or smaller than the combined thickness of the tilting part and the bracket, even if the flange is formed to be inclined relatively to the bracket, the overall thickness of the image tilting device can be maintained at the same thickness as before, resulting in a slim product. have

Claims (3)

An image tilting member for reflecting the light scanned from the optical scanning device by the micro-rotation motion to sharpen the image quality of the displayed image; A bracket coupled to the image tilting member; Is made of a flange formed inclined to the bracket, And the flange is coupled in parallel to the coupling object such that the image tilting member is disposed to be inclined with respect to the coupling object. The method of claim 1, The image tilting member, A tilting unit equipped with a mirror for reflecting light; A support portion rotatably hinged to the tilting portion; Drive means for rotating the tilting portion; It comprises the bracket to which the support is coupled, The drive means, A magnet mounted to the bracket; The coil is mounted to the tilting part and receives a magnetic flux generated from the magnet, and the coil is configured to drive the tilting part. And a yoke portion integrally formed in the bracket to return the magnetic flux emitted from the magnet and passing through the coil back to the magnet. The method of claim 2, The flange is formed to extend on both sides of the bracket, And a horizontal inclination length of the flange relative to the bracket is equal to or smaller than a combined thickness of the tilting part and the bracket.

Images