KR19990029461U - Source mirror holder coupling structure of AMA projector - Google Patents

Abstract

The present invention relates to a source mirror holder coupling structure of an AMA projector, wherein a first base plate and a second base plate are arranged in a horizontal direction at one end of a lamp holder to which a lamp is coupled, and are arranged above and below the lamp. A source mirror holder mounted in a cylindrical shape is rotatably installed between the second base plate and the second base plate. It is fixedly installed, the adjustment screw is installed at the front end of the reflection angle adjustment post to reciprocate in the horizontal direction to rotate the reflection angle adjustment post and the source mirror holder in the horizontal direction, the front end and the lamp holder of the reflection angle adjustment post Between the elastic means is installed.

Therefore, according to the present invention, even after assembling the AMA projector, the reflection angle of the source mirror can be adjusted to obtain an effect of improving the assembly and maintainability of the product.

Description

Source mirror holder coupling structure of AMA projector

The present invention relates to a structure of a source mirror holder of an AMA projector, and more particularly, to a source mirror holder structure of a structure capable of adjusting an angle of a source mirror even when an AMA projector is assembled.

In general, a device for projecting optical energy onto a screen includes a direct-view image display device and a projection-type image display device according to a method of displaying optical energy on a screen. type image display device).

An example of a direct-view image display apparatus is a cathode ray tube (CRT), which is a so-called CRT device, which has excellent image quality but increases in weight and volume as the size of the screen increases, leading to an increase in manufacturing cost. There is.

Projection type image display devices are referred to as liquid crystal displays (hereinafter referred to as LCDs), deformable mirror devices (hereinafter referred to as DMDs), and actuated mirror arrays (hereinafter referred to as AMAs). ).

Since the LCD has a very simple optical structure, it can be thinly formed to reduce the weight and the volume. However, due to the polarity of light, the light efficiency is low, and there is a problem inherent in the liquid crystal material, for example, a slow response speed and a disadvantage in that the inside is easily overheated. In addition, the maximum light efficiency of existing transmission light modulators is limited to a range of 1 to 2% and requires dark room conditions to provide acceptable display quality.

Optical modulators such as DMD and AMA have been developed to solve the problems of the aforementioned LCD type optical modulators.

DMD shows a relatively good light efficiency of about 5%, but serious fatigue problems are caused by the hinge structure employed in the DMD. In addition, there is a disadvantage that a very complicated and expensive driving circuit is required.

In contrast, AMA is a piezoelectrically driven mirror array that provides light efficiency of 10% or more. In an AMA light modulator, each actuator generates a deformation in accordance with an electric field generated by an applied electric image signal and a bias voltage. When the actuator causes deformation, each of the mirrors mounted on the actuator is inclined to reflect the light incident from the light source at a predetermined angle.

The AMA optical modulator has a simple structure and operation principle, and can obtain high light efficiency compared to LCD or DMD. It also provides enough contrast to provide a bright and clear image under normal room temperature light conditions. Moreover, it is not only affected by the polarity of the incident light, but also by the polarity of the reflected light. In addition, the reflective properties of the AMA are relatively less sensitive to temperature, which has the advantage of improving the brightness of the screen compared to other devices that are easily affected by high power light sources.

1 is a schematic diagram showing a projector using the AMA as described above.

As shown, the previously filed projector includes a lamp 1 for radiating high-brightness white light, a source stop 2 formed with a hole to determine the amount of light radiated from the lamp 1, and the source stop ( 2) a source mirror 3 for reflecting the light beams passing through the AMA module assembly 5 in the direction of the AMA module assembly 5, and a dichroic filter for splitting white light into the main beams and reflecting or transmitting the light to each AMA module assembly 5; 4) an AMA module assembly 5 for changing the light path of the main beam incident upon actuation on the piezo actuator, a projection stop 6 for limiting the transmission amount of the main beams whose light path is adjusted, and the synthesized main beams in the direction of the screen. It consists of a projection lens 7 provided for projecting, and a cage 8 for embedding these constituent members.

2 to 3 illustrate embodiments of a conventional source mirror coupling structure. First, the embodiment shown in FIG. 2 illustrates that a lamp 1 is coupled to a lamp holder 11, and one end of the lamp holder 11 is connected to the lamp holder 11. The source mirror holder assembly 12 having a predetermined shape is coupled to be spaced apart from the front of the lamp 1 by a predetermined distance so that the source mirror 3 can maintain a predetermined reflection angle. That is, the source mirror holder assembly 12 includes a horizontal holder 13 for spaced apart the source mirror 3 from the lamp holder 11 and a vertical holder for positioning the source mirror 3 on the optical axis of the lamp. It consists of (14). At one end of the vertical holder 14, a seating surface 15 for forming the source mirror 3 to have a predetermined reflection angle is formed, and the source mirror 3 is fixedly coupled to the seating surface 15. This source mirror 3 reflects the light radiated from the lamp 1 to the dichroic filter 4 and the AMA module assembly 5.

Meanwhile, the conventional embodiment shown in FIG. 3 simplifies the coupling structure than the above-described embodiment. Like the above-described embodiment, the lamp 1 is coupled to the lamp holder 11 and the lamp holder 11 The source mirror holder 23 in which the lamp holder bonding surface 21 and the source mirror bonding surface 22 are integrally formed is joined at one end. That is, the source mirror holder 23 is supported by the lamp holder bonding surface 21 is bonded to the lamp holder 11 so that the source mirror bonding surface 22 maintains a predetermined reflection angle from the lamp holder 11. The source mirror 3 is bonded to the same source mirror bonding surface 22.

However, in the conventional coupling structure of the source mirror holder, the source mirror is coupled at a fixed reflection angle with respect to the lamp, and it is impossible to adjust the reflection angle due to the structure of the source mirror holder. Therefore, there is a disadvantage that the error of the reflection angle due to the assembly tolerance generated in the assembling process cannot be corrected after assembling.

Accordingly, an object of the present invention is to provide a source mirror holder coupling structure capable of adjusting the reflection angle of the source mirror even after assembly.

The present invention for realizing this purpose is provided with the first base plate and the second base plate is aligned in the upper and lower parts of the lamp in the horizontal direction at one end of the lamp holder to which the lamp is coupled, the first base plate and the second base plate A source mirror holder placed in a cylindrical shape is rotatably installed therebetween, a source mirror is installed on a seating surface formed at one end of the source mirror holder, and a reflection angle adjustment post is fixedly installed at one end of the source mirror holder. An adjustment screw is installed at the tip of the reflection angle adjustment post to reciprocate in the horizontal direction so that the reflection angle adjustment post and the source mirror holder can be rotated in the horizontal direction, and an elastic means is provided between the tip of the reflection angle adjustment post and the lamp holder. Provided is a source mirror holder coupling structure provided.

The above object and various advantages of the present invention will become more apparent from the preferred embodiments of the invention described below with reference to the accompanying drawings by those skilled in the art.

1 is a schematic diagram showing a projector using a conventional AMA,

Figure 2 is an exploded perspective view showing an example of a conventional source mirror holder coupling structure,

3 is an exploded perspective view showing another example of a conventional source mirror holder coupling structure;

Figure 4 is an exploded perspective view showing an example of the source mirror holder coupling structure according to the present invention.

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

30; Lamp 32; Lamp holder

34; First base plate 36; 2nd base plate

38; Source mirror holder 40; Seating surface

42; Source mirror 44; Reflective angle adjustable post

46; Adjusting screw 48; Elastic means

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

4 is an exploded perspective view showing an example of the source mirror holder coupling structure according to the present invention, the present invention is the first base plate 34 and the horizontal direction to one end of the lamp holder 32 to which the lamp 30 is coupled; The second base plate 36 is installed in alignment with the upper and lower portions of the lamp 30.

A circular hole 50 is drilled in the center of the first base plate 34. The top of the source mirror holder 38 is inserted into the hole 50.

A semicircular groove 52 is formed at one end of the second base plate 36. A lower portion of the source mirror holder 38 is supported by the semi-circular groove 52.

As such, a source mirror holder 38 having a cylindrical shape is provided between the first base plate 34 and the second base plate 36 so as to be rotatable. That is, a disc support 54 is formed under the source mirror holder 38 so as to coincide with the semicircular groove 52 formed in the second base plate 36. Only half of the disc support 54 is supported by the semicircular groove 52.

Meanwhile, a portion of the cylindrical surface of the source mirror holder 38 is cut in the vertical direction to form a seating surface 40, and the source mirror 42 is adhered to the seating surface 40 by adhering the back surface of the source mirror 42. ) And the lamp 30 can face each other on the optical axis.

On the other hand, the reflection angle adjustment post 44 is fixed to one end of the disc support 54 of the portion that is not supported by the semi-circular groove 52 is fixed.

The front end surface of the reflection angle adjustment post 44 is formed with a front end surface 56 in the axial direction in which the source mirror holder 38 is rotated.

An adjustment screw 46 is provided in front of the front end surface 56 so that the reflection angle adjustment post 44 can be circumferentially moved about the rotation axis of the source mirror holder 38.

The adjusting screw 46 is coupled to the screw holder 48 fixed to the second base plate 36 to move the front end surface 56 of the reflection angle adjusting post 44 while reciprocating in the horizontal direction.

The adjusting screw 46 is formed with a thread 58 limited to the distance traveled by screwing the screw holder 48.

On the other hand, an elastic means 49 is installed between the tip of the reflection angle adjustment post 44 and the lamp holder 32 or the second base plate 36 so that the reflection angle adjustment post 44 is located at the tip of the adjustment screw 46. Exert elastic force to be in close contact.

Hereinafter will be described the operation of the source mirror holder coupling structure according to the present invention.

After assembling the AMA projector according to the present invention, a predetermined error occurs in the reflection angle of the source mirror 42 due to the assembly tolerance.

In the present invention, this can be corrected. The adjustment screw 46 protrudes out of the cage and can be adjusted even after assembly. When the adjusting screw 46 is rotated, the adjusting screw 46 is moved along the thread 58 because the screw holder 48 is fixed.

On the other hand, the elastic means 49 is to maintain the state in which the tip of the reflection angle adjustment post 44 is in close contact with the tip of the adjustment screw 46. In this state, when the tip of the adjusting screw 46 pushes the front end surface 56 of the reflecting angle adjusting post 44, the reflecting angle adjusting post 44 is pushed backward while overcoming the elastic force of the elastic means 49. Flies One end of the reflection angle adjustment post 44 is fixed to the bottom surface of the source mirror holder 38, and the source mirror holder 38 is rotated between the first base plate 34 and the second base plate 36. The reflection angle adjustment post 44 is circumferentially moved around the rotational axis of the source mirror holder 38 because it is coupled as possible. The reflection angle adjusting post 44 is rotated together with the source mirror holder 38, and the source mirror 42 seated at one end of the source mirror holder 38 rotates in one direction while being ramped on the optical axis. The angle facing 30 is changed.

On the other hand, when the adjustment screw 46 is retracted, a restoring force for returning the reflection angle adjustment post 44 to the initial state is generated by the elastic force of the elastic means 49, so that the front end surface 56 is in close contact with the adjustment screw 46. Stay intact.

Thus, even after assembling the AMA projector, the assembly tolerance of the source mirror 42 can be adjusted using the adjustment screw 46, thereby improving the assemblability and maintainability.

As described above, the above description merely illustrates a preferred embodiment of the present invention, and those skilled in the art should recognize that the present invention can be modified and changed without changing the gist of the present invention.

Therefore, according to the present invention, even after assembling the AMA projector, the assembly tolerance of the source mirror can be adjusted using the adjusting screw, thereby achieving an effect of improving assembly and maintainability.

Claims (4)

A first base plate and a second base plate which are arranged in a horizontal direction at one end of the lamp holder to which the lamp is coupled; A source mirror holder mounted in a cylindrical shape rotatably installed between the first base plate and the second base plate; A source mirror installed on a seating surface formed at one end of the source mirror holder; A reflection angle adjustment post fixedly installed at one end of the source mirror holder; An adjustment screw installed to reciprocate in the horizontal direction at the tip of the reflection angle adjustment post to rotate the reflection angle adjustment post and the source mirror holder in a horizontal direction; A source mirror holder coupling structure of an AMA projector comprising elastic means installed between a tip of the reflection angle adjusting post and a lamp holder. 2. The source mirror holder coupling structure of an AMA projector according to claim 1, wherein a circular hole (50) is drilled in a central portion of said first base plate (34). The source mirror holder coupling structure of claim 1, wherein a semicircular groove (52) is formed at one end of the second base plate (36). The source mirror holder coupling structure of claim 1, wherein a disc support (54) is formed under the source mirror holder (38).