KR200358008Y1 - Projection television - Google Patents

Abstract

The present invention relates to a projection television, comprising: a light source unit for emitting light; And a cooling fan mounted on at least one of an upper region and a lower region of the light source unit to cool the light source unit, and cooling air by the cooling fan is introduced into and discharged from the upper and lower surfaces of the light source unit to cool the light source unit. Characterized in that each air passage is formed.

As a result, a cooling fan is provided, and the light source unit can be efficiently cooled by providing an air passage for dissipating heat by using the heat generated from the light source unit moving upward by the convection phenomenon.

Description

Projection television {PROJECTION TELEVISION}

The present invention relates to a projection television, and more particularly, to a projection television that can efficiently cool the light source portion of the projection television.

In general, a projection television is a device that implements a large screen by applying the principle of a projector that projects an image on a screen by using a mirror and an optical lens, and a CRT (Cathode Ray Tube) according to a display element displaying signal processed image information. ), Liquid crystal display (LCD), and digital light processing (DLP).

Such a projection television has a light source unit for supplying light and an optical engine unit for separating and combining light emitted from the light source unit to project an image on a screen.

The light source unit mainly includes arc discharge lamps such as mercury lamps, metal halide lamps, and xenon lamps. Such lamps increase in temperature due to prolonged use, thereby degrading the function of internal circuit components, or partially melting components vulnerable to heat, and shortening the life of the lamp. Therefore, the projection television essentially requires cooling means for cooling the heat emitted from the light source portion.

Accordingly, the projection television disclosed in Korean Patent Application Laid-Open No. 96-19451 cools both the light source and the power splice by providing an electric fan as a cooling means between the light source and the power splice in a forced air cooling method. The fan is mounted on the side region of the light source unit to cool the side surface of the light source unit to generate heat.

By the way, in the light source part cooling structure of the conventional projection television, the electric fan sucks heat emitted from the power splice part and sends it to the light source part to cool the light source part, thereby lowering the cooling efficiency of the light source part.

Accordingly, an object of the present invention is to provide a projection television that can increase the cooling efficiency of the light source unit.

1 is a schematic diagram of a projection television according to the present invention,

Figure 2 is a combined perspective view showing a lamp assembly and an optical engine unit of the projection television according to the present invention,

3 is a partial exploded perspective view of FIG.

4 is an exploded perspective view illustrating main parts of FIG. 3.

* Explanation of symbols for the main parts of the drawings

1: projection television 10: main unit

20 display unit 21 reflector

22 screen 30 lamp assembly

31: light source part 32: front support part 33: rear support part 40: light source receiving part 42: shield 60: optical engine unit 61: optical system 62: panel part 63: projection lens 70: discharge hole

80: cooling fan

According to the present invention, there is provided a projection television, comprising: a light source unit for emitting light; And a cooling fan mounted on at least one of an upper region and a lower region of the light source unit to cool the light source unit, and cooling air by the cooling fan is introduced into and discharged from the upper and lower surfaces of the light source unit to cool the light source unit. This is achieved by forming respective air passages.

Here, the air passing portion is preferably provided to face the upper and lower surfaces of the light source unit, respectively.

The light source unit may include a lamp, a reflector coupled to the lamp to reflect light from the lamp, and a cover provided at the front of the lamp, and the air passage part may be penetrated through the reflector.

Preferably, the cooling fan is a blowing fan provided in a lower region of the light source unit.

Preferably, the cooling fan is a ventilation fan provided in an upper region of the light source unit.

Hereinafter, the projection television according to the present invention will be described in detail with reference to the accompanying drawings.

As shown in FIG. 1, the projection television 1 includes a main body 10 having an optical engine unit 60 therein and an image projected by the optical engine unit 60 provided on the main body 10. The display unit 20 is reflected by the reflector 21 and formed on the screen 22.

2 and 3, a lamp assembly 30 having a light source unit 31 for emitting light, a light source accommodating unit 40 for accommodating the lamp assembly 30, and an interior of the main body 10. A light source housing 50 provided at the rear of the light source accommodating part 40 to protect the light source part 31, a light source housing 50 accommodating the light source accommodating part 40 to which the lamp assembly 30 is coupled, and an optical tunnel. An optical engine unit (60) having an engine (65) for separating and combining light emitted from the lamp assembly (30) and projecting an image on the screen (22), and an engine housing (67) for accommodating the optical engine unit (60). Is provided.

On the other hand, the inside of the main body 10 is provided on the lower side of the lamp assembly 30 and the optical engine unit 60, the base bracket 15 for accommodating the lamp assembly 30 and the optical engine unit 60, and the base bracket ( In the lower region of 15), a cooling fan 80 provided with a blowing fan is mounted to cool the heat generating parts including the light source unit 31.

The lamp assembly 30 includes a light source part 31 having a lamp 34, and a front support part 32 and a rear support part 33 coupled to the front and rear of the light source part 31 to support the light source part 31. It is composed.

The light source unit 31 generally includes an arc discharge lamp such as a mercury lamp, a metal halide lamp, and a xenon lamp.

As shown in FIG. 4, the light source unit 31 is coupled to a lamp 34 that emits light, and a reflector coupled to the lamp 34 to surround the lamp 34 to reflect and focus light from the lamp 34. 35 and a cover 36 provided in front of the lamp 34.

On the other hand, the upper and lower surfaces of the light source unit 31 is formed with an air passage so that the cooling air by the cooling fan 80 is introduced and discharged to cool the light source unit 31.

The air passage part is formed in the lower surface of the light source unit 31 and is formed in the inlet hole (not shown) into which the cooling air generated by the cooling fan 80 flows, and is formed in the upper surface of the light source unit 31 and introduced from the inlet hole. A discharge hole 70 through which cooling air is discharged between the reflector 35 and the cover 36 is formed. Here, the high temperature heat generated from the light source unit 31 is moved upward by the convection phenomenon, at which time the heat of the light source unit 31 can be efficiently discharged to the upper portion by the cooling fan 80. At this time, the heat moved to the upper portion of the light source unit 31 is discharged to the outside through the lamp duct 38 provided in the upper region.

At this time, it is preferable that the discharge hole 70 is provided on the upper surface of the light source unit 31 so as to face the inlet hole so that the cooling air that has cooled the light source unit 31 through the inlet hole is efficiently discharged to the discharge hole 70. . On the other hand, the inflow hole and the discharge hole 70 are formed to penetrate the reflector 35 of the light source unit 31 to a size capable of efficiently dissipating heat. Here, the shape of the air passage portion is not limited to the shape shown in the drawings and can be variously changed within a range in which heat can be efficiently discharged without leaking light from the light source unit 31.

The light source accommodating part 40 has a receiving space 40a formed to receive the light source part 31 supported by the front support part 32 and the rear support part 33, and the light of the light source part 31 passes through the front part 32. The opening 41 is formed. On the other hand, through portions 40b and 40c are formed in upper and lower portions of the light source accommodating part 40 so that cooling air generated by the cooling fan 80 flows toward the light source part 31.

The light source housing 50 is provided to correspond to the shape of the light source accommodating part 40 to accommodate the light source accommodating part 40, and is formed to face the through parts 40b and 40c of the light source accommodating part 40, respectively. The through parts 50b and 50c through which the cooling air passes are formed therethrough.

Accordingly, the cooling air from the cooling fan 80 flows into the inlet hole of the light source unit 31 after passing through the through portions 50c and 40c of the light source housing 50 and the light source accommodating portion 40, respectively. On the other hand, the cooling air introduced into the light source unit 31 cools the light source unit 31 and exits to the discharge hole 70, passing through the light source accommodating part 40 and the through parts 40b and 50b of the light source housing 50. It is discharged to the outside through the lamp duct 38 provided on the upper side of the lamp assembly (30).

The optical engine unit 60 is an assembly of a system for projecting an image, and is composed of an optical system 61, a DLP panel portion 62, a projection lens 63, and the like.

The optical system 61 is provided inside the engine housing 67 and separated by a UV filter (not shown) and a UV filter (not shown) for selectively passing only the visible light region (λ = 415 nm to 780 nm) of light. Dichroic Mirror which separates and reflects the optical tunnel 65 through which the light passes and the RGB of the light passing through the optical tunnel 65 so as to enter each pixel of the panel unit 62 only. And a lens group 66 having a micro lens or the like.

The panel unit 62 is provided with a digital micromirror device (DMD) device, and modulates an image from light incident from the lens group 66 by adjusting a reflection angle for each pixel.

The projection lens 63 projects the image modulated by the panel unit 62 to the reflector 21, and the reflector 21 reflects the image back to the screen 22 to form an image on the display unit 20. FIG.

Fan holders 81 supporting the cooling fan 80 are coupled to the cooling fan 80 at both sides of the cooling fan 80, and between the fan holder 81 and the cooling fan 80 of the cooling fan 80. The vibration absorber 83 which absorbs vibration is inserted. On the other hand, the cooling fan 80 supported by the fan holder 81 is slidingly coupled to the fan housing 82 provided below the base bracket 15.

In the above-described embodiment, the cooling fan 80 for cooling the light source unit 31 is provided as a blowing fan in the lower region of the light source unit 31, but may be provided as a ventilation fan in the upper region of the light source unit 31. In this case, the flow of cooling air by the fan is the same as when the fan is provided.

On the other hand, it is of course possible to increase the cooling efficiency of the light source unit 31 by mounting a fan and a blowing fan in the upper region and the lower region of the light source unit 31, respectively.

In addition, in the above-described embodiment, the panel unit 62 uses a digital micromirror device (DMD) device, but an image may be formed by a liquid crystal display (LCD) or a liquid crystal on silicon (LCOS) device.

As described above, according to the present invention, a cooling fan is installed, and the light source unit can be efficiently cooled by providing an air passage for dissipating heat by using heat generated from the light source unit moving upward by convection. Projection television is provided.

Claims (5)

In projection television, A light source unit emitting light; A cooling fan mounted on at least one of an upper region and a lower region of the light source unit to cool the light source unit, And an air passing portion through which the cooling air by the cooling fan flows in and out of the upper and lower surfaces of the light source unit so as to cool the light source unit. The method of claim 1, And the air passing portion is provided to face the upper surface and the lower surface of the light source unit, respectively. The method of claim 2, And the light source unit includes a lamp, a reflector coupled to the lamp to reflect light from the lamp, and a cover provided in front of the lamp, wherein the air passing part is formed through the reflector. The method according to any one of claims 1 to 3, And the cooling fan is a blowing fan provided in a lower region of the light source unit. The method according to any one of claims 1 to 3, And the cooling fan is a ventilation fan provided in an upper region of the light source unit.