KR100564398B1 - Cooling device of the light source in the projection television - Google Patents

Abstract

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a light source cooling apparatus of a projection television, wherein a plurality of endothermic separation plates are arranged and supplied with power to radiate a light source lamp without generating noise and dust, and to prevent ultraviolet rays from being emitted to the outside. ; A heat dissipation rail electrically connecting the thermoelectric element and connecting the endothermic separation plate in a predetermined path; An insulating sheet installed on an upper portion of the heat dissipation rail to increase thermal conductivity; And a heat sink provided on top of the insulating sheet and including heat sinks having heat dissipation fins, so that the endothermic separator is aligned and sealed to one side of the casing to generate a light source cooling device of the projection television, which is generated in a cooling fan by using a thermoelectric module. It can have a non-powered cooling effect that the noise and dust is blocked, there is an effect that can fundamentally block the ultraviolet rays of the light source to be emitted to the outside.

Projection TV, LCD, Cooling, Thermoelectric Elements

Description

COOLING DEVICE OF THE LIGHT SOURCE IN THE PROJECTION TELEVISION}

1 is a schematic cross-sectional view showing a light source cooling apparatus of a conventional projection television.

2 is a detailed view of a light source of a conventional projection television.

Figure 3 is a schematic diagram for explaining the principle applied to the present invention.

4 is an exploded perspective view of a light source cooling apparatus according to the present invention.

<Description of Symbols for Main Parts of Drawings>

60: light source 65: casing

120: thermoelectric module 122: endothermic separation

130: heat dissipation rail 140: insulation sheet

150: heat sink 155: heat dissipation fin

The present invention relates to a light source cooling apparatus of a projection television, and more particularly, to a light source cooling apparatus of a projection television, in which a heat dissipation casing is installed on a lamp that is a light source of a projection television using an LCD to provide a noiseless and non-powered cooling device. It is about.

As a display device that is widely used for home use, a television is classified into a direct view type image display device using a CRT and a projection type image display device using an LCD.

The direct view type image display device uses a CRT and is called a CRT, which has been subject to limitations due to the enlargement of the screen due to problems with the degree of vacuum between the light source and the CRT itself. In recent years, projection televisions have been developed in which three tri-color cathode ray tubes emit light independently and enlarge and reflect them, thereby projecting and displaying them on a separate screen.

In addition, as a projection image display apparatus, a television in which an LCD is used to replace a CRT in order to overcome a difficulty in vacuum degree for the enlargement constrained in the projection television is called a liquid crystal display system.

In the CRT type and LCD type projection televisions, a light source is used, and since heat is generally generated in the light source, a heat radiating device must be used.

In particular, LCD type projection televisions have become a key issue in that heat dissipation measures are directly related to the enlargement and performance of products due to the characteristics of heat sensitive liquid crystal devices.

Referring to FIG. 1 to explain heat dissipation of a light source in the LCD type projection television, an optical system 20 is installed inside the main body 10 of the projection television, and a high-power lamp is built into the optical system 20 to provide a light beam. And the emitted light beam is projected onto the screen 30 via an LCD panel in the optical system 20.

One or more heat dissipation fans 40 are installed inside the main body 10 for cooling between the high power lamp and the LCD element. In addition, the heat dissipation fan 40 is installed in communication with the heat dissipation duct 50 so that the high-temperature air flow radiated from the optical system 20 is guided to the outside without remaining in the main body 10.

A detailed view of the ultra high power lamp (UHP) is shown in FIG. 2.

The lamp 60 is embedded inside the casing 65 to be protected from impact, and a plurality of heat dissipation holes 70 are installed above the casing 65 to flow the exothermic air of the lamp 60. The housing 45 of the heat dissipation fan is installed above the heat dissipation port 75.

In the structure as described above, the lamp 60 is a light source and the main heat generating unit must be installed as a heat radiating fan 40, bar and noise caused by the heat radiating fan 40 is pointed out as a disadvantage of the projection television If it is used for a long time, the performance may be degraded by dust.

In addition, ultraviolet rays generated from the lamp 60 of high power may be emitted through the heat dissipation port 70 of the casing 65, and may be emitted to the outside of the main body 10.

The present invention has been invented to solve the above problems, an object of the present invention to provide a light source cooling device of a projection television that radiates a light source lamp without generating noise and dust, etc. and does not emit ultraviolet rays to the outside. It is for.

In order to achieve the above object, the present invention provides a projection television having a casing with a built-in high-temperature light source, a plurality of endothermic separation plates are arranged in which a pair of thermoelectric modules are supplied with power; A heat dissipation rail electrically connecting the thermoelectric element and connecting the endothermic separation plate in a predetermined path; An insulating sheet installed on an upper portion of the heat dissipation rail to increase thermal conductivity; And it provides a light source cooling device of a projection television that is installed on top of the insulating sheet and including a heat sink in which heat radiation fins are formed, the endothermic separator is aligned and sealed on one side of the casing.

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

Figure 3 is a schematic diagram for explaining the Peltier device, that is, the thermoelectric module 120 applied to the present invention, the thermoelectric module 120 is a different type of semiconductor or conductor, as is known p-type semiconductor (p) and n-type semiconductor When a current is conducted to the contact point (n), the cooling device module using the Peltier effect generates heat and absorption of heat at the contact point 110 at the same time.

When the current flows to each of the semiconductors n and p as shown in FIG. 3, since the heat of the high temperature is absorbed from the heat absorbing portion 112 at the lower side, the heat absorbing portion 112 is the lamp 60 which is a high temperature light source. Since it is installed adjacent to the heat insulating through the insulator 114 and the heat sink 116 of the upper side.

A preferred embodiment of the present invention according to the thermoelectric module 120 is shown in FIG. 4.

In the light source cooling apparatus according to the present invention, the endothermic separator 122 is installed at one side, preferably the upper side, of the casing 65 in which the lamp 60 is embedded, and the endothermic separator 122 is a pair of semiconductors n. , p) are arranged in plural, and are installed to supply power to one side. In FIG. 4, the endothermic separation plate 122 is illustrated as being installed on the upper side of the casing 65, but may be installed on a plurality of surfaces including the upper side of the casing 65 in order to improve the heat dissipation effect.

In addition, an upper side of the thermoelectric module 120 is electrically connected to the thermoelectric module 120 and a heat dissipation rail 130 for connecting the endothermic separation plate 122 in a predetermined path is installed.

As shown, the heat dissipation rail 130 is installed in such a manner as to interconnect the respective thermoelectric modules 120, which will be described in more detail, the thermoelectric module 120 to the upper side of the thermoelectric module 120. The heat dissipation rail 130 is aligned with the heat absorbing separation plate 122 so as to electrically connect the heat dissipation separation plate 122. That is, among the pair of semiconductors n and p of the thermoelectric module 120 disposed on the endothermic separation plate 122, the thermoelectric element n on one side is connected to the heat radiation rail 130 on one side, and the thermoelectric element p on the other side. The other side of the heat dissipation rail 130 is connected, one pair of thermoelectric modules 120 disposed on one endothermic separation plate 122 is connected to each other heat dissipation rail 130, so that the thermoelectric module 120 as a whole It will form a closed circuit.

In addition, an insulating sheet 140 is installed above the heat dissipation rail 130 to increase thermal conductivity and insulate the current of the heat dissipation rail 130. The insulating sheet 140 is installed in the same manner as the heat dissipation rail 130 so that the heat dissipation rail 130 is insulated while forming a closed circuit.

Thus, the heat sink 150 having the heat dissipation fins 155 is provided on the insulating sheet 140 to finally discharge the heat of the heat absorbing separator 122 to the outside of the casing 65.

In the cooling device configured as described above, since the heat conduction path is completely configured in the casing 65, a separate opening is unnecessary, so that the casing 65 is sealed so that ultraviolet rays of the lamp 60 are not emitted to the outside. Can be configured.

On the other hand, in the cooling device capable of sealing as described above, an insulating plate may be installed to quickly improve the thermal conductivity between the endothermic separation plate 122 and the casing (65). Such an insulating plate is composed of an endothermic plate installed in close proximity to the high temperature light source, and an insulating plate for conducting the high temperature of the endothermic plate to the endothermic separation plate 122.

The operation of the present invention configured as described above will be described.

One side of the casing 65 installed in the projection television to which the present invention is applied is provided with a transparent window so that light of the high power lamp 60 as a light source is transmitted, and the remaining circumference is hermetically sealed and ultraviolet rays dropped from the lamp 60 are casing 65. By not being emitted outside of), the ultraviolet rays which can be emitted from the projection television are essentially blocked.

In the projection television as described above, when the power is turned on and operated, the lamp 60 generates heat while power is supplied to the endothermic separation plate 122 installed on the upper side of the casing 65. The power is branched from a ballast PCB that supplies power to the lamp 60.

The electric current is conducted to the semiconductors n and p of the thermoelectric module 120 disposed on the endothermic separation plate 122 by the power supply as described above, and the currents are connected to the semiconductors constituting the pair of thermoelectric modules 120 different from each other. By backing, an endothermic phenomenon appears from the endothermic separation plate 122.

Heat absorbed by the endothermic separation plate 122 due to the endothermic as described above is conducted to the heat dissipation rail 130 through the thermoelectric module 120, and the heat dissipation rail 130 is formed of different semiconductors from adjacent thermoelectric modules 120. By interconnecting, a plurality of thermoelectric modules 120 may form a path of a constant current.

As the current flows through the plurality of thermoelectric modules 120 as described above, the high heat of the lamp 60 is conducted through the heat dissipation rail 130 to be conducted to the upper insulating sheet 140. The insulating sheet 140 insulates the electric current flowing through the heat dissipation rail 130 from being shorted to the outside and at the same time, conducts high heat of the heat dissipation rail 130 quickly.

Thus, the high heat conducted through the heat dissipation rail 130 is finally conducted to the heat sink 150 through the insulating sheet 140, so that the heat sink 150 maximizes heat conduction and releases heat into the air. Since the heat dissipation fin 155 having the optimal shape is formed, the heat conducted to the insulating sheet 140 is conducted through the heat sink 150 and finally emits high heat to the outside of the casing 65.

The heat conduction path as described above will be described in more detail. In the thermoelectric module 120 where the power is turned on when heat is generated from the lamp 60 while the projection television is operated, the endothermic phenomenon of the plurality of endothermic separation plates 122 is caused by the Peltier effect. The generated and endothermic heat is transferred to the heat dissipation rail 130 on the upper end of the heat absorbing separation plate 122 and finally transferred to the heat sink 150 through the insulating sheet 140. The transferred high heat is convection or radiated out of the casing 65 by the air flow in the heat radiation fin 155 of the heat sink 150.

On the other hand, as shown on the heat conduction path, the casing 65 can be sealed to the outside of the casing 65 because the endothermic separation plate 122 can be built into the casing (65).

Thus, ultraviolet rays emitted by the lamp 60 inside the casing 65 are not emitted outside the casing 65. Of course, in order to protect the inner wall of the casing 65 may be a UV protection coating inside the casing (65).

As described above, in the cooling apparatus of the present invention, a plurality of endothermic separation plates 122 are installed to absorb high heat from the lamp 60 of the projection television by using the cooling and endothermic phenomenon by the Peltier effect, and the high heat absorbed therefrom is insulated. It is characterized by cooling the high temperature lamp 60 by heat dissipating to the heat sink 150 through the sheet 140, and furthermore, the casing 65 in which the lamp 60 is embedded is sealed to fundamentally block ultraviolet rays. Have

The light source cooling apparatus of the projection television of the present invention can have a non-powered cooling effect in which noise and dust generated in the cooling fan are blocked by using a thermoelectric module, and can fundamentally block ultraviolet rays emitted from the light source to the outside. It works.

Claims (4)

delete A projection television is formed on one side of the casing in which the high-temperature light source is embedded, and a pair of thermoelectric modules are disposed on one side of the casing in which the through-hole is formed, and the projection television includes a plurality of endothermic separators to which power is supplied. A plate for rapidly thermally conducting high temperature of the light source between the casing and the endothermic separation plate; A heat dissipation rail electrically connecting the thermoelectric module installed at the upper side of the plate and connecting the endothermic separation plate in a predetermined path; An insulating sheet installed on an upper portion of the heat dissipation rail to increase thermal conductivity; And a heat sink having a heat dissipation fin formed on an upper portion of the insulating sheet. 3. The light source cooling of a projection television according to claim 2, wherein the plate is composed of an endothermic plate which is installed in close proximity to the high temperature light source, and an insulating plate which conducts the high temperature of the endothermic plate to the endothermic separator 122. Device. 3. The light source cooling device of a projection television as set forth in claim 2, wherein said endothermic separation plate (122) is provided on a circumferential surface of said casing (65).

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