KR100798598B1 - The cooling apparatus of the projecting display apparatus - Google Patents

Abstract

According to an aspect of the present invention, there is provided a cooling apparatus of a projection display device, including: a power generation unit attached to a specific portion where heat of a system itself is generated; Power supply adjusting means for controlling a current generated in the power generating section; The power regulated by the power control means is input and includes a cooling unit attached to a portion of the system to be cooled.

Here, the system is a liquid crystal projector, and the power generation unit includes an element attached to a specific portion of heat generated in the system, and a heat sink attached to an opposite surface of the element.

Here, the power adjusting means includes a power adjusting unit to which the DC power generated by the power generating unit is input; A sensor for sensing a temperature or humidity of a cooling part of the system attached to the cooling part; It is provided with a microcomputer for controlling the power control unit via the information signal of the temperature or humidity in the sensor.

The cooling unit includes an element attached to a portion to be cooled in the system and a heat sink attached to an opposite surface of the element.

As described above, the present invention can reduce the space occupied by the power supply unit when the thermoelectric device is applied since an independent power supply unit is not required, and can reduce power consumption of the product by using unnecessary heat generated inside the system.

In addition, the manufacturing cost can be reduced accordingly.

Description

The cooling apparatus of the projecting display apparatus

1 is a view showing the principle of operation of a general thermoelectric element.

2 is a view showing a cooling device of the projection display device according to the present invention.

Explanation of symbols on the main parts of the drawings

210: power generator 211: first thermoelectric element

212: first heat sink 220: power control means

221: power control unit 222: microcomputer

223: sensor 230: cooling unit

231: second thermoelectric element 232: second heat sink

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a liquid crystal projector or a cooling device for a liquid crystal projection, and more particularly, to a cross section of another thermoelectric element by using electromotive force generated by the heat by attaching a thermoelectric element to a high temperature portion inside the liquid crystal projector system to generate electric power. The present invention relates to a cooling device of a projection display device which cools by forming a low temperature in the cooling zone and attaching the low temperature end surface to a portion to be cooled.

The optical engine of a liquid crystal projector or a liquid crystal projection mainly consists of an illumination system using a lamp as a light source, an optical system composed of a series of optical components, and a synthetic system composed of liquid crystals and optical components.

In particular, the lighting system including the lamp is composed of a high-power lamp, an accessory, and an optical component as a light source. In the high-power lamp, a fixture that fixes and protects the lamp due to strong light and heat becomes hot, and thus a material having high heat resistance is used. .

Nowadays, engine and system development technology of projector or projection is focused on miniaturization and high brightness.

Therefore, various technical difficulties are encountered, and one of them is the increase in exothermic density per unit volume due to miniaturization and cooling due to the use of a high power light source.

This cooling problem can be divided into two types: first, the whole system cooling by forced convection, and second, local cooling related to image quality and reliability.

Particularly, the parts requiring local cooling are synthesized systems including polarizers and liquid crystals and chips that process signals at high speed.

Conventionally, forced convective cooling has been mainly applied, and recently, liquid cooling or thermoelectric device technology has been actively applied for cooling synthetic systems.

In addition, the heat sink is attached for cooling the chip, but due to the increase in the signal to be processed per unit time as the performance of the product is required to increase, it is difficult to maintain the management temperature required for the stable operation of the chip with the heat sink. .

1 shows the principle of operation of a general thermoelectric element.

Referring to FIG. 1, the operating principle of the thermoelectric device is that the electromotive force is generated inside the device when there is a temperature difference at both ends of the device. First, as shown in FIG. They have a higher kinetic energy than the electrons in the low temperature unit 120 is diffused to the low temperature unit 120 so that the low temperature unit 120 is charged to '-' and the high temperature unit 110 is charged to '+' to generate a potential difference.

On the contrary, when DC power is supplied by applying a potential difference as shown in FIG. 1 (b), the thermoelectric element plays a role of a kind of heat pump. A temperature difference occurs between both ends, and one side becomes cold and the other side becomes hot. We use for.

The use of thermoelectric elements for local cooling of liquid crystal projectors or liquid crystal projections requires additional power, which requires additional capacity of the system power supply, causing the following problems.

First, the additional power generation increases the power consumption of the product.

Second, the increased capacity of the power supply requires additional cost and space.

Third, increase the amount of heat generated by the power supply.

Fourth, the noise increases due to the increased flow rate for cooling the power supply.

There is a need for the use of a thermoelectric device for the above reasons, but due to the greater side effects are not actively applied.

 SUMMARY OF THE INVENTION The present invention has been made to solve the above problems, by attaching a thermoelectric element to a high temperature portion of an inside of a liquid crystal projector system to generate electric power, thereby utilizing the electromotive force generated by the heat on one cross section of another thermoelectric element. It is an object of the present invention to provide a cooling apparatus using unnecessary heat inside a system that forms a low temperature and attaches and cools a cross section of the low temperature to a portion to be cooled.

In order to achieve the above object, a cooling device of a projection display device according to the present invention includes: a power generation unit attached to a specific portion where heat of a system itself is generated;

Power supply adjusting means for controlling a current generated by the power generation unit;

The power controlled by the power control means is input, characterized in that it comprises a cooling unit attached to the portion to be cooled of the system.

Here, the system is a liquid crystal projector, characterized in that the power generating unit has an element attached to a specific portion of the heat generated in the system, and a heat sink attached to the opposite surface of the element.

Here, the power control means includes a power control unit for inputting the DC power generated by the power generation unit;

A sensor for sensing a temperature or humidity of a cooling part of the system attached to the cooling part;

Characterized in that the microcomputer for controlling the power control unit via the information signal of the temperature or humidity in the sensor.                     

In addition, the cooling unit is characterized in that it comprises a device attached to the portion to be cooled in the system, and a heat sink attached to the opposite surface of the device, characterized in that the device is a thermoelectric element.

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

2 shows a cooling apparatus of the projection display device according to the present invention.

Referring to FIG. 2, the cooling device of the projection display device according to the present invention attaches a lower surface to a hot part of a system to form a high temperature surface, and thus the upper surface of the opposite side is formed with a relatively low temperature surface, and thus a temperature difference thereof. Power having a first thermoelectric element 211 for generating electromotive force by the first heat sink and a first heat sink 212 for cooling heat generated on a low temperature surface by movement of electrons by electromotive force of the first thermoelectric element 211 A generator 210; The power controller 221 adjusts the current input from the power generator 210, a sensor 223 for sensing temperature and humidity, and the power controller through a signal received from the sensor 223. Power control means 220 having a microcomputer 222 for controlling 221; The second thermoelectric element is formed by the DC power input through the power control unit 221 of the power control means 220, the upper surface is formed of a high temperature surface and the lower surface of the opposite side forms a relatively low temperature surface 231 and a cooling unit 230 having a second heat sink 232 cooling the high temperature surface of the second thermoelectric element 231.

The bottom surface of the first thermoelectric element 211 is attached to a hot portion of a system.

Then, the bottom surface of the first thermoelectric element 211 is formed at a high temperature, the upper surface of the opposite side is relatively low temperature, the electrons of the lower surface is moved to the upper surface, the upper surface is'-'and the lower surface is' It is charged to + 'and electromotive force is generated by the potential difference between the two ends, and the electrons diffuse again.

At this time, the first heat sink 212 is attached on the top surface of the first thermoelectric element 211 in order to prevent the temperature rise due to the movement of electrons on the top surface of the first thermoelectric element 211.

Electrons diffused from the first thermoelectric element 211 flow to the power control unit 221 of the power control unit 220.

The sensor 223 is attached to a specific part of the system to be cooled to sense temperature and humidity.

The microcomputer 222 controls the DC power supplied to the power control unit 221 by using the input signal information on the sensor.

The DC power from the power control unit 221 flows into the cooling unit 220.

The upper surface of the second thermoelectric element 231 of the cooling unit 220 becomes high temperature and the lower surface of the second thermoelectric element 231 flows from the power control unit 221.

The second heat sink 232 is attached on the top surface to prevent the temperature of the top surface of the second thermoelectric element 231 from rising.

Cooling may be performed by attaching a specific portion of the system to be cooled on the lower surface, which is the low temperature surface of the second thermoelectric element 231.

As described above, the cooling device of the projection display device according to the present invention does not need an independent power supply unit, thereby reducing the space occupied by the power supply unit when the thermoelectric device is applied, and reducing the power consumption of the product by using unnecessary heat generated inside the system. Can be.

In addition, the manufacturing cost can be reduced accordingly.

Claims (6)

A power generator including a first thermoelectric element forming a lower end as a high temperature surface and a first heat sink configured to cool the heat due to electromotive force generated by the first thermoelectric element; Power control means for controlling a current generated by the power generation unit; And A cooling unit including a second thermoelectric element having an upper end formed at a high temperature surface and a lower heat sink having a second heat sink configured to cool the upper end of the second thermoelectric element; Cooling device of the projection display device comprising a. The cooling device of a projection display device according to claim 1, wherein the system is a liquid crystal projector. The cooling apparatus of claim 1, wherein the power generation unit includes an element attached to a specific portion of heat generated in the system and a heat sink attached to an opposite surface of the element. The apparatus of claim 1, wherein the power control unit comprises: a power control unit to which DC power generated by the power generation unit is input; A sensor for sensing a temperature or humidity of a cooling part of the system attached to the cooling part; And a microcomputer for controlling the power control unit through an information signal of temperature or humidity from the sensor. The cooling apparatus of claim 1, wherein the cooling unit includes an element attached to a portion to be cooled in the system and a heat sink attached to an opposite surface of the element. The cooling device of a projection display device according to claim 3 or 5, wherein the element is a thermoelectric element.

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