KR20030059700A - Device for cooling passage temperature variable-type of projecter LCD - Google Patents

Abstract

PURPOSE: A temperature-variable type cooling path device used in an LCD projector is provided to reduce noise generated due to high-speed rotation of suction/exhaust fans by applying the cooling path device to a photosynthesis system. CONSTITUTION: A temperature-variable type cooling path device includes an air suction part(2) forming a fluid path for sucking air by means of a suction fan, air paths and an air exhaust part(4). The air paths are communicated with the air suction part(2) and are positioned in a photosynthesis system. Size of the air paths is varied depending on a temperature of three liquid crystal panels. The air paths are divided into three fluid paths in order to cool three liquid crystal panels, respectively. The air exhaust part(4) is communicated with the air paths so as to discharge air to an exterior by means of an exhaust fan.

Description

Device for cooling passage temperature variable-type of projecter LCD

The present invention relates to an LCD projector, and more particularly, a region in which a lot of heat is generated in the projector, that is, three condensing lenses and a liquid crystal panel installed corresponding to the condensing lens, and the condensing lens and the liquid crystal panel and the liquid crystal panel. By applying a cooling channel device having a variable size of air flow path according to temperature to a photosynthesis system composed of polarizing filters installed between each prism, not only cooling the entire elements of the photosynthesis system, but also in particular at different wavelengths. When the temperature of any one of the three liquid crystal panels displaying images of each color in response to the color signal is supplied, the largest portion of the panel portion is the temperature of which is raised through an air channel whose size is changed according to the elevated temperature. The cooling system of variable temperature cooling system of LCD projector that can achieve the optimal cooling effect by flowing cooling airflow will be.

In general, an LCD (Liquid Crystal Display) projector is an image device that implements a very large screen by projecting light from a lamp onto a screen, which is an LCD projector optical engine that is fired by forming a certain image therein as shown in FIG. 100 and a projection lens 95 for controlling and adjusting the image to be projected in a desired size and direction, and in particular to the LCD panel 81, 82, 83 using the lamp 10 as a light source. The LCD projector optical engine 100, which is an apparatus that causes an image to form and emits the image, includes a lamp 10 having white light generated therein and a reflector for collecting white light generated by the lamp 10 and reflecting it in one direction. And a FEL (Fly Eye Lens) lens unit 30 for matching the illumination area of the white light reflected through the reflector 20 to the size of the LCD panel and equalizing the light intensity. In the lens unit 30 Total reflection mirrors 41, 42, 43 and 44 for reflecting the white light, a condenser lens 50 for correcting the straightness of the light, and a dichro for passing light of a certain color and reflecting all other light. Dichroic lenses (71, 72, 73) in which a predetermined color of light passing through the dichroic mirrors (61) and (62) and the dichroic mirrors (61) and (62) is once again filtered. And LCD panels 81, 82, 83, which are activated by light of a predetermined color passing through the dichroic lenses 71, 72, 73, and the LCD panels 81, 82 ( 83 is composed of a dichroic prism 90 in which a constant color image is combined and converted into a complete image.

Referring to the operation of the LCD projector configured as described above, first, the white light generated in the lamp 10 of the components of the LCD projector optical engine 100 and emitted in one direction by the reflector 20 is the FEL lens unit 30. It is adjusted at and then reflected on the total reflection mirror 41 and passes through the condenser lens 50. Thereafter, the white light passes through only the red color in the dichroic mirror 61 and reaches the LCD panel 81 through the total reflection mirror 42 and the dichroic lens 71. 81 is activated to generate an image corresponding to red color.

In addition, the light from which the red color is removed from the dichroic mirror 61 passes through the blue light and the green light is reflected by the next dichroic mirror 62. The green light is the dichroic lens 72. After reaching the LCD panel 82, the LCD panel 82 to which the green light is incident is activated to generate an image corresponding to the green color. The blue light passing through the dichroic mirror 62 reaches the LCD panel 83 through the total reflection mirrors 43 and 44 and the dichroic lens 73. By activation, an image corresponding to blue color is generated. In this way, the red, green, and blue images generated by the three LCD panels 81, 82, and 83 are combined by the dichroic prism 90 and converted into a complete image.

However, in order to operate the conventional LCD projector as described above, the lamp 10 generating high brightness light among the components of the LCD projector, and the energy density emitted by the lamp 10 through the mirrors and the lenses, are significantly increased. Polarization filters (polarizing plates) 30a, 71a, 72a, 73a, 81b, 82b, 83b that pass only vertical or horizontal waves of elevated light, and the polarization filters 30a, 71a, 72a, 73a, 81b, 82b, 83b In response to the supply of three-color signals of different wavelengths passing through, a large amount of heat is generated in the liquid crystal panels 81, 82, and 83 that display images of each color, and in particular, the polarization filters 30a, 71a, 72a, 73a, In the case of 81b, 82b, and 83b or the liquid crystal panels 81, 82, and 83, the filter itself or the elements constituting the panel have a very weak characteristic of heat, which requires a great deal of attention to their cooling.

Thus, the air sucked by the intake fan 120 in the main portion (photosynthetic system) that requires cooling as described above to cool the main portion while forming a constant flow path 140, and then by the exhaust fan 160 The cooling flow path device 110 configured to exhaust the air cooling the main portion is mounted to cool the photosynthetic system area where the heat is generated by the air flowing through the cooling flow path device 110. Reference numeral 110 shows three condensing lenses 71, 72 and 73 constituting the photosynthetic system shown in FIG. 2 and liquid crystal panels 81, 82 and 83 corresponding to the condensing lenses 71, 72 and 73, and Polarizing filters 71a, 72a, 73a provided between the condenser lenses 71, 72, 73 and the liquid crystal panels 81, 82, 83, and the liquid crystal panels 81, 82, 83, and the synthetic prism 90, respectively; In order to cool the 81b, 82b, and 83b, as shown in FIG. When air is sucked into the air 130, the air is supplied to the three condensing lenses 71, 72, and 73, the liquid crystal panels 81, 82, and 83, and the polarization filters 71a, 72a, 73a, 81b, and 82b, Cooling the photosynthetic system while flowing through the three air paths 140, which are formed to face 83b), and then flows to the exhaust unit 150, which is one flow path, is installed in the exhaust unit 150. It is configured to be discharged by the exhaust fan 160.

In particular, since the air flow paths 140 formed to face the photosynthetic system of the cooling flow path device 110 configured as described above have a fixed structure, the temperature of the photosynthetic system through a temperature sensor when the temperature of the photosynthetic system rises. Detects and increases the rotational speed of the intake / exhaust fan 120 and 160 installed in the intake unit 130 and the exhaust unit 160 to be sucked and discharged through the intake unit 130 and the exhaust unit 160. Increasing the amount of air, to increase the overall cooling efficiency of the photosynthetic system, which will be described in addition as follows.

As shown in FIG. 4, assuming that the amount of air sucked into the intake unit 130 through the intake fan 120 at room temperature is V _T , the air flow path passes through the intake unit 130. The amount of air flowing through the field 140 to the photosynthetic system is V _T / 3, and the amount of air flowing into the exhaust unit 150 which is one flow path and finally discharged by the exhaust fan 160 is the intake unit 130. V _{T, which} is equal to the amount of air sucked into), is due to an increase in the internal temperature in a conventional projector or an average amount of light transmitted from each panel 81, 82, 83 depending on image conditions, or other factors. the result when the temperature of the photosynthetic system increases, the intake fan 120 that the total amount of V _T of the air is to be sucked into the intake unit 130, the V _T of the air total amount of suction as described above, elements of the photosynthetic system through Flow into the three air flow paths 140 formed to face the Standing V _T / 3 each divided cooling the condenser lens (71, 72, 73 and the liquid crystal panel 81, 82, 83), the polarization filters (71a, 72a, 73a, 81b , 82b, 83b) of the photosynthetic system in Then, the air divided into V _T / 3 while flowing to the exhaust unit 150, which is one flow path, is added to the same volume as V _T , which is the total amount of air initially sucked into the intake unit 130, to exhaust unit 150. It is discharged by the exhaust fan 160 installed in).

At this time, the temperature of any one of the elements of the photosynthetic system (where one is referred to here) receives blue light having a shorter wavelength among three liquid crystal panels 81, 82, and 83 according to the supply of color signals of different wavelengths. The blue liquid crystal panel 83 whose temperature is higher than the other liquid crystal panels 81 and 82 by the energy generated when the image is displayed, the temperature of the raised liquid crystal panel 83 is cooled. In order to increase the rotational speed of the intake / exhaust fan 120, 160 installed in the intake 130 and the exhaust 150 of the cooling flow path device 110 to intake air through the intake 120 because the total amount of V _T increases up and cool the entire liquid crystal panel 83, the temperature is increased by the increased air, and photosynthesis system, as shown in FIG.

However, in the cooling method of cooling the photosynthetic system using the cooling channel apparatus 110 as described above, the intake / exhaust fans 120 and 160 should be rotated at high speed as the temperature around the photosynthetic system becomes higher. In addition, the noise caused by the rotation of the intake / exhaust fan (120, 160) is greatly increased, in particular, when the temperature rise of the liquid crystal panel 83 of a specific portion of the photosynthetic system, the liquid crystal In order to cool the panel 83, there is a big problem that inefficient cooling is achieved based on other parts of the photosynthetic system in which the temperature is not excessively increased, such as increasing the air volume of air to cool the entire photosynthetic system. there was.

In addition, in the case of cooling the photosynthesis system under general cooling conditions without increasing the amount of air as described above, in contrast to the above-described problems, optimum cooling of the liquid crystal panel 83 of a specific portion of the photosynthesis system in which the temperature is excessively increased There was also a big problem that the liquid crystal panel 83 is damaged by high temperature is not made accordingly.

In order to solve the above problems, the present invention provides a heat generating area in the projector, that is, three condensing lenses and a liquid crystal panel installed corresponding to the condensing lens, and the condensing lens and the liquid crystal panel and the liquid crystal panel; By applying a cooling flow path device having a variable size of air flow path according to temperature to a photosynthesis system composed of polarizing filters provided between the respective synthetic prisms, it not only cools all the elements constituting the photosynthesis system, but also in particular at different wavelengths. When the temperature of any one of the three liquid crystal panels displaying images of each color in response to the three-color signal supply increases, the panel portion whose temperature is increased through the air channel whose size varies according to the elevated temperature The purpose of the present invention is to achieve an optimal cooling effect by flowing the cooling airflow of the.

In addition, by applying a cooling flow path apparatus of which the air flow path is variable according to the temperature of the photosynthesis system as described above to the photosynthesis system that generates a lot of heat in the projector, it is possible to achieve high-speed rotation of the intake / exhaust fan that is generated during the conventional photosynthesis system cooling. Another purpose is to reduce the noise.

The object of the present invention is a photosynthesis system comprising three condensing lenses and a liquid crystal panel installed corresponding to the condensing lens, and a polarizing filter provided between the condensing lens and the liquid crystal panel and the liquid crystal panel and the synthetic prism according to temperature. It can be solved by the temperature variable cooling channel of the LCD projector of the present invention configured to vary the size of the air flow path, will be described in detail with reference to the accompanying drawings.

1 is a schematic structural diagram showing a typical LCD projector.

2 is a structural diagram showing a photosynthetic system of FIG.

3 is a structural diagram of a conventional cooling flow path device.

Figure 4 is a state diagram at the normal temperature of the conventional cooling flow path device.

Figure 5 is a state diagram at a high temperature of the conventional cooling flow path device.

6 is a structural diagram of a temperature variable cooling flow passage device of the present invention.

7 is a structural diagram of a heat deformation element applied to the present invention.

8 is an operational state diagram of a thermal deformation element according to temperature.

9 is a structural diagram of an air flow path in which a flow path is changed by a heat deformation element;

10 is a state diagram of the cross-sectional area change of the air flow path with temperature.

11, 12 and 13 are diagrams illustrating the operation of air flow paths located in liquid crystal panels, respectively.

Explanation of symbols on the main parts of the drawings

1. Cooling channel 2. Intake section 3, 3a, 3b, 3c. Air flow path

4. Exhaust Section 5. Intake Fan 6. Exhaust Fan 7. Heat Deflection Element

8. Variable cross section 30a, 71a, 72a, 73a, 81b, 82b, 83b. Polarization filter

81, 82, 83. Liquid crystal panel (LCD panel) 81a, 82a, 83a. Panel

Figure 6 shows the structure of the present invention, the temperature variable cooling flow path apparatus.

The temperature variable cooling flow path device 1 of the present invention comprises three condensing lenses 71, 72, and 73 and liquid crystal panels 81, 82, and 83 provided corresponding to the condensing lenses 71, 72, and 73, and Polarizing filters 71a, 72a, 73a provided between the condenser lenses 71, 72, 73 and the liquid crystal panels 81, 82, 83, and the liquid crystal panels 81, 82, 83, and the synthetic prism 90, respectively; A cooling channel device for cooling heat generated in a photosynthetic system consisting of 81b, 82b, and 83b);

The size (cross-sectional area) of the flow path 3 is varied according to the temperatures of the three liquid crystal panels 81, 82, and 83 of the elements constituting the photosynthetic system so that the temperature of the panels 81, 82, and 83 is increased. The liquid crystal panel 81, 82, 83 is configured to cool the panel 81, 82, 83 by flowing the largest amount of cooling airflow.

The cooling flow path device 1 includes an intake part 2 in the form of a flow path in which a predetermined amount of air is sucked by the rotation of the intake fan 5; The liquid crystal panel is connected to the intake unit 2 and positioned in the photosynthetic system, and the size of the flow path is varied according to the temperature of the three liquid crystal panels 81, 82, and 83 of the elements constituting the photosynthetic system. 81, 82, and 83 air passages (3) formed in the form of three distribution passages to be cooled by each; It is associated with the air flow paths (3), the air flowing through the air flow paths (3) formed in the form of a single flow path so that the air to cool the photosynthetic system is combined and discharged to the outside by the rotation of the exhaust fan (6) The exhaust part 4 is comprised.

Hereinafter, the variable temperature cooling channel of the LCD projector of the present invention will be described in detail.

Figure 7 shows the structure of the thermal deformation element applied to the present invention, Figure 8 shows the operating state of the thermal deformation element according to the temperature, Figure 9 shows the structure of the air flow path in which the flow path is changed by the thermal deformation element will be.

In addition, Figure 10 shows the state of cross-sectional area change of the air flow path with temperature.

The temperature-variable cooling flow path device 1 of the present invention is any one of the elements constituting the photosynthetic system while reducing the noise caused by the high-speed rotation of the intake / exhaust fan 5, 6, which is generated during the conventional photosynthetic system cooling. When the temperature of the portion of the panel 83 rises, the element of the photosynthetic system in order to flow the largest amount of cooling airflow to the panel 83 having the temperature rise so that the panel 83 is cooled by the cooling airflow. The cooling flow path device 1, in which the size (cross-sectional area) of the flow path 3 varies according to the temperatures of three liquid crystal panels 81, 82, and 83, is applied to the photosynthesis system of the LCD projector, thereby forming the photosynthesis system. In addition to cooling the elements as a whole, the largest amount of cooling airflow flows to a particular panel 83 at elevated temperatures for optimum cooling.

At this time, the present invention is for the optimal state cooling effect of the liquid crystal panels (81, 82, 83) for displaying the image of each color in accordance with the supply of the three-color signal of different wavelengths among the elements constituting the photosynthesis system, In this specification, the factors except for the temperature rise of the three liquid crystal panels 81, 82, and 83 are not considered.

As described above, the cooling channel apparatus 1 applied to the photosynthetic system in order to cool the entire photosynthetic system of the LCD projector or the liquid crystal panel at a specific portion of the photosynthetic system includes: an intake unit 2 formed of one flow path; Air passages 3 which are connected to the intake unit 2 and form three flow paths to cool the entire photosynthetic system or a specific panel of the photosynthetic system, and at the same time as being connected to the air channels 3, It is composed of an exhaust unit 4 for discharging the air cooled to cool the photosynthetic system to the outside by forming a flow path, and the characteristic structural form of the present invention configured as described above is as follows.

As illustrated in FIG. 6, the intake unit 2 is formed in one flow path, and a predetermined amount of air is formed in the flow path by the rotation of the intake fan 5 provided at the inlet of the intake unit 2. It is a structure which is sucked into the phosphorus intake part 2.

As shown in FIGS. 6 and 9, the air passages 3 are associated with the intake unit 2, and at the same time, a certain amount of air flowing from the intake unit 2 causes the elements of the photosynthetic system. That is, three condensing lenses 71, 72, and 73, liquid crystal panels 81, 82, and 83 installed corresponding to the condensing lenses 71, 72, and 73, and the condensing lenses 71, 72, and 73 and liquid crystals. Cooling while passing through the panel 81, 82, 83 and the polarization filters 71a, 72a, 73a, 81b, 82b, 83b respectively provided between the liquid crystal panels 81, 82, 83 and the synthetic prism 90, respectively. Three distribution channels 3a, 3b, and 3c are located in the photosynthetic system so that the liquid crystal panels 81, 82, and 83 of the elements of the photosynthetic system are particularly provided. The size (cross-sectional area) of the air channel 3 is variable according to the temperature, so that a large amount of air through the air channel 3 of which the size is variable to a specific portion where the temperature is increased in the photosynthetic system Standing because the flow, has a structure for cooling a specific region which the temperature elevated.

As illustrated in FIG. 6, the exhaust part 4 may be connected with the air flow paths 3 and may be summed with air that has cooled the photosynthetic system in a distributed state through the air flow paths 3. It is formed in the form of a single channel so that the air flowed to the exhaust portion 4 by the rotation of the exhaust fan (6) provided at the outlet of the exhaust portion 4 is discharged to the outside.

At this time, one side cross-section of the air flow paths 3 formed in the form of three distribution flow paths of the cooling flow path device 1 configured as described above, as shown in Figure 9, three liquid crystals of the elements of the photosynthetic system At the same time as detecting the temperature of the panel 81, 82, 83, the thermal expansion coefficient may be changed so that the size (cross-sectional area) of the air flow path 3 may be varied according to the detected temperatures of the liquid crystal panels 81, 82, 83. The variable cross-section 8 is fixed by a heat deformation element (see Fig. 7) 7 in which two large materials are joined to each other.

For this reason, when the temperature of the liquid crystal panels 81, 82, and 83 is a high temperature, as shown in FIG. 10 (a), the heat deformation element 7 fixed to one end surface of the air flow paths 3a, 3b, and 3c. ), The variable cross section 8 fixed to one side of the heat deformation element 7 is formed in accordance with the heat change action (see FIG. 8) in which a material having a large thermal expansion coefficient is bent toward a material having a small thermal expansion coefficient. While moving to one end surface, the cross-sectional areas of the air passages 3a, 3b, and 3c become the widest state, and at the same time, the air flows smoothly through the air passages 3a, 3b, and 3c, which have a wider cross-sectional area as described above. Due to the very low air resistance, under the same fan rotational speed conditions, the volume of air passing through the air passages 3a, 3b, and 3c cross-sectional area per unit time is the largest, and the air passages 3a, 3b, and 3c have increased in cross-sectional area. As air flows, the liquid crystal panels 81, 82, and 83 are concentratedly cooled.

In addition, when the temperatures of the liquid crystal panels 81, 82, and 83 are slightly high or normal temperature, according to the heat change action of the heat deformation element 7 fixed to one end surface of the air flow passage 3 (see FIG. 8). The cross-sectional area of the air flow path 3 is changed in the cross-sectional area of FIGS. As shown in (c), the liquid crystal panels 81 and 82 flow in a predetermined amount of air which is smaller than the air passage amount shown in FIG. , 83).

In addition, the liquid crystal panels 81, 82, and 83, which display images of each color, are supplied in accordance with the supply of three colors of signals of different wavelengths among the photosynthetic systems in which the cooling channel device 1 acting as described above is located. When the temperature rises to different temperatures due to the wavelength and frequency of the color signal, the size (cross-sectional area) of the air flow paths 3 of the cooling flow path device 1 changes according to the temperatures of the liquid crystal panels 81, 82, and 83. In this case, when the temperature of the liquid crystal panel 1 (83) is relatively higher than the temperature of the other two liquid crystal panels 81 and 82 due to the reception of the blue light having the shortest wavelength and the highest frequency, the elevated liquid crystal panel is increased. The cross-sectional area of the air passage 1 (3a) is increased by the temperature of 1 (83), and the amount of air flowing into the liquid crystal panel 1 (83) is increased by the increase in the cross-sectional area of the flow passage 1 (3a). It cools by focusing more on 1 (83).

In addition, when the temperature of the liquid crystal panel 2 (82) or the liquid crystal panel 3 (81) increases, the liquid crystal panel 1 is changed by the cross-sectional area of the air flow path 1 (3) generated when the temperature of the liquid crystal panel 1 (83) increases. The liquid crystal panel 2 (82) or the liquid crystal panel 3 (81) is intensively cooled by changing the cross-sectional areas of the air flow paths 2 and 3 (3b and 3c), which are the same as those of the intensive cooling. Explain.

Hereinafter, the operation of the present invention, the temperature variable cooling flow path device will be described in detail.

11, 12, and 13 illustrate an operational state diagram of air flow paths located in liquid crystal panels, respectively.

Three condensing lenses 71, 72, 73 and liquid crystal panels 81, 82, 83 provided corresponding to the condensing lenses 71, 72, 73, and the condensing lenses 71, 72, 73 and liquid crystal panel ( 81, 82, 83 and each color of the photosynthetic system composed of polarizing filters 71a, 72a, 73a, 81b, 82b, 83b provided between the liquid crystal panels 81, 82, 83 and the synthetic prism 90, respectively. When the three color signals of different wavelengths are received by the three liquid crystal panels 81, 82, and 83 displaying an image of the image, the liquid crystal panels 81, 82, and 83 are arranged according to the length of the wavelength and the magnitude of the frequency. Differential temperature rises occur, and in this case, the liquid crystal panel 1 (83), which receives the blue light with the shortest wavelength and the highest frequency, receives the green and red light. The temperature rises relatively.

As described above, when the temperature of the liquid crystal panel 1 83 increases relative to the temperature of the other two liquid crystal panels 81 and 82 according to the reception of blue light, air is increased by the temperature of the liquid crystal panel 1 83. Among the thermal deformation elements 7 fixed to one end surface of the flow path 1 (3a), a variable material having a large thermal expansion coefficient is fixed to one side of the thermal deformation element 7 according to a heat change action in which the thermal expansion coefficient is bent toward a material having a small thermal expansion coefficient. As the cross-section 8 moves to one side cross-section of the air passage 1 (3a), the cross-sectional area of the air passage 1 (3a) is thereby increased, and as shown in FIG. A large amount of air flows to (3a) to intensively cool the liquid crystal panel 1 (83).

In addition, when the temperature of the liquid crystal panel 3 (81), which has the longest wavelength and the red light having the smallest frequency, rises relatively higher than the temperature of the other two liquid crystal panels 82 and 83, the elevated liquid crystal panel 3 ( The variable cross-section portion 8 fixed to one side of the heat deformation element 7 according to the heat change action of the heat deformation element 7 fixed to one end surface of the air passage 3 (3c) by the temperature of 81 is While moving to one side cross section of the air passage 3 (3c), thereby increasing the cross-sectional area of the air passage 3 (3c), as shown in FIG. As air flows, the liquid crystal panel 3 (81) is concentratedly cooled.

In addition, in the case of the liquid crystal panel 2 in which the green light having the length and frequency of the wavelength is approximately between blue light and red light is received, the air paths 1 and 3 of the liquid crystal panel 1 (83) and the liquid crystal panel 3 (81) are also received. Since the liquid crystal panels 1 and 3 (83) 81 are the same as the process of intensive cooling by the cross-sectional area (3a, 3c) change, the description thereof will be omitted.

In addition, when the temperatures of the liquid crystal panels 81, 82, and 83 rise excessively, the cross-sectional areas of the flow paths 3a, 3b, and 3c may be maximized according to the temperatures of the liquid crystal panels 81, 82, and 83. As shown in FIG. 13, the intake / exhaust fan 5 and 6 installed in the cooling channel 1 of the present invention allow a large amount of air to flow through the enlarged air channels 3. The speed is increased to cool the liquid crystal panels 81, 82, and 83.

In the present invention, the LCD variable temperature variable cooling flow path includes a region in which a lot of heat is generated in the projector, that is, three condenser lenses and a liquid crystal panel installed corresponding to the condensing lens, and between the condenser lens and the liquid crystal panel and the liquid crystal panel and the synthetic prism, respectively. By applying a cooling channel device having a variable air flow path according to temperature to a photosynthesis system comprising polarizing filters installed in the device, not only cooling the entire elements of the photosynthesis system but also supplying three-color signals of different wavelengths. When one of the three liquid crystal panels displaying images of each color according to the temperature rises, the largest amount of cooling airflow is directed to the portion of the panel where the temperature is raised through the air flow channel whose size is changed according to the elevated temperature. There is an excellent effect to achieve the optimum cooling effect by flowing.

In addition, by applying a cooling flow path apparatus of which the air flow path is variable according to the temperature of the photosynthesis system as described above to the photosynthesis system that generates a lot of heat in the projector, it is possible to achieve high-speed rotation of the intake / exhaust fan that is generated during the conventional photosynthesis system cooling. It also has an excellent effect of reducing noise.

Claims (4)

Cooling flow path apparatus for cooling heat generated in a photosynthetic system consisting of three condensing lenses, a liquid crystal panel installed corresponding to the condensing lens, and a polarizing filter disposed between the condensing lens and the liquid crystal panel and the liquid crystal panel and the synthetic prism, respectively. To; The size (cross-sectional area) of the flow path is varied according to the temperatures of three liquid crystal panels among the elements constituting the photosynthetic system and the largest amount of cooling air flows to the portion of the liquid crystal panel where the temperature is increased to cool the panel. A variable temperature cooling channel of the LCD projector characterized in that it is configured to. According to claim 1, wherein the cooling flow path apparatus, the intake unit in the form of a flow path in which a predetermined amount of air is sucked by the rotation of the intake fan; At the same time as being associated with the intake unit, located in the photosynthetic system, the size of the flow path is changed in accordance with the temperature of the three liquid crystal panel of the elements constituting the photosynthetic system in the form of three distribution channels to be cooled by each liquid crystal panel Formed air flow paths; The LCD projector is connected to the air flow passages, and the air flows through the air flow passages formed in a single flow path shape so that the air that cools the photosynthetic system is combined and discharged to the outside by the rotation of the exhaust fan. Temperature variable refrigeration channel. According to claim 2, wherein the air flow path formed in the form of the three distribution channels, the variable cross-section portion by the heat deformation element so that the size (cross-sectional area) of the air flow path can be changed in accordance with the sensed temperature of the liquid crystal panels The variable temperature cooling channel of the LCD projector, characterized in that fixed to the. 4. The variable temperature cooling channel of the LCD projector according to claim 3, wherein the thermal deformation element is formed by joining two materials having a large difference in coefficient of thermal expansion.