JP2008257173A - Light source lamp cooling mechanism and projection type video display apparatus using the same - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a light source lamp cooling mechanism achieving both of the cooling of a light source lamp and the reduction in exhaust air temperature, and a projection type video display apparatus using the same. <P>SOLUTION: The light source lamp cooling mechanism is equipped with a first fan 16 that blows air to an interior air blow outlet communicating with the interior of the light source lamp 19 and exterior air blow outlets 162 and 163 communicating with an outer surface thereof, and a second fan 17 that discharges exhaust air around the light source lamp 19 to exterior. The exterior air blow outlets 162 and 163 are formed to be deviated from the center of the outer surface of the light source lamp 19. The second fan 17 is inclined to be arranged so that the exhaust air is sucked in a direction to the exterior air blow outlets 162 and 163 side. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to a light source lamp cooling mechanism and a projection display apparatus using the same.

  Projection-type image display devices such as liquid crystal projectors use high-pressure mercury lamps or metal halide lamps that emit light with high brightness at high temperatures in the arc tube in the reflector of the light source lamp. The light source lamp is cooled by blowing air from the fan.

Patent Document 1 includes a fan for cooling a light source lamp, and a duct extending from the fan to the light source lamp has an opening (blower) formed in a portion facing the light source lamp. It is disclosed.
JP-A-9-90511

  However, in the conventional light source lamp cooling mechanism as shown in the above-mentioned Patent Document 1, since the fan and its outlet are arranged considering only the cooling of the light source lamp, even if the light source lamp can be cooled, The exhaust temperature will increase accordingly. If the exhaust temperature becomes too high, there will be many complaints from users.

  Projection-type image display devices such as liquid crystal projectors are required to simultaneously increase the output of the light source lamp and downsize the device, and the conventional technology as described above cannot cool the high-output light source lamp. However, since the exhaust temperature becomes too high exceeding the allowable range of the user, it has become difficult to achieve both cooling of the light source lamp and reduction of the exhaust temperature. As a countermeasure, increasing the fan output (rotation speed) increases the fan noise.

  Accordingly, the present invention has been made to solve such problems, and it is intended to provide a light source lamp cooling mechanism capable of achieving both cooling of the light source lamp and reduction of the exhaust temperature, and a projection display apparatus using the same. It is the purpose.

  In order to achieve the above object, the invention according to claim 1 of the present application provides a light source lamp cooling mechanism that cools a light source lamp having an arc tube in a reflector by blowing air from a fan. A first fan that blows air to an internal air outlet that communicates with the interior and an external air outlet that communicates to the outer surface, and a second fan that exhausts the exhaust around the light source lamp to the outside. The blower outlet is formed to deviate from the center of the outer surface of the light source lamp, and the second fan is arranged so as to be inclined so that its suction direction faces the external blower outlet side. is there.

  The invention according to claim 2 is characterized in that two external outlets are formed on the upper and lower sides of the light source lamp so as to deviate from the center of the outer surface.

  According to a third aspect of the present invention, the degree of deflecting the external blower outlet from the central portion of the outer surface of the light source lamp and the degree of tilting the second fan so that the suction direction faces the external blower outlet side. Is set in consideration of the cooling of the light source lamp and the exhaust temperature thereof.

  The invention according to claim 4 is characterized in that the internal air outlet and the external air outlet are formed in a duct extending from the first fan to the light source lamp.

  According to a fifth aspect of the present invention, the light source lamp cooling mechanism according to any one of the first to fourth aspects is provided, the light emitted from the light source lamp is modulated based on a video signal, and the modulated video light is modulated. Is a projection-type image display device characterized in that the image is enlarged and projected.

  According to the light source lamp cooling mechanism of claim 1 of the present application, the inside of the light source lamp having the arc tube that has the highest temperature can be efficiently cooled using the internal outlet. In addition, the outer surface of the light source lamp that does not become as hot as the inside of the light source lamp can be appropriately cooled by using an external air outlet formed by deviating from the center of the outer surface. Further, since the second fan is arranged so as to be inclined so that the suction direction faces the external air outlet side, the air blown from the external air outlet formed by deviating from the center part of the outer surface of the light source lamp The outer surface of the lamp is cooled and a part is directly sucked into the second fan, and the inside of the light source lamp is cooled and mixed with the exhaust gas that has become high temperature and discharged to the outside, thereby reducing the exhaust temperature. it can. Therefore, both the cooling of the light source lamp and the reduction of the exhaust temperature can be achieved without increasing the output of the fan so much, and the noise can be suppressed low.

  According to the light source lamp cooling mechanism of the second aspect, the outer surface of the light source lamp can be substantially uniformly cooled by forming two external outlets vertically from the center of the outer surface of the light source lamp.

  According to the light source lamp cooling mechanism of the third aspect, the degree to which the external blower outlet is deflected from the central portion of the outer surface of the light source lamp and the second fan is inclined so that the suction direction thereof faces the external blower outlet. The degree is set in consideration of the cooling of the light source lamp and its exhaust temperature, so that the cooling of the light source lamp and the reduction of the exhaust temperature can be flexibly made compatible with the increase in the output of the light source lamp and the downsizing of the apparatus.

  According to the light source lamp cooling mechanism of the fourth aspect, the internal blower outlet and the external blower outlet are formed in the duct extending from the first fan to the light source lamp, so that the degree of freedom of the arrangement position of the first fan is increased. Will improve.

  According to the projection type image display apparatus of the fourth aspect, since the light source lamp cooling mechanism as described above is provided, it is possible to achieve both cooling of the light source lamp and reduction of the exhaust temperature without significantly increasing the output of the fan, and low noise. A projection-type image display device that can be suppressed is obtained.

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

  FIG. 1 is a perspective view of a liquid crystal projector as an embodiment of a projection type image display apparatus according to the present invention as seen from diagonally upward on the front side, FIG. 2 is a perspective view of the same as seen from diagonally upward on the back side, and FIG. 1 is a perspective view with the upper case removed, FIG. 4 is a perspective view with the main control board removed, FIG. 5 is a perspective view with the optical system removed, and FIG. 6 is a plan view of FIG. is there.

  As shown in FIG. 1 and FIG. 2, the casing 2 constituting the outline of the liquid crystal projector 1 has a small, horizontally long and thin rectangular parallelepiped shape, and includes an upper case 2a and a lower case 2b. The upper case 2a and the main control board When 3 is removed, the inside appears as shown in FIG.

  A projection window 5 through which the projection lens 4 is exposed is formed on the left side as viewed from the front side of the front wall of the upper case 2a. In addition, an operation window 6 is formed at the left front portion of the upper surface of the upper case 2a so as to expose the adjustment dial 4a for adjusting the zoom and focus of the projection lens 4 corresponding to the projection window 5. An operation display unit 7 is provided on the left rear portion of the upper surface of the upper case 2a.

  On the other hand, many slit-like exhaust holes 8 are formed in the right side wall of the lower case 2b when viewed from the front side. Also, leg portions 9 that can be adjusted in height are provided at both side corners of the bottom front portion of the lower case 2b. Further, a power inlet 10 for connecting a power plug and an input / output terminal group 11 for connecting various input / output cables are exposed on the rear side wall of the lower case 2b.

  As shown in FIGS. 3 and 4, a light source unit 12 is disposed inside the housing 2 at the right rear as viewed from the front side, and an optical system 13 extending from the light source unit 12 to the projection lens 4. Are arranged in a substantially L-shape. In front of the light source unit 12, a power supply circuit board on which circuit parts for supplying power to each part of the apparatus are mounted, and a power supply unit in which a ballast circuit board on which circuit parts for supplying power exclusively for the light source lamp are mounted are housed. A main body 14 is arranged, and a noise removal filter unit 15 for removing noise entering through the power inlet 10 described above is arranged behind the light source unit 12.

  In the present embodiment, the noise removal filter unit 15 is separated from the power supply unit main body 14, and the separated noise removal filter unit 15 is disposed in the vicinity of the rear wall of the casing where the power supply inlet 10 is provided and the power supply unit main body 14. It is arranged so that it is located as much as possible. Specifically, the power supply unit main body 14 is arranged along the front side wall of the horizontally long casing 2, and a core (coil) 15a or the like is mounted on the substrate at a position facing the power supply unit main body 14 on the rear side wall. The noise removal filter unit 15 is disposed along the rear side wall.

  On the other hand, on the back side in the irradiation direction of the light source unit 12, an intake fan 16 composed of a sirocco fan is disposed as a first fan constituting the light source lamp cooling mechanism, and a second light source constituting the light source lamp cooling mechanism is disposed on the side surface side. An exhaust fan 17 composed of an axial fan is disposed as the fan.

  Further, on the side surface side of the power supply unit main body 14, an exhaust fan 18 composed of an axial fan is disposed as a second exhaust fan that is arranged side by side with the exhaust fan 17 and constitutes an exhaust mechanism. The exhaust fan 17 serving as the second fan constituting the light source lamp cooling mechanism also serves as the first exhaust fan constituting the exhaust mechanism.

  FIG. 7 is a diagram illustrating a configuration example of the optical system 13 described above. Note that the optical system 13 is not limited to that shown in FIG. 7, and the present invention can be applied to an apparatus including various optical systems.

  In FIG. 7, white light from the light source lamp 19 passes through the condenser lens 20, the first integrator lens 21, the second integrator lens 22, the polarization beam splitter (PBS) 23, the condenser lens 24, and the like to the first dichroic mirror 25. Irradiated.

  The first integrator lens 21 and the second integrator lens 22 are each composed of a fly-eye lens in which a plurality of lens cells are arranged in a matrix, and has a function of making the illuminance distribution of white light emitted from the light source lamp 19 uniform. have.

  The polarization beam splitter (PBS) 23 includes a polarization separation film and a phase difference plate (1/2 wavelength plate). The polarization separation film transmits, for example, P-polarized light out of the light from the second integrator lens 22 and emits the S-polarized light with a slight optical path change. The P-polarized light that has passed through the polarization separation film is converted into S-polarized light by the phase difference plate provided on the front side (light emission side) and emitted. That is, almost all light is aligned with S-polarized light.

  The light that has passed through the polarization beam splitter 23 passes through the condenser lens 24 and reaches the first dichroic mirror 25. The first dichroic mirror 25 has a function of reflecting only the blue component of the light and allowing the red and green components to pass therethrough, and the red and green component light that has passed through reaches the second dichroic mirror 26. The second dichroic mirror 26 has a function of reflecting the green component of light and passing the red component. Accordingly, the white light emitted from the light source lamp 19 is split into blue light, green light and red light by the first and second dichroic mirrors 25 and 26.

  The blue light reflected by the first dichroic mirror 25 is reflected by the total reflection mirror 27, the green light reflected by the second dichroic mirror 26 remains as it is, and the red light that has passed through the second dichroic mirror 26 is relay lenses 28, 30. Are reflected by the total reflection mirrors 29 and 31 and guided to the image generation optical system 32 respectively.

  In the image generation optical system 32, prism assembly parts 35 (FIG. 5) are provided with a red liquid crystal panel 34r, a green liquid crystal panel 34g, a blue liquid crystal panel 34b, and the like attached to three side surfaces of a cubic color combining prism 33, respectively. 4) is detachably arranged. An output-side polarizing plate 36r is disposed between the color combining prism 33 and the red liquid crystal panel 34r, and an output-side polarizing plate 36g and a front polarizing plate 37g are disposed between the color combining prism 33 and the green liquid crystal panel 34g. In addition, an emission-side polarizing plate 36b and a pre-polarizing plate 37b are disposed between the color synthesis prism 33 and the blue liquid crystal panel 34b. Further, incident-side polarizing plates 38r, 38g, and 38b and condenser lenses 39r, 39g, and 39b are disposed on the incident side of the three liquid crystal panels 34r, 34g, and 34b, respectively.

  Accordingly, the blue light reflected by the first dichroic mirror 25 and the total reflection mirror 27 is guided to the blue condenser lens 39b, where the incident side polarizing plate 38b, the blue liquid crystal panel 34b, the pre-polarizing plate 37b, and the emission side. The color composition prism 33 is reached through the polarizing plate 36b. The green light reflected by the second dichroic mirror 26 is guided to the green condenser lens 39g, and passes through the incident side polarizing plate 38g, the green liquid crystal panel 34g, the front polarizing plate 37g, and the outgoing side polarizing plate 36g. To the color synthesis prism 33. Similarly, red light transmitted through the first dichroic mirror 25 and the second dichroic mirror 26 and reflected by the two total reflection mirrors 29 and 31 is guided to the red condenser lens 39r, and is incident on the polarizing plate 38r. Through the red liquid crystal panel 34r and the emission side polarizing plate 36r, the color composition prism 33 is reached.

  The three color image lights guided to the color combining prism 33 are combined by the color combining prism 33, and the color image light obtained thereby is enlarged and projected onto the front screen via the projection lens 4.

  8 to 11 are enlarged views of a main part showing the light source lamp cooling mechanism in the present embodiment, FIG. 8 is a perspective view seen from the front side obliquely upward, and FIG. 9 is a perspective view seen from the rear side obliquely upward. The upper half of the duct is shown removed. 10 is a perspective view in which the light source lamp holder is removed from FIG. 9, and FIG. 11 is a cross-sectional view of the main part as seen from the back side.

  The light source lamp 19 of the present embodiment is arranged so as to cover an arc tube 191 made of a high-pressure mercury lamp, a metal halide lamp, or the like, and the arc tube 191, a parabolic reflecting surface is formed on the inner surface, and the front surface is opened. And a reflector 192. As shown in FIG. 10, the reflector 192 is formed with an air inlet 193 and an air outlet 194 facing each other at the front opening edge.

  The light source lamp 19 configured as described above is mounted on an aluminum lamp holder 195 as shown in FIGS. The aluminum lamp holder 195 is provided with a heat-resistant glass plate 196 that closes the front opening of the reflector 192, and has a number of small holes corresponding to the intake port 193 and the exhaust port 194 of the reflector 192. A ventilation net 197 is formed so that the fragments are not scattered outside when the arc tube 191 is ruptured.

  As described above, in the conventional light source lamp cooling mechanism, the fan and its outlet are arranged only in consideration of the cooling of the light source lamp, so even if the light source lamp can be cooled, the exhaust temperature is increased accordingly. turn into. Projection-type image display devices such as liquid crystal projectors are required to simultaneously increase the output of the light source lamp and downsize the device, and the conventional technology as described above cannot cool the high-output light source lamp. However, since the exhaust temperature becomes too high exceeding the allowable range of the user, it has become difficult to achieve both cooling of the light source lamp and reduction of the exhaust temperature. As a countermeasure, increasing the fan output (rotation speed) increases the fan noise.

  Therefore, in the present embodiment, as a fan for cooling the light source lamp 19, air is blown to the inner surface of the light source lamp 19 through the air inlet 193 formed in the reflector 192 and the outer surface of the reflector 192. An exhaust fan (first fan) 16 having external air outlets 162 and 163, and an exhaust fan that exhausts the exhaust around the light source lamp 19 to the outside through an exhaust hole 8 formed in the side wall of the housing 2. A second fan) 17. The intake fan 16 is a sirocco fan, and the exhaust fan 17 is an axial fan.

  The external air outlets 162 and 163 of the intake fan 16 are formed so as to be deviated from the center of the outer surface of the reflector 192 of the light source lamp 19, and the exhaust fan 17 is sucked in the external direction of the intake fan 16. It is inclined and arranged so as to face the 162, 163 side.

  The air outlets 161, 162, and 163 are configured such that the front end side of the duct 164 extending to the side of the light source lamp 19 from the intake fan 16 disposed on the side of the light source lamp 19 in the irradiation direction is folded in an arc shape toward the light source lamp 19. It is bent and formed on its tip surface. The internal air outlet 161 is formed to correspond to the air inlet 193 formed in the reflector 192 of the light source lamp 19, but the external air outlets 162 and 163 are the central portions of the outer surface of the reflector 192 of the light source lamp 19. Two are formed vertically deviating from the vertical direction.

  Further, as described above, the degree to which the external air outlets 162 and 163 of the intake fan 16 are deflected from the central portion of the outer surface of the light source lamp 19, and the exhaust fan 17 has an intake direction of the external air outlets 162 and 163 of the intake fan 19. The degree of tilting toward the side is set in consideration of cooling of the light source lamp 19 and its exhaust temperature.

  By configuring as described above, the inside of the light source lamp 19 having the arc tube 191 that has the highest temperature can be efficiently cooled using the internal air outlet 161 of the intake fan 16. Further, the outer surface of the reflector 192 (including the neck portion 198 protruding from the rear end) of the light source lamp 19 that does not reach a temperature as high as the inside of the light source lamp 19 is blown to the outside of the intake fan 16 formed by deviating from the center portion of the outer surface. It can cool moderately using the outlets 162 and 163.

  Further, since the exhaust fan 17 is inclined so that the suction direction thereof faces the external blower outlets 162 and 163 of the intake fan 16, the intake fan 16 formed by deviating from the center of the outer surface of the light source lamp 19 is formed. The air blown from the external air outlets 162 and 163 cools the outer surface of the light source lamp 19 and is partly sucked directly into the exhaust fan 17, and is mixed with exhaust gas that has been heated to a high temperature by cooling the inside of the light source lamp 19. By exhausting to the outside, the exhaust temperature can be reduced.

  Accordingly, both the cooling of the light source lamp 19 and the exhaust temperature can be reduced without significantly increasing the output of the intake fan 16 and the exhaust fan 17, and the noise can be suppressed low.

  Further, by forming two external outlets 162 and 163 for the intake fan 16 on the upper and lower sides away from the center of the outer surface of the light source lamp 19, the outer surface of the light source lamp 19 can be cooled almost uniformly.

  Further, the degree to which the external air outlets 162 and 163 of the intake fan 16 are deviated from the central portion of the outer surface of the light source lamp 19, and the exhaust fan 17 is directed so that the intake direction faces the external air outlets 162 and 163 of the intake fan 16. The degree of inclination of the light source lamp 19 is set in consideration of the cooling of the light source lamp 19 and its exhaust temperature. Can be flexibly compatible.

  Further, since the air outlets 161, 162, and 163 of the intake fan 16 are formed in the duct 164 extending from the intake fan 16 to the light source lamp 19, the degree of freedom of the arrangement position of the intake fan 16 is improved.

  As described above, according to the present embodiment, since the light source lamp cooling mechanism as described above is provided, it is possible to achieve both cooling of the light source lamp 19 and reduction of the exhaust temperature without significantly increasing the outputs of the fans 16 and 17. The liquid crystal projector 1 capable of suppressing noise can be realized.

  12 to 15 are enlarged views of the main part showing the optical component cooling mechanism in the present embodiment, FIG. 12 is a perspective view seen from the front side obliquely upward, FIG. 13 is a plan view, and FIG. 14 is a liquid crystal panel or the like. FIG. 15 is a rear view with the lower half of the duct removed. FIG.

  Conventionally, three liquid crystal panels corresponding to red light, green light, and blue light and polarizing plates arranged on the incident side and output side of each liquid crystal panel are cooled by three fans, one for each color. What you do is known.

  By the way, three liquid crystal panels corresponding to red light, green light, and blue light, and polarizing plates arranged on the incident side and the emission side of each liquid crystal panel have different temperatures and UV degradation degrees for each color. The amount of cooling required also varies. In particular, since blue light is close to the ultraviolet region, the necessary cooling amount is increased to prevent ultraviolet degradation.

  In addition, projection-type image display devices such as liquid crystal projectors are required to simultaneously achieve high brightness by increasing the output of the light source lamp and downsizing and cost reduction of the device (miniaturization of liquid crystal panels, etc.). Therefore, the amount of light per unit area is increasing with high brightness.

  However, the conventional technology in which the cooling is performed by one fan for each color as described above cannot be supported by a model having high brightness and an increased amount of light per unit area. As a countermeasure, increasing the fan output (rotation speed) increases the fan noise. In addition, the PBS must be cooled.

  Therefore, in the present embodiment, the air blown from the three intake fans 41, 42, 43 is blown out through the ducts 411, 421, 431 to the incident side and the emission side of each of the liquid crystal panels 34r, 34g, 34b described above. The outlets r 1, r 2, g 1, g 2, b 1, b 2 are formed, and the air outlet p 1 that blows air from the intake fan 43 through the duct 432 is formed in the PBS 23 described above. And the duct is comprised in the incident side blower outlet b1 and the output side blower outlet b2 of the liquid crystal panel 34b corresponding to blue light so that the ventilation from different intake fans 43 and 41 may be blown off, respectively. Each of the intake fans 41 to 43 is a sirocco fan.

  That is, one intake fan 43 sends air to the incident side outlet b1 of the liquid crystal panel 34b corresponding to blue light and the outlet p1 of the PBS 23, and the other two intake fans 41 and 42 use red light and green light. The ducts are configured to send air to the incident side outlets r1 and g1 and the emission side outlets r2 and g2 of the liquid crystal panels 34r and 34g corresponding to the above and the emission side outlet b2 of the liquid crystal panel 34b corresponding to the blue light. Yes.

  More specifically, of the two intake fans 41, 42, one of the intake fans 42 is connected to the incident side outlet g1 and the emission side outlet g2 of the liquid crystal panel 34g corresponding to green light via the duct 421. The duct 411 is connected to the incident-side outlet r1 and the outlet-side outlet r2 of the liquid crystal panel 34r corresponding to red light and the outlet-side outlet b2 of the liquid crystal panel 34b corresponding to blue light by the other intake fan 41. The duct is configured to extend the air flow.

  With the above configuration, the three intake fans 41 to 43 can cool the PBS 23 in addition to the incident side and the emission side of the liquid crystal panels 34r, 34g, and 34b. Furthermore, the incident side and the emission side of the blue light having a large required cooling amount can be sufficiently cooled by using different intake fans 43 and 41, respectively. Therefore, even if the light intensity per unit area increases with high luminance, the liquid crystal panels 34r, 34g, 34b and the polarizing plates 36r, 36g, 36b, 37g, 37b, 38r, 38g, 38b and PBS 23 can be cooled by three intake fans 41 to 43, and noise can be reduced.

  One intake fan 43 blows air to the incident side outlet b1 of the liquid crystal panel 34b corresponding to blue light and the outlet p1 of the PBS 23, and the other two intake fans 41 and 42 emit red light and green light. The ducts are configured to blow air to the incident side outlets r1 and g1 and the emission side outlets r2 and g2 of the liquid crystal panels 34r and 34g corresponding to the above and the emission side outlet b2 of the liquid crystal panel 34b corresponding to the blue light. Thus, in the case where the blue light liquid crystal panel 34b is arranged on the PBS 23 side as in the optical system 13 of the present embodiment, the above-described effects can be realized with the shortest duct configuration. In addition, the red light intake fan 41 with the lowest temperature can be blown to the emission side outlet b2 of the liquid crystal panel 34b corresponding to the blue light. Note that if the single intake fan 42 is insufficient for the green light whose temperature rises most, it is also possible to blow air from the intake fan 41 for red light.

  Further, as in the present embodiment, of the two intake fans 41, 42, the one intake fan 42 blows air to the incident side outlet g1 and the emission side outlet g2 of the liquid crystal panel 34g corresponding to green light. The other intake fan 41 sends air to the incident side outlet r1 and the outlet side outlet r2 of the liquid crystal panel 34r corresponding to red light and to the outlet side outlet b2 of the liquid crystal panel 34b corresponding to blue light. By configuring the duct, the above-described effects can be realized without complicating the duct configuration.

  As described above, according to the present embodiment, since the optical component cooling mechanism as described above is provided, even if the light intensity per unit area increases with high brightness, the output (rotation speed) of the fan is increased so much. In addition, the liquid crystal projector 1, the liquid crystal panel, the polarizing plate, and the PBS can be cooled by three fans, and the noise can be reduced.

  Next, the power supply unit of this embodiment will be described.

  Conventionally, a noise removal filter unit is generally mounted on a circuit board of a power supply unit.

  As described above, projection-type image display devices such as liquid crystal projectors are required to increase brightness by increasing the output of the light source lamp, and to reduce the size and cost of the device at the same time. Higher power output requires a power supply unit with a larger output.

  However, in a model with a small output, there is no problem even if a noise removal filter unit is mounted on the circuit board of the power supply unit as in the conventional technology described above. However, when the output is large, noise having a core (coil) that cannot be reduced in size. The removal filter section becomes larger and the power supply unit becomes larger.

  As the power supply unit becomes larger, it is necessary to increase the size of the fan for cooling the power supply unit or increase the output (rotation speed), so that the cooling performance is lowered and the noise is increased. As a countermeasure, it is conceivable that the noise removal filter is separated and placed separately. However, noise is likely to enter the connection line, and EMC (ElectroMagnetic Compatibility) countermeasures become extremely difficult due to increased use of the core. It becomes costly.

  Therefore, in the present embodiment, as described above, the noise removal filter unit 15 is separated from the power supply unit main body 14, and the separated noise removal filter unit 15 is separated from the rear wall of the casing and the power supply unit main body provided with the power supply inlet 10. 14 is arranged so as to be located as close as possible to each of the 14.

  Specifically, the power supply unit main body 14 is disposed along the front side wall of the horizontally long casing 2, and the noise removal filter unit 15 is disposed along the rear side wall at a position facing the power supply unit main body 14 on the rear side wall. Is.

  With this configuration, even if the output of the light source lamp 19 is increased, the power supply unit main body 14 can be reduced in size, so that the noise can be reduced by improving the cooling performance. Furthermore, by shortening the connection line, it is possible to reduce the cost by improving the efficiency of EMC countermeasures (reducing the use of cores, etc.).

  In addition, since the noise removal filter unit 15 is disposed in the vicinity of the rear side wall of the housing where the power inlet 10 is provided, the power cord does not come on the side surface of the housing 2, thereby impairing the usability on the side surface of the housing 2. The above-described effects can be obtained.

  Further, the power supply unit main body 14 is disposed along the front side wall of the horizontally long casing 2, and the noise removal filter unit 15 is disposed at a position facing the power supply unit main body 14 on the rear side wall. Even if it is arranged along the back side wall, the connection line can be shortened, so that the above-described effects can be obtained without complicating the arrangement of the components in the housing 2.

  As described above, according to the present embodiment, by providing the power supply unit as described above, even if the output of the light source lamp 19 is increased, the noise is reduced by improving the cooling performance, the efficiency of EMC countermeasures is improved, and the like. The liquid crystal projector 1 capable of reducing the cost can be realized.

  In this embodiment, since the casing 2 is horizontally long, the connection line can be minimized even if the power supply unit main body 14 and the noise removal filter unit 15 are arranged in parallel along the front side wall and the rear side wall, respectively. In the case of a vertically long casing in the front-rear direction, the connection line cannot be minimized by the arrangement as described above. In such a case, for example, if the noise removal filter part is arranged in the front-rear direction, the noise removal filter part is It can arrange | position to each vicinity of a housing | casing back side wall and a power supply unit main body.

  Next, the exhaust mechanism in the present embodiment will be described.

  2. Description of the Related Art Conventionally, there is known a system in which two exhaust fans for exhausting exhaust from a light source lamp, a power supply unit, and the like in the vicinity of a light source lamp are arranged in parallel.

  As described above, projection-type image display devices such as liquid crystal projectors are required to simultaneously increase the output of the light source lamp and downsize the device, and high-temperature exhaust gas is discharged from the high-output light source lamp. However, there are problems in reducing the exhaust temperature and reducing the noise of the exhaust fan.

  However, in order to reduce the noise of the exhaust fans arranged side by side with the conventional technology as described above, it is necessary to keep a distance from the side wall of the housing, which hinders downsizing. In order to reduce the exhaust temperature, the exhaust fans arranged side by side are shaped like a letter C in the direction of each other so that the high-temperature exhaust from the light source lamp and the relatively low-temperature exhaust from the power supply unit are mixed together. Although it is conceivable to arrange them in an inclined manner, in this case as well, there is a need for a space for that purpose, which hinders downsizing.

  Therefore, in the present embodiment, as shown in FIG. 3 and FIG. 4 described above, the first exhaust fan 17 that mainly exhausts the exhaust from the light source lamp 19 (light source lamp unit 12) to the outside, Aside from the second exhaust fan 18 that exhausts the exhaust from the power supply unit body 14 to the outside, the second exhaust fan 18 side end portion of the first exhaust fan 17 is moved inward, The first exhaust fan 17 is disposed so as to be inclined so that the exhaust direction thereof faces the exhaust side of the second exhaust fan 18.

  The first exhaust fan 17 is inclined with respect to a number of slit-like exhaust holes 8 formed on the side wall of the casing, and exhaust is exhausted obliquely forward from the exhaust holes 8. It is arranged so as to be inclined.

  As shown in FIGS. 16 and 17, the first exhaust fan 17 and the second exhaust fan 18 are fixed in advance to the frame body 50 so as to be arranged as described above, and are unitized. If the exhaust fan unit 51 is attached to a predetermined position of the lower case 2b of the housing 2, the above-described arrangement configuration can be easily realized. Since the first exhaust fan 17 draws in hot exhaust from the light source lamp 19, as shown in FIG. 17, the rear side is covered with a cover 52 in which the middle motor portion is closed. The motor unit is configured to be protected against high-temperature exhaust from the light source lamp 19.

  With the above-described configuration, the first exhaust fan 17 is inclined inward to prevent downsizing, and a space can be further formed between the housing side wall and the first exhaust fan 17 to reduce the size. Noise can be reduced. Further, the high temperature exhaust from the light source lamp 19 and the relatively low temperature exhaust from the power supply unit main body 14 are mixed together, and the exhaust temperature can be reduced.

  Further, since the light source lamp becomes high temperature and is disposed at a distance from the exhaust fan conventionally, the above-described configuration and effects can be easily realized.

  Further, since the second exhaust fan 18 mainly exhausts the exhaust from the power supply unit body 14 to the outside, the exhaust of the power supply unit body 14 which is not as hot as the light source lamp 19 but is important can be performed at the same time. .

  Further, the first exhaust fan 17 that exhausts the exhaust from the light source lamp 19 to the outside is disposed so as to be inclined with respect to the many slit-shaped exhaust holes 8 formed in the side wall of the housing, thereby allowing the light source lamp 19 to Since the high-temperature exhaust is discharged into the slit-shaped exhaust holes 8 at an angle, it becomes difficult to be exhausted by that amount, so that it becomes easier to mix with the relatively low-temperature exhaust from the second exhaust fan 18, and so on. The exhaust temperature can be reduced.

  Further, the first exhaust fan 17 that exhausts the exhaust from the light source lamp 19 to the outside is disposed so as to be inclined obliquely forward from the exhaust hole 8 formed in the side wall of the housing, It is possible to prevent the exhaust gas having a high temperature from being blown out in the lateral direction where the operator or the like is present.

  As described above, according to the present embodiment, since the exhaust mechanism as described above is provided, the liquid crystal projector 1 that can be miniaturized while reducing the noise of the exhaust fans 17 and 18 and reducing the exhaust temperature is realized. it can.

  In the present embodiment, the first exhaust fan 17 is inclined. However, if there is room on the inner side in terms of space, the second exhaust fan 18 may be inclined even if the second exhaust fan 18 is inclined as described above. The effect can be expected.

  In the above embodiment, a liquid crystal projector using a liquid crystal panel as a light modulation element is shown as a projection display apparatus. However, the present invention is also applied to a projection display apparatus having another image light generation system. Can do. For example, the present invention can also be applied to a projector using a DLP (Digital Light Processing; registered trademark of Texas Instruments (TI)) system.

The perspective view which looked at the liquid-crystal projector as one Embodiment of the projection type video display apparatus concerning this invention from the front side diagonally upward. Similarly, the perspective view seen from the back side diagonally upward. The perspective view which removed and showed the upper case of FIG. Furthermore, the perspective view which removed and showed the main control board. Furthermore, the perspective view which removed and showed the optical system. FIG. 6 is a plan view of FIG. 5. The figure which shows the structural example of an optical system. The principal part enlarged view which shows the light source lamp cooling mechanism in this embodiment, and the perspective view seen from the front side diagonally upward. Similarly, the perspective view which removed the upper half of the duct and was seen from the back side diagonally upward. The perspective view which removed the holder of the light source lamp from FIG. The principal part sectional view seen from the back side. The principal part enlarged view which shows the optical component cooling mechanism in this embodiment, and the perspective view seen from the front side diagonally upward. Similarly, a plan view. Similarly, the top view which removed the optical component and showed. Similarly, the back view which removed and showed the lower half of the duct. The perspective view which shows the exhaust fan unit which comprises the exhaust mechanism in this embodiment. Similarly, the perspective view which shows the back side.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Liquid crystal projector 2 Case 4 Projection lens 8 Exhaust hole 10 Power supply inlet 12 Light source unit 13 Optical system 14 Power supply unit main body 15 Noise removal filter part 15a Core (coil)
16 Intake fan 161 Internal outlet 162, 163 External outlet 164 Duct 17, 18 Exhaust fan 19 Light source lamp 191 Light emission tube 192 Reflector 193 Inlet 194 Exhaust 198 Neck portion 20, 24, 39r, 39g, 39b Condenser lens 21, 22 First and second integrator lenses 23 Polarizing beam splitter (PBS)
25, 26 First and second dichroic mirrors 27, 29, 31 Total reflection mirrors 28, 30 Relay lens 32 Image generation optical system 33 Color synthesis prism 34r, 34g, 34b Liquid crystal panel 35 Prism assembly parts 36r, 36g, 36b Outgoing side Polarizing plate 37g, 37b Pre-polarizing plate 38r, 38g, 38b Incident side polarizing plate 41, 42, 43 Intake fan 50 Frame 51 Exhaust fan unit 52 Cover

Claims (5)

In a light source lamp cooling mechanism that cools a light source lamp having an arc tube in a reflector by blowing air from a fan,
As the fan, a first fan that blows air to an internal air outlet that communicates with the interior of the light source lamp and an external air outlet that communicates with the outer surface, and a second fan that exhausts the exhaust around the light source lamp to the outside And
The external blower outlet is formed to deviate from the center of the outer surface of the light source lamp, and the second fan is disposed so as to be inclined so that the suction direction faces the external blower outlet side. Light source lamp cooling mechanism.   2. The light source lamp cooling mechanism according to claim 1, wherein the external blower outlet is formed in two upper and lower directions, deviating from a central portion of the outer surface of the light source lamp.   The degree to which the external air outlet is deflected from the center of the outer surface of the light source lamp and the degree to which the second fan is inclined so that the suction direction faces the external air outlet side are the cooling of the light source lamp. 3. The light source lamp cooling mechanism according to claim 1, wherein the cooling mechanism is set in consideration of the exhaust temperature.   4. The light source lamp cooling mechanism according to claim 1, wherein the internal air outlet and the external air outlet are formed in a duct extending from the first fan to the light source lamp. 5. .   5. The light source lamp cooling mechanism according to claim 1, wherein the light emitted from the light source lamp is modulated based on a video signal, and the modulated video light is enlarged and projected. Projection display device.

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