JP4007013B2 - Projection display - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention belongs to the technical field of a projection display device that is most suitable for application to a liquid crystal projector or the like, and is particularly suitable for use by being suspended from a ceiling of a house or the like.
[0002]
[Prior art]
Conventionally, there is a liquid crystal projector shown in FIGS. 15 and 16 as an example of a projection display device. In this conventional liquid crystal projector 81, a projection lens 83 and an exhaust port 84 are arranged and formed side by side on the front surface 82a of an outer casing 82 containing an optical unit (not shown). An exhaust duct 87 having an exhaust fan 86 is disposed between a light source unit 85 that is an internal heat source that generates heat and an exhaust port 84. Then, the projection lens 83 projects an image onto a projection surface 88 such as a screen, and at the same time, the exhaust fan 86 is operated to supply high-temperature heat generated in the light source unit 85 or a power source unit (not shown) that is another internal heat source. For example, the light source unit 85 and the light source unit 85 are heated by exhausting heat generated in a direction parallel to the optical axis P of the projection lens 83 from the exhaust port 84 through the exhaust duct 87 through the exhaust duct 87. The internal heat source such as the power supply unit is air-cooled.
[0003]
At this time, it is also conceivable to arrange the exhaust ports 84 on the left and right side surfaces and the rear surface of the outer casing 82. However, the viewer who views the image projected onto the projection surface 88 by the projection lens 83 is seated around the liquid crystal projector 81 other than the front of the liquid crystal projector 81 outside the projected light flux 89 of the image projected onto the projection surface 88 by the projection lens 83. In general, the hot exhaust hot air 90 generated by the light source unit 85 or the like is heated in the same direction as the projection direction of the projection lens 83 from the exhaust port 84 formed in the front surface 82a of the outer casing 82. If the exhaust air is exhausted forward, the hot exhaust hot air 90 exhausted from the exhaust port 84 is directly scattered to the viewer, causing discomfort, or the wind noise caused by the operation of the exhaust fan 86 is generated by the viewer. It is the most preferable because it is less likely to become annoying.
[0004]
[Problems to be solved by the invention]
However, as in the conventional liquid crystal projector 81, in the method in which the heat generated in the light source unit 85, the power source unit and the like is exhausted from one exhaust port 84 by one exhaust duct 87 using one exhaust fan 86, the light source unit Although the heat of 85 can be exhausted comparatively efficiently, one exhaust fan is usually used for the heat of the power supply unit such as the power supply substrate for setting and the power supply substrate for the light source unit disposed at a position away from the light source unit 85. The cooling is only performed by the movement of air inside the outer casing 82 by the operation of 86, and the cooling efficiency of the entire liquid crystal projector 81 is poor. For this reason, conventionally, there has been a problem that electronic parts such as ICs in the vicinity thereof are adversely affected by heat generated in the power supply unit and the like, and it is likely to cause performance deterioration and shortening of life.
When the electronic components including the power supply unit are disposed near the light source unit 85, the power source unit and the electronic components are adversely affected by the heat of the light source unit, which is higher than the power supply unit, and further performance degradation, shortening of the life, etc. There was a problem that it was easy to invite.
[0005]
Further, in the structure in which the projection lens 83 and the exhaust port 84 are arranged side by side on the front surface 82a of the outer casing 82 as in the conventional liquid crystal projector 81, the optical unit and the projection lens 83 in the outer casing 82 are arranged in the outer casing 82. Therefore, the weight balance of the liquid crystal projector 81 in the horizontal width direction becomes unbalanced. For this reason, as shown in FIG. 16, when the liquid crystal projector 81 is suspended from a ceiling 93 such as a room by a suspending tool 94, the liquid crystal projector 81 tends to tilt in the left-right width direction. When the operator lifts the liquid crystal projector 81 with both hands over the ceiling 93 and hangs it on the ceiling 93, it is difficult to balance the liquid crystal projector 81 in the left-right direction, and the mounting work is significantly hindered. It was easy to invite accidents such as falling and falling by breaking the balance. In addition, when the liquid crystal projector 81 is suspended from the ceiling 93 of the room or the like by the suspending tool 94, generally, the operator can hang the projection lens 83 on a wall or the like so that the liquid crystal projector 81 is lifted with both hands. However, when the projection lens 83 is offset to one side of the outer casing 82, the projection lens 83 is set to one side from the operator's head position. Since the position is shifted, the projection lens 83 cannot be positioned at the center of the projection surface 88 with the operator's head position as a guideline, and workability is very poor.
[0006]
The present invention has been made to solve the above-described problems, and can efficiently exhaust heat generated by a plurality of heat sources inside the outer casing, and can easily balance the weight of the outer casing in the left-right direction. An object of the present invention is to provide a projection display device.
[0007]
[Means for Solving the Problems]
  Projection type display device of the present invention for achieving the above objectClaim 1IsAn optical unit having a light valve is accommodated in an optical unit cover at the rear part of the projection lens disposed almost in the center of the outer casing, and is biased toward one side of the outer casing at the rear end of the optical unit cover. A light source part is arranged in the light source part cover arranged at the position, an exhaust opening is formed on the front side of the light source part cover,Cooling air drawn by a sirocco fanThe light valve andLight sourcePartIntake duct leading toIs disposed at the bottom inside the outer casing, and a first exhaust duct connected to a first exhaust port formed at a position biased to one end side of the front surface of the outer casing is provided on the outer casing. A first exhaust mechanism is disposed along the inner side of one of the side surfaces, and is disposed in the intake side end of the first exhaust duct, in proximity to the exhaust opening of the light source unit cover. Is configured,
  A second exhaust duct connected to a second exhaust port formed at a position biased to the other end side of the front surface of the outer casing is formed along the other side surface of the outer casing; A power supply unit including the light source power supply unit is disposed in the second exhaust duct, and a second exhaust fan is disposed on the second exhaust port side of the second exhaust duct to constitute a second exhaust mechanism. It has been done.
  Further, according to a second aspect of the present invention, the second exhaust duct of the second exhaust mechanism includes a side surface of the outer casing, a side surface of the optical unit cover, and the above-described configuration. It is comprised by the insulating board arrange | positioned between the side surface of an optical unit cover, and the front side of the said outer casing.
  According to a third aspect of the present invention, the projection type display device according to the second aspect of the present invention is characterized in that the outer casing is flattened by forming the second exhaust duct in the second exhaust mechanism in a substantially J shape. It is a box shape, and both left and right side surfaces are formed into a substantially U-shaped symmetrical shape by a gentle continuous curved surface toward the rear.
[0008]
  The projection type display device of the present invention configured as described above.According to the first aspect of the present invention, the first exhaust mechanism is configured such that the light source unit cover is biased toward one side surface of the outer casing with respect to the optical unit cover, and an exhaust opening is formed on the front side of the light source unit cover. The cooling air sucked by the sirocco fan is sucked into the light bulb in the optical unit cover and the light source part in the light source part cover by the air intake duct, and close to the exhaust opening on the front side of the light source part cover. In addition, the first exhaust fan efficiently exhausts the heat of the light source section to the outside of the outer casing through the first exhaust duct from the first exhaust outlet that is biased toward one end of the front surface of the outer casing. It is configured as follows. The second exhaust mechanism is connected to a second exhaust port biased toward the other end side of the front surface of the outer casing, and a second exhaust duct having a power source unit including a light source power source unit disposed therein is provided. A power supply unit including the power supply unit for the light source is efficiently and forcibly exhausted by a second exhaust fan formed along the other side surface of the outer casing and disposed on the second exhaust port side of the second exhaust duct. It is configured.
  At this time, the light source cover of the first exhaust mechanism is biased toward one side of the outer casing with respect to the optical unit cover, and an exhaust opening is formed on the front side of the light source cover. Thus, the exhaust heat from the light source unit that becomes high temperature hardly affects the exhaust of the power source unit including the power source unit for the light source in the second exhaust duct, and includes the power source unit for the light source.Power supply partThe heat ofSecond exhaust fanThrough the second exhaust duct,And efficient and independent of the light sourceCan be evacuated and includes a light source power supplyThere is a synergistic effect that the power supply part is adversely affected by the high temperature heat from the light source part, and it is difficult to cause performance deterioration and shortening of service life.The Further, since the first exhaust mechanism and the second exhaust mechanism are arranged on both sides of the projection lens, the projection display device can be thinned.
  According to a second aspect of the projection display apparatus of the present invention, the second exhaust duct of the second exhaust mechanism includes a side surface of the outer casing, a side surface of the optical unit cover, a side surface of the optical unit cover, and a front side of the outer casing. Therefore, it is possible to reduce the cost by sharing the parts and to reduce the size by saving the space.
  Further, according to claim 3 of the projection type display device of the present invention, the second exhaust duct is formed in a substantially J shape, so that the outer casing is a flat box shape, and the left and right side surfaces are rearward with a gentle continuous curved surface. It is possible to provide a projection display device having a flat and elegant design that can be formed in a substantially U-shaped symmetrical shape.
[0009]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, an embodiment in which the projection display device of the present invention is applied to a liquid crystal projector will be described with reference to FIGS.
First, a basic embodiment of the liquid crystal projector 1 will be described with reference to FIGS. The outer casing 2 is formed in a flat box shape by a lower case 3 and an upper case 4 formed of heat-resistant synthetic resin or the like, and the upper case 4 is detachably coupled to the upper portion of the lower case 3 by screwing or the like. Has been. The front surface 2a of the outer casing 2 is curved in a gentle arc shape, and the left and right side surfaces 2b, 2c and the rear surface 2d of the outer casing 2 are curved in a substantially U shape with a symmetric shape by a gentle continuous curved surface. Has been. Then, a pair of left and right adjusters 5 are attached to the position displaced on the front surface 2a side of the bottom surface 2e of the outer casing 2, and a substantially central portion of the position displaced to the rear surface 2d side of the bottom surface 2e. Is provided with a single stand portion 6 integrally formed with the lower case 3. Therefore, when the liquid crystal projector 1 is placed on a table or the like, the height of the pair of left and right adjusters 5 is adjusted so that the liquid crystal projector 1 can be kept horizontal by three-point support by the adjuster 5 and the stand unit 6. It is configured. When the liquid crystal projector 1 is suspended from the ceiling, the liquid crystal projector 1 is attached with bolts or the like to a ceiling suspension bracket (not shown) installed on the ceiling via screw holes 7 provided at four locations of the lower case 3.
[0010]
  Next, in the outer casing 2, the optical unit 11 is horizontally disposed on the left-right center P <b> 1 of the outer casing 2, and the optical unit 11 is screwed at a predetermined height position on the lower case 3. Has been. The optical axis P2 of the projection lens 12 connected to the front end of an image composition unit 11b (to be described later) of the optical unit 11 is disposed substantially concentrically with the center P1 of the outer casing 2, and the projection lens 12 is outside. It is screwed onto the lower case 3 in a state of protruding in front of the front surface 2 a of the housing 2. Then, the light source portion 11a of the optical unit 11, which is a first internal heat source that generates the highest temperature heat during image projection, which will be described later, is in the outer casing 2 and on the side surface 2b side of the rear end portion of the optical unit 11. Biased倚The light source unit 11a is also screwed onto the lower case 3.
[0011]
Further, a set power supply substrate 13 and a light source which constitute a power supply unit that is a second internal heat source that generates low-temperature heat during image projection, which will be described later, and that supplies power for driving the liquid crystal projector 1. There is a partial power supply board 14. The set power supply board 13 is a power supply circuit board for driving circuits necessary for a general display device such as a control circuit, a signal processing circuit, and a liquid crystal panel drive circuit of the projector 1. The light source unit power supply substrate 14 is a power supply circuit substrate for lighting the light source unit to emit light. The power supply substrate 13 for setting is horizontally disposed on the other side surface 2c side of the optical unit 11 in the outer casing 2, and the power source substrate 14 for light source unit is disposed on the rear side of the optical unit 11 in the outer casing 2. It is horizontally arranged on the rear surface 2d side which is the part side. The set power supply board 13 and the light source power supply board 14 are also screwed horizontally at a predetermined height position on the lower case 3.
[0012]
The first and second exhaust ports 15 and 16 are formed symmetrically at the left and right side positions of the gently arcuate front surface 2a of the outer casing 2 at the left and right symmetrical positions around the projection lens 12. Yes. Since the first and second exhaust ports 15 and 16 are formed symmetrically along the gentle arcuate front surface 2a, the first and second exhaust ports 15 and 16 have A left-right symmetrical opening angle θ1 is set to the left and right sides with respect to the reference plane P3 perpendicular to the optical axis P2 of the projection lens 12. A front grill 17 made of a perforated plate such as a punching metal or a net-like member is attached to the first and second exhaust ports 15 and 16. Further, on the front surface 2 a of the outer casing 2, a large number of connectors 18 and the like are provided at positions corresponding to the lower portions of the projection lens 12 and the first and second exhaust ports 15 and 16.
[0013]
In the outer casing 2, a first exhaust mechanism for exhausting high-temperature heat generated by the light source unit 11 a of the optical unit 11, which is a first internal heat source, from the first exhaust port 15 to the outside of the outer casing 2. 21 and a second exhaust mechanism 26 that exhausts low-temperature heat generated by the set power supply substrate 13 and the light source power supply substrate 14 serving as the second internal heat source from the second exhaust port 16 to the outside of the outer casing 2. And are provided.
[0014]
The first exhaust mechanism 21 is disposed inside one side 2b (FIG. 4), which is one side of the optical unit 11, and is disposed between the light source unit 11a and the first exhaust port 15. A rectangular tube-type or cylindrical-type first exhaust duct 22 formed by a connected heat-resistant synthetic resin or the like, and an intake-side end 22a close to the light source 11a side in the first exhaust duct 22 The first exhaust fan 23, which is an exhaust fan for large output, and the exhaust side end 22b close to the first exhaust port 15 side in the first exhaust duct 22 are integrally formed. The first exhaust mechanism 21 is constituted by a plurality of vertical and parallel first air guide plates 24 which are air guide means. The first exhaust fan 23 is screwed into the first exhaust duct 22, and the first exhaust duct 22 is screwed onto the lower case 3.
[0015]
Further, the second exhaust mechanism 26 is disposed inside the other side surface 2c (FIG. 6) of the optical unit 11, and extends to the other side portion and the rear side portion of the optical unit 11 as shown by hatching in FIG. A second exhaust duct 27 of a different diameter cylindrical shape that is curved and formed in a substantially J shape or substantially L shape along the inside of the other side surface 2c and the rear surface 2d of the outer casing 2, and the second exhaust duct A rectangular tube-shaped or cylindrical second auxiliary exhaust duct 28 disposed between the second exhaust port 16 and the second exhaust port 16, and the second auxiliary exhaust duct 28 in the vicinity of the second exhaust duct 27 side. A small second exhaust fan 29 disposed in the intake side end portion 28a, and an exhaust side end portion 28b adjacent to the second exhaust port 16 side in the second auxiliary exhaust duct 28. A plurality of second parallel air guide plates 30 that are integrally formed and are parallel to each other. Mind mechanism 26 is configured.
[0016]
The bottom portion of the second exhaust duct 27 curved in a substantially J shape in the second exhaust mechanism 26 is constituted by the set power supply substrate 13 and the light source power supply substrate 14, and the outer side surface portion and the outer rear portion. The surface portion is composed of duct walls 4 c and 4 d that are also used as the upper case 4, the inner rear surface portion is composed of the rear surface portion 11 d of the optical unit 11, and the inner side surface portion is composed of the insulating plate 31. The insulating plate 31 is attached to the lower case 3 by fastening with the set power supply board 14 with screws or the like, and the insulating plate 31 is raised substantially in an L shape above the set power supply board 14. . Then, the distorted portion 11c portion existing from the side surface portion to the front surface portion of the optical unit 11 by the vertical portion 31a raised vertically from the set power supply substrate 14 of the insulating plate 31 is used as a duct of the upper case 4. A horizontal part 31b that covers the wall 4c substantially in parallel and is bent horizontally outward from the vertical part 31a is disposed at the upper position of the second exhaust duct 27 (FIGS. 1 and 6). A plurality of intake ports 32 formed by a large number of parallel slits are formed at a plurality of locations corresponding to the bottom of the second exhaust duct 27 at the bottom of the lower case 3.
[0017]
Then, like the second exhaust duct 27, the duct walls 4c and 4d also used as the upper case 4, the rear surface portion 11d of the optical unit 11 and the insulating plate 31 have different shear surface shapes, and are almost loose. If a long exhaust cavity curved in a J shape is configured, an exhaust cavity having a large area and excellent air circulation can be easily formed inside the outer casing 2. Accordingly, large heat generating components such as the set power supply board 13 and the light source power supply board 14 can be easily accommodated in the second exhaust duct 27 and efficiently cooled by air. It is also effective in reducing costs by reducing man-hours.
[0018]
The first and second exhaust mechanisms 21 and 26 have a plurality of vertical and parallel first and second air guide plates 24 and 30 so that the exhaust hot air described later does not enter the projection light beam described later. The exhaust hot air is configured as a wind guiding means for guiding the projected light flux to the left and right sides of the projection light flux. The plurality of first and second wind guide plates 24 and 30 which are parallel in the vertical direction are provided on the projection lens 12. A symmetrical inclination angle θ2 is set that spreads in the left and right sides toward the front of the outer casing 2 with respect to a reference line P4 parallel to the optical axis P2.
[0019]
Next, an intake mechanism 35 is horizontally incorporated in the lower position of the optical unit 11 inside the bottom surface 2e of the outer casing 2, and is formed by a plurality of parallel slits formed at the bottom of the lower case 3. The intake mechanism 35 is configured by an intake port 36, an intake fan 37 such as a sirocco fan, and an intake duct 38. The intake duct 38 has three inlets 39 for sending cooling air from below into an image composition unit 11b of the optical unit 11 described later, and one inlet 40 for sending cooling air from below into the light source unit 11a. Is provided.
[0020]
  Next, the optical unit 11 will be described with reference to FIG. 8. First, the light source unit 11 a of the optical unit 11 is incorporated in the reflecting mirror 46, which is a reflector housed in the light source unit cover 45, and in the center of the reflecting mirror 46. And a discharge lamp 47 such as a high-pressure mercury lamp as a light source. And opened to the front side of the light source unit cover 45ExcretionAn intake side end 22a of the first exhaust duct 22 and the first exhaust fan 23 in the first exhaust mechanism 21 face the air opening 45a. Next, the image synthesizing part 11b of the optical unit 11 is arranged at the front end part in the optical unit cover 49, and this image synthesizing part 11b is arranged on the optical axis P11 which is on the extension line of the optical axis P2 of the projection lens 12. Three square modulation prisms (image synthesis means) and three spatial modulation elements arranged in parallel and close to the three surfaces excluding the projection lens 12 side of the cross prism 50 Liquid crystal panels 51R, 51G, 51B and the like. Each of the liquid crystal panels 51R, 51G, 51B has an incident-side polarizing plate 52a and an emitting-side polarizing plate 52b arranged on the incident surface and the emitting surface, respectively, and modulates the incident light based on the applied signal and emits it. It constitutes a light valve.
[0021]
In the optical unit cover 49, the optical axis P12 of the white light emitted from the light source unit 11a is arranged at right angles to the optical axis P11, and each liquid crystal panel 51R, The first and second multi-lens arrays 53a and 53b, which are means for uniformizing the light irradiating the surfaces of 51G and 51B, are disposed, and further, polarized light that converts light from the light source unit 11a into light having a predetermined polarization direction. A PS converter 54 serving as conversion means and a condenser lens 55 are arranged. Then, the white light emitted from the light source unit 11a is reflected at 90 ° by the mirror 56a disposed on the optical axis P12 so as to be inclined at 45 °, and is optically parallel to the optical axis P12 of the projection lens 12. On P13, a first dichroic mirror 57a for G transmission and R reflection for B and a mirror 56b are respectively inclined at 45 °. Then, the second dichroic mirror 57b for G reflection, the relay lens 58a, and the R lens for R reflection are reflected on the optical axis P14 reflected at 90 ° with respect to the optical axis P13 by the first dichroic mirror 57a. A mirror 56c is arranged. The dichroic mirror 57b is inclined at 45 ° with respect to the optical axes P11 and P14 at the intersection of the optical axes P11 and P14.
[0022]
The mirror 56c is inclined at 45 ° with respect to the optical axis P14, and the relay lens 58b and the R reflecting mirror 56d are disposed on the optical axis P15 reflected at 90 ° by the mirror 56c. Two liquid crystal panels 51R and 51B are arranged on the optical axes P16 and P17 that are reflected by the two mirrors 56b and 56d at 90 ° and incident on the left and right sides of the cross prism 50 from the opposite sides, respectively, and are dichroic mirrors. One liquid crystal panel 51G is arranged on the optical axis P11 which is reflected at 90 ° by 57b and is incident on the cross prism 50. Further, condensing lenses 59a, 59b, and 59c are disposed at positions on the opposite sides of the liquid crystal panels 51R, 51G, and 51B on the three optical axes P11, P16, and P17 from the cross prism 50, respectively. In addition, between the cross prism 50 of the image composition unit 11b and the three liquid crystal panels 51R, 51G, and 51B, and the three liquid crystal panels 51R, 51G, and 51B and the three condenser lenses 59a, 59b, and 59c, An air cooling gap 60 is formed vertically between the two.
[0023]
As shown in FIGS. 1, 5 and 7, three inlets 39 corresponding to the liquid crystal panels 51R, 51G, 51B are formed in a U-shape in the upper part of the intake duct 38 of the intake mechanism 35, A single inlet 40 is formed at the top of the front end of the intake duct 38. Then, at the bottom 49a and the top 49b of the optical unit cover 49 of the optical unit 11, vertical air cooling is formed on both sides of the three liquid crystal panels 51R, 51G, 51B on the three surfaces around the cross prism 50 described above. Three bottom opening portions 49c and an upper opening portion 49d are arranged in a U-shape at the vertical position of the gap 60. The three second inlets 39 formed in the intake duct 38 are opposed to the lower portions of the three bottom openings 49c. Further, the inlet 40 formed at the upper end of the intake duct 38 is connected to the lower portion of the intake opening 45 b of the light source cover 45 through the bottom opening 49 e formed in the bottom 49 a of the optical unit cover 49. Yes.
[0024]
The optical unit 11 is configured as described above, and white light emitted when the discharge lamp 47 of the light source unit 11a is turned on is reflected by the reflecting mirror 46 to become almost parallel light, and this white light is incident on the optical axis P12. Is emitted along. Then, the white light is formed into uniform white light having no luminance unevenness by the first and second multi-lens arrays 53a and 53b formed of a large number of lenses. That is, the substantially parallel light of the white light is divided into a large number of light beams by the large number of lenses of the first multi-lens array 53a, and then the large number of light beams are approximately at the centers of the corresponding many lenses of the second multi-lens array 53b. The condensed light is transmitted through the PS converter 54 and polarized and converted, and the condenser lens 55 collects light so as to irradiate a region corresponding to the liquid crystal panel surface, thereby causing uneven brightness. Uniform white light without light is formed. Then, the uniform white light without unevenness of brightness is incident almost uniformly on the entire surface of three liquid crystal panels 51R, 51G, and 51B, which will be described later, via the optical axes P11, P13, P14, P15, P16, and P17. Will be.
[0025]
At this time, the white light is reflected and / or transmitted through the color separation means constituted by the mirrors 56a, 56b, 56c, 56d and the dichroic mirrors 57a, 57b, so that the wavelength band is red light and green light. The light is divided into light of three colors, that is, G and B that is blue light (hereinafter, red light, green light, and blue light are simply referred to as R, G, and B). First, the white light is reflected by the mirror 56a, changes the traveling direction from the optical axis P12 to the optical axis P13 to 90 °, and then enters the first dichroic mirror 57a. The first dichroic mirror 57a reflects R and G, changes the traveling direction by 90 ° to the optical axis P14, and transmits B. The R and G reflected by the first dichroic mirror 57a are incident on the second dichroic mirror 57b. The second dichroic mirror 57b transmits R, reflects G, and travels 90 ° toward the optical axis P2. change.
[0026]
Then, R that has passed through the second dichroic mirror 57b passes through the relay lens 58a on the optical axis P14, is reflected by the mirror 56c, changes its traveling direction by 90 °, and passes through the relay lens 58b on the optical axis P15. Thereafter, the light is reflected by the mirror 56d and the traveling direction thereof is changed by 90 °, and enters the incident surface of the liquid crystal panel 51R through the condenser lens 59a on the optical axis P16.
[0027]
Further, G reflected by the second dichroic mirror 57b and changing the traveling direction by 90 ° is incident on the incident surface of the liquid crystal panel 51G via the condenser lens 59b on the optical axis P11. Further, B reflected by the mirror 56b and changing the traveling direction by 90 ° is incident on the incident surface of the liquid crystal panel 51B via the condenser lens 59c on the optical axis P17.
[0028]
In this case, the three light beams R, G, and B are aligned in the polarization direction by the incident-side polarizing plates 52a of the three liquid crystal panels 51R, 51G, and 51B, and are incident on the three liquid crystal panels 51R, 51G, and 51B. To do. The three liquid crystal panels 51R, 51G, and 51B are modulated by the applied video signal corresponding to each wavelength band, and the polarization plane of the light is rotated. With respect to the three lights R, G, and B whose polarization planes are rotated, video light is obtained by transmitting a predetermined polarization component by the exit side polarization plate 52b of each of the three liquid crystal panels 51R, 51G, and 51B. These three image lights of R, G, and B are incident on the three surfaces of the cross prism 50 from the three optical axes P11, P16, and P17.
[0029]
The cross prism 50 reflects the R and B image light at 90 ° by two orthogonal reflecting surfaces 50a and 50b, and transmits the G image light at the two reflecting surfaces 50a and 50b. The cross prism 50 combines three image lights of R, G, and B. Then, the combined three image lights of R, G, and B are projected onto the projection surface 61 such as a screen by the projection lens 12, and a full-color image (video) is projected on the projection surface 61.
[0030]
By the way, during the projection of the image onto the projection surface 61 by the optical unit 11, the light source unit 11a is heated to the highest temperature by the heat generated by the discharge lamp 47. In addition, the three liquid crystal panels 51R, 51G, and 51B arranged on the three surfaces around the cross prism 50 in the image synthesizing unit 11b of the optical unit 11, and the incident surface and the emission surface, which are both surfaces thereof, are arranged. The incident side polarizing plate 52a and the outgoing side polarizing plate 52b are heated by the heat accompanying absorption of light whose polarization plane is rotated by application of an image signal or absorption of light of an unnecessary polarization component of incident light. The temperature of the entire image composition unit 11b also rises. Furthermore, since heat-generating components such as capacitors and ICs are mounted on the set power supply substrate 13 and the light source unit power supply substrate 14, heat is also generated on the set power supply substrate 13 and the light source unit power supply substrate 14. Will occur.
[0031]
Therefore, in the liquid crystal projector 1, during the image projection, the first and second internal heat sources such as the light source unit 11a and the image synthesis unit 11b of the optical unit 11 and the power source substrate 13 for setting and the power source substrate 14 for light source unit. The first exhaust mechanism 21, the intake mechanism 35, and the second exhaust mechanism 26 can efficiently and forcibly cool the heat generated by the first exhaust mechanism 21 and the second exhaust mechanism 26.
[0032]
Here, the forced air cooling operation of the light source unit 11a and the image composition unit 11b of the optical unit 11 will be described with reference to FIGS. 1 to 8. First, the intake fan 37 of the intake mechanism 35 shown in FIG. External cooling air is sucked into the intake duct 38 from the intake port 36 on the bottom surface 2 e of the housing 2, and a part of the external cooling air is drawn from the three inlets 39 on the proximal end side of the intake duct 38 to the optical unit 11. Three liquid crystal panels 51R on three surfaces around the cross prism 50 shown in FIGS. 7 and 8 are sent vertically to the lower part of the image synthesizing part 11b through the three bottom opening parts 49c. , 51G, 51B are fed vertically into the air-cooling gap 60 on both sides from the lower side to the upper side, and around the cross prism 50 and around the liquid crystal panels 51R, 51G, 51B, Force cool the incident side polarization plate 52a and the incident-side polarization plate 52b portion of the respectively. Along with this, another part of the external cooling air sucked into the intake duct 38 is fed into the light source part cover 45 in the light source part 11a of the optical unit 11 from the inlet 40, and the bottom opening 49e and the intake opening 45b. Through.
[0033]
  At the same time, the first exhaust fan 23 of the first exhaust mechanism 21 is actuated to generate hot hot air in the light source unit cover 45 from the exhaust opening 45a of the light source unit cover 45 in the light source unit 11a. While forced intake into the intake side end 22 a of the first exhaust duct 22, hot air at the outer peripheral portion of the light source cover 45 is also forced into the intake side end 22 a of the first exhaust duct 22. Then, the first exhaust hot air 41 forcedly sucked into the first exhaust duct 22 is changed to the first exhaust duct 22.ExcretionThe air is forcedly exhausted from the first exhaust port 15 of the front surface 2 a of the outer casing 2 through the air duct 22.
[0034]
As a result, in the light source unit 11a, the forced intake action of the external air by the intake mechanism 35 and the forced exhaust action of the first exhaust mechanism 21 are performed in synergy, and the light source unit 11b is efficiently forced to be forced. Can be air-cooled. At this time, the air is sucked into the air intake duct 38 by the air intake fan 37 of the air intake mechanism 35 and is passed through the three inlet openings 39 through the three bottom openings 49c at the three positions around the cross prism 50 in the optical unit cover 49. The incident side polarizing plate 52a and the incident side polarizing plate 52b on both side surfaces of the cross prism 50 and the three liquid crystal panels 51R, 51G, 51B by a part of the external cooling air sent from below into the vertical air cooling gap 60. Is also effectively air-cooled. A part of the external air sent into the air cooling gap 60 from below is sucked into the light source cover 45 in the optical unit cover 49 by the suction action by the first exhaust fan 23 of the first exhaust mechanism 21. After exiting the optical unit cover 49 from the three upper openings 49d, the light is sucked into the outer peripheral portion of the light source cover 45 and exhausted from the exhaust port 15 by the first exhaust duct 22.
[0035]
Next, the forced air cooling operation of the set power supply board 13 and the light source unit power supply board 14 will be described with reference to FIGS. 1 to 8. When the second exhaust fan 29 of the second exhaust mechanism 26 is operated, the outer casing is operated. The external cooling air is sucked into the second exhaust duct 27 from the plurality of air inlets 32 on the bottom surface 2e, and is generated in the power supply board 13 for the set and the power supply board 14 for the light source unit in the second exhaust duct 27. The second hot exhaust air 42, which is the generated heat, is forcibly exhausted from the second exhaust port 16 on the front surface 2a of the outer casing 2 to the outside through the second auxiliary exhaust duct 28. At this time, since the second exhaust duct 27 has good air fluidity as described above, the hot air exhaust efficiency is good, and large heat-generating components such as the set power supply board 13 and the light source power supply board 14 are used. Efficient forced air cooling can be achieved.
[0036]
Next, a description will be given of the wind guide action of the exhaust hot air by the plurality of first and second wind guide plates 24 and 30 constituting the air guide means in the first and second exhaust mechanisms 21 and 26, respectively.
[0037]
As shown in FIG. 1, the liquid crystal projector 1 includes a first exhaust hot air 41 that is high-temperature heat generated by a light source unit 11a that is a first internal heat source, and a set that is a second internal heat source. The second exhaust hot air 42, which is heat generated by the power supply board 13 for the light source and the power supply board 14 for the light source unit, is enclosed by the first and second exhaust fans 23 and 29 in the first and second exhaust mechanisms 21 and 26. 2 is exhausted from the first and second exhaust ports 15 and 16 of the front surface 2a to the front side of the outer casing 2 in the same direction as the image projection direction by the projection lens 12.
[0038]
At this time, the exhaust direction of the first and second exhaust hot air 41 and 42 discharged from the first and second exhaust ports 15 and 16 to the front of the outer casing 2 is parallel to the optical axis P2 of the projection lens 12. In particular, a short focal length lens having a short focal length is used as the projection lens 12, and the projection angle (field angle) of the projected luminous flux 62 of the image projected on the projection surface 61 such as a screen by the projection lens 12 is used. ) When θ is large, a part of the first and second exhaust hot air 41 and 42 enters a part of the projection light beam 62, and the refractive index of the air in the projection light beam 62 at the intrusion part. A non-uniform region of air density that changes locally is generated. As a result, image quality deterioration due to a hot flame phenomenon that causes image fluctuation or distortion in a part of the image projected onto the projection surface 61 through the non-uniform region of the air density occurs.
[0039]
Therefore, in the liquid crystal projector 1, as shown in FIG. 1, the first and second exhaust mechanisms 21 and 26 have a plurality of first and second air guide plates 24 and 30 that are vertical and parallel to each other. A tilt angle θ2 having a symmetrical shape that spreads in the left and right sides toward the front of the outer casing 2 with respect to a reference line P4 parallel to the optical axis P2 of the projection lens 12 is set. Also in the second exhaust ports 15 and 16, a symmetrical opening angle θ1 is set to the left and right sides with respect to the reference plane P3 perpendicular to the optical axis P2 of the projection lens 12.
[0040]
As a result, the first and second exhaust hot air 41 and 42 exhausted from the first and second exhaust ports 15 and 16 to the front of the outer casing 2 are projected onto the projection surface 61 by the projection lens 12. The light beam 62 can escape to the area outside the projection light beam 62 in the directions of arrows A and B on both the left and right sides. Accordingly, part of the first and second exhaust hot air 41 and 42 exhausted from the first and second exhaust ports 15 and 16 to the front of the outer casing 2 has entered the projection light beam 62 of the projection lens 12. In addition, it is possible to prevent the image quality deterioration such as image fluctuation and distortion due to the hot flame phenomenon from occurring in a part of the image projected on the projection surface 61, and always project a good quality image on the projection surface 61. it can.
[0041]
Next, the action of hanging the liquid crystal projector 1 on the ceiling 64 of the house will be described with reference to FIG. As described above, in the liquid crystal projector 1, the optical axis P2 of the projection lens 12 is disposed on the center P1 in the left-right direction of the outer casing 2, and the first and second exhaust ports 15, 16 and the first and second The exhaust mechanisms 21 and 26 are arranged symmetrically on the left and right sides of the center P1 of the outer casing 2, so that the projection lens and the color which occupy a large proportion of the weight of the entire projection display device. Since the optical unit for performing separation / combination is located at the center, it is easy to balance the weight of the liquid crystal projector 1 in the left-right width direction. Accordingly, when the operator hangs the liquid crystal projector 1 upside down with both hands and hangs the liquid crystal projector 1 on the ceiling 64 with a ceiling bracket (not shown), the liquid crystal projector 1 is moved in the horizontal direction. Inclination is unlikely to occur. Further, in order to suspend the liquid crystal projector 1 from the ceiling 64, when the operator lifts the liquid crystal projector 1 with both hands overhead and mounts the liquid crystal projector 1 on the ceiling 64, the weight balance of the liquid crystal projector 1 in the horizontal direction is taken. Since it is difficult, accidents such as falling and falling are lost in advance, and the liquid crystal projector 1 can be safely suspended from the ceiling 64.
[0042]
In addition, when the operator lifts the liquid crystal projector 1 over his head with both hands to hang the liquid crystal projector 1 on the ceiling 64, the projection lens 12 can be easily positioned over the operator's head. The projection lens 12 can be positioned at the center of the projection surface 61 such as a screen hung on a wall or the like using the head position of the head as a guide, and the workability of the operation of hanging the liquid crystal projector 1 from the ceiling 64 is dramatically improved. Can be improved.
[0043]
Next, modified examples of the embodiment of the liquid crystal projector 1 and the like will be sequentially described with reference to FIGS. First, in the first modification of the liquid crystal projector 1 shown in FIG. 10, the first and second exhaust fans 23 and 29 which are the air guiding means of the first and second exhaust mechanisms 21 and 26 are provided in the first. The arrow A which is disposed in the exhaust side end 22b of the exhaust duct 22 and the exhaust side end 28b of the second auxiliary exhaust duct 28 and which is the exhaust direction of the first and second exhaust fans 23 and 29 , B direction is set to a symmetrical tilt angle θ2 that spreads in the left and right sides toward the front of the outer casing 2 with respect to a reference line P4 parallel to the optical axis P2 of the projection lens 12.
[0044]
As a result, the first and second exhaust hot air 41 and 42 exhausted to the front of the outer casing 2 from the first and second exhaust ports 15 and 16 by the first and second exhaust fans 23 and 29 are projected to the projection lens. 12, the projection light beam 62 of the image projected onto the projection surface 61 can be symmetrically escaped in the left and right sides in the directions of arrows A and B, and these are the same as in the basic embodiment described above. It is possible to prevent the occurrence of image quality deterioration such as fluctuation and distortion of an image projected on the projection surface 61 due to part of the first and second exhaust hot air 41 and 42 entering the projection light beam 62. it can.
Further, only the exhaust hot air 41 from the light source unit 11 a that is higher in temperature than the exhaust hot air 42 from the set power supply substrate 13 and the light source power supply substrate 14 constituting the power supply unit is supplied to the first exhaust fan 23. It may be inclined in the exhaust direction A by an inclination angle θ2 so as not to enter the projection light beam 62.
[0045]
Next, the second modified example of the liquid crystal projector 1 shown in FIG. 11 shows only the first exhaust port 15 and omits the second exhaust port 16, but is formed of heat-resistant synthetic resin or the like. On the front surface of the outer casing 2, a plurality of first and second air guide plates 24 and 30 which are vertical and parallel as air guide means are integrally formed in the first and second exhaust ports 15 and 16, These first and second air guide plates 24 and 30 are symmetrically inclined so as to spread in the left and right sides toward the front of the outer casing 2 with respect to a reference line P4 parallel to the optical axis P2 of the projection lens 12. The angle θ2 is set. And according to this 2nd modification, there can exist an effect similar to basic embodiment mentioned above.
[0046]
Next, the third modification of the liquid crystal projector 1 shown in FIG. 12 shows only the first exhaust port 15 and omits the second exhaust port 16, but is formed of a heat-resistant synthetic resin. A plurality of vertical and parallel air guide plates 67 as air guide means are integrally formed in the front grill 66, and the front grill 66 is formed in the first and second exhaust ports 15 and 16 of the front surface 2 a of the outer casing 2. Are mounted symmetrically and detachably. The air guide plates 67 in the front grille 66 are symmetrically inclined so as to spread in the left and right sides toward the front of the outer casing 2 with respect to a reference line P4 parallel to the optical axis P2 of the projection lens 12. The angle θ2 is set. And according to this 3rd modification, there can exist an effect similar to the 2nd modification mentioned above.
[0047]
Next, the fourth modified example of the liquid crystal projector 1 shown in FIG. 13 shows only the first exhaust port 15 and omits the second exhaust port 16, but the third modified example described above. A partial spherical surface 68 having a shape obtained by cutting a part of the spherical surface is formed on the outer peripheral surface of the front grill 66 shown in FIG. 6 and is formed on the inner peripheral surfaces of the first and second exhaust ports 15 and 16 of the front surface 2a of the outer casing 2. An inclination angle adjusting mechanism of the air guide plate 67 that allows the inclination angle of the air guide plate 67 to be freely adjusted by slidably supporting the partial spherical surface 68 on the outer periphery of the front grille 66 with the formed partial spherical surface 69. 70 is shown. That is, in this case, the front grill 66 can be freely rotated and adjusted in two circumferential directions orthogonal to the center of the partial spherical surface 69, and the rotation of the front grill 66 can be used to adjust the wind guide plate 67. The inclination direction can be freely adjusted in all directions (360 °).
[0048]
Next, a fifth modification of the liquid crystal projector 1 shown in FIG. 14 shows another example of the tilt angle adjusting mechanism 70 of the air guide plate 67, and a plurality of vertical and parallel guides. One end of the wind plate 67 is rotatably supported by a plurality of fulcrum pins 71, and one angle adjusting link 72 is connected to the other end side of these wind guide plates 67 by a plurality of connecting pins 73. Then, by sliding the link 72 in the longitudinal direction, the plurality of air guide plates 67 can be simultaneously rotated around the plurality of fulcrum pins 71 so that the inclination angles of the plurality of air guide plates 67 can be freely adjusted. It is a thing.
[0049]
Although the embodiments of the present invention have been described above, the present invention is not limited to the above-described embodiments, and various modifications can be made based on the technical idea of the present invention.
[0050]
【The invention's effect】
The projection display device of the present invention configured as described above generates heat at two locations respectively generated by the first and second internal heat sources having different temperatures such as the light source unit and the power source unit in the outer casing. And the first and second exhaust mechanisms having the second exhaust fan can be independently exhausted, so that the first and second internal heat sources in the outer casing are separately provided, Air cooling can be performed efficiently without being influenced by heat mutually, and the air cooling efficiency of the entire outer casing can be significantly improved. For example, in the exhaust mechanism that air-cools the power supply unit, it is possible to air-cool electronic components of other circuits without being affected by the heat from the light source unit that is a higher-temperature internal heat source than the power supply unit. Therefore, it is possible to prevent the power supply unit and the electronic components of the circuit from being adversely affected by the high temperature heat from the light source unit, leading to performance deterioration and shortening of the service life. An apparatus can be realized.
[0051]
In addition, since the projection lens is arranged in the approximate center of the outer casing, and the first and second exhaust ports of the first and second exhaust mechanisms are arranged on the left and right sides of the projection lens on the front surface of the outer casing, the projection display It is easy to balance the weight of the entire device, and the projection type display device can be stably suspended from the ceiling of the house, etc. In addition, the exhaust direction of the hot air exhausted from the first and second exhaust ports is used as a projection lens screen. It can be set in the same direction as the projection direction of the image onto the projection surface, etc., so that the hot exhaust hot air is directly scattered to the viewer, causing discomfort, or by the operation of the first and second exhaust fans Wind noise is unlikely to be annoying to the viewer, and usability can be significantly improved. In particular, when the operator holds the projection display device overhead with both hands and attaches it to the ceiling of the house, it is easy to balance the weight of the projection display device, and the projection display device is overhead with both hands. Since the projection lens can be naturally positioned at the overhead position, the projection lens can be easily positioned at the center of the projection surface using the operator's head position as a guide. Easy installation of the projection display device.
[0052]
Further, since the first and second exhaust ducts are provided between the first and second internal heat sources and the first and second exhaust ports, the heat generated by the first and second internal heat sources is the first. And it can exhaust efficiently from the 1st and 2nd exhaust port through the 2nd exhaust duct.
[0053]
In addition, since at least one of the first and second exhaust ducts is also used as a part of the outer casing, the structure and manufacturing are simple, and the cost is reduced by reducing the number of parts and the number of assembly steps. be able to.
[0054]
In addition, since the first and second exhaust ducts are disposed inside the outer casing on both sides of the optical unit disposed substantially at the center of the outer casing, it is easy to balance the weight of the projection display device.
[0055]
Further, since the second exhaust duct inside the outer casing is formed in a substantially J shape or substantially L shape along the duct wall that is also used as the outer casing, the volume in the second exhaust duct can be increased. Thus, a plurality of power supply units such as a set power supply substrate and a light source unit power supply substrate can be easily arranged in the second exhaust duct, and the plurality of power supply units can be efficiently air-cooled.
[0056]
In addition, since the air inlets to the first and second exhaust ducts are formed in the outer casing, the first and second exhaust air is sucked into the first and second exhaust ducts from these air inlets. The second internal heat source can be efficiently forced-air cooled.
[0057]
In addition, since the intake fan and the intake duct that perform forced intake to the image combining unit and the light source unit of the optical unit are arranged at the bottom of the outer casing, the forced intake action to the image combining unit and the light source unit by the intake mechanism and the first The image synthesizing unit and the light source unit can be efficiently forced-air cooled by a synergistic effect with the forced exhausting action by the exhaust mechanism.
[Brief description of the drawings]
FIG. 1 is a partially cutaway plan view illustrating a basic embodiment in which a projection display device of the present invention is applied to a liquid crystal projector.
FIG. 2 is a plan view of the liquid crystal projector with the upper case removed.
FIG. 3 is a front view of the above liquid crystal projector.
FIG. 4 is a top view of the above liquid crystal projector.
FIG. 5 is a bottom view of the above liquid crystal projector.
6 is a cross-sectional view of the above-described liquid crystal projector as viewed in the direction of arrows AA in FIG.
FIG. 7 is a cross-sectional view showing an expanded intake mechanism of the liquid crystal projector.
FIG. 8 is a partially cutaway plan view illustrating the optical unit of the liquid crystal projector.
FIG. 9 is a rear view for explaining the mounting operation of the above liquid crystal projector to the ceiling of the house.
FIG. 10 is a partially cutaway plan view showing a first modification of the liquid crystal projector according to the embodiment.
FIG. 11 is a partially cutaway plan view showing a second modification of the embodiment of the liquid crystal projector.
FIG. 12 is a partially cutaway plan view showing a main part of a third modification of the embodiment of the liquid crystal projector.
FIG. 13 is a partially cutaway plan view showing a main part of a fourth modification of the embodiment of the liquid crystal projector.
FIG. 14 is a partially cutaway plan view showing the main part of a fifth modification of the embodiment of the liquid crystal projector.
FIG. 15 is a partially cutaway plan view illustrating a conventional liquid crystal projector.
FIG. 16 is a rear view for explaining an operation of attaching a conventional liquid crystal projector to a ceiling of a house.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 is a liquid crystal projector which is a projection type display apparatus, 2 is an outer casing, 2a is the front of an outer casing, 3 is a lower case, 4 is an upper case, 4c, 4d is a duct wall used also by the upper case, 5 is a stand part Dual-use adjuster, 6 is a stand unit, 11 is an optical unit, 11a is a light source unit of an optical unit that is a first internal heat source, 11b is an image composition unit of an optical unit that is a first internal heat source, 12 is a projection lens, Reference numerals 13 and 14 denote a second internal heat source and a power supply unit set power supply substrate and a light source unit power supply substrate, 15 and 16 denote first and second exhaust ports, and 21 and 26 denote first and second power sources. Exhaust mechanism, 22 and 27 are first and second exhaust ducts, 23 and 29 are first and second exhaust fans, 35 is an intake mechanism, 32 and 36 are intake ports, 37 is an intake fan, and 38 is an intake duct. It is.

Claims (3)

An optical unit having a light valve is accommodated in an optical unit cover at the rear part of the projection lens disposed almost in the center of the outer casing, and is biased toward one side of the outer casing at the rear end of the optical unit cover. The light source part is disposed in the light source part cover arranged at the position, the exhaust opening is formed on the front side of the light source part cover, and the cooling air sucked by the sirocco fan is used for the light valve and the light source part. A first exhaust duct connected to a first exhaust port formed at a position biased to one end side of the front surface of the outer casing. A first exhaust fan, which is disposed along the inner side of one side surface of the outer casing and is disposed in the intake side end of the first exhaust duct, is adjacent to the exhaust opening of the light source cover, and is 1 exhaust mechanism is configured,
A second exhaust duct connected to a second exhaust port formed at a position biased to the other end side of the front surface of the outer casing is formed along the other side surface of the outer casing; A power supply unit including the light source power supply unit is disposed in the second exhaust duct, and a second exhaust fan is disposed on the second exhaust port side of the second exhaust duct to constitute a second exhaust mechanism. projection display device according to claim <br/> that is. Insulation in which the second exhaust duct of the second exhaust mechanism is disposed between the side surface of the outer casing, the side surface of the optical unit cover, and the side surface of the optical unit cover from the front side of the outer casing. projection display device according to claim 1, characterized in <br/> that are constituted by a plate. By forming the second exhaust duct in the second exhaust mechanism to be substantially J-shaped, the outer casing is a flat box shape, and the left and right side surfaces are rearward and the left and right side surfaces are rearwardly symmetric, and are substantially U-shaped. The projection type display device according to claim 2, wherein the projection type display device is formed in a mold.

Images