JP3506109B2 - projector - Google Patents

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a projector including an electro-optical device that forms an optical image according to image information.

[0002]

2. Description of the Related Art Conventionally, a light source, an electro-optical device that forms an optical image of a light beam emitted from the light source according to image information, and a projection lens that magnifies and projects an image formed by the electro-optical device. There is known a projector including an outer case that houses these components.

Such projectors have been used in conferences, academic societies,
It is widely used for multimedia presentations at exhibitions, etc., and may be brought in as needed, or moved to another place for storage after the end, so miniaturization is promoted.

Further, in order to make a projected image clear by a projector, high brightness of a light source lamp as a light source has been promoted.

In such a projector having high brightness and downsizing, the temperature inside the device easily rises.
It is necessary to efficiently cool the heat-sensitive electro-optical device.

Therefore, an air inlet is formed on the lower surface of the outer case, and a cooling fan for introducing external air as cooling air from the air inlet is provided below the electro-optical device to cool the electro-optical device. ing.

[0007]

However, in the above-described conventional projector, it is necessary to lower the center of gravity in order to ensure stability at the time of installation, and from the desk or the like where the projector is installed to the bottom surface of the outer case. The height dimension of is reduced. Therefore, even if a large amount of cooling air is introduced from the lower surface of the projector by the cooling fan, there is a limit to the amount of air introduced from the gap portion. Especially, in the projector with high brightness and downsizing, the electro-optical device is used. However, there is a problem that it cannot be sufficiently cooled.

It is an object of the present invention to provide a projector having a cooling structure which efficiently cools an electro-optical device and can cope with high brightness of a light source lamp and downsizing of the device.

[0009]

The present invention is a projector including an electro-optical device that forms an optical image according to image information, and an outer case that covers a main body including the electro-optical device. An air inlet for taking in outside air as cooling air is formed on the upper surface of the case, and an exhaust port for discharging the air inside the projector to the outside is formed on the front surface of the exterior case. A cooling fan for cooling the electro-optical device by introducing cooling air from the air intake port is provided above the device.

According to the present invention as described above, since the upper surface of the outer case is normally opened upward, an air inlet is provided on the upper surface, and the cooling air is provided above the electro-optical device from the air inlet. By providing the cooling fan for introducing the inside of the device, it becomes possible to easily blow the cooling air sufficient for cooling the electro-optical device to the electro-optical device. As a result, it is possible to efficiently cool the electro-optical device, and it is possible to obtain a cooling structure that can cope with high brightness of the light source lamp and downsizing of the device.

[0011]

[0012]

[0013]

[0014]

[0015]

[0016]

[0017]

Further, since the exhaust port is formed on the front surface of the outer case, the air taken into the inside of the device by the cooling fan can be exhausted to the front of the device, so that the rear or side of the device can be observed. The exhausted air is not blown on the person, and the observer does not feel uncomfortable.

Further, light leakage from the exhaust port is not recognized by an observer behind or on the side of the device, and the image visibility of the observer can be improved. If the exhaust port is provided with a light-shielding structure that prevents light leakage from the exhaust port, light leakage from the exhaust port can be prevented.

Further, the above-mentioned projector is provided with a projection lens for enlarging and projecting an image formed by the electro-optical device, and an optical component housing for housing the optical components. These projection lens and optical component housing are Are combined and arranged in a plane U shape having a concave portion, and the concave portion faces the front surface side of the outer case, and the concave portion is supplied with electric power to a drive circuit board or the like for driving the electro-optical device. A power supply unit is arranged, and an air outlet heated by the power supply unit and an apparatus fan for discharging the air, which has been taken in by the cooling fan and cooled inside the projector, to the outside of the projector, are independently provided in the exhaust port. A power supply fan for exhausting air is preferably provided.

Here, the power supply unit for supplying electric power to the drive circuit board and the like heats, but since the periphery thereof is surrounded by the optical component casing and the projection lens, there is no escape of heat. Therefore, if an exhaust port and an exhaust fan are provided exclusively for the power supply unit, the air heated by the power supply unit can be actively discharged. Thereby, the temperature rise of the power supply unit is suppressed, and the power supply unit can be easily stabilized.

A temperature detecting device for detecting the temperature of the cooling air in the vicinity of the power supply unit is provided near the power supply unit, and the power supply fan is independently controlled by the temperature detected by the temperature detecting device. Is desirable.

Here, it is preferable that the temperature detecting device is configured to output a detection signal to a control board for controlling the power supply fan. If the temperature detection device is configured in this way, for example, if the temperature of the power supply unit is detected to be high, the rotation speed of the power supply fan is increased to control the power supply unit to cool rapidly, and conversely If it is detected that the temperature is low, the rotation speed of the power supply fan can be decreased to control the power supply unit to be cooled slowly.

The reference temperature, which serves as a reference for the detection temperature being high or low, is appropriately determined on the basis of the results obtained by experiments and the like.

With this configuration, it is possible to easily prevent the temperature from rapidly rising by supplying power to the drive circuit board or the like, and it is possible to easily prevent the power supply unit from being overheated. Become.

Further, a lamp drive circuit board for driving the lamp is provided on the side of the U-shaped main body which is arranged in a planar U-shape by combining the above-mentioned projection lens and the housing for optical components, and the lamp drive circuit board is provided. The circuit board is covered with a protective cover member, and a cooling air introduction flow path for guiding the cooling air taken in from the cooling fan is formed between the projection lens and the optical component housing, and Between the lower surface and the inner lower surface of the outer case, is introduced from the cooling air introduction flow path,
It is preferable that an exhaust flow path that guides the cooling air that has cooled the electro-optical device to the device fan is formed, and an opening that guides part of the cooling air flowing through the exhaust flow path to the inside is formed in the protective cover member.

With this configuration, the inside of the protective cover member can be cooled, so that the inside of the projector can be cooled more efficiently.

Further, since the intake and exhaust passages are formed, the air is efficiently circulated, and the cooling efficiency of the electro-optical device is further improved. Furthermore, by forming the cooling air introduction flow path and the exhaust flow path in this way, the structure inside the projector can be simplified, and the cooling air flows under the optical component housing, so that It is possible to easily cool the optical components such as the lens and the mirror that are arranged.

[0029]

[0030]

[0031]

[0032]

[0033]

[0034]

[0035]

[0036]

[0037]

[0038]

[0039]

BEST MODE FOR CARRYING OUT THE INVENTION A. First Embodiment Hereinafter, a first embodiment according to the present invention will be described with reference to the drawings.

(1) Overall Configuration of Apparatus FIG. 1 is a schematic perspective view of a projector 1 according to this embodiment.

In the projector 1, the luminous flux emitted from the light source lamp as the light source is red (R), green (G) and blue (B).
Are separated into three primary colors, and the respective luminous fluxes of these colors are modulated according to the image information through the liquid crystal panel that constitutes the electro-optical device, and the modulated luminous fluxes of the respective colors are combined by a prism (color combining optical system). , Is of a format in which enlarged display is performed on the projection surface via the projection lens 6. Each component is housed inside an outer case 2 as a housing.

(2) Structure of Exterior Case The exterior case 2 is basically composed of an upper case 3 that covers the upper surface of the device, a lower case 4 that forms the bottom surface of the device, and a rear case that covers the back surface. The upper case 3 and the lower case 4 are made of magnesium die-cast, and the rear case is made of resin.

An air intake port 240 is provided on the upper surface of the upper case 3 substantially at the center right side (right side when viewed from the front).
The air intake 240 is provided in a resin filter replacement lid 241 that covers the opening. Filter replacement lid 241
Inside, an air filter (not shown) is provided. By attaching and detaching the filter exchange lid 241 from the upper surface side of the upper case 3, it is possible to exchange the internal air filter.

On the front surfaces of the upper case 3 and the lower case 4, an exhaust port 160 is formed as a vent for exhausting the air inside the apparatus.

The air intake 24 of such an outer case 2
An AC inlet for supplying external power and various input / output terminal groups (not shown) are arranged on the side surface and the rear surface near 0.

(3) Internal Structure of Device FIG. 2 to FIG. 4 show the internal structure of the projector 1.

As shown in these figures, inside the apparatus 1, a light source lamp unit 8 is arranged on one side of the projection lens 6 with a space, and the projection lens 6 and the light source lamp unit 8 are arranged. An optical unit 10 that constitutes an optical system arranged between them, a driver board (not shown) that drives an electro-optical device 925 in the optical unit 10, a main board (not shown) that controls the entire device 1, and an AC inlet. Light source lamp unit 8 by transforming the power from
, Driver board, main board, electro-optical device 9
25, a power supply unit (not shown) for supplying to a cooling fan 17 arranged above 25, an exhaust fan (not shown) arranged in front of the light source lamp unit 8, and the like. The power supply unit may be divided into a plurality of parts in consideration of the arrangement space in the device 1.

The light source lamp unit 8 is the projector 1
As shown in FIG. 5, it has a light source 183 composed of a light source lamp 181 and a concave mirror 182, and a lamp housing (not shown) for accommodating the light source 183. The light source lamp unit 8 as described above is cooled by the cooling air from the cooling fan 17 or the cooling air sucked from the gap between the exterior case 2 and the projection lens 6. The cooling air first cools the electro-optical device 925 and the like immediately after being sucked, and then flows to the left side so as to cool almost the entire inside of the device 1, and finally most of it is the light source lamp unit. The gas is exhausted from the exhaust port 160 through an exhaust fan (not shown) through the inside of the chamber 8. Therefore, since the light source lamp unit 8 is arranged immediately in front of the exhaust fan, the light source 183 inside thereof is disposed.
Can be efficiently cooled with a large amount of cooling air.

The optical unit 10 is a unit which optically processes the light flux emitted from the light source lamp unit 8 to form an optical image corresponding to image information, and includes an illumination optical system 923, a color light separation optical system 924, Electro-optical device 925,
And a cross dichroic prism 910 as a color light combining optical system. Electro-optical device 92
5 and the optical elements of the optical unit 10 other than the cross dichroic prism 910 are the upper and lower light guides 90.
It is configured so as to be sandwiched and held between the upper and lower portions 1 and 902. The upper light guide 901 and the lower light guide 902 are integrated and fixed to the lower case 4 side with a fixing screw. Here, FIG. 3 is a view showing the inside by inverting the upper light guide 901 removed from the lower light guide 902.

The rectangular parallelepiped cross dichroic prism 910 has a lower light guide 90 as shown in FIG.
It is fixed to the upper surface side of 2 by a fixing screw. In addition, each of the liquid crystal panels 925R and 925 that constitute the electro-optical device 925
25G and 925B are cross dichroic prism 9
It is fixed to the three side surfaces of 10 through fixing members.

Further, although not shown, each liquid crystal panel 925R, 925G, 92 of the electro-optical device 925.
A driver board for driving and controlling 5B is arranged above the optical unit 10, and a main board on which a control circuit for controlling the entire projector 1 is formed is arranged upright behind the optical unit 10. Therefore, the main board and the driver board are arranged at right angles to each other and electrically connected. Further, the AV board provided with the above-mentioned input terminal group is erected in the same manner as the main board and electrically connected to this main board.

The projection lens 6 is provided with a flange 62 on the base end side with respect to the projection direction of the projection lens 6. The flange 62 is formed in a rectangular shape that projects radially outward from the outer peripheral surface of the projection lens 6, and is a square plate-shaped head plate 64 that is erected on the edge of the lower light guide 902.
It is fixed to. As a result, the projection lens 6 is attached to the lower light guide 902.

(4) Structure of Optical System Next, the structure of the optical system of the projector 1, that is, the structure of the optical unit 10 will be described with reference to the schematic diagram shown in FIG.

As described above, the optical unit 10 includes the illumination optical system 923 and the dichroic mirrors 941 and 94.
2 and a color mirror separation optical system 924 including a reflection mirror 943.
And the reflection mirrors 971 and 972, the incident side lens 954,
A relay optical system 927 including a relay lens 973, three field lenses 951, 952 and 953, three liquid crystal panels 925R, 925G and 925B, a cross dichroic prism 910, and a projection lens 6 are provided. On the light incident side surfaces of the liquid crystal panels 925R, 925G and 925B, incident side polarization plates 960B and 960 are respectively provided.
G and 960R are arranged. Also, on the light output side,
Emission side polarization plates 961B, 961G, and 961R are arranged, respectively.

The illumination optical system 923 includes a light source 183 that emits a substantially parallel light beam, a first lens array 921, and a second lens array 921.
Lens array 922, superimposing lens 932, and reflecting mirror 931. The illumination optical system 923 is an integrator illumination optical system for illuminating the image forming areas of the three liquid crystal panels 925R, 925G, and 925B substantially uniformly.

The light source 183 includes a light source lamp 181 as a radiation light source for emitting a radial ray and a light source lamp 181.
And a concave mirror 182 that emits the radiated light emitted from the light source as a substantially parallel light flux. A halogen lamp, a metal halide lamp, or a high-pressure mercury lamp is often used as the light source lamp 181. As the concave mirror 182, it is preferable to use a parabolic mirror or an ellipsoidal mirror.

The first lens array 921 has a structure in which small lenses 9211 having a substantially rectangular contour are arranged in a matrix of M rows and N columns. Each small lens 9211
Divides the parallel light beam incident from the light source into a plurality of (that is, M × N) partial light beams, and forms each partial light beam in the vicinity of the second lens array 922. Each small lens 92
The contour shape of 11 is the liquid crystal panel 925R, 925G,
It is set so as to be substantially similar to the shape of the image forming area of 925B. For example, if the aspect ratio (ratio of horizontal and vertical dimensions) of the image forming area of the liquid crystal panel is 4: 3, the aspect ratio of each small lens is also set to 4: 3.

The second lens array 922 also corresponds to the small lenses 9211 of the first lens array 921,
The small lenses 9221 are arranged in a matrix of M rows and N columns. The second lens array 922 has a function of aligning the central axes (chief rays) of the respective partial light fluxes emitted from the first lens array 921 so that they are vertically incident on the incident surface of the superimposing lens 932. Furthermore, the superimposing lens 932 divides the plurality of partial luminous fluxes into three liquid crystal panels 92.
It has a function of superimposing on 5R, 925G, and 925B. In addition, field lenses 951, 952, 953
Has a function of converting each partial light flux irradiated on the liquid crystal panels 925R, 925G, and 925B into a light flux parallel to each central axis (principal ray). It should be noted that the second lens array 922 includes a reflection mirror 931 as shown in FIG.
The first lens array 921 and the first lens array 921 are inclined by 90 degrees. The reflection mirror 931 is provided to guide the light flux emitted from the first lens array 921 to the second lens array 922. It is not always necessary depending on the configuration of the illumination optical system. For example, the first lens array 921 and the light source are the second lens array 92.
It is not necessary if it is provided in parallel with 2.

In the optical unit 10 shown in FIG. 5, the substantially parallel light flux emitted from the light source 183 is divided into the first and second lens arrays 921 and 921 constituting the integrator optical system.
It is divided into a plurality of partial light beams by 922. The partial luminous fluxes emitted from the respective small lenses 9211 of the first lens array 921 are substantially superimposed on the image forming areas of the liquid crystal panels 925R, 925G, 925B by the superimposing lens 932. As a result, each liquid crystal panel 925R, 925
G and 925B are illuminated by illumination light whose in-plane distribution is substantially uniform.

The color light separation optical system 924 includes two dichroic mirrors 941 and 942 and a reflection mirror 943, and outputs the light emitted from the superimposing lens 932 to red, green and
It has the function of separating the light of three colors of blue. The first dichroic mirror 941 reflects the red light component of the light flux emitted from the illumination optical system 923, and transmits the blue light component and the green light component. The red light reflected by the first dichroic mirror 941 is reflected by the reflection mirror 943, reaches the liquid crystal panel 925R for red through the field lens 951. The field lens 951 converts each partial light flux emitted from the second lens array 922 into a light flux parallel to the central axis (chief ray) thereof. The same applies to the field lenses 952 and 953 provided in front of the other liquid crystal panels 925G and 925B.

Of the blue light and the green light transmitted through the first dichroic mirror 941, the green light is reflected by the second dichroic mirror 942, passes through the field lens 952, and reaches the liquid crystal panel 925G for green. On the other hand, the blue light is the second dichroic mirror 94.
2 through which the incident side lens 954 and the relay lens 973 are transmitted.
Then, the light passes through a relay optical system 927 having a reflection mirror 972 and further through a field lens 953 to reach a liquid crystal panel 925B for blue light. Note that the relay optical system 927 is used for blue light because the optical path of blue light is longer than the optical paths of other color lights, so that the reduction of light utilization efficiency due to light diffusion is prevented. This is because That is, the partial light flux incident on the incident side lens 954 is directly transmitted to the field lens 953.

On the light entrance / exit surface side of the liquid crystal panel 925R,
An incident side polarization plate 960R and an emission side polarization plate 961R are arranged respectively. The incident side polarization plate 960R transmits only specific polarized light of the incident light. The liquid crystal panel 925R modulates the polarized light of the red light emitted from the incident side polarization plate 960R according to the given image information.
The emission side polarization plate 961R transmits only a specific polarized light of the modulated light emitted from the liquid crystal panel 925R.

Incident-side polarization plates 960G and 960B and emission-side polarization plates 961G and 961B are arranged on the light incident / exit surfaces of the liquid crystal panels 925G and 925B, respectively. The liquid crystal panels 925R and 925 of this embodiment are
As G and 925B, for example, one using a polysilicon TFT as a switching element can be adopted.

The cross dichroic prism 910 is
It has a function as a color light combining optical system that combines color lights of three colors to form a color image. The cross dichroic prism 910 includes a dielectric multilayer film that reflects red light,
A dielectric multilayer film that reflects blue light is formed in a substantially X shape along the interfaces of the four rectangular prisms. Three color lights are combined by these dielectric multilayer films.

The light constituted by the cross dichroic prism 910 is emitted toward the projection lens 6. The projection lens 6 has a function as a projection unit that projects the combined light onto a projection surface such as a projection screen to display a color image.

(5) Structure of Projection Lens The projection lens 6 is for enlarging and projecting the input optical image. As shown in FIG. 6, a plurality of lenses 61 arranged along a predetermined axis are provided. I have it. Multiple lenses 6
1 is fixed inside a tubular body 69 composed of a plurality of members. Further, in the vicinity of the base end side with respect to the projection direction of the projection lens 6, a rectangular flange 62 projecting from the outer peripheral surface of the tubular body 69 outward in the radial direction is formed. The flange 62 is formed on the tip side of the base end surface of the projection lens 6.

Of the plurality of lenses 61, the lens 61A disposed closest to the base end side in the projection direction has a shape in which the upper end side thereof is cut out as shown in FIG. Further, according to the shape of the lens 61A, the cylindrical body 6
9 also has a shape in which the upper end side is cut out. And
Of the side surface of the lens 61A, the portion other than the notched portion is covered with the tubular body 69. Further, a cut-out portion of the side surface of the lens 61A is covered with a plate body 67 having a light-shielding property so that dust can be prevented from entering the projection lens 6 and light leakage can be prevented. Has become. The plate 67 has a frame portion 67A along the outer periphery of the lens surface of the lens 61A, and the frame portion 67A has three parts.
It is fixed to the tubular body 69 by one screw 68. The number of lenses 61A whose upper end is notched is set according to the position of the flange 62 formed on the projection lens 6.

Further, as described above, the projection lens 6 is
It is fixed to the lower light guide 902 via a head plate 64 as a support member that supports the base end side. The head plate 64 is formed in a rectangular shape that is slightly larger than the contour of the flange 62. The lens 6 is attached to the head plate 64.
An opening 65 is formed according to the shape of the outer periphery of 1A, and the lens 61A is inserted into this opening 65 (FIG. 4).

Here, in the projection lens of this embodiment, since the upper end side of the lens 61A on the base end side is cut out, unlike the case of the normal circular lens 61,
The area of the opening 65 can be reduced. Therefore,
The height dimension of the head plate 64 can be reduced. Furthermore, since the ratio of the area occupied by the opening 65 to the area of the head plate 64 can be reduced, the head plate 64 can be thinned.

Liquid crystal panels 925R, 925G, 925 as light modulators that constitute the electro-optical device 925.
The center P of the image forming area of B is, as shown in FIG.
An extension line of the axis 60 of the projection lens 6 and the liquid crystal panel 925R,
It is arranged below the intersection Q with 925G and 925B. Therefore, the liquid crystal panels 925R, 925G, 925
The optical image from B is the cross dichroic prism 91.
The light passes through 0 and enters the projection lens 6 from below the axis 60, and also projects so as to pass through the projection lens 6 and spread above the axis 60. Therefore, the lens 6 arranged closest to the base end with respect to the projection direction.
Even if the upper end side of 1A is cut out, the image can be enlarged and projected onto the projection surface without any problem.

(6) Cooling Structure of Electro-Optical Device FIG. 9 shows a cooling structure of the electro-optical device 925 in the projector 1 described above. Electro-optical device 92
5, a cooling fan 17 that introduces external air as cooling air from the air intake 240 to cool the electro-optical device 925 (thickness is, for example, 10 to 15 mm).
Degree) is provided. Since the air intake 240 above the cooling fan 17 is provided above,
There is no limit to the amount of air introduced. Therefore, the cooling fan 17 can easily blow sufficient cooling air to the electro-optical device 925.

In this cooling fan 17, the lens 61A arranged closest to the base end side with respect to the above-mentioned projection direction has a shape in which the upper end side is cut out, so that the cutout portion is brought closer to the electro-optical device 925. It is arranged. On the other hand, a step portion 307 is provided on a pair of vertical walls 64A formed substantially perpendicular to the mounting surface of the projection lens 6 of the head plate 64, and the liquid crystal panels 925R and 925R of the upper light guide 901.
A step portion 308 is provided on the surface facing the 25G and 925B. The cooling fan 17 includes the step 307 and the step 3
08 and is fixed by screws. The height positions of the step portion 307 and the step portion 308 are determined by the electro-optical device 9
Even if the cooling fan 17 is provided above the cooling fan 25,
The upper end of 7 does not protrude from the upper edge of the head plate 64.

The lower light guide 902 on which the electro-optical device 925 is installed is mounted on the guide member 301 protruding from the upper surface of the lower case 4. As a result, a gap 302 having a height dimension H of about 8 mm is formed between the upper surface of the lower case 4 and the lower surface of the lower light guide 902. In addition, the electro-optical device 925
A hole 303 communicating with the gap 302 is formed in the peripheral lower light guide 902. By doing this,
The cooling air introduced by the cooling fan 17 flows as shown by the arrow in FIG. 9, and fresh cooling air is constantly blown to the electro-optical device 925, and then the gap 302 is formed.
It is possible to efficiently cool the power source unit and the light source lamp unit 8 disposed inside the device 1 by circulating the gas through the device.

The above-mentioned air intake 240 has a light blocking structure 305 in order to prevent light leakage from the air intake 240 to the outside of the apparatus. The light shielding structure 305 is formed in a louver shape in which a plurality of plate members 306 are arranged in parallel across the air intake 240. Each plate member 306
Are arranged so as to be inclined toward the rear side of the device 1. This makes it difficult to see the inside from the outside, that is, almost no light leaks to the outside. Here, even if the light leaks to the outside, the leaked light is emitted from the gap between the plate-shaped members 306 toward the front of the device 1, that is, the emission direction of the leaked light is regulated,
Leaked light is prevented from entering the eyes of an observer behind the device. Therefore, the air intake port 240 is formed to have two functions, that is, a function of preventing light leakage and a function of introducing the cooling air described above.

Next, the procedure for cooling the electro-optical device 925 will be described.

First, by the rotation of the cooling fan 17, the cooling air is forcibly taken into the inside of the apparatus 1 from the air intake 240. The cooling air taken in flows as shown by the arrow in FIG. 9 and is blown onto the electro-optical device 925. The air blown into the holes 303 and the gaps 30.
2 and flows along the lower case 4 to cool the light source lamp unit 8 inside the device 1, the power supply unit, etc.,
It is discharged to the outside of the device 1 by an exhaust fan.

(7) Effects of First Embodiment According to the present embodiment as described above, the following effects can be obtained.

That is, the air inlet 240 is provided on the upper surface of the exterior case 2 which is open at the upper side, and the cooling fan 17 for introducing the cooling air from the air inlet 240 into the inside of the device 1 is provided above the electro-optical device 925. Since there is no limit on the amount of air to be introduced, it is possible to easily blow sufficient cooling air to the electro-optical device 925 to cool the electro-optical device 925. As a result, the electro-optical device 925 can be efficiently cooled, and a cooling structure that can cope with higher brightness of the light source lamp 181 and downsizing of the device 1 can be obtained.

Further, the lens arranged closest to the base end side with respect to the projection direction is a lens 61A whose upper end side is cut out to have a substantially flat surface, and the upper end side is cut out, so that the electro-optical device 925 has a lens. Since the cooling fan 17 provided above is arranged close to the electro-optical device 925, cooling air with large wind force can be introduced into the electro-optical device 925, and the electro-optical device 925 can be cooled more efficiently. . Further, since the cooling fan is provided close to the electro-optical device, the height dimension of the projector 1 can be reduced, and the projector 1 can be downsized and thinned.

Further, the air intake 240 is connected to the light shielding structure 30.
Since it is set to 5, it is possible to prevent light leakage from the air intake 240 and improve the image visibility of an observer behind the device 1. Further, since the louver-shaped light-shielding structure 305 is employed, the light-shielding structure 305 alone can prevent light leakage and introduce cooling air, and the projector 1 can be provided without increasing the number of parts. Can be miniaturized.

B. Second Embodiment Next, a second embodiment according to the present invention will be described with reference to the drawings. The same or corresponding components as those of the first embodiment are designated by the same reference numerals, and the description will be omitted or simplified.

(1) Internal Structure of Device In the second embodiment, one exhaust fan 16 is provided in the vicinity of the exhaust port 160 of the first embodiment.
Two are provided near 60.

More specifically, as shown in FIG. 10, inside the apparatus 1, the projection lens 6 combined in a planar U-shape having a recess 71 and the upper and lower light guides 901 which are optical component casings, 902 (FIG. 2) is the concave portion 7
1 is arranged so as to face the front side of the outer case 2. A power supply unit 9 that supplies electric power to a drive circuit board such as a driver board that drives the electro-optical device 925 is disposed in the recess 71. Further, a rectangular parallelepiped box-shaped protective cover member 72 is arranged on one side of the upper light guide 901 opposite to the power supply unit 9. Inside the protective cover member 72, the light source lamp 1
A lamp drive circuit board for driving 81 is arranged (not shown). On the side surface of the protective cover member 72 facing the upper light guide 901, an opening 72A for introducing cooling air into the protective cover member 72 is formed on the rear side of the device 1, and on the front side of the device 1, An outlet 72B is formed for passing a connection line that connects the above-mentioned substrate and the light source lamp 181 to each other.

An exhaust fan 16, which is a device fan, is provided in front of the light source lamp unit 8, that is, between the end face of the upper light guide 901 and the exhaust port 160. In addition, the power supply fan 1 is provided in front of the power supply unit 9, that is, between the end surface of the power supply unit 9 and the exhaust port 160.
5 are provided. The exhaust fan 16 is for exhausting the air, which has been taken in by the cooling fan 17 and has cooled the inside of the device 1, to the outside of the device 1, and the power supply fan 15 is the air heated by the power supply unit 9. Is for exclusive use of the power supply unit 9 for independently exhausting. The exhaust fan 16 and the power supply fan 15 are arranged adjacent to each other. Here, the width dimension of the exhaust port 160 is larger than the width dimension from one side surface of the exhaust fan 16 to one side surface of the power supply fan 15.

A thermosensor (not shown), which is a temperature detecting device, is provided near the power supply unit 9. The thermosensor is composed of a thermistor that detects the temperature of the heated air near the power supply unit 9. This thermosensor outputs a temperature detection signal to a main board (not shown). The main board uses the signal from the thermo sensor to supply power to the fan 15.
The power supply fan 15 is controlled to control the rotation speed of the power supply fan 15. In other words, the power supply fan 15 is independently controlled by the temperature detected by the thermosensor.

That is, if the thermo sensor detects that the temperature of the power supply unit 9 is high, the rotation of the power supply fan 15 is increased by the control operation of the main board, and the air heated by the power supply unit 9 is rapidly heated by the device 1. Exhausted to the outside. On the contrary, if the thermo sensor detects that the temperature of the power supply unit 9 is low, the control operation of the main board lowers the rotation speed of the power supply fan 15, so that the air heated by the power supply unit 9 is gradually discharged to the outside of the device 1. Exhausted. It should be noted that the reference temperature, which serves as a reference for the detection temperature being high or low, can be appropriately determined based on the results obtained in experiments and the like.

In the present embodiment, the configuration other than the above-described portions, for example, the structure of the optical system is the same as that of the first embodiment described above, and therefore the description thereof is omitted.

Next, the air flow path inside the projector 1 will be described.

In the projector 1, as shown by the arrows in FIG. 11, the cooling air introducing passage 8 is mainly used.
1, device exhaust flow path 85, and power supply unit exhaust flow path 8
4 are formed. However, the air flowing through each of the flow paths 81, 84, 85 does not strictly flow along the arrows in the figure, but is sucked and exhausted substantially through the gaps between the constituent parts as shown by the arrows. Is.

The cooling air introduction flow path 81 is a flow of cooling air sucked from the air intake 240 into the apparatus 1 by the cooling fan 17 arranged between the projection lens 6 and the upper light guide 901 and the lower light guide. It is a road. After cooling the electro-optical device 925, this cooling air is discharged to the outside of the device 1 by the exhaust fan 16 through the device exhaust flow path 85.

The device exhaust flow path 85 is formed between the lower surface of the lower light guide and the inner lower surface of the outer case 2, and the second device exhaust flow path 85 is formed inside the protective cover member 72. A device exhaust flow path 83 is provided. First
The device exhaust flow path 82 is a first flow path of cooling air that has cooled the electro-optical device 925, passes under the lower light guide and the light source lamp unit 8, and is exhausted from the exhaust port 160 to the outside of the device 1 by the exhaust fan 16. Is discharged to. Thereby, the optical unit 1 provided above the lower light guide
0, the light source lamp unit 8 and the like can be efficiently cooled. The second device exhaust flow path 83 is a second flow path of the cooling air that has cooled the electro-optical device 925, and a part of the cooling air passing through the first device exhaust flow path 82 has an opening 72.
Enter the inside of the protective cover member 72 from A, and the outlet 72B
To the outside of the protective cover member 72 from the exhaust fan 16
Is discharged from the exhaust port 160 to the outside of the apparatus 1.

The power supply unit exhaust flow path 84 is a flow path for the air heated by the power supply unit 9, and the heated air is supplied from the exhaust port 160 by the power supply fan 15 to the apparatus 1.
It is discharged to the outside.

(2) Effects of the Second Embodiment According to the second embodiment as described above, the same effects as those of the first embodiment can be obtained and the following effects can be obtained.

That is, since the air outlet 160 for exhausting the air inside the device 1 to the outside is provided on the front surface of the outer case 2, the air taken into the device 1 by the cooling fan 17 is exhausted to the front of the device 1. can do. As a result, the exhausted air is not blown to the observer behind or on the side of the apparatus 1, and the observer does not feel uncomfortable.

Further, since the exhaust port 160 is formed on the front surface of the outer case 2, light leakage from the exhaust port 160 is not recognized by an observer behind or on the side of the apparatus 1 and the image of the observer is visually recognized. It is possible to improve the sex.

Further, the exhaust fan 16 is connected to the exhaust port 160.
And the power supply fan 15 dedicated to the power supply unit 9 are provided, the air heated by the power supply unit 9 can be positively discharged, the temperature rise of the power supply unit 9 can be suppressed, and the power supply unit 9 can be stabilized. Can be easily achieved.

Further, since the thermosensor is provided near the power supply unit 9 and the power supply fan 15 is independently controlled by the temperature detected by the thermosensor, power is supplied to the drive circuit board and the temperature is rapidly changed. It is possible to easily prevent the power source unit 9 from rising, and to easily prevent the power supply unit 9 from being heated.

Further, inside the apparatus 1, a cooling air introduction flow channel 81, a first device exhaust flow channel 82 and a second device exhaust flow channel 8 are provided.
Since the apparatus exhaust flow path 85 and the power supply unit exhaust flow path 84 each including 3 are provided, the inside of the protective cover member 72 can be cooled, and the inside of the projector 1 can be cooled more efficiently.

Further, since the intake and exhaust passages are formed, the air is efficiently circulated, and the electro-optical device 92
The cooling efficiency of No. 5 can be further improved. Further, by forming the cooling air introduction flow path 81 and the exhaust flow paths 84 and 85 in this way, the structure inside the projector 1 can be simplified, and the cooling air flows under the lower light guide. Optical components such as lenses and mirrors arranged inside the upper light guide 901 and the lower light guide can also be easily cooled.

C. Third Embodiment Next, a third embodiment according to the present invention will be described with reference to the drawings. The same or corresponding components as those of the first and second embodiments are designated by the same reference numerals, and the description thereof will be omitted or simplified.

(1) Internal Structure of Device In the third embodiment, a current plate 91 is provided in the gap between the upper light guide 901 and the prism 910 of the first embodiment.

As shown in FIG. 12, cooling is provided at two corners of the upper light guide 901 formed so as to surround the light modulators 925R, 925G, and 925B attached to the side surface of the cross dichroic prism 910. Fan mounting portions 90 for screwing the fans 17 are provided respectively. Of these fan mounting parts 90,
The fan mounting portion 90 on the liquid crystal panel 925B side is provided with a rectifying plate 91 that guides the cooling air from the cooling fan 17 to the liquid crystal panel 925B.

As shown in FIG. 13, the current plate 91 includes an attachment piece 92 attached to the fan attachment portion 90, and
The attachment piece 92 is provided with an extension piece 93 extending vertically from the end of the attachment piece 92 toward the electro-optical device 925 and the lower light guide 902, and is formed in an L-shaped cross section. Then, the tip of the extending piece 93 has an image forming area 94 of the liquid crystal panel 925B.
Extends below the upper edge of the. Here, the image forming area 94 is an area used for forming an image in the central portion of the liquid crystal panel 925B. In this part,
Since the light is concentrated, it is easy to overheat. Further, when a material such as liquid crystal whose modulation characteristic is easily changed by heat is used, the image quality may be deteriorated due to the temperature rise of the image forming area. However, in the present embodiment, since the tip of the extending piece 93 extends below the upper edge of the image forming area 94 of the liquid crystal panel 925B, the cooling air from the cooling fan 17 is directed to the image forming area 9.
4 can be directly sprayed, so that such a problem can be reduced. Further, in the present embodiment, the current plate 91 is connected to the liquid crystal panel 92.
By attaching to the fan attaching portion 90 on the 5B side and directing the surface of the extending piece 93 toward the liquid crystal panel 925B side,
Particularly, a large amount of cooling air is blown onto the image forming area 94 of the liquid crystal panel 925B. Since blue light has a larger energy than other colored lights, it is easy to heat, but in the present embodiment, the cooling air flowing downward while rotating from the cooling fan 17 hits the head plate 64 and is reflected to cool the liquid crystal panel 925B. In addition, the current plate 91
Since the light is reflected by and is blown directly onto the image forming area 94, the blue light image forming area 94 can be efficiently cooled.

(2) Effects of the Third Embodiment According to the third embodiment as described above, the same effects as those of the first and second embodiments can be obtained, and the following effects can be obtained.

That is, since the rectifying plate 91 is provided in the gap between the upper light guide 901 and the prism 910, the cooling air from the cooling fan 17 can be guided to the liquid crystal panel by the rectifying plate 91, and the upper light guide. The air flowing through the gap between the 901 and the prism 910 is efficiently circulated, and the cooling efficiency of the electro-optical device 925 can be further improved.

Further, the current plate 91 is mounted on the upper light guide 901.
Since it is attached to the device, it is not necessary to separately provide a structure for supporting the current plate 91 inside the device, and the structure can be simplified. As a result, the work of attaching the current plate 91 can be easily performed, and as a result, the work of assembling the projector 1 can be performed easily.

Further, since the current plate 91 is attached between the fan attachment portion 90 and the cooling fan 17, the current plate 91 can be fixed to the upper light guide 901 at the same time as the cooling fan 17. In addition, the cooling air introduced from the cooling fan 17 into the inside of the device is efficiently guided to the liquid crystal panel 9
25B, so that the cooling efficiency of the liquid crystal panel 925B can be further improved.

Further, since the tip of the extension piece 93 is extended below the upper edge of the image forming area 94, the cooling air can be applied to the extension piece 93 and directly blown onto the image forming area 94. From this point as well, the cooling efficiency of the liquid crystal panel 925B can be further improved.

Further, the current plate 91 is attached to the liquid crystal panel 925.
Since it is arranged in the vicinity of B, it is easy to overheat the liquid crystal panel 925.
A large amount of cooling air can be blown to B, and a rapid temperature rise of the liquid crystal panel 925R can be suppressed.

D. Modification of Embodiments The present invention is not limited to the above-described embodiments, and includes modifications such as the following.

For example, in the first embodiment, the plate member 306 is arranged so as to incline so as to descend toward the rear side of the device 1. However, the present invention is not limited to this, and for example, the device 1 may be used.
You may incline and may arrange | position so that it may go down toward the front side.

In the first embodiment, the light shielding structure 3
The plate-shaped member 306 having a louver shape is adopted as the member 05, but the plate-like member 306 is not limited to this, and may have any structure that prevents light leakage, and its shape and structure may be appropriately determined in practice.

Furthermore, in the first embodiment, the light shielding structure 305 is provided at the air intake 240, but the invention is not limited to this.
For example, the light shielding structure 305 may be provided so as to cover the filter replacement lid 241 where the air intake port 240 is formed, or may be provided inside the filter replacement lid 241, that is, provided above the cooling fan 17. The air intake 2
It suffices to prevent light leakage from 40 to the outside.

Further, in the first embodiment, the number of lenses with the upper end side cut out is one of the lenses 61A arranged at the most proximal end side with respect to the projection direction, but it is not limited to this. Alternatively, a plurality of sheets may be used. At this time, the number of lenses whose upper ends are notched is set depending on the positions and the number of parts arranged inside the apparatus 1 and the desired size of the projector 1, and the number of lenses is set to the liquid crystal panels 925R, 925G, and
It is desirable to set it so as not to affect the optical image from 925B.

Further, in the second embodiment, the air flow path is composed of the cooling air introduction flow path 81, the apparatus exhaust flow path 85, and the power supply unit exhaust flow path 84, but the present invention is not limited to this. Alternatively, for example, four flow paths may be formed, or 5
One flow path may be formed, and the number, configuration, etc. of the flow paths are
It may be appropriately determined according to the arrangement of each component.

In the second embodiment, the thermosensor is provided near the power supply unit 9 to control the power supply fan 15. However, the present invention is not limited to this.
The heated air may be discharged to the outside of the device 1 at regular intervals.

Further, in the second embodiment, in addition to the exhaust fan 16, the power supply fan 15 for independently exhausting the air heated by the power supply unit 9 is provided. However, the present invention is not limited to this, and in short, the power supply unit. It suffices that the air heated by 9 can be positively discharged, the temperature rise of the power supply unit 9 can be suppressed, and the power supply unit 9 can be easily stabilized.

Further, in the third embodiment, the extension piece 93 is used.
Although the tip of the extended portion is arranged below the upper edge of the image forming area 94, the present invention is not limited to this. For example, if the shape of the extending piece is formed so as to blow cooling air to the image forming area 94, It may be arranged above the upper edge of the image forming area 94.

Furthermore, in the third embodiment, the current plate 9
Although No. 1 is attached to the fan attaching portion 90, the present invention is not limited to this, and for example, an exclusive attaching portion for attaching the current plate to the upper light guide 901 may be provided and attached to this.

Further, in the third embodiment, the current plate 91 is used.
Was attached to the light guide, but is not limited to this and may be attached to the head plate 64, for example.

In the above embodiment, the liquid crystal panel 92 is used.
Although the rectifying plate was provided only for 5B, the present invention is not limited to this. For example, the upper light guide 901 and the prism 910 may be provided.
The liquid crystal panel 925R or the liquid crystal panel 925G may be provided as long as it does not impede the flow of the cooling air in the gap between and.

Further, in the above-described embodiment, the exhaust port 160 is provided on the front surface of the outer case 2, but not limited to this, it may be provided on the side surface of the outer case 2, for example.

In the above embodiment, the electro-optical device 925.
Is a TFT driven liquid crystal panel 925R, 925G, 92
5B, the present invention is not limited to this, and the present invention may be applied to a projector equipped with an optical modulation device configured by another driving method.

In the above embodiment, the electro-optical device 925 has three liquid crystal panels 925R, 925G and 92.
Although it is composed of 5B, the present invention is not limited to this, and the present invention may be adopted in an optical modulation device composed of one or two liquid crystal panels.

In the above embodiment, the electro-optical device 9 is used.
Although the panel constituting 25 is a liquid crystal panel, it may be a panel other than the liquid crystal panel, for example, a device for forming an image by plasma emission, an optical modulator including a device using a micromirror is provided. The present invention may be adopted in a projector.

Further, the electro-optical device 925 in the above embodiment is of a type that transmits and modulates the light fluxes R, G and B, but the invention is not limited to this, and the incident light is reflected and modulated. The present invention may be applied to a projector equipped with a reflection-type light modulation device that emits light.

In addition, the specific structure, shape, and the like when carrying out the present invention may be other structures and the like as long as the object of the present invention can be achieved.

[0128]

According to the present invention as described above, an air inlet for taking in external air as cooling air is formed on the upper surface of the outer case, and the inner air is discharged to the outside on the front surface of the outer case. To form an exhaust port for, to introduce cooling air from the air inlet above the electro-optical device, a cooling fan for cooling the electro-optical device is provided.
Sufficient cooling air can be easily blown to the electro-optical device, and the air taken in by the cooling fan can be exhausted to the front of the device 1. As a result, there is an effect that the electro-optical device can be efficiently cooled, and a cooling structure that can cope with high brightness of the light source lamp and downsizing of the device can be obtained.

[Brief description of drawings]

FIG. 1 is an external perspective view showing a projector according to a first embodiment of the invention.

FIG. 2 is a perspective view showing an internal structure of the projector in the embodiment.

FIG. 3 is a perspective view showing an internal structure of the projector in the embodiment.

FIG. 4 is a perspective view showing an internal structure of the projector in the embodiment.

FIG. 5 is a schematic diagram for explaining the structure of the optical system in the embodiment.

FIG. 6 is a vertical sectional view showing a projection lens in the embodiment.

FIG. 7 is a perspective view showing a projection lens in the embodiment.

FIG. 8 is a diagram showing an optical image in the embodiment.

FIG. 9 is a sectional view of the projector in the embodiment.

FIG. 10 is a perspective view showing an internal structure of a projector according to a second embodiment of the invention.

FIG. 11 is a perspective view showing an air flow path inside the projector in the embodiment.

FIG. 12 is an exploded perspective view showing an internal structure of a projector according to a third embodiment of the invention.

FIG. 13 is a cross-sectional view showing a main part in the embodiment.

[Explanation of symbols]

DESCRIPTION OF SYMBOLS 1 projector 2 exterior case 6 projection lens 8 light source 9 power supply unit 15 power supply fan 16 exhaust fan 17 which is a device fan cooling fan 61 lens 61A lens 71 disposed at the base end side concave portion 72 protective cover member 81 cooling air introduction flow path 84 Power supply unit exhaust flow path 85 Device exhaust flow path 90 Fan mounting portion 91 Rectifying plate 92 Mounting piece 93 Extension piece 94 Image forming area 160 Exhaust port 240 Air intake 305 Light blocking structure 306 Plate-shaped members 901, 902 Optical component housing Upper and lower light guides 925 electro-optical device

─────────────────────────────────────────────────── ─── Continuation of front page (56) Reference JP-A-4-50829 (JP, A) JP-A-4-267232 (JP, A) JP-A-10-186546 (JP, A) JP-A-11- 160793 (JP, A) (58) Fields investigated (Int.Cl. ⁷ , DB name) G03B 21/00 G02F 1/13 505 G03B 21/16 H04N 5/74

Claims (3)

(57) [Claims] 1. A projector comprising: an optical unit that optically processes a light beam emitted from a light source to form an optical image corresponding to image information; and an outer case that covers a main body including the optical unit. The optical unit includes an illumination optical system, a color light splitting optical system that splits a light flux from the illumination optical system including the light source into three color lights, and 3 split by the color light splitting optical system.
Three electro-optical devices for respectively modulating the two colored lights, a cross dichroic prism for combining the optical images from the electro-optical device, and a projection lens for enlarging and projecting the optical image combined by the cross dichroic prism, The illumination optical system and the color light separating optical system are arranged in an optical component casing, the three electro-optical devices are arranged around the cross dichroic prism, and the projection lens and the optical component casing are arranged. Is a combination
And is arranged in a U-shape having a concave portion.
The concave portion faces the front side of the outer case,
A drive circuit board or the like for driving the electro-optical device is provided in the recess.
A power supply unit for supplying electric power to the outer case, and one air inlet for taking in external air as cooling air is formed on the upper surface of the outer case. A cooling fan for cooling the electro-optical device by introducing the cooling air from the air inlet is provided above the two electro-optical devices, and the cooling fan is used to take in the electro-optical device. cold
After disposing, the lower surface of the optical component casing and the exterior case
Through the exhaust passage formed between the inner lower surface of the
The color light separation optical system and the illumination optical system in that order
The air that has cooled the inside of the projector is discharged to the outside of the projector.
Device fan and the cooling fan
Then, cool the electro-optical device and the power supply unit in this order.
Power supply for discharging the exhausted air to the outside of the projector.
And a fan formed on the front surface of the outer case.
A project characterized by being arranged in parallel with the mouth
Ta. 2. The projector according to claim 1, wherein a temperature detection device that detects the temperature of the cooling air near the power supply unit is provided near the power supply unit, and the power supply fan is the temperature detection device. A projector characterized by being independently controlled by the detected temperature. 3. The projector according to claim 1, wherein the lamp is driven to the side of a U-shaped body that is arranged in a planar U-shape by combining the projection lens and the optical component casing. And a lamp drive circuit board for covering the lamp drive circuit board with a protective cover member, and the protective cover member is formed with an opening for guiding a part of the cooling air flowing through the exhaust passage to the inside. Projector.