JP5751508B2 - Image projection device - Google Patents

Description

  The present invention relates to an image projection apparatus.

  2. Description of the Related Art Conventionally, there has been known an image projection apparatus that forms an image by an image forming unit using light emitted from a light source based on image data from a personal computer or a video camera, and projects the image onto a screen or the like. It has been.

The image projection device controls the ballast substrate as a power stabilization unit, the light source, and the image forming unit to supply stable power (current , voltage ) to the light source in response to fluctuations in the light source. A power factor correction (PFC) power supply board is disposed as a power supply board for supplying power to a control board as a control unit for performing the above operation. Further, the PFC power supply board boosts the AC voltage supplied from the power cable for the power stabilizing unit and the control unit.

  The PFC power supply board and the ballast board are provided with a large number of electric elements such as capacitors, coils, and resistors, and these electric elements generate heat and the temperature rises. When the temperature of the PFC power supply board or ballast board rises and becomes high, there is a risk that the operation performance and durability will be lowered.

  Patent Document 1 describes an image projection apparatus that blows air to a PFC power supply board to air-cool the PFC power supply board.

  However, as described above, a large number of electric elements such as capacitors, coils and resistors are attached to the PFC power supply board, and the area of the board itself is large and the air flow direction is long. As a result, on the downstream side of the flow path of the air flowing on the PFC power supply board, air whose temperature has risen due to heat removal from the PFC power supply board on the upstream side flows. As a result, there is a possibility that a portion that is not sufficiently air-cooled is generated on the downstream side of the air flow path of the PFC power supply substrate. For this reason, by increasing the rotation speed of a fan or the like as a blower that blows air to the PFC power supply board, or by using a large fan, the airflow is also increased to the downstream side of the air flow path of the PFC power supply board. Low temperature air can flow. However, when the rotational speed of the blower is increased, wind noise increases, resulting in increased device noise and increased power consumption.

  Further, depending on the size and arrangement position of the air blowing means such as a fan, there may be a portion that is out of the air flow path of the air blowing means on the PFC power supply substrate having a large area, and a portion that is not air-cooled may occur. For this reason, it is necessary to use a large air blowing means and to increase the flow path of the air blown by the air blowing means. In this case, the apparatus becomes large. Furthermore, the PFC power supply board has a large area as described above, and has a large volume because a large number of electric elements are attached thereto. Therefore, the PFC power supply board cannot be arranged in the empty space after arranging the optical elements of the image projection apparatus, and it is necessary to prepare a space for arranging the PFC power supply board. What has been described about the PFC power supply substrate here is also the same for the above-described ballast substrate, and both of them are causes of the enlargement of the apparatus.

The present invention has been made in view of the above problems, and an object of the present invention is to provide an image projection apparatus that has good substrate cooling efficiency and can effectively use the space in the apparatus.

In order to achieve the above object, an invention according to claim 1 is an image projection apparatus that includes a light source provided in a light source unit and projects an image using light from the light source. A substrate holder that is partitioned from the light source unit by a member having an opening, and a power supply substrate that is attached to the first surface and is disposed with the substrate surface facing the light source. A blower for generating an air flow in a space on the substrate holder side with respect to the member and between the light source and the power supply substrate; And a ballast substrate disposed in the direction with the substrate surface facing the second surface.

According to the image projection apparatus of the present invention may cooling efficiency of the substrate, it is possible to effectively utilize the space in the apparatus.

The perspective view which shows the projector and projection surface which concern on this embodiment. An optical path diagram from the projector to the projection surface. FIG. 2 is a schematic perspective view showing a configuration of a projector. FIG. The perspective view of an image forming unit. The schematic perspective view of a light source unit. The perspective view which looked at the projector from the installation surface side. The perspective view which shows a mode that the light source exchange cover was removed from the apparatus. The schematic perspective view which shows the optical component arrange | positioned at an illumination unit. FIG. 3 is a perspective view showing an illumination unit, an image forming unit, and a projection lens unit of a first optical unit. The perspective view which shows a 1st optical unit with an illumination unit and an image formation unit. AA sectional drawing of FIG. The perspective view which shows a 2nd optical unit with a 1st optical unit, an illumination unit, and an image formation unit. The perspective view which shows the 2nd optical system which a 2nd optical unit hold | maintains with a projection lens unit, an illumination unit, and an image formation unit. The perspective view which shows the optical path from a 1st optical system to a projection surface. The schematic diagram which showed the arrangement | positioning relationship of each unit in an apparatus. FIG. 4 is a diagram illustrating an example of use of the projector according to the present embodiment. The figure which shows the usage example of the conventional projector. The figure which shows the usage example of the conventional projector different from FIG. Explanatory drawing explaining the flow of the air in a projector. The figure which showed the structure shown in FIG. 20 more concretely. AA sectional drawing of FIG. BB sectional drawing of FIG. CC sectional drawing of FIG. DD sectional drawing of FIG. EE cross section of FIG. The perspective view which shows the board | substrate arrange | positioned at an apparatus main body. In FIG. 27, the perspective view of the state which removed the exhaust fan and the light source housing. The perspective view which shows a power supply unit. The perspective view which shows a ballast board | substrate unit. The perspective view when a ballast board | substrate unit is removed from the apparatus main body. The block diagram of electric power supply.

Hereinafter, an embodiment of a projector as an image projection apparatus to which the present invention is applied will be described. FIG. 1 is a perspective view showing a projector 1 and a projection surface 101 such as a screen according to the present embodiment. In the following description, the normal direction of the projection plane 101 is the X direction, the short axis direction (vertical direction) of the projection plane is the Y direction, and the long axis direction (horizontal direction) of the projection plane 101 is the Z direction.
As shown in FIG. 1, a transmissive glass 51 from which a projected image P is emitted is provided on the upper surface of the projector 1, and the projected image P emitted from the transmissive glass 51 is projected onto a projection surface 101 such as a screen. .
An operation unit 83 for the user to operate the projector 1 is provided on the upper surface of the projector 1. A focus lever 33 for adjusting the focus is provided on the side surface of the projector 1.

FIG. 2 is an optical path diagram from the projector 1 to the projection plane 101.
The projector 1 includes a light source unit (not shown) provided with a light source and an image forming unit A that forms an image using light from the light source. The image forming unit A includes an image forming unit 10 having a DMD 12 (Digital Mirror Device) as an image forming element, and an illumination unit 20 that folds light from a light source and irradiates the DMD 12 to generate a light image. Has been. Further, it has a projection optical system B for projecting an image onto the projection plane 101. The projection optical system B includes at least one transmission-type refractive optical system, and includes a first optical unit 30 including a coaxial first optical system 70 having a positive power, a folding mirror 41, and a positive power. And a second optical unit 40 provided with a curved mirror 42 having the same.

  The DMD 12 emits light from a light source (not shown) by the illumination unit 20, and generates an image by modulating the light emitted by the illumination unit 20. The image generated by the DMD 12 is projected onto the projection surface 101 via the first optical system 70 of the first optical unit 30, the folding mirror 41 of the second optical unit 40, and the curved mirror 42.

FIG. 3 is a schematic perspective view showing the internal configuration of the projector 1.
As shown in FIG. 3, the image forming unit 10, the illumination unit 20, the first optical unit 30, and the second optical unit 40 are arranged side by side in the Y direction in the drawing in the direction parallel to the projection plane and the image plane of the projection image. Has been. Further, a light source unit 60 is disposed on the right side of the illumination unit 20 in the drawing.

  3 are the leg portions of the lens holder 32 of the first optical unit 30, and the reference numeral 262 is a screwing portion for screwing the image forming unit 10 to the illumination unit 20. .

  Next, the structure of each unit will be described in detail.

First, the light source unit 60 will be described.
FIG. 4 is a schematic perspective view of the light source unit 60.
The light source unit 60 has a light source bracket 62, and a light source 61 such as a halogen lamp, a metal halide lamp, or a high-pressure mercury lamp is mounted on the light source bracket. Further, the light source bracket 62 is provided with a connector portion 62a for connecting to a power supply side connector (not shown) connected to the power supply unit 80 (see FIG. 14).

  A holder 64 holding a reflector (not shown) is screwed to the light emitting side of the light source 61 above the light source bracket 62. An exit window 63 is provided on the surface of the holder 64 opposite to the light source 61 arrangement side. The light emitted from the light source 61 is collected on the emission window by a reflector (not shown) held by the holder and is emitted from the emission window 63.

  Further, light source positioning portions 64a1 to 64a3 are provided on the upper surface of the holder 64 and both ends in the X direction of the lower surface of the holder in order to position the light source unit 60 on the illumination bracket 26 (see FIG. 6) of the illumination unit 20. The light source positioning portion 64a3 provided on the upper surface of the holder 64 has a protruding shape, and the two light source positioning portions 64a1 and 64a2 provided on the lower surface of the holder 64 have a hole shape.

  Further, a light source inlet 64b through which air for cooling the light source 61 flows is provided on the side surface except the upper surface of the holder 64, and air heated by the heat of the light source 61 is provided on the upper surface of the holder 64. A light source exhaust port 64c to be exhausted is provided.

  As will be described later, the light source bracket 62 is provided with a passage portion 65 into which air sucked from the intake blower 91 (see FIG. 21 and the like) flows. In addition, on the air inflow side on the near side of the passage portion 65 in the drawing, a part of the air flowing into the passage portion 65 flows between the light source unit 60 and an opening / closing cover 54 (see FIG. 7) described later. The opening 65a is provided. The cooling of the light source unit 60 will be described later.

  Further, when the flat surface portion 64d2 provided with the light source positioning protrusion 64a3 and the flat surface portion 64d1 provided with the light source positioning holes 64a1 and 64a2 shown in FIG. It is an abutting part which abuts against the lighting bracket.

Next, the lighting unit 20 will be described.
FIG. 5 is a perspective view showing the optical system components housed in the illumination unit 20 together with other units.
As shown in FIG. 5, the illumination unit 20 includes a color wheel 21, a light tunnel 22, two relay lenses 23, a cylinder mirror 24, and a concave mirror 25, which are held by an illumination bracket 26. Yes. The illumination bracket 26 has a housing-like portion 261 in which the two relay lenses 23, the cylinder mirror 24, and the concave mirror 25 are accommodated. Of the four side portions of the housing-like portion 261, Only the right side in the figure has a side surface, and the other three surfaces are open. An OFF light plate 27 (see FIG. 6) is attached to the side opening on the back side in the X direction in the figure, and the side opening on the near side in the X direction in the figure is shown in any drawing. An uncovered cover member is attached. As a result, the two relay lenses 23, the cylinder mirror 24, and the concave mirror 25 housed in the housing-like portion 261 of the illumination bracket 26 are either the illumination bracket 26 or the OFF light plate 27 (see FIG. 6). It is covered with a cover member not shown in the drawing.

  Further, an irradiation through-hole 26d for exposing the DMD 12 is provided on the lower surface of the housing-like portion 261 of the illumination bracket 26.

  The lighting bracket 26 has three leg portions 29. These leg portions 29 are in contact with the base member 53 (see FIG. 19) of the projector 1 and support the weight of the first optical unit 30 and the second optical unit 40 that are stacked and fixed on the illumination bracket 26. Further, by providing the leg portions 29, a space for the outside air to flow in is formed in the heat sink 13 (see FIG. 6) as a cooling means for cooling the DMD 12 of the image forming unit 10, as will be described later.

  Note that reference numerals 32a3 and 32a4 shown in FIG. 5 are leg portions of the lens holder 32 of the first optical unit 30, and reference numeral 45a3 is a screwing portion 45a3 of the second optical unit 40.

6 is a perspective view of the illumination unit 20, the projection lens unit 31, and the image forming unit 10 as viewed from the direction A in FIG.
An upper surface 26b orthogonal to the Y direction in the figure is provided on the upper portion of the housing-like portion 261 of the illumination bracket 26. The four corners of the upper surface 26b are provided with through holes through which screws for screwing the first optical unit 30 pass (the through holes 26c1 and 26c2 are shown in FIG. The through hole is not shown). In addition, positioning holes 26e1 and 26e2 for positioning the first optical unit 30 in the illumination unit 20 are provided adjacent to the through holes 26c1 and 26c2 on the front side in the X direction in the drawing. Of the two positioning holes provided on the near side in the X direction in the figure, the positioning hole 26e1 on the color wheel 21 arrangement side is a main reference for positioning and has a round hole shape. The positioning hole 26e2 on the opposite side is a positioning secondary reference and is a long hole extending in the Z direction. Further, the periphery of each through hole 26c1, 26c2 protrudes from the upper surface 26b of the illumination bracket 26, and serves as a positioning projection 26f for positioning the first optical unit 30 in the Y direction. When the positional accuracy in the Y direction is increased without providing the positioning protrusions 26f, it is necessary to increase the flatness of the entire upper surface of the illumination bracket 26, which increases the cost. On the other hand, by providing the positioning projection 26f, it is only necessary to increase the flatness of only the portion of the positioning projection 26f. Therefore, the cost can be reduced and the positional accuracy in the Y direction can be increased.

  In addition, a light shielding plate 262 into which the lower portion of the projection lens unit 31 is fitted is provided at the opening on the upper surface of the illumination bracket 26, and prevents light from entering the housing-like portion 261 from above.

  Further, between the through holes 26c1 and 26c2 on the upper surface 26b of the illumination bracket 26, as will be described later, the second optical unit 40 is cut out so as not to be an obstacle when screwed to the first optical unit 30. .

  A projection-like light source positioning portion 64a3 (see FIG. 4) provided on the upper surface of the holder 64 of the light source unit 60 is fitted to the end portion of the illumination bracket 26 on the color wheel 21 side (the front side in the Z direction in the figure). A cylindrical light source positioned portion 26a3 having a through hole formed in the vertical direction is provided. Further, below the light source positioned portion 26a3, two protruding light source positioned portions 26a1 into which two hole-shaped light source positioning portions 64a1 and 64a2 provided on the light source bracket 62 side of the holder 64 are fitted. 26a2 are provided. Then, the three light source positioning portions 64a1 to 64a3 of the holder 64 are fitted into the three light source positioned portions 26a1 to 26a3 provided on the illumination bracket 26 of the illumination unit 20, so that the light source unit 60 is an illumination unit. Positioned and fixed to 20 (see FIG. 3).

  An illumination cover 28 is attached to the illumination bracket 26 so as to cover the color wheel 21 and the light tunnel 22.

FIG. 7 is a diagram illustrating an optical path L of light within the illumination unit 20.
The color wheel 21 has a disk shape and is fixed to the motor shaft of the color motor 21a. The color wheel 21 is provided with filters such as R (red), G (green), and B (blue) in the rotation direction. Light collected by a reflector (not shown) provided on the holder 64 of the light source unit 60 passes through the emission window 63 and reaches the peripheral end of the color wheel 21. The light that reaches the peripheral end of the color wheel 21 is separated into R, G, and B light in a time-sharing manner by the rotation of the color wheel 21.

  The light separated by the color wheel 21 enters the light tunnel 22. The light tunnel 22 has a rectangular tube shape, and the inner peripheral surface thereof is a mirror surface. The light that has entered the light tunnel 22 is reflected by the inner peripheral surface of the light tunnel 22 a plurality of times, is converted into a uniform surface light source, and is emitted toward the relay lens 23.

  The light passing through the light tunnel 22 passes through the two relay lenses 23, is reflected by the cylinder mirror 24 and the concave mirror 25, and is focused on the image generation surface of the DMD 12 to form an image.

Next, the image forming unit 10 will be described.
FIG. 8 is a perspective view of the image forming unit 10.
As shown in FIG. 8, the image forming unit 10 includes a DMD board 11 on which the DMD 12 is mounted. The DMD 12 is mounted on a socket 11 a provided on the DMD board 11 with an image generation surface on which micromirrors are arranged in a lattice shape facing upward. The DMD board 11 is provided with a drive circuit for driving the DMD mirror. A heat sink 13 as a cooling means for cooling the DMD 12 is fixed to the back surface of the DMD board 11 (the surface opposite to the surface on which the socket 11a is provided). A portion of the DMD board 11 where the DMD 12 is mounted penetrates, and the heat sink 13 is formed with a protrusion 13a (see FIG. 7) to be inserted into a through hole (not shown). The tip of the protrusion 13a is planar. The protrusion 13a is inserted into a through hole (not shown), and the flat surface at the tip of the protrusion 13a is brought into contact with the back surface (the surface opposite to the image generation surface) of the DMD 12. A heat transfer sheet that can be elastically deformed is affixed to the flat portion or the place where the heat sink 13 on the back surface of the DMD 12 abuts to improve the adhesion between the flat portion of the protrusion 13a and the back surface of the DMD 12, thereby increasing the thermal conductivity. May be.

  The heat sink 13 is pressed and fixed to the surface opposite to the surface on which the socket 11a of the DMD board 11 is provided by the fixing member 14. The fixing member 14 has a plate-like fixing portion 14a facing the right side portion of the rear surface of the DMD board 11 in the drawing and a plate-like fixing portion 14a facing the left portion of the rear surface of the DMD board 11 in the drawing. doing. A pressing portion 14b provided to connect the left and right fixing portions is provided near one end and the other end in the X direction of each fixing portion.

  When the image forming unit 10 is screwed to the illumination bracket 26 (see FIG. 6), the heat sink 13 is pressed and fixed by the fixing member 14 to the surface opposite to the surface on which the socket 11a of the DMD board 11 is provided. The

  Hereinafter, fixing of the illumination bracket 26 of the image forming unit 10 will be described. First, the DMD 12 positions the image forming unit 10 on the illumination bracket 26 so as to face the opening surface of the irradiation through hole 26d provided on the lower surface of the illumination bracket 26 of the illumination unit 20 shown in FIG. Next, a screw is inserted from the lower side in the drawing so as to pass through a through hole (not shown) provided in the fixing portion 14 a and the through hole 15 of the DMD board 11, and the screw is provided in the lighting bracket 26. The image forming unit 10 is fixed to the illumination bracket 26 by screwing into a screw hole provided on the lower surface of the stopper 262 (see FIG. 3). Further, when a screw is screwed into a screwing portion 262 provided on the illumination bracket 26, the pressing portion 14b presses the heat sink 13 on the DMD board side. Thereby, the heat sink 13 is pressed and fixed by the fixing member 14 to the surface opposite to the surface on which the socket 11a of the DMD board 11 is provided.

  As described above, the image forming unit 10 is fixed to the illumination bracket 26, and the three legs 29 shown in FIG. 5 also support the weight of the image forming unit 10.

  A plurality of movable micromirrors are arranged in a lattice pattern on the image generation surface of the DMD 12. Each micromirror can tilt the mirror surface by a predetermined angle around the twist axis, and can have two states of “ON” and “OFF”. When the micromirror is “ON”, the light from the light source 61 is reflected toward the first optical system 70 (see FIG. 2) as indicated by the arrow L2 in FIG. When it is “OFF”, the light from the light source 61 is reflected toward the OFF light plate 27 held on the side surface of the illumination bracket 26 shown in FIG. 6 (see arrow L1 in FIG. 7). Therefore, by driving each mirror individually, light projection can be controlled for each pixel of the image data, and an image can be generated.

  The light reflected toward the OFF light plate 27 (not shown) is absorbed as heat and cooled by the flow of outside air.

Next, the first optical unit 30 will be described.
FIG. 9 is a perspective view showing the first optical unit 30 together with the illumination unit 20 and the image forming unit 10.
As shown in FIG. 9, the first optical unit 30 is disposed above the illumination unit 20, and has a projection lens unit 31 holding a first optical system 70 (see FIG. 2) composed of a plurality of lenses. And a lens holder 32 for holding the projection lens unit 31. The lens holder 32 is provided with four leg portions 32a1 to 32a4 extending downward (only the leg portions 32a2 and 32a3 are shown in FIG. 9. The leg portion 32a1 is shown in FIG. 3 and the leg portion 32a4. 5), screw holes for being screwed to the illumination bracket 26 are formed on the bottom surfaces of the leg portions 32a1 to 32a4.

  The projection lens unit 31 is provided with a focus gear 36, and the idler gear 35 is engaged with the focus gear 36. A lever gear 34 meshes with the idler gear 35, and a focus lever 33 is fixed to the rotation shaft of the lever gear 34. The tip portion of the focus lever 33 is exposed from the apparatus main body as shown in FIG.

  When the focus lever 33 is moved, the focus gear 36 is rotated via the lever gear 34 and the idler gear 35. When the focus gear 36 rotates, the plurality of lenses constituting the first optical system 70 in the projection lens unit 31 move in predetermined directions, and the focus of the projection image is adjusted.

  The lens holder 32 has screw through holes 32c1 to 32c3 through which screws 48 for screwing the second optical unit 40 to the first optical unit 30 pass (four in FIG. 9). The screw through-holes are illustrated, and the screw through-holes 32c1 to 32c3 each show a state in which the screw 48 is penetrated, and what is visible in the figure is the tip side of the screw portion of the screw 48 .) Further, second optical unit positioning protrusions 32d1 to 32d3 protruding from the surface of the lens holder 32 are formed around the screw through holes 32c1 to 32c4 (32d1 to 32d3 are shown in FIG. 9).

FIG. 10 is a cross-sectional view taken along the line AA of FIG.
As shown in FIG. 10, the leg portions 32a1 and 32a2 are provided with positioning protrusions 32b1 and 32b2. The right-side positioning protrusion 32b1 in the drawing is a round hole-shaped positioning hole 26e1 that is the main reference for positioning provided on the upper surface 26b of the illumination bracket 26, and the left-side positioning protrusion 32b2 in FIG. Positioning in the Z-axis direction and the X-axis direction is performed by inserting the reference holes into the long hole-shaped positioning holes 26e2, respectively. The screw 37 is inserted into the through holes 26c1 to 26c4 provided on the upper surface 26b of the illumination bracket 26, and the screws 37 are screwed into the screw holes provided in the leg portions 32a1 to 32a4 of the lens holder 32. One optical unit 30 is positioned and fixed to the illumination unit 20.

  The upper side of the lens holder 32 of the projection lens unit 31 is covered with a mirror holder 45 (see FIG. 12) of the second optical unit described later. As shown in FIG. 3, the portion between the lens holder 32 below the lens holder 32 of the projection lens unit 31 and the upper surface 26b of the illumination bracket 26 of the illumination unit 20 is exposed. Since the projection lens unit 31 is fitted with the lens holder 32, light does not enter the optical path of the image from the exposed portion.

Next, the second optical unit 40 will be described.
FIG. 11 is a perspective view showing the second optical system provided in the second optical unit 40 together with the projection lens unit 31, the illumination unit 20, and the image forming unit 10.
As shown in FIG. 11, the second optical unit 40 includes a folding mirror 41 and a concave curved mirror 42 constituting the second optical system. The surface of the curved mirror 42 that reflects the light can be a spherical surface, a rotationally symmetric aspherical surface, a free curved surface shape, or the like.

FIG. 12 is a perspective view showing the second optical unit 40 together with the first optical unit 30, the illumination unit 20, and the image forming unit 10.
As shown in FIG. 12, the second optical unit 40 also includes a transmissive glass 51 for transmitting the light image reflected from the curved mirror 42 and protecting the optical system components in the apparatus.

  The second optical unit 40 includes a mirror bracket 43 that holds the folding mirror 41 and the transmission glass 51, a free mirror bracket 44 that holds the curved mirror 42, and a mirror holder 45 to which the mirror bracket 43 and the free mirror bracket 44 are attached. have.

  The mirror holder 45 has a box shape, and has an upper surface, a lower surface, and a back side in the X direction in the drawing, and has a substantially U-shape when viewed from above. Edges extending in the X direction on the Z direction front side and the back side of the upper opening of the mirror holder 45 are inclined so as to rise from the X direction front side end portion to the X direction back side in the drawing. Part and a parallel part parallel to the X direction in the figure, and the inclined part is on the near side in the X direction in the figure from the parallel part. Further, the edge of the upper opening of the mirror holder 45 extending in the Z direction on the near side in the X direction in the drawing is parallel to the Z direction in the drawing.

  The mirror bracket 43 is attached to the upper part of the mirror holder 45. The mirror bracket 43 includes an inclined surface 43a that is inclined so as to rise from the front end in the X direction in the drawing, which contacts the inclined portion of the upper opening edge of the mirror holder 45, and the mirror holder 45. And a parallel surface 43b parallel to the X direction that contacts the parallel portion of the edge of the upper opening. Each of the inclined surface 43a and the parallel surface 43b has an opening, the folding mirror 41 is held so as to close the opening of the inclined surface 43a, and is transmitted so as to close the opening of the parallel surface 43b. A glass 51 is held.

  The folding mirror 41 is positioned and held on the inclined surface 43 a of the mirror bracket 43 by pressing both ends in the Z direction against the inclined surface 43 a of the mirror bracket 43 by a plate pressing member 46 having a leaf spring shape. The one end of the folding mirror 41 in the Z direction is fixed by two mirror pressing members 46, and the other end is fixed by one mirror pressing member 46.

  The transmissive glass 51 is positioned and fixed to the mirror bracket 43 by pressing both ends in the Z direction against the parallel surface 43b of the mirror bracket 43 by the plate spring-like glass pressing members 47. The transmissive glass 51 is held by one glass pressing member 47 at each of both ends in the Z direction.

  The free mirror bracket 44 that holds the curved mirror 42 has arm portions 44a that are inclined so as to descend from the back side in the X direction toward the front side in the figure, on the front side and the back side in the Z-axis direction. The free mirror bracket 44 has a connecting portion 44b that connects these two arm portions at the upper portion of the arm portion 44a. The free mirror bracket 44 has an arm portion 44 a attached to the mirror holder 45 so that the curved mirror 42 covers the opening on the back side in the X direction of the mirror holder 45 in the figure.

  In the curved mirror 42, the substantially central portion of the end portion on the transmission glass 51 side is pressed against the connecting portion 44b of the free mirror bracket 44 by a leaf spring-like free mirror pressing member 49, and the Z axis direction in the drawing on the first optical system side Both ends are fixed to the arm portion 44a of the free mirror bracket 44 by screws.

  The second optical unit 40 is stacked and fixed on the lens holder 32 of the first optical unit 30. Specifically, a lower surface 451 facing the upper surface of the lens holder 32 is provided at the lower portion of the mirror holder 45, and the lower surface 451 has a cylindrical shape for screwing to the first optical unit 30. Four screwing portions 45a1 to 45a3 are formed (see FIG. 11 for the screwing portions 45a1 and 45a2, see FIG. 5 for the screwing portions 45a3, and the remaining screwing portions are not shown). The second optical unit 40 passes the screws 48 through the screw through holes 32c1 to 32c3 provided in the lens holder 32 of the first optical unit 30, and screws the screws 48 into the screw fixing portions 45a1 to 45a3. The first optical unit 30 is screwed. At this time, the lower surface of the mirror holder 45 of the second optical unit 40 contacts the second optical unit positioning protrusions 32d1 to 32d4 of the lens holder 32, and the second optical unit 40 is positioned and fixed in the Y direction. .

  When the second optical unit 30 is mounted and fixed on the lens holder 32 of the first optical unit 30, the upper part of the projection lens unit 31 above the lens holder 32 is a mirror of the second optical unit 40 as shown in FIG. It is stored in the holder 45. Further, when the second optical unit 40 is mounted and fixed on the lens holder 32, there is a gap between the curved mirror 42 and the lens holder 32, and the idler gear 35 (see FIG. 9) enters the gap. It becomes a shape.

FIG. 13 is a perspective view showing an optical path from the first optical system 70 to the projection surface 101 (screen).
The light beam that has passed through the projection lens unit 31 constituting the first optical system 70 forms an intermediate image conjugate with the image generated by the DMD 12 between the folding mirror 41 and the curved mirror 42. This intermediate image is formed as a curved surface image between the folding mirror 41 and the curved mirror 42. Next, the optical image is incident on the concave curved mirror 42 and is projected onto the projection plane 101 by the curved mirror 42 to convert the intermediate image into a “further enlarged image”.

  As described above, the projection optical system is configured by the first optical system 70 and the second optical system, and an intermediate image is formed between the first optical system 70 and the curved mirror 42 of the second optical system. By performing the enlarged projection with the mirror 42, the projection distance can be shortened, and it can be used even in a narrow conference room.

  As shown in FIG. 13, the first optical unit 30 and the second optical unit 40 are stacked and fixed on the illumination bracket 26. The image forming unit 10 is also fixed. Therefore, the leg portion 29 of the illumination bracket 26 is fixed to the base member 53 so as to support the weight of the first optical unit 30, the second optical unit 40 and the image forming unit 10.

FIG. 14 is a schematic diagram showing the arrangement relationship of each unit in the apparatus.
As shown in the figure, the image forming unit 10, the illumination unit 20, the first optical unit 30, and the second optical unit 40 are stacked in the Y direction, which is the minor axis direction of the projection surface. The image forming unit 10, the illumination unit 20, the first optical unit 30, and the second optical unit 40 are arranged in the Z direction, which is the major axis direction of the projection plane, with respect to the stacked body. Thus, in this embodiment, the image forming unit 10, the illumination unit 20, the first optical unit 30, the second optical unit 40, and the light source unit are in a direction parallel to the projected image and the projection plane 101. Arranged side by side in the direction or Z direction. More specifically, more specifically, an image forming unit A composed of the image forming unit 10 and the illumination unit 20 and a projection optical unit B composed of the first optical unit 30 and the second optical unit 40 are laminated. The light source unit 60 is connected to the image forming unit A in a direction orthogonal to the formed direction. Further, the image forming unit A and the light source unit 60 are disposed on the same straight line parallel to the base member 53. The image forming unit A and the projection optical unit B are arranged on the same straight line perpendicular to the base member 53, and are arranged in the order of the image forming unit A and the projection optical unit B from the base member 53 side. .

  In the present embodiment, a power supply unit 80 for supplying power to the light source 61 and the DMD 11 is stacked above the light source unit 60. The light source unit 60, the power supply unit 80, the image forming unit A, and the projection optical unit B include the upper surface of the projector described above, the base member 53, and an exterior cover 59 (see FIG. 18) that covers the periphery of the projector 1. It is stored in the container of the projector 1.

FIG. 15 is a diagram illustrating a usage example of the projector 1 of the present embodiment, and FIGS. 16 and 17 are diagrams illustrating a usage example of the conventional projector 1A.
As shown in FIGS. 15 to 17, when the projector 1 is used in, for example, a conference room, the projector 1 is used by projecting an image onto a projection surface 101 such as a whiteboard by placing the projector 1 on a table 100.

  As shown in FIG. 16, a conventional projector 1 </ b> A is a projection image in which a DMD 12 (image generation element), an illumination unit 20, a first optical system 70, and a second optical system (curved mirror 42) are projected onto a projection plane 101. Are arranged in series in a direction perpendicular to the plane of the. Therefore, it becomes longer in the direction orthogonal to the projection plane of the projector 1A (X direction), and the projector 1A takes up a space in the direction orthogonal to the projection plane 101. A chair on which a person who sees an image projected on the projection plane 101 sits and a desk to be used are generally arranged in a direction orthogonal to the projection plane, so that the projector has a space in a direction orthogonal to the projection plane. If you take it, the space for chairs and the space for desks are limited, which is inconvenient.

  In the projector 1B shown in FIG. 17, the DMD 12 (image forming element), the illumination unit 20, and the first optical system 70 are arranged in series in parallel with the plane of the projection image projected onto the projection plane 101. Therefore, the length in the direction orthogonal to the projection plane 101 can be shortened compared to the projector 1B shown in FIG. However, in the projector 1B shown in FIG. 17, the light source 61 is arranged in a direction orthogonal to the plane of the projection image projected onto the projection plane 101 with respect to the illumination unit 20, so On the other hand, the length in the direction perpendicular to the length cannot be sufficiently shortened.

  On the other hand, in the projector 1 of the present embodiment shown in FIG. 15, the image forming unit A composed of the image forming unit 10 and the illumination unit 20 and the projection optical unit B composed of the first optical unit 30 and the folding mirror 41 are provided. The projection plane 101 and the image plane of the projection image projected onto the projection plane 101 are arranged in series in the Y direction in the drawing. In addition, the light source unit 60 and the illumination unit 20 are arranged in series in the Z direction in the drawing in a direction parallel to the plane of the projection image projected on the projection plane 101. That is, in the projector 1 according to the present embodiment, the light source unit 60, the image forming unit 10, the illumination unit 20, the first optical unit 30, and the folding mirror 41 are on the plane of the projection image projected on the projection plane 101. The light source unit 60, the image forming unit 10, the illumination unit 20, the first optical unit 30, and the folding mirror 41 are each projected onto a projection surface. And it arrange | positions so that a plane parallel to the image plane of a projection image may be crossed. Thus, the light source unit 60, the image forming unit 10, the illumination unit 20, the first optical unit 30, and the folding mirror 41 are parallel to the plane of the projection image projected on the projection plane 101 (in the drawing). (Z direction or Y direction), as shown in FIG. 15, the length in the direction orthogonal to the projection plane 101 (X direction in the figure) is shorter than that of the projector shown in FIG. 16 or FIG. can do. Thereby, it can suppress that the projector 1 becomes the obstruction of the arrangement space of a chair and the arrangement space of a desk, and the highly convenient projector 1 can be provided.

  In the present embodiment, as shown in FIG. 14, a power supply unit 80 for supplying power to the light source 61 and the DMD 11 is stacked above the light source unit 60. Thereby, the Z direction of the projector 1 is also shortened.

  In the present embodiment, the second optical system is configured by the folding mirror 41 and the curved mirror 42. However, the second optical system may be configured by only the curved mirror 42. The folding mirror 41 may be a plane mirror, a mirror having a positive refractive power, or a mirror having a negative refractive power. In this embodiment, a concave mirror is used as the curved mirror 42, but a convex mirror can also be used. In this case, the first optical system 70 is configured not to form an intermediate image between the first optical system 70 and the curved mirror 42.

  Since the light source 61 reaches the end of its life when used over time, it needs to be periodically replaced. For this reason, in this embodiment, the light source unit 60 is detachably provided from the apparatus main body.

FIG. 18 is a perspective view of the projector 1 as viewed from the installation surface side.
As shown in FIG. 18, the base member 53 constituting the bottom surface of the projector 1 is provided with an opening / closing cover 54, and the opening / closing cover 54 is provided with a rotation operation portion 54 a. When the rotation operation unit 54a is rotated, the fixing of the opening / closing cover 54 and the apparatus main body is released, and the opening / closing cover 54 can be detached from the apparatus main body. A power inlet 56 is provided at a location adjacent to the X direction of the opening / closing cover 54 of the base member 53.

  Further, as shown in FIG. 18, on one YX plane of the exterior cover 59 of the projector 1, an air inlet 84 and an external input unit 88 for inputting image data from an external device such as a personal computer are provided. It has been.

FIG. 19 is a perspective view showing a state in which the opening / closing cover 54 is removed from the apparatus.
When the opening / closing cover 54 is removed, as shown in FIG. 19, the surface of the light source bracket 60 opposite to the side where the light source 61 is mounted is exposed. A handle portion 66 is attached to the light source bracket 62 so as to be rotatable with respect to the light source bracket 62 with O1 indicated by a dotted line in the figure as a rotation center.

  When the light source unit 60 is taken out from the apparatus main body, the light source unit 60 is removed from the opening of the apparatus main body by rotating the handle portion 66 and grasping the handle portion 66 and pulling it out to the front side in the figure. When the light source unit 60 is attached to the apparatus main body, the light source unit 60 is inserted from the opening of the apparatus main body. When the light source unit 60 is inserted into the apparatus main body, the connector 62a shown in FIG. 4 is connected to a power supply side connector (not shown) of the apparatus main body, and the three light source positionings of the holder 64 shown in FIG. The portions 64a1 to 64a3 are fitted into the three light source positioned portions 26a1 to 26a3 provided on the illumination bracket 26 of the illumination unit 20 shown in FIG. 6, and the light source unit 60 is positioned on the apparatus main body. The installation of 60 is completed. Then, the opening / closing cover 54 is attached to the base member 53. In the present embodiment, the light source unit 60 is provided with the portion 66. However, as shown in FIG. 19, a passage portion 65 provided so as to protrude toward the opening / closing cover 54 may be used as the handle portion.

  Further, the base member 53 is provided with three leg portions 55. By rotating the leg portion 55, the amount of protrusion from the base member 53 is changed, and the height direction (Y direction) is adjusted. Can be done.

  Further, as shown in FIG. 19, an exhaust port 85 is provided on the other YX plane of the exterior cover 59.

FIG. 20 is an explanatory diagram illustrating the flow of air in the projector 1 of the present embodiment. This figure is a diagram of the projector 1 viewed from a direction (X direction) orthogonal to the projection plane 101. In FIG. 21, the components corresponding to the respective reference numerals in FIG. 20 in the present embodiment are numbered. 20 and 21, the arrows in the drawings indicate the direction of air flow. 22 is a cross-sectional view taken along the line AA in FIG. 21, and FIG. 23 is a cross-sectional view taken along the line BB in FIG. 24 is a cross-sectional view taken along the line CC of FIG. 25 is a cross-sectional view taken along the line DD of FIG. 26 is a cross-sectional view taken along line EE in FIG.
As shown in FIG. 20, one of the side surfaces of the projector 1 (left side in the figure) is provided with an intake port 84 that is open for taking outside air into the projector 1, and the other side surface of the projector 1 (right side in the figure). Is provided with an open exhaust port 85 for exhausting air in the projector 1. An exhaust fan 86 is provided so as to face the exhaust port 85.

Part of the exhaust port 85 and the intake port 84 is provided so as to be between the light source unit 60 and the operation unit 83 when the projector 1 is viewed from a direction (X direction) orthogonal to the projection plane 101. Yes. Further, a flow path through which air can flow is formed between the back surface of the curved mirror 42 and the exterior cover 59 facing the back surface. As a result, the outside air taken in from the intake port 84 wraps around the ZY plane of the mirror holder 45 of the second optical unit 40 and the back surface of the curved mirror 42 shown in FIG. It moves toward the exhaust port 85 along the curved surface on the back surface (see FIGS. 22, 24, and 26). The curved mirror 42 is a concave mirror having a positive power as described above, and the back surface of the curved mirror 42 is a convex shape that roughly follows the shape of the surface. The power supply unit 80 disposed on the upper part of the light source unit 60 has a substantially square U-shape having only a side on the light source unit 60 side when viewed from the Z direction in the figure (see FIG. 23). Then, the outside air taken in from the intake port 84 is directed to the intake port 85 along the curved surface of the back surface of the mirror holder 45 and the curved mirror 42, and the three directions except for the light source unit 60 side in the four directions are directed to the power supply unit 80. It flows into the enclosed space and is discharged from the exhaust port 85.

  In this way, a part of the exhaust port 85 and the intake port 84 is located between the light source unit 60 and the operation unit 83 when the projector 1 is viewed from a direction (X direction) orthogonal to the projection plane 101. By providing the air flow, it is possible to generate an air flow that passes between the light source unit 60 and the operation unit 83 and is discharged from the exhaust port 85.

  Further, a light source blower 95 is disposed at a location where air around a color motor 21a (see FIG. 5) for rotating the color wheel 21 of the illumination unit 20 can be sucked (see FIG. 25). Thereby, the color motor 21 a and the light tunnel 22 can be cooled by the airflow generated by the intake of the light source blower 95.

  The air sucked by the light source blower 95 passes through the light source duct 96 and flows into the light source air inlet 64b (see FIG. 4) of the holder 64. Further, part of the air flowing into the light source duct 96 flows between the light source housing 97 and the exterior cover 59 through an opening 96 a formed on the surface of the light source duct 96 facing the exterior cover 59 (see FIG. 19). .

  The air flowing between the light source housing 97 and the exterior cover 59 from the opening 96 a of the light source duct 96 is discharged from the exhaust port 85 by the exhaust fan 86 after cooling the light source housing 97 and the exterior cover 59.

  The air that has flowed to the light source inlet 64 b flows into the light source 61, cools the light source 61, and is then exhausted from the light source exhaust port 64 c provided on the upper surface of the holder 64. As shown in FIG. 21, the air exhausted from the light source exhaust port 64 c flows from the opening on the upper surface of the light source housing 97 toward the exhaust port 85 along the fluid guide 87. Thereafter, the low-temperature air that has entered the second optical unit 40 and flows into the space surrounded by the power supply unit 80 is mixed with the low-temperature air, and is then discharged from the exhaust port 85 by the exhaust fan 86. As described above, the high-temperature air exhausted from the light source exhaust port 64c is mixed with the outside air and then exhausted, whereby the air exhausted from the exhaust port 85 can be prevented from becoming high temperature. The fluid guide 87 is not always necessary, and even if the fluid guide 87 is not provided, the high-temperature air exhausted from the light source exhaust port 64c is a space surrounded by a main PFC power supply board 80a and a sub PFC power supply board 80b described later. Thus, the air is exhausted from the exhaust port 85 by the air passing from the intake port 84 to the exhaust port 85 through the back surface of the curved mirror 42. However, by using the fluid guide 87, it is possible to suppress the high-temperature air exhausted from the light source exhaust port 64c from going directly to the vicinity of the main PFC power supply board 80a and the sub PFC power supply board 80b. However, if all of the high-temperature air exhausted from the light source exhaust port 64c is avoided from the main PFC power supply board 80a and the sub PFC power supply board 80b by the fluid guide, it is mixed with the air that has passed through the back surface of the phase mirror 42. Since all the high-temperature air is exhausted from the exhaust port 85 without lowering the temperature, the exhaust port 85 is heated. Therefore, the air exhausted from the light source exhaust port 64c and passing through the fluid guide 87 surely passes through the space surrounded by the main PFC power supply board 80a and the sub PFC power supply board 80b more reliably from the intake port 84 to the curved mirror 42. Since it can be mixed with the air which goes to the exhaust port 85 through the back surface, it is safe for the user.

  Moreover, it is preferable that the operation unit 83 operated by the user is provided on the upper surface of the apparatus so that the user can easily operate. However, in this embodiment, since the transmissive glass 51 for projecting an image on the projection surface 101 is provided on the upper surface of the projector 1, the operation unit is located at a position overlapping the light source 61 when the projector is viewed from the Y direction. 83 must be provided.

  In the present embodiment, air that has flowed between the light source unit 60 and the operation unit 83 from the air inlet 84 toward the air outlet 85 and that has cooled the light source 61 and has reached a high temperature is exhausted toward the air outlet. Therefore, it is possible to suppress the movement of the high-temperature air to the operation unit 83. Thereby, it is possible to suppress the temperature of the operation unit 83 from rising due to the air heated to a high temperature by cooling the light source 61. Further, a part of the air that flows around the second optical unit 40 from the intake port 84 and flows toward the exhaust port 85 passes just below the operation unit 83 to cool the operation unit 83. This can also suppress the temperature rise of the operation unit 83.

Further, outside air is taken in from the power supply inlet 56 provided in the base member 53 shown in FIG. A ballast substrate 3a (see FIGS. 24 and 25) for supplying stable power (current and voltage ) to the light source 61 is disposed on the inner side of the light source housing 97 in the X direction in FIG. The outside air sucked from the port 56 cools the ballast substrate 3a while moving upward between the light source housing 97 and the ballast substrate 3a. Then, after flowing into a space surrounded by the power supply unit 80 disposed above the ballast substrate, the exhaust fan 86 exhausts the air from the exhaust port 85.

  In the present embodiment, the fan that generates the airflow from the intake port 84 to the exhaust port 85 is provided on the exhaust side as the exhaust fan 86. Therefore, compared with the case where a fan is provided at the intake port, the fan is connected to the inside of the apparatus. The supply amount of air supplied to can be increased. This is because when the fan is provided at the intake port 84, the second optical unit 40 is in the direction of sending out the air of the fan, so that the air volume of the outside air supplied from the fan to the inside of the apparatus is reduced by the second optical unit 40. Resulting in. On the other hand, when a fan is provided on the exhaust port 85 side as the exhaust fan 86, normally there is no object on the exhaust side of the exhaust port 85, so the amount of air discharged from the exhaust fan 86 does not decrease. Therefore, since the same amount of air as the amount of exhaust exhausted from the exhaust fan 86 is taken in from the intake port 84, the supply amount of air supplied from the intake port to the inside of the apparatus may decrease as a result. Absent. Therefore, air can flow from the intake port 84 toward the exhaust port 85 with a predetermined wind pressure, and the heated air rising from the light source 61 is sent to the exhaust port 85 by an air flow from the intake port 84 to the exhaust port 85. Can go well.

  A cooling unit 120 that cools the heat sink 13 of the image forming unit 10, the light source unit 60, the light source bracket 62, and the like is disposed on the lower left side of the apparatus main body. The cooling unit 120 includes an intake blower 91, a vertical duct 92, and a horizontal duct 93.

  The intake blower 91 is disposed oppositely below the intake port 84, and sucks outside air from the surface facing the intake port 84 via the intake port 84, and from the surface opposite to the surface facing the intake port. The inside air is sucked and flows into a vertical duct 92 disposed below the suction blower 91. The air flowing into the vertical duct 92 moves downward and is sent to the horizontal duct 93 connected at the lower part of the vertical duct 92.

  A heat sink 13 is disposed in the horizontal duct 93, and the heat sink 13 is cooled by the air flowing through the horizontal duct 93. By cooling the heat sink 13, the DMD 12 can be efficiently cooled, and the DMD 12 can be prevented from reaching a high temperature.

  The air that has moved in the horizontal duct 93 flows into the passage portion 65 or the opening portion 65a provided in the light source bracket 62 of the light source unit 60 shown in FIG. The air flowing into the opening 65a flows between the opening / closing cover 54 and the light source bracket 62, and cools the opening / closing cover 54.

  On the other hand, the air that has flowed into the passage portion 65 cools the light source bracket 62 and then flows into the portion of the light source 61 opposite to the light exit side, and cools the light source 61 on the side opposite to the reflecting surface of the reflector 67. In the light source 61. The reflector 67 is cooled. Therefore, the air passing through the passage portion 65 takes heat from both the light source bracket 62 and the light source 61. The air that has passed near the reflector 67 passes through the exhaust duct 94 that guides the air from the height of the light source bracket 62 to the height near the lower portion of the exhaust fan 86, and then merges with the air exhausted from the light source exhaust port 64C. The fluid guide 87 is passed to the exhaust port 85. The exhaust fan 86 exhausts the exhaust port 85. The air flowing between the opening / closing cover 54 and the light source bracket 62 through the opening 65 a cools the opening / closing cover 54, moves inside the apparatus, and is discharged from the exhaust port 85 by the exhaust fan 86. .

  By providing the light source bracket 62 with the passage portion 65 and cooling the light source bracket 62, the temperature rise of the light source 61 can be suppressed. Therefore, the light source 61 can be cooled satisfactorily even if the flow rate of the cooling air flowing into the light source 61 is reduced. Thereby, the rotation speed (rpm) of the light source blower 95 can be reduced, and the wind noise of the light source blower 95 can be suppressed. Moreover, since the rotation speed (rpm) of the light source blower 95 can be reduced, the power saving of the apparatus can be achieved.

FIG. 27 is a perspective view showing a substrate disposed in the apparatus main body.
As shown in FIG. 27, the projector 1 according to the present embodiment has stable power (current and voltage) for the control board 2 and the light source 61 as a control unit for controlling driving of the DMD 12 that is an image forming element. The ballast substrate unit 3 having a ballast substrate 3a (see FIG. 24) as a power stabilizing unit for supplying the voltage, and boosting an AC voltage supplied from a power cable (not shown) And a power supply unit 80 including a PFC power supply board as a power supply unit for supplying power to the power supply unit.

FIG. 28 is a perspective view of FIG. 27 with the exhaust fan 86 and the light source housing 97 removed.
As shown in FIG. 28, the control board 2 is disposed so as to face the side surfaces (ZY plane) of the illumination unit 20 and the first optical unit 30. The ballast substrate unit 3 is disposed at a position adjacent to the control substrate 2 in the Z direction (horizontal direction) and adjacent to the light source unit 60 in the X direction (direction orthogonal to the projection image). The power supply unit 80 is disposed above the light source unit 60 and the ballast substrate unit 3. Further, the power supply unit 80 is provided with a thermal switch 182 that cuts off the supply of voltage from a power cable (not shown) when the temperature of the power supply unit 80 exceeds a predetermined temperature.

FIG. 29 is a perspective view showing the power supply unit 80.
29 and FIG. 23, the PFC power supply board of the power supply unit 80 is divided into a main PFC power supply board 80a as a first power supply board and a sub PFC power supply board 80b as a second power supply board. Yes. The main PFC power supply board 80 a is attached to a substantially L-shaped main board holder 81, and the sub PFC power supply board 80 b is attached to the sub board holder 82. The light source unit 60 and the light source 61 are arranged on the normal line of the main PFC power supply board 80a.

The main substrate holder 81 has a substrate attachment surface 81a on which the main PFC power supply substrate 80a is attached on the lower surface, and a cover surface 81b extending downward from the front side end in the X direction of the substrate attachment surface 81a in the drawing.
The sub-substrate holder 82 is attached to the front end of the substrate attachment surface 81a in the X direction in the drawing so that the sub-PFC power supply substrate 80b faces the cover surface 81b. The thermal switch 182 is provided on the sub PFC power supply board 80b. Then, as shown in FIG. 27, the power supply unit 80 is placed so that the board mounting surface 81a, the cover surface 80b, and the sub board holder 82 of the main board holder 81 surround the air suction port of the exhaust fan 86. A plurality of constituent boards, specifically, the main PFC power supply board 80a and the sub PFC power supply board 80b are attached to the apparatus main body.

  As a result, a flow path surrounding the air flow toward the exhaust fan 86 is formed by suction of the exhaust fan 86 as the air blowing means, that is, among the flow paths for guiding the air toward the exhaust port 85 from different directions. The main PFC power supply substrate 80a, the sub PFC power supply substrate 80b, and the cover surface 81b are arranged so as to form two surfaces. However, the power supply unit 80 may be configured by three substrates to form three surfaces of the flow path. Further, when the fluid guide 87 is present, a space in which the main PFC power supply board 80 a and the sub PFC power supply board partially surround the flow path from the fluid guide 87 to the exhaust port 85. When there is no fluid guide 87, the space surrounding the main PFC power supply board 80a and the sub PFC power supply board 80b is a flow path from the light source exhaust port 64c to the exhaust port 85. Further, it also functions as an air flow path from the intake port 84 to the exhaust port 85 through the back surface of the curved mirror 42. More specifically, the main PFC power supply board 80a and the sub PFC power supply board 80b are two faces of a substantially quadrangular prism or a polygonal cylinder that can move the air to the surface of the exhaust fan 86 that exhausts air. Are arranged as follows. In addition, the main PFC power supply board 80a and the sub PFC power supply are provided on the surface closest to the light source unit 60 among the four surfaces of the above-described substantially quadrangular prisms so as not to hinder the air flow from the light source unit 60 toward the exhaust port 85. None of the substrates 80b is arranged. In addition, by disposing neither the main PFC power supply board 80a nor the sub PFC power supply board 80b on the face closest to the exterior cover on the side opposite to the projection face among the faces of the substantially quadrangular prisms described above, It is possible to prevent the flow of air toward the exhaust port 85 along the back surface of the concave curved mirror 42 and the velocity of the air flow toward the exhaust port 85 along the back surface of the concave curved mirror 42. Will not be damaged. Of the surfaces of the substantially quadrangular prisms, the surface closest to the exterior cover on the side opposite to the projection surface, neither the main PFC power supply board 80a nor the sub PFC power supply board 80b is disposed. It is agreed that neither the main PFC power supply board 80a nor the sub PFC power supply board 80b is arranged on the cover surface 81b. The curved mirror 42 is a concave mirror having a positive power as described above, and the back surface of the curved mirror 42 is a convex shape that roughly follows the shape of the surface. The flow path formed by the main PFC power supply board 80a and the sub PFC power supply board 80b is connected to the flow path (second flow path) formed by the back surface of the curved mirror 42 and the exterior cover 59 facing this back surface. Therefore, the air that is taken into the intake port 84 on the side surface of the exterior cover 59 and flows toward the exhaust port 85 along the back surface of the concave curved mirror 42 is connected to the sub PFC power supply board 80b and the main PFC power supply board 80a. The air is exhausted from the exhaust port 85 by the exhaust fan 86 through the space surrounded by the cover surface 81b. As a result, the main PFC power supply board 80a and the sub PFC power supply board 80b are heated by the light source unit 60 and the fluid guide 87, but by the air flowing toward the exhaust port 85 along the back surface of the concave curved mirror 42 Since it is cooled, the temperature rise of the main PFC power supply board 80a and the sub PFC power supply board 80b can be suppressed. Furthermore, it is possible to reduce the size of the apparatus by arranging the power supply unit 80 in a space that could not be used as an arrangement place of the power supply unit 80 due to the problem of waste heat from the light source 61 in the past.

  Here, when the main PFC power supply board 80a and the sub PFC power supply board 80b are arranged side by side in the air flow direction, the PFC power supply board arranged on the downstream side in the air flow direction depends on the upstream PFC power supply board. The PFC power supply board on the downstream side is not sufficiently cooled because it is cooled by the heated air. However, as in the present embodiment, the main PFC power supply board 80a and the sub PFC power supply board 80b are taken into the intake port 84 and arranged so as to surround the air flowing toward the exhaust port 85, thereby lowering the temperature. The main PFC power supply board 80a and the sub PFC power supply board 80b can be cooled with air. As a result, the main PFC power supply board 80a and the sub PFC power supply board 80b, that is, the entire PFC power supply board can be satisfactorily cooled even at a location affected by high-temperature exhaust from the light source unit 60.

  In addition, the air suction port of the exhaust fan 86 includes the surface of the main PFC power supply board 80a on which the electric elements such as coils, capacitors, and resistors are arranged, the face of the sub PFC power supply board 80b on which the electric elements are arranged, and the cover surface 81b. Is configured to surround. Thereby, low-temperature air taken in from the intake port 84 can be applied to electrical elements such as a coil and a capacitor that generate heat, and the PFC power supply board can be efficiently cooled.

  In the present embodiment, since the sub PFC power supply board 80b is orthogonal to the main PFC power supply board 80a, the main PFC power supply board 80a and the sub PFC power supply board are parallel to each other. Thus, the apparatus can be reduced in size as compared with the case where the main PFC power supply board 80a and the sub PFC power supply board 80b are arranged side by side.

  In the above description, the power supply unit 80 is shaped so that the sub PFC power supply board faces the cover surface 81b. However, the power supply unit 80 may be arranged so that the sub PFC power supply board 80b and the main PFC power supply board 80a face each other. Even in such a configuration, the main PFC power supply board 80a and the sub PFC power supply board 80b can surround the air flow path, and the entire PFC power supply can be cooled well. On the main PFC power supply board 80a and the sub PFC power supply board 80b, a large number of electric elements such as coils that are long in the direction orthogonal to the board surface are attached. Therefore, when the sub PFC power supply board is arranged so as to face the main PFC power supply board 80a, the electric elements on the main PFC power supply board 80a and the sub PFC power supply board with respect to the air flow direction toward the exhaust fan 86 The electric element on 80b is arranged so as to be folded. As a result, the air toward the exhaust fan 86 collides with the electric element, and the air flow in the space surrounded by the main PFC power supply board 80a, the sub PFC power supply board 80b, and the cover surface 81b may be deteriorated. On the other hand, when the sub PFC power supply board 80b is arranged so as to be orthogonal to the main PFC power supply board, a cover of a space surrounded by at least the main PFC power supply board 80a, the sub PFC power supply board 80b, and the cover surface 81b is used. The air flowing on the lower side of the surface 81b (side away from the main PFC power supply board 80a) can go to the exhaust fan 86 without hitting the electric element. As a result, the air flow in the space surrounded by the main PFC power supply board 80a, the sub PFC power supply board 80b, and the cover surface 81b is better than when the sub PFC power supply board 80b is opposed to the main PFC power supply board 80a. Can be efficiently cooled.

FIG. 30 is a perspective view showing the ballast substrate unit 3.
As shown in FIG. 30, the ballast substrate unit 3 has a ballast substrate holder 3b for holding the ballast substrate 3a. A vent hole 3c is provided on the lower surface of the ballast substrate holder 3b.

FIG. 31 is a perspective view when the ballast substrate unit 3 is removed from the apparatus main body.
As shown in FIG. 31, a power supply air inlet 56 is provided immediately below a portion of the base member 53 where the ballast substrate unit 3 is attached. The ballast substrate unit 3 is attached to the apparatus main body so that the ventilation port 3 c of the ballast substrate holder faces the power supply inlet 56 and the ballast substrate 3 a faces the light source housing 97.

  The air sucked from the power supply inlet 56 by the suction force of the exhaust fan 86 rises between the light source housing 97 and the ballast substrate 3a as shown by an arrow J1 in FIG. Thereby, the light source housing 97 and the ballast substrate 3a can be cooled. Then, as shown by the arrow J2, the main PFC power supply board 80a, the cover surface 81b, and the sub PFC power supply board 80b flow into the enclosed space, and after cooling the PFC power supply boards 80a and 80b, the arrow J3 shows. As described above, the air is exhausted from the exhaust fan 86 to the outside of the apparatus.

  Thus, in the present embodiment, the air that cools the ballast substrate 3a is caused to flow into the space surrounded by the main PFC power supply substrate 80a, the cover surface 81b, and the sub PFC power supply substrate 80b, and the PFC power supply substrate 80a, Since 80b is also cooled, the ballast substrate 3a and the PFC power supply substrates 80a and 80b can be efficiently cooled.

FIG. 32 is a block diagram of power supply.
As shown in FIG. 32, the sub PFC power supply board 80b converts the AC voltage supplied from the PCF switch unit 183 and the power cable 190 into a DC voltage, and supplies the control board 2 with a DC voltage of 3.3V. A start-up voltage converter 184.

  In the main PFC power supply board 80a, a control voltage conversion unit 185 for converting an AC voltage supplied from the power cable 190 into a DC voltage and supplying a DC voltage of 12V to the control board 2, a ballast switch unit 186, And a booster 187 that boosts an AC voltage of 100 V to 380 V. In the present embodiment, as shown in FIG. 32, the power supply unit 80 is composed of a plurality of substrates. However, even if the ballast substrate 3a, which is a power stabilizing unit that stabilizes the power to the light source 61, is divided into a plurality of substrates. The same effect can be obtained. Alternatively, one of the divided ballast substrates 3a and the main PFC power supply substrate 80a may form two surfaces of the flow path.

  When the plug of the power cable 190 is plugged into an outlet and an AC voltage is applied to the sub PFC power supply board 80b, a DC voltage of 3.3V is applied from the starting voltage converter 184 to the control board 2. When a DC voltage of 3.3 V is applied to the control board 2, for example, the temperature detected by temperature detecting means such as a thermistor provided at a predetermined position of the device is checked, and the device is in a normal state. If it is determined that there is, the PFC switch unit 183 of the sub PFC power supply board 80b is turned on.

  When the PFC switch unit 183 is turned on, the AC voltage from the power cable 190 is supplied to the main PFC power supply board 80a. When an AC voltage is supplied to the main PFC power supply board 80 a, a DC voltage of 12 V is applied from the control voltage conversion unit 185 to the control board 2. When a DC voltage of 12 V is applied, the control board 2 checks the temperature of the light source 61, for example, and turns on the ballast switch unit 186 of the main PFC power supply board 80a if there is no abnormality in the light source 61 or the like.

When the ballast switch unit 186 of the main PFC power supply board 80a is turned on, an AC voltage from the power cable 190 is applied to the booster 187, and the booster 187 boosts the AC voltage to 380V, and the ballast board 3a Then, a voltage of 380 V is applied to the light source 61 by controlling so that stable power (current , voltage ) is supplied. As a result, the light source is turned on.

1: Projector 2: Control board 3: Ballast board unit 3a: Ballast board 3b: Ballast board holder 3c: Ventilation port 10: Image generating unit 11a: Socket 11: DMD board 12: DMD
13: Heat sink 14: Fixing member 20: Illumination unit 21: Color wheel 22: Light tunnel 23: Relay lens 24: Cylinder mirror 25: Concave mirror 26: Illumination brackets 26a1 to 26a3: Light source positioned portions 26c1 to 26c4: Through hole 26d : Irradiation through-holes 26e1, 26e2: Positioning hole 26f: Positioning protrusion 27: OFF light plate 28: Illumination cover 29: Leg 30: First optical unit 31: Projection lens unit 32: Lens holders 32a1 to 32a4: Legs 32b1 32b4: Positioned protrusions 32c1 to 32c4: Screw through holes 32d1 to 32d4: Second optical unit positioning protrusions 33: Focus lever 34: Lever gear 35: Idler gear 36: Focus gear 40: Second optical unit 41: Folding mirror 42: Curved surface Mirror 43: Mirror bracket 44: Free mirror bracket 45: Mirror holders 45a1 to 45a4: Screw fixing portion 46: Mirror pressing member 47: Glass pressing member 49: Free mirror pressing member 51: Transmission glass 53: Base member 53c: Light source unit extraction Port 53d: Notch 53e: Hooked portion 54: Opening / closing cover 54a: Rotating operation unit 56: Power supply inlet 59: Exterior cover 60: Light source unit 61: Light source 62: Light source bracket 62a: Connector portion 64: Holders 64a1 to 64a3: Light source positioning unit 64b: inlet 64c: exhaust port 65: passage 65a: opening 70: first optical system 80: power supply unit 80a: main PFC power supply board 80b: sub PFC power supply board 81: main board holder 81a: board attachment Surface 81b: Cover surface 82: Sub-board Luda 83: Operation section 84: Intake port 85: Exhaust port 86: Exhaust fan 87: Fluid guide 91: Intake blower 92: Vertical duct 93: Horizontal duct 94: Exhaust duct 95: Light source blower 96: Light source duct 97: Light source housing 98 : Mixing duct 98a: Inlet 98b: Outlet 99: Light source exhaust duct 100: Table 101: Projection surface 120: Cooling part A: Image forming part B: Projection optical part

JP 2007-78924 A

Claims (9)

In an image projection apparatus that includes a light source provided in a light source unit and projects an image using light from the light source.
A substrate holder provided with a first surface and a second surface extending to the light source side, and partitioned from the light source unit by a member having an opening ;
A power supply board attached to the first surface and disposed with the substrate surface facing the light source;
A blower for generating an air flow in the space between the light source and the power supply board in the space on the substrate holder side with respect to the member ;
An image projection apparatus comprising: a ballast substrate disposed with a substrate surface facing the second surface in a direction opposite to the second surface with respect to the space. The power supply substrate is a substrate having a function of converting an AC voltage into a DC voltage,
The image projection apparatus according to claim 1, wherein the ballast substrate is a substrate that controls electric power supplied from the power supply substrate and supplies the power to the light source. The power supply substrate is a substrate having a function of boosting a voltage,
The image projection apparatus according to claim 1, wherein the ballast substrate is a substrate that controls electric power supplied from the power supply substrate and supplies the power to the light source. The power supply substrate is a substrate having a function of converting an AC voltage into a DC voltage,
The image projection apparatus according to claim 1, wherein the ballast substrate is a substrate that supplies stable power to the light source. The power supply substrate is a substrate having a function of boosting a voltage,
The image projection apparatus according to claim 1, wherein the ballast substrate is a substrate that supplies stable power to the light source.   The image projection apparatus according to claim 1, wherein the first surface and the second surface form an L shape.   The image projection apparatus according to claim 1, wherein a substrate surface of the ballast substrate is disposed so as to be orthogonal to a substrate surface of the power supply substrate.   The image projection apparatus according to claim 1, wherein the first surface, the second surface, and the ballast substrate form a U-shape. In an image projection apparatus that includes a light source in an exterior and projects an image using light from the light source,
In the exterior,
A first substrate that is disposed with the substrate surface facing the light source, and has a function of converting an AC voltage into a DC voltage;
A second substrate having a function of converting an alternating voltage into a direct current voltage disposed in a space between the light source and the first substrate with a substrate surface facing;
A member arranged to face the second substrate with respect to the space;
An image projection apparatus comprising: a blower that generates an air flow between the light source and the first substrate.

Images