JP6631145B2 - projector - Google Patents

Description

  The present invention relates to a projector.

Conventionally, an illumination device, a light modulation device that modulates light emitted from the illumination device to form an image according to image information, and a projection optical device that enlarges and projects the image on a projection surface such as a screen Is known (for example, see Patent Document 1).
The projector described in Patent Document 1 includes a color separation optical device that separates a light flux emitted from a light source into red, green, and blue light, three liquid crystal panels provided for each of the separated light, In addition to the prism for synthesizing the color lights modulated by the three liquid crystal panels and the above-mentioned projection optical device for projecting the synthesized light, air introduced from outside the housing is blown to the liquid crystal panel to cool the liquid crystal panel. A cooling device.

JP 2001-312003 A

In recent years, there has been a demand for higher resolution of projected images in projectors. For this reason, it is conceivable to provide an optical path changing element for increasing the resolution of the projected image higher than the resolution of the light modulation device such as a liquid crystal panel to increase the resolution of the projected image between the prism and the projection optical device. .
However, when a projector provided with an optical path changing element is used, for example, in an event venue such as outdoors, there is a possibility that fats and oils or dust based on smoke or the like may adhere to the optical path changing element. In such a case, there is a problem that the driving of the optical path changing element is affected.
Therefore, there is a demand for a projector in which dust and the like hardly adhere to the optical path changing element.

  SUMMARY An advantage of some aspects of the invention is to provide a projector that can prevent dust from adhering to an optical path changing element.

  A projector according to one embodiment of the present invention provides a light source, a light modulation device that modulates light emitted from the light source, a projection optical device that projects light modulated by the light modulation device, and the light modulation device. An optical path changing element that is arranged between the projection optical device and changes the optical path of light modulated by the light modulator by swinging, an exterior housing that constitutes an exterior, and the optical path changing element is disposed inside; And an internal housing that is provided.

Examples of the optical path changing element include a shift element that changes the optical path of incident light.
According to the above aspect, since the optical path changing element is disposed in the internal housing, it is possible to suppress the attachment of dust to the optical path changing element. Therefore, the brightness of the image projected from the projector can be further increased.

In the above aspect, it is preferable that the light modulation device is disposed in the internal housing.
According to the above aspect, since the light modulation device and the light path changing element are arranged in the internal housing, it is possible to suppress the attachment of dust to the light modulation device and the light path changing element. Therefore, the brightness of the image projected from the projector can be further increased.

In the above aspect, the optical modulator includes a plurality of light modulators, and a light combiner that combines and emits light modulated by the plurality of light modulators, wherein the projection optical device is emitted from the light combiner. It is preferable that the light is projected and the photosynthesis device is disposed in the internal housing.
According to the above aspect, since the plurality of light modulation devices, the light path changing elements, and the light combining devices are arranged in the internal housing, it is possible to suppress the attachment of dust to the light path changing elements, the light path changing elements, and the light combining device. Therefore, the brightness and the saturation of the image projected from the projector can be increased.

In the above aspect, the optical device further includes a support member disposed in the inner housing and supporting the photosynthesis device, wherein the optical path changing element changes an optical path of light incident by being swung by the permanent magnet and the permanent magnet. An optical member, a holding portion for holding the optical member and the permanent magnet, a pair of coils disposed on the holding portion with the permanent magnet interposed therebetween, a coil holding portion for holding the pair of coils, And a heat conducting portion that is in contact with the coil holding portion, and the heat conducting portion preferably contacts the support member so as to be able to conduct heat.
Here, when electric power is supplied to a pair of coils disposed with the permanent magnet interposed therebetween, the permanent magnet is displaced, thereby generating a magnetic force for displacing the optical path changing element, and the temperature of the coil is increased. As described above, when the temperature of the coil increases, the magnetic force of the coil that generates the magnetic force may be weakened.
On the other hand, according to the one aspect, the heat conducting portion fixed to the coil holding portion of the optical path changing element comes into contact with the support member, so that when the heat of the coil rises, the heat of the coil becomes conductive. It is conducted to the support member through the portion. Thus, it is possible to suppress an increase in the temperature of the pair of coils included in the optical path changing element. Therefore, since the magnetic force of the coil provided in the optical path changing element can be prevented from being reduced, the driving of the optical path changing element can be stabilized.

In the above aspect, the internal housing is a closed housing, and the photosynthesis device has a first support surface and a second support surface that are located on opposite sides and connected to the support member, The support member includes a first support portion connected to the first support surface, and a second support portion connected to the second support surface, and the heat conducting portion includes the first support portion and the second support portion. It is preferable that at least one of the second support portions is in heat conductive contact.
According to the above aspect, at least one of the first support portion and the second support portion supporting the first support surface and the second support surface of the photosynthesis device comes into contact with the heat conduction portion, so that the heat of the coil increases. In this case, the heat of the coil is conducted to the support member via the heat conducting part. Thus, it is possible to suppress an increase in the temperature of the pair of coils included in the optical path changing element. Therefore, since the magnetic force of the coil provided in the optical path changing element can be prevented from being reduced, the driving of the optical path changing element can be stabilized.

In the above aspect, it is preferable that the heat conductive portion comes into contact with the internal housing so as to be able to conduct heat.
According to the above aspect, since the heat conducting portion comes into contact with the inner housing in a heat conductive manner, when the heat of the coil rises, the heat of the coil is conducted to the inner housing via the heat conducting portion. You. Thus, it is possible to suppress an increase in the temperature of the pair of coils included in the optical path changing element. Therefore, since the magnetic force of the coil provided in the optical path changing element can be prevented from being reduced, the driving of the optical path changing element can be stabilized.

In the above aspect, it is preferable that the inner housing has a heat conduction part that comes into contact with the heat conduction part.
According to the above aspect, since the heat conducting portion contacts the heat conducting portion of the inner casing, when the heat of the coil rises, the heat of the coil is transferred to the heat conducting portion of the inner casing via the heat conducting portion. Conducted to the site. Accordingly, it is possible to reliably suppress the temperature of the pair of coils included in the optical path changing element from rising. Therefore, since a decrease in the magnetic force of the coil provided in the optical path changing element can be reliably suppressed, the driving of the optical path changing element can be reliably stabilized.

In the above aspect, it is preferable that the cooling device be provided in the inner housing and circulate the cooling gas in the inner housing, and a part of the cooling gas be circulated to the support member.
According to the above aspect, since the cooling device is disposed in the internal housing, the light modulation device, the optical path changing device, and the photosynthesis device disposed in the internal housing can be cooled. In addition, since the cooling gas flows through the supporting member to which the heat of the coil has been transmitted through the heat conducting portion, the supporting member can be reliably cooled. Therefore, an increase in the temperature of the pair of coils included in the optical path changing element can be suppressed.

FIG. 1 is a schematic perspective view illustrating an appearance of a projector according to an embodiment of the invention. FIG. 2 is a schematic diagram illustrating a schematic configuration of a projector according to the embodiment. FIG. 2 is a plan view of a shift element of the projector according to the embodiment, as viewed from a light incident side. FIG. 3 is a plan view of the shift element according to the embodiment as viewed from a light emission side. FIG. 3 is a side view of the shift element according to the embodiment. FIG. 3 is an exploded perspective view of the shift element according to the embodiment. FIG. 2 is a schematic diagram showing a schematic configuration of a closed cooling device according to the embodiment.

Hereinafter, a first embodiment of the present invention will be described with reference to the drawings.
[Projector external configuration]
FIG. 1 is a schematic perspective view showing a projector 1 according to the present embodiment.
The projector 1 according to the present embodiment modulates light emitted from a lighting device 31 described later to form an image according to image information, and enlarges and projects the image on a projection surface such as a screen. Device.
As will be described in detail later, the projector 1 includes a shift element that changes the optical path of the incident light, and the circulating cooling device has a function of circulating cooling the shift element in addition to an optical modulator described below.
As shown in FIG. 1, such a projector 1 includes an exterior housing 2 constituting an exterior.

The exterior housing 2 is formed in a substantially rectangular parallelepiped shape having a top surface portion 21, a bottom surface portion 22, a front surface portion 23, a back surface portion 24, a left side surface portion 25, and a right side surface portion 26.
An opening (not shown) for attaching and detaching a light source device 31A, 31B, which will be described later, to the inside of the exterior housing 2 is formed in the top surface portion 21, and the opening is covered by a cover member 212.
Although not shown, the bottom portion 22 is provided with a leg portion that comes into contact with the installation surface when the device is placed on an installation surface such as an installation table.
An opening 231 exposing a part of a projection optical device 35 constituting the image forming apparatus 3 described later is formed in the front part 23.
In addition to these, although not shown, the right side portion 26 is formed with an introduction port for introducing the air outside the exterior housing 2 into the inside, and the left side portion 25 is provided with the air inside the exterior housing 2 to the outside. An exhaust port for exhaust is formed.

[Internal Configuration of Projector]
FIG. 2 is a schematic diagram illustrating an internal configuration of the projector 1.
As shown in FIG. 2, the projector 1 includes an image forming apparatus 3 and a circulating cooling device 4 arranged inside the external housing 2, in addition to the external housing 2. In addition, although not shown, the projector 1 includes a control device that controls the projector 1 and a power supply device that supplies power to electronic components included in the projector 1.

[Configuration of Image Forming Apparatus]
The image forming apparatus 3 forms and projects an image according to the image information input from the control device. The image forming apparatus 3 includes a lighting device 31, a uniformizing device 32, a color separating device 33, an electro-optical device 34, a projection optical device 35, and an optical component housing 36.
Among these, the optical component casing 36 is a box-shaped casing in which the illumination optical axis Ax is set, and the lighting device 31, the uniformizing device 32, and the color separating device 33 are the optical component casing 36. At a position on the illumination optical axis Ax. Further, although the electro-optical device 34 and the projection optical device 35 are located outside the optical component housing 36, they are arranged according to the illumination optical axis Ax.

The illuminating device 31 includes a pair of light source devices 31A and 31B opposed to each other and a reflection mirror 31C disposed between the pair of light source devices 31A and 31B.
Each of the pair of light source devices 31A and 31B includes a light source lamp 311 and a reflector 312, and a storage body 313 that stores these inside. These light source devices 31A and 31B emit light toward the reflection mirror 31C.
The reflection mirror 31C reflects the light incident from the light source devices 31A and 31B in the same direction, and thereby causes the light to enter the equalizing device 32.

The equalizing device 32 equalizes the illuminance in a plane orthogonal to the central axis of the light beam emitted from the lighting device 31. The homogenizing device 32 includes a cinema filter 321, a first lens array 322, a UV filter 323, a second lens array 324, a polarization conversion element 325, and a superimposing lens 326.
Among these, the polarization conversion element 325 aligns the polarization directions of the incident light into one type.
The color separation device 33 separates the light beam incident from the equalization device 32 into three color lights of red (R), green (G), and blue (B). The color separation device 33 includes dichroic mirrors 331 and 332, reflection mirrors 333 to 336, and relay lenses 337 to 339.

The electro-optical device 34 modulates each of the separated color lights according to image information, and then combines the modulated color lights. The electro-optical device 34 includes a field lens 340, a liquid crystal panel 341 as a light modulation device provided for each color light (liquid crystal panels for red, green, and blue are 341R, 341G, and 341B, respectively), and incident-side polarization. It has a plate 342 and an output side polarizing plate 343, an optical compensator 344, and one color combining device 345. Among these, the color synthesizing device 345 corresponds to the light synthesizing device of the present invention, and the light emitted from the color synthesizing device 345 is incident on the shift element 5 described later.
The circulation cooling device 4 has a function of cooling the electro-optical device 34 and the shift element 5.
The shift element 5 enhances the resolution of the projected image by periodically shifting the optical path of the light emitted by the color combining device 345.
The crystal diffuser 6 diffuses the light emitted from the shift element 5 and incident on the crystal diffuser 6 to the projection optical device 35 to emit the light.
The configurations of the circulation cooling device 4 and the shift element 5 will be described later in detail.

  The projection optical device 35 is a projection lens that enlarges and projects the light beam (light beam that forms an image) synthesized by the color synthesis device 345 onto the projection surface. As such a projection optical device 35, a set lens in which a plurality of lenses are arranged in a lens barrel can be adopted.

[Structure of shift element]
FIG. 3 is a plan view of the shift element 5 as viewed from the light incident side of the shift element 5, and FIG. 4 is a plan view of the shift element 5 as viewed from the light emission side. FIG. 5 is a side view showing the shift element 5, and FIG. 6 is an exploded perspective view showing the shift element 5.
The shift element 5 corresponds to the optical path changing element of the present invention, and has a function of changing (shifting) the optical path of light incident on the shift element 5 and emitted from the shift element 5. Such a shift element 5 includes an optical member 51, a frame portion 52, a permanent magnet 53, a first frame 54, a second frame 55, and a pair of coil holding portions 56 and 57, as shown in FIGS. .
Among them, the optical member 51 is formed of a light-transmitting member having a light-transmitting property, and in the present embodiment, is formed of a rectangular plate-shaped glass.

  In the following drawings and description, the traveling direction (projection direction) of light emitted from the color synthesizing device 345 and incident on the shift element 5 is defined as a Z direction, and is orthogonal to the Z direction and orthogonal to each other. The directions are an X direction and a Y direction. In the present embodiment, when the projector 1 is arranged so that the Z direction is parallel to the horizontal direction in a plan view, the projector 1 is arranged in the upper direction which is the opposite direction to the vertical direction (that is, from the bottom surface 22 to the top surface 21 of the exterior housing 2). Is defined as the Y direction, and the direction from left to right as viewed from the Z direction (light traveling direction) (ie, the direction from the left side surface 25 to the right side surface 26 of the exterior housing 2) is the X direction. And

[Configuration of frame part]
The frame 52 has a function of holding the optical member 51 and the permanent magnet 53. As shown in FIG. 6, the frame 52 is formed in a rectangular plate shape having four corners CR1 to CR4. An opening 521 into which the optical member 51 is fitted is formed at a substantially central portion of the frame 52. Fitting grooves 522 and 523 into which the permanent magnets 53 are fitted are formed at positions on the Y direction side of the opening 521 of the frame 52 and positions on the opposite side to the Y direction. Of the fitting grooves 522 and 523, the fitting groove 522 is formed on the side opposite to the X direction with respect to the fitting groove 523.

Further, a positioning protrusion 524 projecting toward the Z direction is formed on an end edge of the fitting groove 522 on the Y direction side and the opposite side to the X direction in the frame portion 52. A positioning protrusion 525 that protrudes in the Z direction is formed on an edge of the mating groove 523 on the side opposite to the Y direction and on the X direction side. Further, positioning projections 526 and 527 projecting in the direction opposite to the Z direction are formed at positions corresponding to the positioning projections 524 and 525 on the surface of the frame portion 52 on the side opposite to the Z direction. Have been.
In other words, the positioning protrusions 524 and 526 on the Y direction side are formed near the corner CR3 among the four corners CR1 to CR4 of the frame 52, and the positioning protrusions 525 and 527 on the side opposite to the Y direction are Are formed in the vicinity of a corner CR2 which is a diagonal of the corner CR3.
The permanent magnet 53 is formed in a prism shape as shown in FIG. The permanent magnet 53 (permanent magnet 531) is fitted in the fitting groove 522, and the permanent magnet 53 (permanent magnet 532) is fitted in the fitting groove 523. In this way, the permanent magnets 531 and 532 are fixed to the frame 52.

[Configuration of First Frame]
The first frame 54 is disposed on the side opposite to the Z direction of the frame 52, and has a function of holding the frame 52 together with the second frame 55. The first frame 54 is formed in a rectangular plate shape, and an opening 541 is formed in a substantially central portion of the first frame 54. The opening 541 has substantially the same shape as the optical member 51. Thus, the light incident from the opening 541 is incident on the optical member 51.
Further, a through hole 542 is formed at an end edge of the first frame 54 in the Y direction and on the opposite side to the X direction, and on a side opposite to the Y direction of the first frame 54, and A through hole 543 is formed at the edge on the X direction side. The positioning protrusions 524 of the frame 52 are inserted into the through holes 542, and the positioning protrusions 525 are inserted into the through holes 543.

[Configuration of Second Frame]
The first frame 54 is disposed on the Z direction side of the frame 52 and has a function of holding the frame 52 together with the first frame 54. The second frame 55 is formed in a rectangular plate shape, and an opening 551 is formed in a substantially central portion of the second frame 55. The opening 551 is formed in substantially the same shape as the optical member 51.
Further, a through hole 552 is formed at an end edge of the second frame 55 on the Y direction side and opposite to the X direction, and on a side opposite to the Y direction of the second frame 55 and A through hole 553 is formed at the edge on the X direction side. The positioning projections 526 of the frame 52 are inserted through the through holes 552, and the positioning projections 527 are inserted through the through holes 553.
With such a configuration, the first frame 54 and the second frame 55 sandwich the frame 52. Note that the frame 52, the first frame 54, and the second frame 55 correspond to the holding unit of the present invention.

[Configuration of coil holding unit]
The pair of coil holding portions 56 and the pair of coil holding portions 57 include an air-core coil CL corresponding to the coil of the present invention inside. The power is supplied to the air-core coil CL so that the air-core coil CL displaces the permanent magnet 53, thereby generating a magnetic force for displacing the shift element 5. Among these, the pair of coil holders 56 includes a coil holder 561 fixed to the first frame 54 and a coil holder 562 fixed to the second frame 55.
Hole portions 5611 and 5621 are formed in these coil holding portions 561 and 562, respectively. The positioning protrusion 524 of the frame 52 is fitted into the hole 5611 via the through hole 542 of the first frame 54. On the other hand, the positioning protrusion 526 of the frame 52 is fitted into the hole 5621 through the through hole 552 of the second frame 55. Thus, the coil holding unit 561 is fixed to the first frame 54, and the coil holding unit 562 is fixed to the second frame 55.

  On the other hand, the pair of coil holders 57 includes a coil holder 571 fixed to the first frame 54 and a coil holder 572 fixed to the second frame 55. Hole portions 5711 and 5721 are formed in these coil holding portions 571 and 572, respectively. The positioning protrusion 525 of the frame 52 is fitted into the hole 5711 through the through hole 543 of the first frame 54. On the other hand, the positioning protrusion 527 of the frame 52 is fitted into the hole 5721 via the through hole 553 of the second frame 55. Thus, the coil holding section 571 is fixed to the first frame 54, and the coil holding section 572 is fixed to the second frame 55.

As described above, the coil holding portions 561 and 562 of the pair of coil holding portions 56 are arranged in the opposite direction to the X direction, near the corner CR3 on the Y direction side, and at overlapping positions and orientations. . On the other hand, when the shift element 5 is viewed along the Z direction, the coil holding portion 571 and the coil holding portion 572 of the pair of coil holding portions 57 are near the corner CR2 on the X direction side and the opposite side to the Y direction. And are arranged in overlapping positions and orientations. In other words, when the shift element 5 is viewed from the side opposite to the Z direction, the pair of coil holding units 56 are arranged on the liquid crystal panel 341B side, and the pair of coil holding units 57 are arranged on the liquid crystal panel 341R side. .
The frame portion 52, the first frame 54, the second frame 55, the pair of coil holding portions 56, and the pair of coil holding portions 57 are made of a metal having thermal conductivity, and in this embodiment, are made of aluminum. Have been. Accordingly, when the temperature of the air-core coil CL rises, the air-core coil CL is applied to each of the frame portion 52, the first frame 54, the second frame 55, the pair of coil holding portions 56, and the pair of coil holding portions 57. Heat is conducted.

A power supply unit (not shown) is connected to each of the coil holding units 561, 562, 571, and 572. The power supply unit displaces the permanent magnets 531 and 532 by supplying power to the air-core coil CL via the coil holding units 561, 562, 571, and 572, and thus displaces the shift element 5. Generates magnetic force.
Specifically, when the permanent magnets 531 and 532 attached to the frame 52 are displaced, the shift element 5 moves in the direction of approaching and separating along the rotation angle L1 shown in FIGS. The angle of the optical member 51 fitted in the opening 521 of the frame 52 is changed.
In other words, by supplying electric power to each of the coil holding units 561, 562, 571, and 572, the optical path of light that enters the optical member 51 and exits from the optical member 51 can be changed.

[Configuration of circulation cooling device]
FIG. 7 is a schematic diagram illustrating a schematic configuration of the circulation cooling device 4. In FIG. 7, in order to make the description easy to understand, a liquid crystal panel 341R constituting the electro-optical device 34, a field lens 340 corresponding to the liquid crystal panel 341R, an incident side polarizing plate 342 and an outgoing side polarizing plate 343, an optical compensation Illustration other than the plate 344 is omitted.
The circulating cooling device 4 includes a closed casing 41 corresponding to the inner casing of the present invention, and has a function of cooling the electro-optical device 34 and the shift element 5 arranged in the closed casing 41. Such a circulating cooling device 4 includes a prism base 42, a first fan 43, a second fan 44, and a heat sink 45, in addition to the closed casing 41.
When the shift element 5 is arranged in the closed casing 41, the heat conducting portions TC1 to TC4 are fixed to the coil holding portions 561, 562, 571, and 572, respectively. The heat conducting portions TC1 to TC4 are formed of a heat conducting sheet having heat conductivity. Therefore, when the temperature of the air-core coil CL rises, the heat of the coil holding parts 561, 562, 571, 572 is conducted to the heat conducting parts TC1 to TC4.

[Configuration of sealed housing]
The closed casing 41 houses a liquid crystal panel 341, an incident-side polarizing plate 342, an outgoing-side polarizing plate 343, an optical compensating plate 344, a color combining device 345, a holding member 346, and a shift element 5 that constitute the electro-optical device 34 therein. This is a box-shaped housing that is disposed inside the exterior housing 2. The closed casing 41 has a closed structure in which gas outside the closed casing 41 hardly flows into the inside. In other words, the liquid crystal panel 341, the incident-side polarizing plate 342, the outgoing-side polarizing plate 343, the optical compensator 344, the color synthesizing device 345, the holding member 346, and the shift element 5 are substantially sealed in the sealed housing 41.
The closed housing 41 includes a top surface portion 41A, a bottom surface portion 41B, a first side surface portion 41C, a second side surface portion 41D, and third and fourth side surface portions on the X direction side and the side opposite to the X direction (not shown). ). The sealed housing 41 includes a top surface portion 41A, a bottom surface portion 41B, a first side surface portion 41C, a housing portion 411 that forms the third side surface portion and the fourth side surface portion, and a plate that forms a second side surface portion 41D. And the quartz crystal diffuser 6.

  Among these, the housing 411 is made of resin or the like. An opening 4111 is formed at a substantially central portion of the first side surface portion 41C constituting the housing portion 411. A field lens 340 corresponding to the liquid crystal panel 341G is fitted into the opening 4111. An opening is also formed in each of the substantially central part of the third side part and the substantially central part of the fourth side part, and the field lens 340 corresponding to the liquid crystal panels 341R and 341B is fitted into the opening. Thereby, each color light separated by the color separation device 33 is incident on the liquid crystal panel 341 via the field lens 340.

The plate portion 412 forms a part of the second side surface portion 41D of the closed casing 41, and an opening 4121 is formed at a substantially central portion of the plate portion 412. The quartz diffusion plate 6 is fitted into the opening 4121. Further, the plate-shaped portion 412 is made of a metal having thermal conductivity, and in this embodiment, is made of aluminum.
Further, the first portion 4122 located on the Y direction side of the plate portion 412 is in contact with the heat conducting portion TC1 so as to be able to conduct heat, and the second portion located on the side opposite to the Y direction of the plate portion 412. 4123 is in contact with heat conduction portion TC2 so as to be able to conduct heat. The prism base 42U is fixed to the first part 4122, and the prism base 42L is fixed to the second part 4123. Therefore, when the temperature of the air-core coil CL rises, the heat of the coil holding portions 562 and 572 is conducted to the heat conducting portions TC1 and TC2, and the heat of the heat conducting portions TC1 and TC2 is conducted to the plate portion 412. Is done.
The first portion 4122 and second portion 4123 is equivalent to the heat transfer guide portion position of the present invention.

[Configuration of prism base]
Here, among the constituent elements of the electro-optical device 34, the liquid crystal panels 341 (341 R, 341 G, 341 B), the output-side polarizing plate 343, and the optical compensator 344 are attached to the color synthesizing device 345 by the holding member 346, and are integrated. To form a prism unit. The color synthesizing device 345 constituting this prism unit is constituted by a cross dichroic prism having a substantially rectangular prism. The color synthesizing device 345 includes three incident surfaces on which light emitted from the liquid crystal panel 341 is individually incident, one exit surface on which the incident surface is incident, and emits combined light, and a plurality of light emitting surfaces. And a first support surface 3451 and a second support surface 3452 which are respectively intersected with the entrance surface and the exit surface, and are connected to the prism base 42 at positions opposite to each other.
The prism base 42 corresponds to the support member of the present invention, and has a function of fixing the prism unit in the housing 41 by supporting the color combining device 345. The prism base 42 is made of a metal having thermal conductivity, and in this embodiment, is made of aluminum. The prism base 42 includes a prism base 42U corresponding to the first support of the present invention, and a prism base 42L corresponding to the second support of the present invention.

As shown in FIG. 7, each of the prism bases 42U, 42L includes a substantially L-shaped support portion 421U, 421L and an extension portion 422U, 422L extending in the Z direction from an end of the support portion 421U, 421L. Prepare.
A first support surface 3451, which is a surface on the Y direction side of the color synthesizing device 345, is in contact with a surface of the support portion 421U of the prism base 42U on the side opposite to the Y direction, and the first support surface 3451 on the Z direction side of the support portion 421U. The surface is in contact with a heat conducting part TC3 so as to conduct heat. Further, the end of the extension 422U on the Z direction side is fixed to the surface of the plate-shaped portion 412 on the side opposite to the Z direction.
On the other hand, a second support surface 3452, which is a surface on the side opposite to the Y direction of the color synthesizing device 345, is in contact with the surface of the support portion 421L of the prism base 42L on the Y direction side, and the Z direction of the support portion 421L. A heat conducting portion TC4 is in contact with the side surface so as to conduct heat. Further, an end of the extension 422U on the Z direction side is fixed to a surface of the plate-shaped portion 412 on the side opposite to the Z direction.
With this configuration, the prism unit (color synthesizing device 345) is fixed in the housing 41, and heat from the heat conducting portions TC3 and TC4 is conducted to the prism bases 42U and 42L.
Further, radiation fins may be provided on the surfaces of the prism bases 42U and 42L. By providing the heat radiation fins, the contact area with the cooling gas discharged from the first fan 43 described later can be increased, and the heat conducted from the heat conducting portions TC3 and TC4 can be efficiently cooled. .

[Configuration of cooling fan]
The first fan 43 corresponds to a part of the cooling device of the present invention, and is configured by a sirocco fan. As shown in FIG. 7, the first fan 43 is disposed on the side of the first side face 41C on the bottom face 41B. The first fan 43 is arranged so that the intake surface 431 faces the Y direction. Further, the exhaust surface 432 is arranged facing the Z direction side. Therefore, when the first fan 43 is driven, the cooling gas in the closed casing 41 is sucked from the intake surface 431, and the cooling gas is discharged from the exhaust surface 432 in the Z direction. A part of the cooling gas discharged from the exhaust surface 432 is branched in the Y direction by a duct (not shown), and the branched cooling gas passes through the liquid crystal panel 341, the incident side polarizing plate 342, the emitting side polarizing plate 343, and the like. Cooling.

The second fan 44 corresponds to a part of the cooling device of the present invention, and is constituted by an axial fan. The second fan 44 is disposed between the top surface 41A and the first side surface 41C in the closed casing 41. The second fan 44 is arranged such that the intake surface 441 faces the Y direction. In addition, the exhaust surface 432 facing the intake surface 441 is disposed facing the side opposite to the Y direction. That is, the intake surface 431 of the first fan 43 and the exhaust surface 442 of the second fan 44 are arranged to face each other. For this reason, when the second fan 44 is driven, the cooling gas in the closed casing 41 sucked from the intake surface 441 of the second fan 44 is discharged from the exhaust surface 442 toward the first fan 43, and the cooling gas Is sucked by the first fan 43.
Note that the first fan 43 and the second fan 44 are each configured by a sirocco fan and an axial fan, but the present invention is not limited to this, and both may be configured by a sirocco fan, It may be constituted by a flow fan.

[Configuration of heat sink]
The heat sink 45 has a function of lowering the temperature of a portion to which the heat sink 45 is connected. This heat sink 45 is connected to the top surface portion 41A of the closed casing 41. Thereby, the cooling gas flowing in the position facing the heat sink 45 in the closed casing 41 is cooled by the heat sink 45.

[Cooling gas circulation channel]
In the circulating cooling device 4 having such a configuration, when the first fan 43 is driven, the cooling gas sucked from the intake surface 431 is discharged from the exhaust surface 432 and flows along the bottom surface portion 41B. The cooling gas flowing along the bottom surface portion 41B collides with the second side surface portion 41D, and flows in the Y direction, that is, toward the top surface portion 41A. In a process in which the cooling gas flows from the bottom surface 41B to the top surface 41A, the shift element 5, the prism bases 42U and 42L, the prism unit, and the plate portion 412 are cooled by the cooling gas. The cooling gas that has cooled the shift element 5, the prism bases 42U and 42L, the prism unit, and the plate-shaped portion 412 flows along the top surface portion 41A by suction from the intake surface 441 of the second fan 44. In this process, the cooling gas is cooled by the heat sink 45 and is sucked by the second fan 44. Then, the cooling gas is sucked from the intake surface 431 of the first fan 43, which is discharged from the exhaust surface 442 of the second fan 44 toward the first fan 43.

  As described above, when the first fan 43 and the second fan 44 are driven, the cooling gas in the closed casing 41 circulates clockwise. In this manner, the plate-shaped portion 412 to which the heat from the coil holding portions 562 and 572 and the heat conducting portions TC1 and TC2 are conducted is cooled. Further, the prism bases 42U and 42L to which the heat from the coil holding units 561 and 571 and the heat conduction units TC3 and TC4 have been conducted are cooled. Thereby, the heat conducted from the air-core coil CL is radiated, and the air-core coil CL is eventually cooled.

The projector 1 according to the embodiment described above has the following effects.
Since the plurality of liquid crystal panels 341R, 341G, and 341B, the shift element 5, and the color synthesizing device 345 are arranged in the closed casing 41, dust adheres to the liquid crystal panel 341, the color synthesizing device 345, and the shift element 5. Can be suppressed. Therefore, the brightness and the saturation of the image projected from the projector 1 can be increased.

Here, when electric power is supplied to the pair of air-core coils CL disposed with the permanent magnet 53 interposed therebetween, the permanent magnet 53 is displaced, and thus a magnetic force for displacing the shift element 5 is generated. The temperature of the air core coil CL rises. As described above, when the temperature of the pair of air-core coils CL increases, the magnetic force of the pair of air-core coils CL that generates magnetic force may be weakened.
On the other hand, according to the present embodiment, since the heat conducting portions TC1 to TC4 fixed to the coil holding portions 561, 562, 571, and 572 of the shift element 5 come into contact with the prism base 42 as a support member, the above-described empty space is obtained. When the heat of the core coil CL rises, the heat of the air core coil CL is transmitted to the support member via the heat conducting part. Thus, it is possible to suppress the temperature of the pair of air-core coils CL provided in the shift element 5 from rising. Therefore, a decrease in the magnetic force of the air core coil CL provided in the shift element 5 can be suppressed, so that the drive of the shift element 5 can be stabilized.

  Since the support portions 421U and 421L supporting the first support surface 3451 and the second support surface 3452 of the color synthesis device 345 are in contact with the heat conduction portions TC3 and TC4, when the heat of the air-core coil CL rises, The heat of the air-core coil CL is transmitted to the prism base 42 via the heat conducting portions TC3 and TC4. Thus, it is possible to suppress the temperature of the pair of air-core coils CL provided in the shift element 5 from rising. Therefore, a decrease in the magnetic force of the air core coil CL provided in the shift element 5 can be suppressed, so that the drive of the shift element 5 can be stabilized.

  Since the heat conducting portions TC1 and TC2 contact the closed housing 41, more specifically, the first portion 4122 and the second portion 4123 having thermal conductivity of the closed housing 41 in a heat conductive manner, the air core When the heat of the coil CL rises, the heat of the air-core coil CL is transmitted to the plate portion 412 of the closed casing 41 via the heat conducting portions TC1 and TC2. Thereby, the temperature of the pair of air-core coils CL provided in the shift element 5 can be reliably prevented from rising. Accordingly, the magnetic force of the air-core coil CL provided in the shift element 5 can be reliably prevented from lowering, so that the drive of the shift element 5 can be reliably stabilized.

  Since the first fan 43 as a cooling device is disposed in the closed casing 41, the liquid crystal panel 341, the shift element 5, and the color combining device 345 disposed in the closed casing 41 can be cooled. In addition, since the cooling gas flows through the prism base 42 to which the heat of the air-core coil CL has been transmitted through the heat conducting portions TC1 to TC4, the prism base 42 can be reliably cooled. Therefore, it is possible to suppress an increase in the temperature of the pair of air-core coils CL provided in the shift element 5.

[Modification of Embodiment]
The present invention is not limited to the above embodiment, and includes modifications and improvements as long as the object of the present invention can be achieved.
In the above embodiment, the shift element 5, the color synthesizing device 345, and the liquid crystal panel 341 are arranged in the closed casing 41. However, the present invention is not limited to this. For example, only the shift element 5 may be arranged in the closed casing 41, or only the shift element 5 and the liquid crystal panel 341 may be arranged in the closed casing 41. If necessary, it is only necessary that the shift element 5 be disposed in the closed casing 41.

  In the above embodiment, the closed casing 41 is substantially sealed. However, the present invention is not limited to this. For example, the closed casing 41 may not be sealed, and may be configured to supply the cooling gas from the unsealed portion.

  In the above embodiment, the heat conducting portions TC1 to TC4 are fixed to the coil holding portions 561, 562, 571, and 572. However, the present invention is not limited to this. For example, a configuration may be adopted in which the coil holding portions 561, 562, 571, and 572 do not directly include the heat conducting portions TC1 to TC4 but directly contact the prism base 42 and the plate-shaped portion 412 so as to be able to conduct heat. Even in this case, the same effect as in the above embodiment can be obtained.

  In the above-described embodiment, the heat conductive portions TC1 to TC4 are configured by a heat conductive sheet having heat conductivity. However, the present invention is not limited to this. For example, the heat conducting portions TC1 to TC4 are not limited to solids, and may be made of grease having heat conductivity. That is, the heat conducting portions TC1 to TC4 may be made of any material as long as they have heat conductivity.

  In the above embodiment, the first portion 4122 and the second portion 4123 of the plate-shaped portion 412 with which the heat conducting portions TC1 and TC2 come into heat conductive contact have thermal conductivity. However, the present invention is not limited to this. For example, the plate portion 412 may be made of a resin or the like.

  In the above embodiment, the heat conducting portions TC1 and TC2 are in contact with the plate portion 412 so as to be able to conduct heat. However, the present invention is not limited to this. For example, only the heat conducting portion TC1 may be in contact with the plate portion 412 so as to be able to conduct heat, or only the heat conducting portion TC2 may be in contact with the plate portion 412 so as to be able to conduct heat. In this case, for example, a portion of the heat conductive portions TC1 and TC2 that does not contact the plate-shaped portion 412 so as to be able to conduct heat may be made of a material having no heat conductivity.

  In the above embodiment, the circulation cooling device 4 includes the first fan 43 and the second fan 44. However, the present invention is not limited to this. For example, the circulation cooling device 4 may include only one of the first fan 43 and the second fan 44. Even in this case, the liquid crystal panel 341, the color synthesizing device 345, and the shift element 5 disposed in the closed casing 41 can be cooled. Further, the first fan 43 and the second fan 44 may not be provided in the closed casing 41. In this case, for example, a heat sink may be connected to the outside of the closed casing 41, and cooling may be performed from the outside of the closed casing 41 by a cooling fan.

  In the above embodiment, the heat sink 45 constituting the circulation cooling device 4 is connected to the top surface portion 41A. However, the present invention is not limited to this. For example, the heat sink 45 may be provided on any of the bottom surface 41B, the first side surface 41C, and the second side surface 41D. Further, the number of heat sinks 45 is not limited to one, and may be provided on each of the bottom surface portion 41B, the first side surface portion 41C, and the second side surface portion 41D, or the heat sink 45 may not be provided.

  In the above embodiment, the prism bases 42U and 42L are provided. However, the present invention is not limited to this. For example, only one of the prism bases 42U and 42L may be provided. In particular, if only the prism base 42U is provided, the cooling gas from the bottom surface portion 41B can be made to flow through the shift element 5 more.

  In the above embodiment, the first support surface 3451 and the second support surface 3452 supported by the prism bases 42U and 42L are the surface on the Y direction side of the color combining device 345 and the surface on the opposite side to the Y direction. However, the present invention is not limited to this. For example, the prism bases 42U and 42L may support the surface on the X direction side and the surface on the opposite direction to the X direction of the color combining device 345. In this case, the liquid crystal panels 341R and 341B as light modulation devices may be disposed so as to face the first support surface 3451 and the second support surface 3452.

In the above embodiment, the shift element 5 includes the optical member 51, the frame portion 52, the permanent magnet 53, the first frame 54, the second frame 55, and the pair of coil holding portions 56 and 57. However, the present invention is not limited to this. For example, the first frame 54 and the second frame 55 may be integrated. Further, the pair of coil holding portions 56 and the pair of coil holding portions 57 are provided, but only one of them may be provided.
That is, as long as power is supplied to the air-core coil CL held by the coil holding portions 56 and 57, the optical member 51 swings, and the optical path of the light incident on the optical member 51 can be changed, any configuration is possible. There may be.

  In the above embodiment, the shift element 5 has the configuration shown in FIGS. However, the present invention is not limited to this. For example, any configuration may be used as long as the optical member 51 can be swung by a solenoid or the like to change the optical path of incident light.

  In the above embodiment, the second side surface portion 41D is configured by the plate-shaped portion 412 and the crystal diffusion plate 6. However, the present invention is not limited to this. For example, instead of the crystal diffusion plate 6, a light-transmitting member that simply allows light from the shift element 5 to pass therethrough may be used.

In the above embodiment, the air-core coil CL is held by the coil holding portions 56 and 57. However, the present invention is not limited to this. For example, the air core coil CL may be directly fixed to the first frame 54 and the second frame 55.
In the above embodiment, the color synthesizing device 345 is configured by a cross dichroic prism. However, the present invention is not limited to this. For example, the color combining device 345 may have any shape as long as it can combine light incident from the liquid crystal panel 341.

  In the above-described embodiment, the pair of coil holding portions 56 are arranged near the corner CR3 in the first frame 54, that is, when the shift element 5 is viewed from the side opposite to the Z direction, the Y direction is opposite to the X direction. The pair of coil holding portions 57 are arranged at positions in the direction side, and are arranged near the corner portion CR2 in the first frame 54, that is, at a position on the X direction side opposite to the Y direction. However, the present invention is not limited to this. For example, the positions of the pair of coil holders 56 and the pair of coil holders 57 may be reversed.

  In the above embodiment, the pair of coil holding portions 56 and 57 hold the air-core coil CL. However, the present invention is not limited to this. For example, the pair of coil holding portions 56 and 57 may hold an iron core coil. That is, any shape and type of coil may be used as long as a magnetic force can be generated by supplying electric power.

  In the above embodiment, the frame portion 52, the first frame 54, the second frame 55, and the pair of coil holding portions 56, 57 are made of aluminum. However, the present invention is not limited to this. For example, the frame portion 52, the first frame 54, the second frame 55, and the pair of coil holding portions 56, 57 are not limited to aluminum, and may be made of any material having thermal conductivity. Good.

  In the above embodiment, the transmission type liquid crystal panel 341 (341R, 341G, 341B) is used as the light modulation device. However, the present invention is not limited to this. For example, a reflective liquid crystal panel may be used instead of the transmissive liquid crystal panel 341 (341R, 341G, 341B). In this case, color separation and color synthesis may be performed by the color synthesis device 345 without providing the color separation device 33.

In the above embodiment, the projector 1 includes the three liquid crystal panels 341 (341R, 341G, 341B), but the present invention is not limited to this. That is, the invention can be applied to a projector using two or less or four or more liquid crystal panels.
Further, a DMD (digital micromirror device) or the like may be used instead of the liquid crystal panel 341.

In the above embodiment, the projector 1 includes the pair of light source devices 31A and 31B. However, the present invention is not limited to this. For example, the number of light source devices may be one or four.
In the above embodiment, the arrangement of the image forming apparatus 3 is the arrangement shown in FIG. However, the present invention is not limited to this. For example, the image forming apparatus may be arranged in a substantially L shape or a substantially U shape.

DESCRIPTION OF SYMBOLS 1 ... Projector, 2 ... Exterior housing, 31 ... Illumination device (light source), 340 ... Field lens, 341, 341R, 341G, 341B ... Liquid crystal panel (light modulation device), 342 ... Incident side polarizing plate, 343 ... Exit side Polarizing plate, 344: optical compensator, 345: color synthesizing device (light synthesizing device), 3451: first supporting surface, 3452: second supporting surface, 346: holding member, 35: projection optical device, 4: circulating cooling device, 41 ... sealing housing (the housing), 411 ... housing, 4111 ... opening, 412 ... plate portion, 4121 ... opening, 4122 ... first site (thermal conduction unit position), 4123 ... second site (thermal conduction unit position), 41A ... top face portion, 41B ... bottom portion, 41C ... first side surface portion, 41D ... second side portions, 42 ... prisms base (supporting member), 421L ... support portion, 421U ... support Part, 422U ... Extended , 42 ... Prism base, 42L ... Prism base (first support), 42U ... Prism base (second support), 421U, 421L ... Support, 422U, 422L ... Extension, 43 ... First fan (cooling) Device), 431 ... intake surface, 432 ... exhaust surface, 44 ... second fan (cooling device), 441 ... intake surface, 442 ... exhaust surface, 45 ... heat sink, 5 ... shift element (optical path changing element), 51 ... optical Member, 52: Frame portion (holding portion), 53, 531, 532: Permanent magnet, 561, 562, 571, 572: Coil holding portion, 6: Quartz diffuser, CL: Air-core coil (coil), TC1, TC2 , TC3, TC4... Heat conducting parts.

Claims (7)

A light source,
A plurality of light modulators for modulating light emitted from the light source,
A light combining device that combines and emits light modulated by the plurality of light modulation devices,
A projection optical device that projects the light synthesized by the photosynthetic apparatus,
An optical path changing element disposed between the plurality of light modulation devices and the projection optical device, and changing an optical path of light modulated by the plurality of light modulation devices by swinging,
An exterior housing constituting an exterior,
An internal housing in which the optical path changing element and the photosynthesis device are disposed,
A support member that supports the photosynthesis device disposed in the internal housing,
With
The optical path changing element,
A permanent magnet,
An optical member that changes the optical path of light that has been rocked and incident by the permanent magnet,
A holding unit that holds the optical member and the permanent magnet,
A pair of coils disposed on the holding portion with the permanent magnet interposed therebetween,
A coil holding unit that holds the pair of coils,
A heat conducting part that is in contact with the coil holding part and is connected to the support member so as to be capable of conducting heat;
A projector comprising: The projector according to claim 1,
The projector according to claim 1, wherein the plurality of light modulation devices are disposed in the internal housing. The projector according to claim 1 or 2 ,
The photosynthesis device has a first support surface and a second support surface that are located on opposite sides and connected to the support member,
The support member has a first support portion connected to the first support surface, and a second support portion connected to the second support surface,
The projector, wherein the heat conducting unit is connected to both the first support unit and the second support unit so as to be able to conduct heat. The projector according to any one of claims 1 to 3 ,
The projector according to claim 1, wherein the inner housing has a heat conducting part connected to the heat conducting part so as to be able to conduct heat. The projector according to claim 4 , wherein
A cooling device arranged in the inner housing and circulating a cooling gas in the inner housing,
The internal housing is a closed housing,
The projector, wherein the cooling device causes the cooling gas to flow through the optical path changing element, the support member, and the heat conduction portion in the closed casing. The projector according to any one of claims 1 to 4 ,
A cooling device arranged in the inner housing and circulating a cooling gas in the inner housing,
A part of the cooling gas flows through the support member. The projector according to any one of claims 1 to 6 ,
The projector according to claim 1, wherein the light path changing element is disposed between the light combining device and the projection optical device.

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