JP2014211462A - Projector - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a projector that can perform efficient cooling with a simple configuration.SOLUTION: A cooling fan 42 is driven to send air 90 outside an opening H11b to the inside of a housing part R12 as a cooling air 91, and send cooling air 92 and 93 being parts of the cooling air 91 inside the housing part R12 to the inside of a housing part R11 so that the cooling air 92 and 93 inside the housing part R12 are joined to a cooling air 96.

Description

  The present invention relates to projector cooling.

  Projectors are often used as means for projecting computer images, video images, and the like onto a screen. The projector condenses illumination light from a light source on a display element, generates a color image, and projects the color image on a screen. The display element is, for example, a DMD (Digital Micromirror Device), a liquid crystal element, or the like. As this projector, a projector using a discharge lamp as a light source is known, and a technique for efficiently taking in light emitted from the discharge lamp into an optical unit has been developed.

  However, a discharge lamp often used in a projector generates a great deal of heat, and it is not easy to cool each part of the light emitting bulb to an appropriate temperature. Moreover, even if the cooling is appropriately performed, the life of the discharge lamp is generally 2000 to 3000 hours. Therefore, there is a problem in maintainability in order to use a projector that uses a discharge lamp as a display device.

  From this point of view, projectors equipped with a semiconductor light source have recently been developed. The semiconductor light source is, for example, an LED (Light Emitting Diode), a semiconductor laser, or the like. The lifetime of the semiconductor light source is very long, about ten times that of a typical lamp. Furthermore, the semiconductor light source generates less heat and consumes less power. For this reason, miniaturization of projectors using semiconductor light sources has been attempted.

  Patent Document 1 discloses a technique (hereinafter also referred to as Related Art A) for efficiently cooling a semiconductor light source (light source device) in a projector using a semiconductor light source. Specifically, in Related Technology A, a plurality of cooling fans and openings are provided on the edge (side surface) of the projector casing. In Related Art A, a plurality of cooling fans and openings are used to take (send) outside air at different positions into the casing as cooling air for cooling the light source device, the heat generation source, and the like in the casing. .

  Further, in Related Technology A, the inside of the housing is configured so that the cooling air taken in by each cooling fan does not interfere with each other. Specifically, a partition member, a guide member, and the like are disposed in the housing between each light source device and the heat source. As described above, efficient cooling is realized by smoothly discharging the cooling air. As a result, in Related Technology A, a bright image is projected, and the life of the semiconductor light source is extended.

JP 2011-078898 A1

  However, Related Technology A has the following problems. Specifically, in Related Art A, a cooling fan is arranged for each light source device and each main heat source. Further, Related Art A has a configuration for taking in outside air at different positions for each cooling fan using a plurality of cooling fans. In order to realize the configuration, in Related Technology A, a partition member, a guide member, and the like are arranged in a complicated manner in the housing. Therefore, there is a problem that the structure of the projector of related technology A is complicated and expensive.

  SUMMARY An advantage of some aspects of the invention is that it provides a projector capable of performing efficient cooling with a simple structure.

  In order to achieve the above object, a projector according to an aspect of the present invention includes a light source that emits light, an optical unit that emits image light that forms an image using light emitted from the light source, and A power supply unit that supplies power for operating the projector; first and second cooling fans that cool the light source; and a housing, and at least the second cooling fan in the housing. Is used as a boundary to form a first housing part that is an area for housing the optical unit and a second housing part that is an area for housing the power supply unit. A part of the housing forming the part is provided with a first opening for intake and a second opening for exhaust, and the first opening and the second opening Each is provided on a different side of the housing, A portion of the housing forming a second housing portion is provided with a third opening for intake, and the third opening includes the side surface on which the second opening is provided. The first cooling fan is provided on a different side surface of the casing, and the first cooling fan is provided at a position for using the outside air of the first opening, and the outside air of the first opening is The second cooling fan is driven so as to be sent into the first casing portion as one cooling air, and the second cooling fan uses the outside air of the third opening as the second cooling air to the second casing. The second cooling air is sent into the portion and the second cooling air in the second housing portion is merged with the first cooling air in the first housing portion. The combined cooling air that is driven so as to be sent to and the first cooling air and the second cooling air are merged is discharged from the second opening.

  According to the present invention, the second cooling fan sends the outside air of the third opening into the second casing part as the second cooling air, and the second casing part. The second cooling air is driven so as to be sent into the first casing portion so that the second cooling air merges with the first cooling air.

  Thereby, the 1st cooling wind and the 2nd cooling wind merge, and the confluence | merging cooling wind with which the air volume increased can be used in a 1st housing | casing part. As a result, the optical unit in the first housing part can be efficiently cooled. That is, by using the combined cooling air in which a plurality of cooling airs are combined, efficient cooling can be performed with a simple structure.

1 is a schematic plan view showing a configuration of a projector according to Embodiment 1 of the present invention. It is the schematic which shows the internal structure of the projector seen from the side surface of the projector which concerns on Embodiment 1 of this invention. It is a figure for demonstrating the wind which generate | occur | produces inside the projector which concerns on Embodiment 1 of this invention. It is a perspective view of a cooler. It is a top view of a cooler. It is a figure which shows the structure which further provided the partition material in the housing | casing.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. In the following description, the same components are denoted by the same reference numerals. Their names and functions are also the same. Therefore, detailed description thereof may be omitted.

  It should be noted that the dimensions, materials, shapes, relative arrangements, and the like of the constituent elements exemplified in the embodiments are appropriately changed depending on the configuration of the apparatus to which the present invention is applied and various conditions. It is not limited to those examples. Moreover, the dimension of each component in each figure may differ from an actual dimension.

<Embodiment 1>
FIG. 1 is a schematic plan view showing the configuration of a projector 1000 according to Embodiment 1 of the present invention. In FIG. 1, the X, Y, and Z directions are orthogonal to each other. The X, Y, and Z directions shown in the following figures are also orthogonal to each other. Hereinafter, a direction including the X direction and the direction opposite to the X direction (−X direction) is also referred to as an X-axis direction. In the following, the direction including the Y direction and the direction opposite to the Y direction (−Y direction) is also referred to as a Y-axis direction. In the following, a direction including the Z direction and a direction opposite to the Z direction (−Z direction) is also referred to as a Z-axis direction. Hereinafter, a plane including the X-axis direction and the Z-axis direction is also referred to as an XZ plane.

  FIG. 2 is a schematic diagram showing an internal configuration of projector 1000 viewed from the side of projector 1000 according to Embodiment 1 of the present invention. In FIG. 2, for convenience of explanation, a side surface parallel to the XZ plane is not illustrated in the housing of the projector 1000.

  FIG. 3 is a diagram for explaining the wind generated inside projector 1000 according to Embodiment 1 of the present invention. 1 and 3 do not show the upper surface of the housing of the projector 1000 for convenience of explanation. In particular, FIG. 3 does not show a control circuit 16, which will be described later, light source drive circuits 17, 18, which will be described later, an audio circuit 20, which will be described later, and the like for convenience of explanation.

  Referring to FIGS. 1, 2 and 3, projector 1000 includes a housing 50, an optical unit 100, cooling fans 41, 42a, 42b, partition members 26a, 26b, control circuit 16, and light source drive. Circuits 17 and 18, speaker 19, audio circuit 20, power supply unit 21, and coolers 12, 13, 39 R, and 39 B are provided.

  The housing 50 accommodates each component (for example, the optical unit 100) of the projector 1000. The shape of the housing 50 is a rectangular parallelepiped. In addition, the shape of the housing | casing 50 is not limited to a rectangular parallelepiped, For example, a cube etc. may be sufficient.

  The partition members 26a and 26b and the cooling fans 41, 42a and 42b are provided in the housing 50 as shown in FIG. The partition member 26a is provided between the cooling fan 41 and the cooling fan 42a. The partition member 26b is provided in the vicinity of the cooling fan 42b. Details of the cooling fans 41, 42a, and 42b will be described later.

  Inside the case 50, case parts R11, R12 are formed by the partition members 26a, 26b and the cooling fans 41, 42a, 42b. That is, the partition members 26a and 26b are used as boundaries for forming the housing portions R11 and R12.

  The housing portion R11 is a region that houses the optical unit 100. The housing portion R11 is formed by a part of the housing 50, the partition members 26a and 26b, the cooling fans 42a and 42b, and one side surface of the cooling fan 41, as shown in FIGS. It is an area. One side surface of the cooling fan 41 is the surface of the cooling fan 41 that is closest to the speaker 19.

  The casing portion R12 is an area that houses the speaker 19, the audio circuit 20, the power supply unit 21, and the like. That is, the housing portion R12 is a region that does not accommodate the optical unit 100. The housing portion R12 is formed by a part of the housing 50, partition members 26a and 26b, cooling fans 42a and 42b, and one side surface of the cooling fan 41, as shown in FIGS. It is an area. That is, the cooling fans 41, 42a, and 42b function as partition members that form the housing portions R11 and R12.

  Hereinafter, each of the cooling fans 42 a and 42 b is also collectively referred to as a cooling fan 42. That is, the housing parts R11 and R12 are formed in the housing 50 using at least the cooling fan 42 as a boundary.

  Although described in detail later, the optical unit 100 emits image light constituting an image. The optical unit 100 includes light sources 30R, 30B, and 30G, a light source group 31, a light valve 36, an illumination optical unit 37, and a projection optical unit 38.

  The light source 30R emits red light (red band light). The light source 30B emits blue light (blue band light). The light source group 31 emits excitation light. The light source group 31 includes a plurality of light sources 30L that emit excitation light.

  The light source 30G has a phosphor. The light source 30G uses the phosphor and the excitation light emitted from the light source group 31 to emit green light (green band light) as fluorescence. Hereinafter, each of the light sources 30R, 30B, 30G, and 30L is also simply referred to as a light source 30. Each light source 30 is cooled by cooling fans 41, 42a, and 42b.

  The light valve 36 is, for example, a DMD, a liquid crystal element, or the like. The illumination optical unit 37 includes a lens, a dichroic mirror, a light guide element, a reflection mirror, and the like. The illumination optical unit 37 combines (condenses) the light emitted from the light sources 30 and irradiates the light valve 36 with the combined light. The light valve 36 emits image light constituting an image using the irradiated light.

  The projection optical unit 38 projects (emits) the image light emitted from the light valve 36 onto a screen (not shown). That is, the optical unit 100 emits video light using the light emitted from each light source 30.

  The casing 50 is provided with intake openings H11a and H11b and an exhaust opening H12. Specifically, a part of the casing 50 that forms the casing part R11 is provided with an opening H11a for intake and an opening H12 for exhaust. 1 and 3, each of the opening H11a and the opening H12 is provided on a different side surface of the housing 50. That is, the side surface of the housing 50 on which the opening H11a is provided is different from the side surface of the housing 50 on which the opening H12 is provided.

  In addition, an opening H11b for intake is provided in a part of the casing 50 that forms the casing portion R12. Note that the opening H11b is provided on a side surface of the housing 50 different from the side surface on which the opening H12 is provided.

  Although details will be described later, the openings H11a and H11b are provided to take in cooling air for cooling the heat-generating components in the housing 50 into the housing 50. Although details will be described later, the opening H12 is provided to discharge cooling air that has cooled the heat-generating component.

  As shown in FIGS. 1 and 2, the control circuit 16 is provided near the upper portion of the housing 50. Specifically, the control circuit 16 is disposed across the housing part R11 and the housing part R12. The control circuit 16 includes a signal processing unit, a control unit that controls each unit of the projector 1000, and the like. The signal processing unit converts an external input signal into a video signal that drives the light valve 36 that is a display element.

  Referring to FIG. 2, the light source drive circuits 17 and 18 are disposed in a space (gap) between the optical unit 100 and the housing 50 housed in the housing portion R11.

  The light source drive circuit 17 is provided on the upper portion of the housing portion R11 (optical unit 100). The light source drive circuit 17 is a circuit for driving the light sources 30R and 30B. Specifically, the light source drive circuit 17 controls the turning on and off of the light sources 30R and 30B and the light emission amounts of the light sources 30R and 30B according to the control of the control circuit 16.

  The light source drive circuit 18 is provided below the housing portion R11 (optical unit 100). The light source drive circuit 18 is a circuit for driving the light source group 31 (light source 30L). Specifically, the light source drive circuit 18 controls the turning on and off of the light source 30L and the light emission amount of the light source 30L according to the control of the control circuit 16.

  The audio circuit 20 converts an audio signal input from the outside into a signal for outputting audio from the speaker 19.

  As shown in FIG. 2, the power supply unit 21 is provided in the lower part of the housing portion R12. The power supply unit 21 supplies power for operating the projector 1000. Specifically, the power supply unit 21 receives power from the outside of the projector 1000, converts it into a voltage necessary for driving the circuit of the projector 1000, and supplies it.

  Each of the coolers 12, 13, 39R, 39B is a heat sink having a function of cooling heat. The cooler 12 is provided in the vicinity of the cooling fans 42a and 42b. The cooler 12 is provided in the vicinity of the light source 30G and the light source group 31 in order to cool the heat generated by the light source 30G and the light source group 31.

  FIG. 4 is a perspective view of the cooler 12. FIG. 5 is a plan view of the cooler 12. Referring to FIGS. 4 and 5, the cooler 12 includes cooling fin portions 12 a and 12 b and a plate portion 12 c.

  The cooling fin portion 12 a is composed of a plurality of heat radiation fins 112. The shape of each radiating fin 112 is, for example, a plate shape. Specifically, the cooling fin portion 12a is configured by arranging a plurality of heat radiation fins 112 so that wind can pass in the X-axis direction and the Z-axis direction. The cooling fin portion 12b also has the same configuration as the cooling fin portion 12a.

  The shape of the plate portion 12c is a plate shape. The plate part 12c has a cooling surface 12ca. The cooling surface 12ca is thermally connected to the light source group 31 (light source 30L) in order to cool the light source group 31.

  The cooler 13 is provided in the vicinity of the light valve 36 in order to cool the heat generated by the light valve 36. Although details will be described later, the coolers 12 and 13 are cooled by cooling fans 42a and 42b. The cooler 39R is provided in the vicinity of the light source 30R and the opening H11a in order to cool the heat generated by the light source 30R. The cooler 39B is provided in the vicinity of the light source 30B and the opening H11a in order to cool the heat generated by the light source 30B.

  The cooling fans 41 and 42 have a function of generating wind for cooling a heat generating component (for example, a light source). The cooling fan 41 is configured to send the outside air 94 of the opening H11a as cooling air 96 into the housing portion R11. That is, the cooling fan 41 is provided at a position for using the outside air 94 of the opening H11a.

  Specifically, the cooling fan 41 is provided between the opening H11a and the coolers 39R and 39B. That is, the cooling fan 41 is provided in the vicinity of the opening H11a. The cooling fan 41 is driven so as to send the outside air 94 of the opening H11a into the casing portion R11 as the cooling air 96. The outside air 94 is composed of outside air 94a and 94b. The outside air 94a and 94b sent into the housing portion R11 by the cooling fan 41 corresponds to the coolers 39B and 39R, respectively. Thereby, the coolers 39B and 39R are cooled.

  Here, the opening H11a and the opening H12 are configured to face each other so that the cooling air 96 generated using the opening H11a is directed to the opening H12. With this configuration, the cooling air 96 flows from the cooling fan 41 toward the opening H12.

  The opening H11a and the opening H12 may not be opposed to each other. In the configuration, for example, the opening H11a and the opening H12 may be provided so that a surface parallel to the opening H11a and a surface parallel to the opening H12 are orthogonal to each other.

  The coolers 39R and 39B are cooled by the cooling air 96 generated by driving the cooling fan 41. Thereby, the cooler 39R cools the heat generated by the light source 30R. The cooler 39B cools the heat generated by the light source 30B.

  The cooling fans 42a and 42b are disposed adjacent to each other along the Y-axis direction. Further, as described above, the cooling fans 42a and 42b function as a partition member that forms the housing portions R11 and R12.

  The cooling fan 42a is driven so as to send the outside air 90 of the opening H11b as cooling air 91 into the housing portion R12. The cooling air 91 in the casing portion R12 flows in the −Y direction from the opening H11b along the partition member 26a. That is, the cooling air 91 passes through the power supply unit 21. Moreover, the partition member 26a has a function of controlling the flow of the cooling air 91 in the housing portion R12. Specifically, the partition member 26a has a function of controlling the air flow so that the cooling air 91 is taken into the housing portion R12 only from the opening H11b. Thereby, the power supply unit 21 is cooled.

  Further, the cooling fan 42a is driven so as to send the cooling air 93, which is a part of the cooling air 91 in the housing portion R12, into the housing portion R11. Note that the cooling air 93 (cooling air 91) is sent to the housing portion R11 only from the portion where the cooling fan 42a is disposed by the partition members 26a and 26b. That is, the partition members 26a and 26b have a function of guiding the cooling air 93 in the housing part R12 into the housing part R11.

  The cooling air 93 sent into the housing part R <b> 11 is a part of the cooling air 95. The cooling air 93 is composed of cooling air 93a and 93b. The cooling air 93a, 93b becomes a part of the cooling air 95 by driving the cooling fan 42a, and a part of the cooling air 95 corresponds to the light source 30G and the cooler 12. Thereby, the light source 30G and the cooler 12 are cooled. The cooling air 95 merges with the cooling air 96 in the housing portion R11.

  The cooling fan 42b is driven so as to send the outside air 90 of the opening H11b into the housing portion R12 as the cooling air 91, similarly to the cooling fan 42a. Further, the cooling fan 42b is driven so as to send the cooling air 92, which is a part of the cooling air 91 in the housing portion R12, into the housing portion R11. Note that the cooling air 92 (cooling air 91) is sent to the housing portion R11 only from the portion where the cooling fan 42b is disposed by the partition members 26a and 26b. That is, the partition members 26a and 26b have a function of guiding the cooling air 92 in the housing part R12 into the housing part R11.

  The cooling air 92 sent into the housing part R <b> 11 is a part of the cooling air 95. The cooling air 92 is composed of cooling air 92a and 92b. The cooling air 92 a and 92 b become part of the cooling air 95 by driving the cooling fan 42 b, and a part of the cooling air 95 corresponds to the coolers 12 and 13. Thereby, the coolers 12 and 13 are cooled.

  In addition, by disposing the cooling fan 42a at an appropriate position in the Y-axis direction, the light source 30G can be cooled by the cooling air having a high flow velocity generated at the outer edge of the cooling fan 42a. As a result, the light source 30G can be efficiently cooled.

  In addition, by disposing the cooling fan 42b at an appropriate position in the Y-axis direction, the cooler 13 can be cooled by cooling air having a high flow velocity generated at the outer edge of the cooling fan 42b. As a result, the cooler 13 can be efficiently cooled.

  As described above, each of the cooling fans 42a and 42b sends the outside air 90 of the opening H11b into the housing portion R12 as the cooling air 91, and the cooling air that is part of the cooling air 91 in the housing portion R12. The cooling air 92 and 93 in the housing portion R12 is driven to be sent into the housing portion R11 so that the cooling air 92 and 93 merge with the cooling air 96.

  Hereinafter, the air that the cooling air 95 and the cooling air 96 merge together is also referred to as a combined cooling air 97. The combined cooling air 97 flows toward the exhaust opening H12 and is discharged from the opening H12. That is, each of the cooling fans 41, 42a, and 42b is driven so that the combined cooling air 97 is discharged from the opening H12.

  Specifically, the combined cooling air 97 is formed by the optical unit 100, the portion of the housing 50 that constitutes the housing portion R11, the cooling fans 41, 42a, and 42b, and the partition members 26a and 26b. The air is discharged from the opening H12 to the outside of the housing 50 through the space.

  In the following, the cooling air at the upper part of the housing portion R12 included in the cooling air 92 and 93 is also referred to as cooling air 9u. In the following, the cooling air in the lower part of the housing portion R12 included in the cooling air 92 and 93 is also referred to as cooling air 9d. The cooling air 9u, 9d is the cooling air shown in FIG.

  The cooling air 95 includes cooling airs 95u and 95d. As shown in FIG. 2, the cooling air 95u is air that flows through the upper portion of the housing portion R11. The cooling air 9u becomes the cooling air 95u after passing through the cooling fin portion 12a by driving the cooling fan 42 (42a, 42b). The cooling air 9d becomes cooling air 95d after passing through the cooling fin portion 12b by driving the cooling fan 42.

  The cooler 12 is configured as described above with reference to FIGS. 4 and 5. For this reason, by driving the cooling fans 42a and 42b arranged in the vicinity of the cooler 12, cooling air having a high flow velocity generated at the outer edge of each of the cooling fans 42a and 42b is provided at the upper and lower portions of the cooler 12, respectively. Can be sent to the cooling fin portions 12a and 12b. As a result, the light source group 31 having a large temperature rise can be efficiently cooled.

  The configuration of the cooler 39B in the vicinity of the light source 30B and the configuration of the cooler 39R in the vicinity of the light source 30R may be the same as the configuration of the cooler 12. Thereby, more efficient cooling can be performed. Furthermore, the configuration of the cooler 13 in the vicinity of the light valve 36 may be the same as the configuration of the cooler 12.

  Further, in the present embodiment, as described above, the housing portions R11 and R12 are provided in the housing 50. Therefore, the power supply unit 21 can be efficiently cooled by driving the cooling fans 42a and 42b without providing a cooling fan dedicated to the power supply unit 21 provided in the housing portion R12.

  Furthermore, high-temperature components such as the control circuit 16 and the audio circuit 20 disposed in the upper part of the casing 50 can be cooled by the cooling air 9u flowing in the upper part of the casing part R12. In other words, the audio circuit 20 which is a heat generating component is provided in a position where the cooling air (for example, the cooling air 9u and the cooling air 91) is applied in the housing portion R12.

  Note that the above-described cooling air 95u generated by driving the cooling fan 42 in the housing portion R11 corresponds to the light source drive circuit 17. In the housing portion R11, the cooling air 95d generated by driving the cooling fan 42 corresponds to the light source drive circuit 18. In the housing portion R11, the light source drive circuits 17 and 18 also receive cooling air 96. That is, in the light source drive circuits 17 and 18 that are heat generating components, at least one of the cooling air 96 and the cooling air 95 that is the cooling air 92 and 93 sent into the housing portion R11 is generated in the housing portion R11. It is provided at the corresponding position.

  Thereby, the light source drive circuits 17 and 18 can be efficiently cooled. In addition to the light source drive circuits 17 and 18, the cooling air 95 u and 95 d can also cool the optical components and other structures included in the optical unit 100 that require cooling.

  As described above, according to the present embodiment, the cooling fan 42 sends the outside air 90 of the opening H11b into the housing part R12 as the cooling air 91, and the cooling air 91 in the housing part R12. The cooling air 92 and 93 in the housing portion R12 are driven to be sent into the housing portion R11 so that the cooling air 92 and 93 that are a part of the cooling air merge with the cooling air 96.

  As a result, the cooling air 96 and the cooling air 95 which is the cooling air 92 and 93 sent into the housing portion R11 merge to use the combined cooling air 97 having an increased air volume in the housing portion R11. can do. As a result, the optical unit 100 in the housing portion R11 can be efficiently cooled. That is, by using the combined cooling air in which a plurality of cooling airs are combined, efficient cooling can be performed with a simple structure.

  Therefore, it is possible to reduce the number of cooling fans, the number of partition members, the number of intake and exhaust openings, and the like. As a result, the degree of freedom of component placement in the housing 50 can be improved.

  Further, since the airflow of the combined cooling air obtained by combining the cooling air 96 and the cooling air 92 and 93 sent into the housing portion R11 is larger than the airflow of the cooling air 96 or the cooling air 92 and 93, heat generation is generated. A large light source, a heat generating component of the optical unit 100, etc. can be efficiently cooled.

  Moreover, according to this Embodiment, since the cooling fans 42a and 42b are arrange | positioned in the housing | casing 50, the noise which generate | occur | produces for cooling can be made small.

  Further, according to the present embodiment, as described above, the power supply unit 21 is efficiently cooled by driving the cooling fans 42a and 42b without providing a dedicated cooling fan for the power supply unit 21 provided in the housing portion R12. it can.

In the present embodiment, as described above, the light source drive circuits 17 and 18 are disposed in the space (gap) between the optical unit 100 and the housing 50 housed in the housing portion R11.
Thereby, the projector 1000 can be made compact.

  As described above, it is possible to improve the light emission efficiency and obtain the projector 1000 that is bright and quiet and compact.

  When cooling efficiency is taken into consideration and the entire projector 1000 is compactly combined into a rectangular space, it is desirable that the main elements that require individual cooling be arranged in the vicinity of the opening for intake. That is, it is desirable that the main elements that require individual cooling be arranged along the vicinity of the outer edge of the housing 50.

  In the present embodiment, the light source group 31 that requires a relatively long dimension is disposed next to the light bulb 36 that is disposed along the long side direction of the housing 50. Further, next to the light source group 31, a light source 30 </ b> G having a relatively low need for cooling among red light, green light, and blue light is disposed. Further, a light source 30B that emits blue light and a light source 30R that emits red light are disposed in the vicinity of the short side of the housing 50.

  Thereby, the configuration of the light source 30B or the light source 30R is configured such that a plurality of light sources are arranged like the light source group 31, so that even when strong cooling is required, the projector 1000 as a whole has a good balance of cooling design. This enables a compact layout design.

  In the present embodiment, a cooling fan that generates cooling air that requires a large amount of air is disposed inside the housing 50. For this reason, the projector 1000 can be made silent.

  The cooler (for example, cooler 12) used in projector 1000 is not limited to a heat sink. The cooler may be, for example, liquid cooling means such as a heat pipe, other refrigerant air cooling means, or the like. Various types of fans such as an axial fan and a sirocco fan may be applied as the cooling fan.

  In addition, the arrangement positions of the power supply unit, the control circuit, and the light source drive circuit, and the functions and names of the circuits are not limited to the contents described in this embodiment.

  The projector 1000 configured as described above can achieve both improved cooling efficiency and a compact layout. Therefore, the projector 1000 can project a bright image by promoting improvement in light emission efficiency.

  In the related art A described above, a cooling fan is required for each light source device and each main heat source. Therefore, it is necessary to provide a wide opening for cooling air intake and exhaust for the housing.

  Further, in Related Art A, since the cooling fan is disposed in the vicinity of the side surface of the housing, there is a problem that noise from the cooling fan is large. In Related Art A, many guide members (partition members) for controlling the flow of cooling air are provided in a wide range. For this reason, the related art A has a problem in that there is a great restriction on the structural component arrangement and the degree of freedom of layout in the housing is low.

  Therefore, projector 1000 according to the present embodiment is configured as described above, and can solve the above-described problem in related art A.

  In the present invention, the embodiments can be appropriately modified and omitted within the scope of the invention.

  For example, the housing portions R11 and R12 are formed in the housing 50, but the present invention is not limited to this. Within the housing 50, three or more housing portions may be formed. The casing 50 in this configuration includes, for example, a plurality of casing parts including casing parts R11 and R12.

  In this embodiment, a configuration in which one cooling fan is arranged and a configuration in which two cooling fans are arranged are shown, but the present invention is not limited to this configuration. For example, the number of cooling fans may be selected based on the size of the cooling fan and the size of the cooling fins, and is not limited to the number of cooling fans in this embodiment. For example, the number of cooling fans 42 functioning as a partition member is not limited to 2, and may be 1 or 3 or more. For example, the housing 50 may include three or more cooling fans. The housing 50 in this configuration includes, for example, a plurality of cooling fans including the cooling fans 41 and 42.

  In the present embodiment, the casing 50 is provided with the intake openings H11a and H11b. However, the present invention is not limited to this. For example, the housing 50 may have a configuration in which three or more openings for intake are provided. The housing 50 in this configuration includes, for example, a plurality of intake openings including openings H11a and H11b.

  In the present embodiment, the casing 50 is provided with the exhaust opening H12. However, the present invention is not limited to this. For example, the housing 50 may be configured to be provided with two or more openings for exhaust. The housing 50 in this configuration includes, for example, one or more exhaust openings including the opening H12.

  In the present embodiment, the casing 50 is provided with the partition members 26a and 26b. However, the present invention is not limited to this. For example, the housing 50 may be configured to be provided with one or three or more partition members having a function of controlling the flow of cooling air. The housing 50 in this configuration includes, for example, a partition material that has a function of controlling the flow of cooling air in the housing 50.

  Moreover, the housing | casing 50 which concerns on this Embodiment is good also as a structure (henceforth the deformation | transformation structure A) further including the partition material 28, as shown in FIG.

  In the modified configuration A, the partition member 28 has a function of controlling the flow of cooling air. Specifically, the partition member 28 is provided so as to divide the cooling air 91 in the housing portion R12 into two. Moreover, the partition material 28 has the opening part H13. The opening H13 is provided in the partition member 28 so as to distribute sufficient cooling air to components having a large heat generation amount in the power supply unit 21.

  With the above configuration, the cooling air 91 flowing in the power supply unit 21 is divided into the cooling air 98 and the cooling air 99 by the partition member 28.

  In the modified configuration A, the cooling fan 42a drives the cooling air 93, which is a part of the cooling air 99 in the housing part R12, to be sent into the housing part R11. The cooling fan 42b is driven so that the cooling air 98 in the housing portion R12 passes through the opening H13 and the cooling air 92 that is a part of the cooling air 98 is sent into the housing portion R11.

  Accordingly, in the modified configuration A, the cooling air can be optimally fed into the entire power supply unit 21 without depending on the positions of the cooling fans 42a and 42b in the Y-axis direction. Therefore, in the modified configuration A, the power supply unit 21 can be cooled more efficiently than the configuration in which the partition member 28 is not provided.

  In the modified configuration A, two or more partition members 28 may be provided so as to divide the cooling air 91 into three or more. That is, the partition member 28 may be provided so as to divide the cooling air 91 in the housing portion R12 into at least two. Further, the number of openings provided in the partition member 28 is not limited to 1, and may be 2 or more.

  21 Power supply unit, 26a, 26b, 28 Partition material, 30, 30B, 30G, 30L, 30R Light source, 41, 42, 42a, 42b Cooling fan, 50 housing, 100 optical unit, 1000 projector, H11a, H11b, H12, H13 opening.

Claims (8)

A projector,
An optical unit that includes a light source that emits light, and that uses the light emitted from the light source to emit image light that constitutes an image;
A power supply unit for supplying power for operating the projector;
First and second cooling fans for cooling the light source;
A housing,
In the casing, using at least the second cooling fan as a boundary, a first casing portion that is an area for storing the optical unit and a second casing that is an area for storing the power supply unit. A body part is formed,
A portion of the housing forming the first housing portion is provided with a first opening for intake and a second opening for exhaust,
Each of the first opening and the second opening is provided on a different side surface of the housing,
A part of the housing forming the second housing portion is provided with a third opening for intake air,
The third opening is provided on a side surface of the housing different from the side surface on which the second opening is provided.
The first cooling fan is provided at a position for using the outside air of the first opening, and the first housing uses the outside air of the first opening as a first cooling air. Drive to send in the part,
The second cooling fan sends outside air from the third opening as second cooling air into the second housing portion, and the second cooling fan in the second housing portion. Driving the second cooling air into the first housing portion so that the cooling air merges with the first cooling air;
The combined cooling air in which the first cooling air and the second cooling air are merged is discharged from the second opening. The projector further includes:
Used as a boundary for forming the first housing portion and the second housing portion, and has a function of controlling the flow of the second cooling air in the second housing portion. The projector according to claim 1, further comprising a partition member. The projector according to claim 2, wherein the partition member further has a function of guiding the second cooling air in the second housing part into the first housing part. The projector further includes:
The projector according to claim 1, further comprising a heat generating component provided at a position where the second cooling air hits in the second casing portion. The projector further includes:
In the first housing part, the first cooling air is provided at a position corresponding to at least one of the first cooling air and the third cooling air that is the second cooling air sent into the first housing part. The projector according to claim 1, further comprising another heat generating component. The first opening and the second opening face each other so that the first cooling air generated using the first opening is directed to the second opening. The projector according to any one of 1 to 5. The housing is
A plurality of housing parts including the first and second housing parts;
A plurality of cooling fans including the first and second cooling fans;
A plurality of intake openings including the first and third openings;
One or more exhaust openings including the second opening;
A partition member having a function of controlling the flow of cooling air. The projector according to any one of claims 1 to 6. The housing is
A plurality of housing parts including the first and second housing parts;
A plurality of cooling fans including the first and second cooling fans;
A plurality of intake openings including the first and third openings;
One or more exhaust openings including the second opening;
A partition material having a function of controlling the flow of cooling air;
The second cooling air in the second housing part is provided so as to be divided into at least two parts, has at least one opening, and has a function of controlling the flow of the cooling air. The projector according to claim 1, further comprising another partition member.

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