JP2011170362A - Light source device and projector - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an easy-to-produce light source device that emits color light beams with high color purity, and a projector. <P>SOLUTION: The projector includes: the light source device 63; a display element; and a projector control means and the like. The light source device 63 includes: a fluorescent wheel 71 in which a transmissive portion transmitting excitation light and a reflective portion are arranged in the circumferential direction while a plurality of phosphor layers emitting different wavelength band light rays are formed in the circumferential direction in the reflective portion; a driving device turning the fluorescent wheel 71; a light source 72 irradiating the phosphor layers of the fluorescent wheel 71 with the excitation light; a dichroic mirror disposed between the light source 72 and the fluorescent wheel 71 to transmit the excitation light and reflect fluorescent light from phosphor; and a plurality of reflection mirrors and dichroic mirrors condensing the excitation light transmitted through the transmissive portion of the fluorescent wheel and the fluorescent light reflected by the dichroic mirror to the same optical path, to emit the condensed light in the same direction. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention relates to a light source device and a projector including the light source device.

  2. Description of the Related Art Today, data projectors are widely used as image projection apparatuses that project a screen of a personal computer, a video image, an image based on image data stored in a memory card or the like onto a screen. This projector focuses light emitted from a light source on a micromirror display element called DMD (digital micromirror device) or a liquid crystal plate, and displays a color image on a screen.

  Conventionally, projectors using a high-intensity discharge lamp as the light source have been the mainstream of such projectors. However, in recent years, developments and proposals using light-emitting diodes, laser diodes, organic EL, phosphor light emission, etc. as light sources have been made. A lot has been done. For example, in Japanese Patent Application Laid-Open No. 2004-341105 (Patent Document 1), a disk-shaped transparent substrate provided with a phosphor layer that receives ultraviolet light as excitation light emitted from a solid light source and converts it into visible light. A light source device having a fluorescent wheel and a solid-state light source has been proposed.

JP 2004-341105 A

  The proposal of Patent Document 1 proposes that a visible light reflecting film that transmits ultraviolet light and reflects visible light is formed on a wheel surface of a fluorescent wheel on which ultraviolet light is incident, thereby allowing incident ultraviolet light to be emitted on the wheel surface on the emission side. Irradiate the phosphor layer disposed on the surface to generate fluorescent light and emit it to the emission side, and also reflect the fluorescent light emitted from the phosphor layer to the incident surface side to the emission side by the visible light reflection film, The amount of fluorescent light emitted from the fluorescent wheel can be increased.

  For the purpose of preventing damage to optical components irradiated with excitation light, a blue laser diode that emits blue wavelength band light as excitation light may be used as the solid light source of the light source device. In this case, the fluorescent wheel is configured to use the blue band light as it is through the fluorescent wheel by forming a diffusion layer on the wheel surface.

  And, since it is necessary to form a reflective film that transmits blue band light and reflects other visible light on the incident surface of the fluorescent wheel used in such a light source device, it takes time for manufacturing and increases the cost. It was a factor.

  Therefore, as a light source device, the wheel base material is formed of a metal plate or the like, and the blue band light as excitation light and the fluorescent light of red or green wavelength band emitted from the phosphor are reflected by the reflecting surface of the metal plate. Thus, a configuration in which light in the red, green, and blue wavelength bands is sequentially emitted can be considered.

  However, in such a case, if the optical paths of light in the red, green, and blue wavelength bands are made the same, the red or green wavelength band that emits light when the red or green phosphor layer is irradiated with blue excitation light. There is a problem that the color purity is deteriorated because the light source light in the blue wavelength band reflected by the fluorescent light is mixed.

  In addition, since the entrance surface and the exit surface of the fluorescent light wheel for blue band light are the same, the optical layout and the optical components have a special configuration in order to separate the light path from which the blue light source light enters and the light path from which it exits. There is also a problem that it is necessary.

  The present invention has been made in view of such problems of the prior art, and the fluorescent wheel itself is used as a reflector without providing a special reflective layer that reflects only light in a specific wavelength band on the fluorescent wheel surface. In addition, by providing a transmission part that transmits the light source light to a part of the reflector, it is possible to separate the light emission path of the light source light emitted from the fluorescent wheel and each color fluorescent light, and the structure is simple. An object of the present invention is to provide a light source device that can be easily manufactured and can emit light of each color with high color purity, and a projector including the light source device.

  The light source device of the present invention has a plurality of segment regions on a base material, at least one of the plurality of segment regions being a reflecting portion, and a fluorescent light that emits light of a predetermined wavelength band upon receiving excitation light at the reflecting portion A disc-shaped light-emitting plate in which a body layer is formed and at least one of the plurality of segment regions is a transmission part that transmits light, a light source that irradiates a phosphor layer of the light-emitting plate with excitation light, A dichroic mirror disposed between a light source and the light emitting plate to transmit excitation light and reflect fluorescent light from the phosphor, excitation light transmitted through a transmission part of the light emitting plate, and fluorescence reflected from the dichroic mirror A plurality of reflecting mirrors and dichroic mirrors that collect light on the same optical path and irradiate in the same direction, and a driving device that rotates the light emitting plate in the circumferential direction, and Segment The region is arranged in a circumferential direction, the light source for irradiating the light emitting plate with the excitation light is a blue-band laser emitter, and there are a plurality of phosphors forming the phosphor layer, and at least red-band light And a phosphor emitting green band light.

  Furthermore, in the light source device of the present invention, a diffusion layer for diffusing the excitation light is formed in the transmission part of the light emitting plate.

  Further, the light source device of the present invention is combined with a mirror such as the dichroic mirror in the path between the light source and the light emitting plate and the path of the fluorescent light from the light emitting plate or the light source light transmitted through the light emitting plate. And a condensing optical system formed by the lens and a plurality of lenses arranged with a plurality of lenses for condensing light.

  And the said condensing optical system is arrange | positioned between the said light-emitting plate and the said light source, permeate | transmits light source light, without changing the optical axis of the light source light inject | emitted from the said light source, and the said fluorescent substance A first optical axis conversion mirror that is a dichroic mirror that converts the direction of the optical axis of the fluorescent light emitted from the layer, and a dichroic that converts the direction of the optical axis of the light source light that passes through the diffusion layer of the light-emitting plate A second optical axis conversion mirror that is a mirror or a normal reflection mirror, or a dichroic mirror that transmits the light source light without converting the optical axis of the light source light, and the fluorescent light converted by the first optical axis conversion mirror A third and a fourth optical axis conversion mirror for condensing the fluorescent light and the light source light on the same optical path by further converting the optical axis converted by the optical axis or the second optical axis conversion mirror; .

  The first optical axis conversion mirror is disposed between the light emitting plate and the light source on the optical axis of the light source, and the second optical axis conversion mirror is disposed on the optical axis of the light source. The third optical axis conversion mirror is disposed on a position opposite to the light source with respect to the light emitting plate, and the third optical axis conversion mirror is disposed on an optical axis of fluorescent light converted by the first optical axis conversion mirror, The optical axis conversion mirror is disposed to face the second optical axis conversion mirror and the third optical axis conversion mirror.

  The second to fourth optical axis conversion mirrors convert either one of the two reflection mirrors that convert the optical axis of the light source light or fluorescent light and the optical axis of the light source light or fluorescent light. And one dichroic mirror for converting the other.

  The second optical axis conversion mirror is a reflection mirror that converts the optical axis of the light source light transmitted through the diffusion layer of the light emitting plate by 90 degrees, and the third optical axis conversion mirror is the first optical axis conversion mirror. The fourth optical axis conversion mirror is a reflection mirror that converts the optical axis of the fluorescent light converted by the mirror by 90 degrees without changing the optical axis of the light source light converted by the second optical axis conversion mirror. The dichroic mirror converts the optical axis of the fluorescent light converted by the third optical axis conversion mirror by 90 degrees.

  The second optical axis conversion mirror is a reflection mirror that converts the optical axis of the light source light transmitted through the diffusion layer of the light emitting plate by 90 degrees, and the fourth optical axis conversion mirror is the second optical axis conversion mirror. It is a reflection mirror that converts the optical axis of the light source light converted by the mirror by 90 degrees, and the third optical axis conversion mirror does not change the optical axis of the fluorescent light converted by the first optical axis conversion mirror. In addition, the optical axis of the light source light converted by the fourth optical axis conversion mirror may be a dichroic mirror that converts the optical axis by 90 degrees.

  The second to fourth optical axis conversion mirrors may be three reflecting mirrors that convert the optical axis of the light source light.

  The projector of the present invention includes any one of the light source devices described above, a display element, a light source side optical system that guides light from the light source device to the display element, and an image emitted from the display element. A projection-side optical system that projects onto a screen and projector control means for controlling the light source device and the display element are provided.

  According to the present invention, the fluorescent wheel itself is used as a reflecting plate without providing a special reflecting layer that reflects only light in a specific wavelength band on the fluorescent wheel surface, and the transmission unit transmits light source light to a part of the reflecting plate. It is possible to separate the emission light path of the light source light emitted from the fluorescent wheel and the fluorescent light of each color, and the simple configuration is easy to manufacture, and each color light with high color purity can be obtained. A light source device capable of emitting light and a projector including the light source device can be provided.

It is an external appearance perspective view which shows the projector provided with the light source device which concerns on the Example of this invention. It is a figure which shows the functional circuit block of the projector provided with the light source device which concerns on the Example of this invention. 1 is a schematic plan view showing an internal structure of a projector including a light source device according to an embodiment of the present invention. It is the front schematic diagram of the fluorescent wheel which concerns on the Example of this invention, and the plane schematic diagram which shows a partial cross section. It is a plane schematic diagram of the light source device which concerns on the Example of this invention. It is a schematic diagram which shows the variation of the optical path of the light source light and fluorescence light in the light source device which concerns on the Example of this invention. It is a table | surface which shows the example of a combination of the optical axis conversion mirror in the light source device which concerns on the Example of this invention.

  Hereinafter, modes for carrying out the present invention will be described. The projector 10 includes a light source device 63, a display element 51, a cooling fan, a light source side optical system 62 that guides light from the light source device 63 to the display element 51, and an image emitted from the display element 51 on a screen. A projection-side optical system 90 for projecting and projector control means for controlling the light source device 63 and the display element 51 are provided.

  The light source device 63 has a fluorescent wheel 71 that is a light emitting plate. The fluorescent wheel 71 has three fan-shaped segment regions adjacent to each other on a substrate whose rotation can be controlled. Two of the three segment regions are reflective portions, and a phosphor layer 131G that emits green wavelength band light upon receiving excitation light and a phosphor layer 131R that emits red wavelength band light are formed on the reflective portion. The The remaining one segment area is a transmission part, which transmits light.

  Specifically, a transmission part and a reflection part that transmit excitation light are arranged in the circumferential direction, and a plurality of phosphor layers 131 that emit light in different wavelength bands are formed in the circumferential direction in the reflection part. The light source device 63 further includes a wheel motor 73 that is a driving device that rotates the fluorescent wheel 71, a light source 72 that irradiates the phosphor layer 131 of the fluorescent wheel 71 with excitation light, and the light source 72 and the fluorescent wheel 71 between The first optical axis conversion mirror 1, which is a dichroic mirror that is arranged to transmit excitation light and reflect fluorescent light from the phosphor, and the excitation light and first optical axis conversion mirror that have passed through the transmission part of the fluorescent wheel 71 A plurality of reflecting mirrors and dichroic mirrors that allow the fluorescent light reflected at 1 to be condensed on the same optical path and irradiated in the same direction;

  The light source 72 that irradiates the excitation light to the fluorescent wheel 71 is a laser emitter that emits a blue band laser, and there are a plurality of phosphors that form the phosphor layer 131, and emits red band light as described above. A phosphor and a phosphor emitting green band light.

  Furthermore, a diffusion layer 141 that diffuses excitation light is formed on the diffusion plate 140 that is a transmission part of the fluorescent wheel 71.

  In addition, the light source device 63 transmits light between the light source 72 and the fluorescent wheel 71 together with a mirror such as a dichroic mirror in the path of the fluorescent light emitted from the fluorescent wheel 71 and the light source light transmitted through the fluorescent wheel 71. A condensing optical system formed by a lens and a mirror on which a plurality of lenses for condensing light are arranged.

  The condensing optical system is disposed between the fluorescent wheel 71 and the light source 72, transmits the light source light without changing the optical axis of the light source light emitted from the light source 72, and is a phosphor layer. The first optical axis conversion mirror 1, which is a dichroic mirror that converts the direction of the optical axis of the fluorescent light emitted from 131, and the normal direction of the optical axis of the light source light that passes through the diffusion layer 141 of the fluorescent wheel 71 A second optical axis conversion mirror 2 that is a reflection mirror, a third optical axis conversion mirror 3 that further converts the optical axis of the fluorescent light converted by the first optical axis conversion mirror 1, and a second optical axis conversion mirror 2. By transmitting the light source light without converting the optical axis of the converted light source light, and further converting the fluorescent light converted by the third optical axis conversion mirror 3, the fluorescent light and the light source light are on the same optical path. And a fourth optical axis conversion mirror 4 for condensing the light.

  Specifically, the first optical axis conversion mirror 1 is disposed between the fluorescent wheel 71 and the light source 72 on the optical axis of the light source 72, and the second optical axis conversion mirror 2 is on the optical axis of the light source 72. The third optical axis conversion mirror 3 is disposed on the optical axis of the fluorescent light converted by the first optical axis conversion mirror 1, and is disposed at a position opposite to the light source 72 with respect to the fluorescent wheel 71. The fourth optical axis conversion mirror 4 is arranged to face the second optical axis conversion mirror 2 and the third optical axis conversion mirror 3.

  The second to fourth optical axis conversion mirrors 2 to 4 transmit the light source light without changing the optical axis of the light source light and the two reflection mirrors for converting the optical axis of the light source light or the fluorescent light, and the fluorescence. And a single dichroic mirror for converting the optical axis of light.

  The second optical axis conversion mirror 2 is a reflection mirror that converts the optical axis of the light source light transmitted through the diffusion layer 141 of the fluorescent wheel 71 by 90 degrees, and the third optical axis conversion mirror 3 is the first optical axis conversion The fourth optical axis conversion mirror 4 changes the optical axis of the light source light converted by the second optical axis conversion mirror 2 and is a reflection mirror that converts the optical axis of the fluorescent light converted by the mirror 1 by 90 degrees. And a dichroic mirror that converts the optical axis of the fluorescent light converted by the third optical axis conversion mirror 3 by 90 degrees.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. FIG. 1 is an external perspective view of the projector 10. In this embodiment, the left and right indicate the left and right directions with respect to the projection direction, and the front and rear indicate the front and rear directions with respect to the traveling direction of the light bundle emitted from the projector 10. As shown in FIG. 1, the projector 10 has a substantially rectangular parallelepiped shape, and has a lens cover 19 that covers the projection port on the side of the front panel 12 that is a side plate in front of the main body case. Is provided with a plurality of exhaust holes 17. Further, although not shown, an Ir receiver for receiving a control signal from the remote controller is provided.

  In addition, a key / indicator section 37 is provided on the top panel 11 which is a main body case. The key / indicator section 37 includes a power switch key, a power indicator for notifying power on / off, and projection on / off. There are arranged keys and indicators such as a projection switch key for switching, an overheat indicator for notifying when a light source device, a display element, a control circuit or the like is overheated.

  In addition, on the back side of the main body case, there are provided various terminals 20 such as an input / output connector section and a power adapter plug for providing a USB terminal, a D-SUB terminal for inputting image signals, an S terminal, an RCA terminal, etc. Yes. A plurality of intake holes 18 are formed in the vicinity of the lower portion of the right side panel 14 which is a side plate of the main body case (not shown) and the left side panel 15 which is the side plate shown in FIG.

  Next, projector control means of the projector 10 will be described with reference to the block diagram of FIG. The projector control means includes a control unit 38, an input / output interface 22, an image conversion unit 23, a display encoder 24, a display drive unit 26, and the like. Image signals of various standards input from the input / output connector unit 21 are input / output. The image conversion unit 23 converts the image signal into a predetermined format suitable for display via the interface 22 and the system bus (SB), and outputs the image signal to the display encoder 24.

  The display encoder 24 develops and stores the input image signal in the video RAM 25, generates a video signal from the stored contents of the video RAM 25, and outputs the video signal to the display drive unit 26.

  The display drive unit 26 drives the display element 51, which is a spatial light modulation element (SOM), at an appropriate frame rate corresponding to the image signal output from the display encoder 24. When the light source 72 of the light source device 63 is turned on, the light beam emitted from the light source device 63 is incident on the display element 51 through the light source side optical system, and the display element 51 controlled by the display driving unit 26 By forming an optical image with reflected light, an image can be projected and displayed on a screen (not shown) via a projection lens group serving as a projection-side optical system. The movable lens group 97 of the projection side optical system is driven by the lens motor 45 for zoom adjustment and focus adjustment.

  In addition, the image compression / decompression unit 31 performs a recording process in which the luminance signal and the color difference signal of the image signal are data-compressed by a process such as ADCT and Huffman coding, and are sequentially written in a memory card 32 that is a detachable recording medium. Further, the image compression / decompression unit 31 reads out the image data recorded on the memory card 32 in the reproduction mode, decompresses individual image data constituting a series of moving images in units of one frame, and converts the image data into the image conversion unit 23. Is output to the display encoder 24 and the processing for enabling the display of a moving image or the like based on the image data stored in the memory card 32 is performed.

  The control unit 38 controls operation of each circuit in the projector 10, and includes a ROM that stores operation programs such as a CPU and various settings fixedly, and a RAM that is used as a work memory. .

  An operation signal of a key / indicator unit 37 composed of a main key and an indicator provided on the upper panel 11 of the main body case is directly sent to the control unit 38, and a key operation signal from the remote controller is sent to the Ir receiving unit 35. , And the code signal demodulated by the Ir processor 36 is output to the controller 38.

  Note that an audio processing unit 47 is connected to the control unit 38 via a system bus (SB). The sound processing unit 47 includes a sound source circuit such as a PCM sound source, converts the sound data into analog in the projection mode and the playback mode, and drives the speaker 48 to emit loud sounds.

  The control unit 38 controls the power control circuit 41. The power control circuit 41 turns on the light source 72 of the light source device 63 when the power switch key is operated. Further, the control unit 38 causes the cooling fan drive control circuit 43 to perform temperature detection using a plurality of temperature sensors provided in the light source device 63 and the like, and controls the rotation speed of the cooling fan based on the temperature detection result. Further, the control unit 38 causes the cooling fan drive control circuit 43 to keep the cooling fan rotating even after the projector body is turned off by a timer or the like, and further turns off the projector body depending on the result of temperature detection by the temperature sensor. Control is also performed.

  Next, the internal structure of the projector 10 will be described. FIG. 3 is a schematic plan view showing the internal structure of the projector 10. As shown in FIG. 3, the projector 10 has a power supply control circuit board 102 with a power supply circuit block 101 and the like attached in the vicinity of the right panel 14, and a sirocco fan type blower 110 arranged in the approximate center. A control circuit board 103 is disposed near 110, a light source device 63 is disposed near the front panel 12, and an optical system unit 70 is disposed near the left panel 15. Further, the projector 10 is airtightly divided into an intake side space chamber 121 on the rear panel 13 side and an exhaust side space chamber 122 on the front panel 12 side by a partition wall 120 in the casing, and the blower 110 has a suction port 111 is disposed in the intake side space chamber 121 and the discharge port 113 is positioned at the boundary between the exhaust side space chamber 122 and the intake side space chamber 121.

  The optical system unit 70 includes an illumination side block 78 located in the vicinity of the light source device 63, an image generation block 79 located on the back panel 13 side, and a projection side block located between the illumination side block 78 and the left panel 15. It is a substantially U-shape composed of 80 and 3 blocks.

  The illumination side block 78 includes a part of the light source side optical system 62 that guides the light emitted from the light source device 63 to the display element 51 provided in the image generation block 79. As the light source side optical system 62 included in the illumination side block 78, the light guide device 75 that converts the light beam emitted from the light source device 63 into a light beam having a uniform intensity distribution, and condenses light transmitted through the light guide device 75. There is a condensing lens.

  The image generation block 79 includes, as the light source side optical system 62, an optical axis changing mirror 74 that changes the optical axis direction of the light beam emitted from the light guide device 75, and light reflected by the optical axis changing mirror 74 as a display element. A plurality of condensing lenses for condensing on 51 and an irradiation mirror 84 for irradiating the display element 51 with a light beam transmitted through these condensing lenses at a predetermined angle. Further, the image generation block 79 includes a DMD serving as a display element 51, and a display element cooling device 53 for cooling the display element 51 is disposed on the rear panel 13 side of the display element 51. Prevents high temperatures.

  The projection-side block 80 includes a lens group of the projection-side optical system 90 that emits light that is reflected by the display element 51 and forms an image to the screen. The projection-side optical system 90 includes a fixed lens group 93 built in a fixed lens barrel and a movable lens group 97 built in a movable lens barrel, and is a variable focus lens having a zoom function, and is movable by a lens motor. Zoom adjustment and focus adjustment are enabled by moving the lens group 97.

  Further, in the internal structure of the projector 10, members having a lower temperature than the light source device 63 are disposed in the intake side space chamber 121. Specifically, the power supply control circuit board 102 and the blower 110 are arranged. A control circuit board 103, an image generation block 79 of the optical system unit 70, a projection side block 80 of the optical system unit 70, and a condenser lens in the illumination side block 78 of the optical system unit 70. .

  On the other hand, in the exhaust-side space chamber 122, a light source device 63 that has a relatively high temperature, a light guide device 75 provided in the illumination-side block 78 of the optical system unit 70, and an exhaust temperature reducing device 114 are arranged.

  The light source device 63 is a fluorescent wheel 71 that is a light emitting plate that emits light in the wavelength bands of red, green, and blue, which are the three primary colors of light when irradiated with light, and a drive device that rotationally drives the fluorescent wheel 71. A wheel motor 73, a plurality of light sources 72 that irradiate the fluorescent wheel 71 with light in the blue wavelength band, and a plurality of mirrors that guide light in the red, green, and blue wavelength bands emitted from the fluorescent wheel 71 to the light guide device 75. And.

  The plurality of light sources 72 are arranged such that the optical axis of each light source 72 is substantially orthogonal to the optical axis of the light guide device 75. Further, the fluorescent wheel 71 is disposed in the vicinity of the front panel 12 so as to face the light source 72. Specifically, the optical axis of the light source 72 and the wheel surface of the fluorescent wheel 71 are arranged so as to be orthogonal to each other. That is, the rotation axis of the wheel motor 73 that rotates the fluorescent wheel 71 is parallel to the optical axis of the light source 72. The fluorescent wheel 71 is configured to emit red and green fluorescent light toward the light source 72 and transmit blue band light from the light source 72.

  As shown in FIG. 4, the fluorescent wheel 71, which is a light-emitting plate, has three fan-shaped segment regions on a disk-shaped base material. Of the three, two segment regions are reflection portions, and the remaining one segment region is a transmission portion. Specifically, the fluorescent wheel 71 has a fan shape in which a red phosphor layer 131R and a green phosphor layer 131G are arranged adjacent to each other in the circumferential direction as two types of phosphor layers 131 that emit light in different wavelength bands. A reflecting plate 130 serving as a reflection portion of the light source and a diffusion plate 140 serving as a fan-shaped transmission portion disposed so that the diffusion layer 141 is adjacent to the phosphor layer 131 are provided on the rotating shaft of the wheel motor 73. It is integrally formed by being bonded and fixed to a motor hub. Further, the boundary surface between the reflecting plate 130 and the diffusing plate 140 is also bonded.

  In the fluorescent wheel 71, a circular opening corresponding to the shape of a cylindrical rotating shaft that is a connecting portion with the wheel motor 73 is formed at the center, and the rotating shaft is inserted into the circular opening so that the motor hub is mounted. By being adhered to the vicinity of the central part of the reflector 130 and the diffuser plate 140, they are firmly connected and integrated.

  As a result, the fluorescent wheel 71 is integrally rotated in the circumferential direction by the wheel motor 73 as a driving device that is driven and controlled by the control unit 38 of the projector control means at a rotational speed of about 120 times per second. .

  The reflecting plate 130 as the reflecting portion is made of an opaque base material made of a heat conductive member such as a copper plate or aluminum, and a blue light source from the light source 72 is deposited on the entire surface on the light source 72 side where the phosphor layer 131 is attached by silver deposition or the like A reflection layer for reflecting light and fluorescent light in the red and green wavelength bands generated by the phosphor is formed, and a phosphor layer 131 is formed on the reflection layer. This reflection layer can be easily formed because it is only necessary to mirror-finish one surface of the reflection plate 130.

  Then, in the vicinity of the outer peripheral portion of the fan-shaped reflector 130 having a dominant arc that is a semi-circular arc or more, two belt-shaped phosphor layers 131 are disposed adjacent to each other in the circumferential direction by coating. Is formed. The reflection plate 130 absorbs light from the light source 72 as excitation light when irradiated with light source light, and contains red phosphor containing a phosphor that emits red wavelength band light which is a primary color when excited. Similarly, a green phosphor layer 131G containing a phosphor emitting green wavelength band light which is a primary color by absorbing light from the light source 72 as excitation light is formed in the red phosphor layer 131R. It is formed to be adjacent to. The phosphor layer 131 is composed of a phosphor crystal and a binder.

  The diffusing plate 140 serving as a transmission portion is made of a transparent base material such as a glass base material or a transparent resin base material, and has a diffusion layer 141 on the entire surface on the light source 72 side. Specifically, the diffuser plate 140 is an optical process such as a roughing process such as a blast process on one entire surface of a fan-shaped transparent substrate having an arc that is approximately one third of the circumference of the arc. As a result, a diffusion layer 141 that imparts a diffusion effect when the incident blue light source light is transmitted is formed.

  The diffusion layer 141 is disposed adjacent to the phosphor layer 131 by disposing the diffusion plate 140 adjacent to the reflector 130 in the circumferential direction. The diffusion layer 141 may be formed by adhering a band-shaped solid material that is an optical material, in addition to performing an optical treatment on the surface of the transparent substrate. Alternatively, the diffusion layer 141 may be formed on the opposite surface without forming the diffusion layer 141 on the light source 72 side.

  The light source 72 irradiates light to the phosphor layer 131 and the diffusion layer 141 disposed in the vicinity of the outer peripheral portion of the phosphor wheel 71, and the red and green light emitted from the red and green phosphor layers 131R and 131G. The laser light emitter or the blue light emitting diode emits light in the blue wavelength band, which is visible light having a shorter wavelength than the light in the wavelength band.

  In this way, the fluorescent light emitted from the phosphor layer 131 formed in the reflecting portion of the fluorescent wheel 71 by arranging the light source 72 and the fluorescent wheel 71 having the phosphor layer 131 and the diffusion layer 141 to face each other. It is possible to separate the light source light that has passed through the diffuser plate 140 that is the transmission part of the fluorescent wheel 71. That is, by sequentially irradiating the phosphor layer 131 and the diffusion layer 141 of the rotating fluorescent wheel 71 with the blue light source light, the light source light emitted from the light source 72 is irradiated to the phosphor layer 131 of the fluorescent wheel 71 as excitation light. When the fluorescent light is emitted to the light source 72 side and the light source light emitted from the light source 72 is irradiated to the diffusion layer 141 of the transmission part of the fluorescent wheel 71, the light source light is emitted to the side opposite to the light source 72. Will be diffused and transmitted.

  And, since the reflection layer is formed on the surface where the phosphor layer 131 is arranged in the reflection plate 130 which is a reflection part, when the directional light source light is irradiated from the light source 72 to the red phosphor layer 131R, The phosphor of the red phosphor layer 131R absorbs blue light as excitation light and emits fluorescence light in the red wavelength band in all directions. Among these, the red fluorescent light emitted toward the light source 72 enters the light guide device 75 via a condensing optical system having a mirror, and the red fluorescent light emitted toward the opaque base material is reflected by the reflective layer. Therefore, most of the reflected light is incident on the light guide device 75 through the condensing optical system having a mirror as the light emitted from the fluorescent wheel 71.

  In addition, the blue light source light irradiated to the reflection layer without being absorbed by the phosphor of the red phosphor layer 131R is also reflected by the reflection layer and emitted again to the red phosphor layer 131R side to excite the phosphor. Therefore, it is possible to improve the utilization efficiency of the blue light source light and to emit light brightly.

  The blue light source light that is reflected by the reflective layer and is not absorbed by the phosphor and returns from the red phosphor layer 131R to the light source 72 side travels along with the red fluorescent light from the red phosphor layer 131R to the light source 72 side. Blue light source light is separated from red fluorescent light by a dichroic mirror that is an optical axis conversion mirror that reflects red light and transmits blue light. That is, only the red fluorescent light out of the light emitted from the fluorescent wheel 71 toward the light source 72 is reflected by the dichroic mirror and enters the light guide device 75 via another mirror or lens of the condensing optical system. It will be.

  Similarly, when the green phosphor layer 131G is irradiated with the light from the light source 72, the green wavelength band fluorescent light emitted from the green phosphor emits brightly similarly to the red fluorescent light, and the optical axis conversion mirror After being separated from the blue light source light that is reflected by the light source 72 and returns to the light source 72 side, the light enters the light guide device 75 via another mirror or lens of the condensing optical system.

  Then, when light source light such as a laser in the blue wavelength band is irradiated from the light source 72 to the diffusion layer 141, the emitted light from the phosphor layer 131 in order to impart a diffusion effect to the blue light source light incident on the diffusion layer 141. Blue light having the same diffused light as (red light and green light) is emitted from the diffusion layer 141, and the blue light is incident on the light guide device 75 via a condensing optical system having a mirror. .

  Thus, when the fluorescent wheel 71 is rotated and directional light source light is emitted from the light source 72, the red, green, and blue wavelength band lights are guided from the fluorescent wheel 71 through the condensing optical system having a mirror. The DMD that sequentially enters the display 75 and the DMD that is the display element 51 of the projector 10 displays the light of each color in a time-sharing manner according to the data, whereby a color image can be generated on the screen.

  As shown in FIG. 5, the light source device 63 includes a collimator lens 150 that is disposed on the emission side on the optical axis of the light source 72 and converts the emitted light from the light source 72 into parallel light. The light source device 63 reflects or transmits light of a predetermined wavelength band emitted from the fluorescent wheel 71, and collects each color light emitted from the fluorescent wheel 71 on the same optical path. A condensing optical system including optical axis conversion mirrors 1 to 4 and a plurality of convex lenses that condense a light bundle emitted from the fluorescent wheel 71 and incident on the light guide device 75 is provided.

  Hereinafter, the condensing optical system of the present embodiment will be described. This condensing optical system matches the optical axes of the red and green fluorescent lights emitted from the fluorescent wheel 71 in different directions and the optical axes of the blue light source lights to match the red, green and blue lights with the same light. Four optical axis conversion mirrors arranged at predetermined positions so as to be condensed on the road are provided. The optical axis conversion mirror is disposed between the light source 72 and the fluorescent wheel 71, transmits the excitation light, and reflects the fluorescent light from the phosphor, and transmits through the transmission part of the fluorescent wheel 71. The excitation light and the fluorescent light reflected by the dichroic mirror are collected on the same optical path and are composed of a plurality of reflection mirrors and dichroic mirrors that can irradiate light in the same direction.

  Specifically, the condensing optical system is disposed between the fluorescent wheel 71 and the light source 72, transmits the light source light without changing the optical axis of the light source light emitted from the light source 72, and The first optical axis conversion mirror 1, which is a dichroic mirror that converts the direction of the optical axis of the fluorescent light emitted from the phosphor layer 131, and the direction of the optical axis of the light source light that passes through the diffusion layer 141 of the fluorescent wheel 71 Fluorescent light by further converting the optical axis of the second optical axis conversion mirror 2 to be converted and the optical axis of the fluorescent light converted by the first optical axis conversion mirror 1 and the optical axis converted by the second optical axis conversion mirror 2 And third and fourth optical axis conversion mirrors 3 and 4 for condensing the fluorescent light and the light source light on the same optical path by matching the optical axes of the light source light and the light source light.

  In the present embodiment, the first optical axis conversion mirror 1 is disposed between the light source 72 and the fluorescent wheel 71 on the optical axis of the light source 72, and the optical axis of the blue light source light emitted from the light source 72. And a dichroic mirror that converts the optical axes of red and green fluorescent light emitted from the fluorescent wheel 71 by 90 degrees without changing the angle. That is, the first optical axis conversion mirror 1 transmits the blue light source light as the excitation light emitted from the light source 72 and emits the red and green wavelength bands emitted from the phosphor of the phosphor layer 131 of the phosphor wheel 71. The fluorescent light is reflected by changing the direction at an angle of 90 degrees.

  The second optical axis conversion mirror 2 is disposed on the optical axis of the light source 72 at a position opposite to the light source 72 with respect to the fluorescent wheel 71, and is transmitted through the diffusion layer 141 in the transmission part of the fluorescent wheel 71. It is a normal reflecting mirror that converts the optical axis of the light source light by 90 degrees. That is, the second optical axis conversion mirror 2 reflects the blue band light emitted from the fluorescent wheel 71 by changing the direction at an angle of 90 degrees. The second optical axis conversion mirror 2 may be a dichroic mirror that can reflect blue band light without using a reflection mirror.

  The third optical axis conversion mirror 3 is disposed on the optical axes of the red and green fluorescent lights converted by the first optical axis conversion mirror 1 so as to face the first optical axis conversion mirror 1, and the first light This is a reflection mirror that converts the optical axis of the fluorescent light converted by the axis conversion mirror 1 by 90 degrees. That is, the third optical axis conversion mirror 3 reflects the fluorescent light in the red and green wavelength bands reflected by the first optical axis conversion mirror 1 by changing the direction by an angle of 90 degrees. The third optical axis conversion mirror 3 may be a dichroic mirror that can reflect red and green light without using a reflection mirror.

  The fourth optical axis conversion mirror 4 is disposed so as to face the second optical axis conversion mirror 2 and the third optical axis conversion mirror 3, and converts the optical axis of the blue light source light converted by the second optical axis conversion mirror 2. This is a dichroic mirror that converts the optical axes of red and green fluorescent light converted by the third optical axis conversion mirror 3 by 90 degrees without being changed. That is, the fourth optical axis conversion mirror 4 is an optical axis of blue light source light reflected by the second optical axis conversion mirror 2 and fluorescent light in the red and green wavelength bands reflected by the third optical axis conversion mirror 3. Fluorescence in the red and green wavelength bands reflected at the third optical axis conversion mirror 3 is transmitted at a position where the axis intersects and transmits the blue light source light reflected by the second optical axis conversion mirror 2 and travels straight. The light is reflected to change direction by an angle of 90 degrees.

  As a result, the blue light source light transmitted through the fourth optical axis conversion mirror 4 and the red and green fluorescent lights reflected by the fourth optical axis conversion mirror 4 are condensed on the same optical path, and all these Colored light is emitted in the same direction.

  In this manner, by arranging the four optical axis conversion mirrors 1 to 4 in the condensing optical system, the optical axis of each color light emitted from the fluorescent wheel 71 is converted to coincide with the optical axis of the light guide device 75. By doing so, each color light can be condensed on the same optical path and irradiated in the same direction, so that the emitted light of each color from the fluorescent wheel 71 can be sequentially incident on the light guide device 75.

  This condensing optical system combines light with a mirror such as a dichroic mirror between the light source 72 and the fluorescent wheel 71 and in the path of the fluorescent light from the fluorescent wheel 71 and the light source light transmitted through the fluorescent wheel 71. Are formed by a lens and a mirror provided with a plurality of lenses for condensing light. As a result, the light beam whose traveling direction has been changed by the mirror can be condensed by the lens, and light can be efficiently incident on the light guide device 75.

  Specifically, the blue light emitted from the plurality of light sources 72 is collimated by the collimator lens 150 if the light source 72 is a blue light emitting diode, or the collimator if the light source 72 is a blue laser light emitter. The light is converted into parallel light having increased directivity by the lens 150, and is condensed by the first convex lens 153 a disposed between the collimator lens 150 and the first optical axis conversion mirror 1. Further, by arranging the condensing lens group 155 in the vicinity of both the front and back surfaces of the fluorescent wheel 71, the blue band light condensed by the first convex lens 153a is further condensed by the condensing lens group 155. While irradiating the wheel 71, each light bundle emitted from both front and back surfaces of the fluorescent wheel 71 is also condensed.

  Further, a second convex lens 153b is disposed between the second optical axis conversion mirror 2 and the fourth optical axis conversion mirror 4, and a third optical axis conversion mirror 1 and a third optical axis conversion mirror 3 are disposed between the third optical axis conversion mirror 1 and the third optical axis conversion mirror 3. A convex lens 153c is disposed, a fourth convex lens 153d is disposed between the third optical axis conversion mirror 3 and the fourth optical axis conversion mirror 4, and further, between the fourth optical axis conversion mirror 4 and the light guide device 75. Since the light guide device incident lens 154 is disposed on the light guide device, the light emitted from the fluorescent wheel 71 is incident on the light guide device 75 as a condensed light beam bundle.

  Therefore, the blue light source light emitted from the light source 72 via the collimator lens 150 is condensed by the first convex lens 153a, passes through the first optical axis conversion mirror 1, and is further condensed by the condenser lens group 155. Then, the phosphor layer 131 or the diffusion layer 141 of the phosphor wheel 71 is irradiated.

  Then, when the light source light is applied to the diffusion layer 141 of the diffusion plate 140 that is a transmission part of the fluorescent wheel 71, the blue light source light that has passed through the diffusion layer 141 and becomes diffused light The light is condensed by the condensing lens group 155 arranged in the direction opposite to the light source 72 side and is irradiated to the second optical axis conversion mirror 2. The blue light source light is reflected by the second optical axis conversion mirror 2, collected by the second convex lens 153b, and then transmitted by the fourth optical axis conversion mirror 4 and collected by the light guide device incident lens 154. And enters the light guide device 75.

  Then, when the light source light is irradiated onto the phosphor layer 131 of the reflecting plate 130 that is the reflecting portion of the fluorescent wheel 71, red or green wavelength band fluorescent light is emitted to the light source 72 side. Then, the fluorescent light is condensed by the condensing lens group 155 on the light source 72 side of the fluorescent wheel 71 and irradiated to the first optical axis conversion mirror 1. Here, the fluorescent light is reflected by the first optical axis conversion mirror 1, but the blue light source light reflected without being absorbed by the fluorescent material of the fluorescent material layer 131 passes through the first optical axis conversion mirror 1. It will be. Thereby, red or green fluorescent light and blue light source light can be separated to prevent a decrease in color purity.

  In addition, the fluorescent light reflected by the first optical axis conversion mirror 1 is collected by the third convex lens 153c and applied to the third optical axis conversion mirror 3. Then, the fluorescent light is reflected by the third optical axis conversion mirror 3 and condensed by the fourth convex lens 153d, and then irradiated to the fourth optical axis conversion mirror 4. The fluorescent light is further reflected by the fourth optical axis conversion mirror 4, condensed by the light guide device incident lens 154, and incident on the light guide device 75.

  Thus, according to the present invention, the fluorescent wheel 71 itself is used as the reflective plate 130 without providing a special reflective layer that reflects only light in a specific wavelength band on the surface of the fluorescent wheel 71. By providing a diffusion plate 140 having a diffusion layer 141 that transmits and diffuses light source light as a transmission part in the part, the emission light paths of the light source light emitted from the fluorescent wheel 71 and each color fluorescent light can be separated. it can. As a result, it is possible to provide the light source device 63 that can be easily manufactured with a simple configuration, and the projector 10 including the light source device 63.

  Further, in the light emitted from the fluorescent wheel 71, there is a slight amount of blue light source light reflected from the fluorescent wheel 71 together with the red or green fluorescent light, but the first optical axis conversion mirror 1 which is a dichroic mirror is used. By arranging between the light source 72 and the fluorescent wheel 71, the blue light source light reflected by the fluorescent wheel 71 mixed in the fluorescent light in the red or green wavelength band can be cut, so the light source light is mixed in the fluorescent light. Accordingly, it is possible to provide the light source device 63 that can emit each color light with high color purity that is reliably prevented, and the projector 10 including the light source device 63.

  By adopting a blue band laser emitter as the light source 72, the phosphor can be efficiently excited to emit light. In addition, by forming a phosphor layer 131 having at least a phosphor that emits red band light and a phosphor that emits green band light on the fluorescent wheel 71, it is possible to generate red and green wavelength band lights that are primary colors. Can do. Furthermore, by providing the diffusing layer 141 in the transmission part, it is possible to diffuse and transmit directional laser light and to make the blue wavelength band light which is the primary color enter the light guide device 75 as diffused light similar to fluorescent light. it can.

In addition, without providing the diffusion layer 141 in the transmission part, the transmission part is formed by a space as a normal glass plate or a through-hole having a frame around it, and the diffusion plate is disposed on the light source 72 side closest to the fluorescent wheel 71 or fluorescent light. There may be a fixed arrangement on the optical path of the blue light source light such as between the wheel 71 and the second optical axis conversion mirror 2. In addition, when the light source 72 is a blue light emitting diode, the light source device 63 may be configured such that the diffusion layer 141 is not provided on the transmission part or the optical path of the blue light source light.
Various types of configurations can be adopted for the types and installation modes of the optical axis conversion mirrors 1 to 4 used in the condensing optical system of the light source device 63.
Hereinafter, another variation example of the arrangement configuration of the optical axis conversion mirrors 1 to 4 will be described with reference to FIGS. 6 and 7.

  FIG. 6A shows an optical path L of the light source light emitted from the light source 72 and an optical path F of the fluorescent light emitted upon receiving the light source light in the optical layout (see FIG. 5) of the light source device 63 described above. It is a schematic diagram. That is, in the first optical layout shown in FIG. 6A, as shown in FIG. 7, the first optical axis conversion mirror 1 transmits a blue light source light and reflects red and green fluorescent lights. Is done. The second optical axis conversion mirror 2 is a reflection mirror that reflects blue light source light. The third optical axis conversion mirror 3 is a reflection mirror that reflects red and green fluorescent light, and the fourth optical axis conversion mirror 4 is a dichroic mirror that transmits blue light source light and reflects red and green fluorescent light. It is.

  The optical layout is a second optical layout in which the fourth optical axis conversion mirror 4 of the first optical layout is a dichroic mirror that reflects blue light source light and transmits red and green fluorescent light as shown in FIG. (See FIG. 6B).

  Further, the second optical axis conversion mirror 2 is a dichroic mirror that transmits blue light source light and reflects red and green fluorescent light, and a third optical layout using the fourth optical axis conversion mirror 4 as a reflection mirror (FIG. 6). (See (c)) can also be adopted. Thus, only the fluorescent light is repeatedly reflected, and the light source light and the fluorescent light can be condensed on the same optical path on the optical axis of the light source 72.

  Further, the second optical axis conversion mirror 2 in the third optical layout is a dichroic mirror that reflects the blue light source light and transmits the red and green fluorescent lights, so that the fourth optical layout (another optical layout) (see FIG. 6 (d)) can also be configured.

  Further, in the condensing optical system of the light source device 63, the second optical axis conversion mirror 2 is a reflection mirror that converts the optical axis of the blue light source light transmitted through the diffusion layer 141 of the diffusion plate 140 of the fluorescent wheel 71 by 90 degrees. The fourth optical axis conversion mirror 4 is a reflection mirror that converts the optical axis of the blue light source light converted by the second optical axis conversion mirror 2 by 90 degrees, and the third optical axis conversion mirror 3 is the first optical axis conversion mirror 3 A dichroic mirror that converts the optical axis of the blue light source light converted by the fourth optical axis conversion mirror 4 by 90 degrees without changing the optical axes of the red and green fluorescent lights converted by the optical axis conversion mirror 1; The fifth optical layout (see FIG. 6E) can also be employed.

  Further, a sixth optical layout (FIG. 6 (FIG. 6)) is another optical layout in which the third optical axis conversion mirror 3 in the fifth optical layout is a dichroic mirror that transmits blue light source light and reflects red and green fluorescent light. f) can also be configured.

  In addition, as described above (see FIGS. 6A to 6F), the second to fourth optical axis conversion mirrors 2 to 4 have two reflections for converting the optical axis of the light source light or fluorescent light. The second to fourth optical axis conversion is not limited to the case where the mirror is constituted by a mirror and one dichroic mirror that converts the other without changing any one of the optical axes of the light source light and the fluorescent light. The mirrors 2 to 4 adopt the seventh optical layout (see FIG. 6G), which is three reflecting mirrors that convert the optical axis of the blue light source light, and mainly reflect the blue light source light repeatedly. Thus, red and green fluorescent light and blue light source light can be condensed on the same optical path.

  As described above, various optical layouts can be adopted by arranging the characteristics of the second to fourth optical axis conversion mirrors 2 to 4 in various combinations at predetermined positions and angles. Therefore, as described above, not only can the light source device 63 and the projector 10 that have high color purity and are easy to manufacture be provided, but also the degree of freedom in arrangement with respect to equipment such as the projector 10 in which the light source device 63 is mounted is increased. Can do.

  The present invention is not limited to the above embodiments, and can be freely changed and improved without departing from the gist of the invention. For example, the phosphor layer 131 disposed on the reflector 130 is not limited to the case where the red and green phosphor layers 131R and 131G are disposed, and emits light in a wavelength band that is a complementary color such as yellow. It is also possible to add the phosphor layer 131 to be made available.

  Further, the number of optical axis conversion mirrors arranged in the light source device 63 is not limited to four, and five or more light source lights separated and separated can be condensed on the same optical path. The provision of the four optical axis conversion mirrors 1 to 4 is preferable because the light source device 63 can be simple and compact.

  In the above-described embodiments, the dichroic mirror is used to select the conversion in the optical axis direction and the transmission and reflection of light according to the wavelength. However, the present invention is not limited to this. For example, other dichroic prisms and the like are used. The above dichroic mirror may be replaced with an alternative means.

  Furthermore, the fluorescent wheel 71 may be formed and fixed as a rectangular light emitting plate instead of a disc shape. In this case, an adjustment device that changes the irradiation direction of the light from the light source 72 is disposed between the light source 72 and the light emitting plate, or a light source drive that drives the light source 72 to change the position and / or irradiation direction. By providing the device so that the irradiation spot of the light from the light source 72 is sequentially positioned in each segment region, each color light can be incident on the light guide device 75 via the condensing optical system. As the adjusting device, for example, an optical polarizer using a KTN crystal, an acoustooptic device, a MEMS mirror, or the like can be employed.

1 First optical axis conversion mirror 2 Second optical axis conversion mirror
3 Third optical axis conversion mirror 4 Fourth optical axis conversion mirror
10 Projector
11 Top panel 12 Front panel
13 Rear panel 14 Right panel
15 Left panel 17 Exhaust hole
18 Air intake hole 19 Lens cover
20 Various terminals 21 Input / output connector
22 I / O interface 23 Image converter
24 Display encoder 25 Video RAM
26 Display drive unit 31 Image compression / decompression unit
32 Memory card 35 Ir receiver
36 Ir processing section 37 Key / indicator section
38 Control unit 41 Power control circuit
43 Cooling fan drive control circuit 45 Lens motor
47 Audio processor 48 Speaker
51 Display element 53 Display element cooling device
62 Light source side optical system 63 Light source device
70 Optical system unit 71 Fluorescent wheel
72 Light source 73 Wheel motor
74 Optical axis change mirror 75 Light guide device
78 Lighting block 79 Image generation block
80 Projection side block 84 Irradiation mirror
90 Projection side optical system 93 Fixed lens group
97 Movable lens group 101 Power supply circuit block
102 Power supply control circuit board 103 Control circuit board
110 Blower 111 Air inlet
113 Discharge port 114 Exhaust temperature reduction device
120 Partition wall 121 Inlet side space
122 Exhaust side space 130 Reflector
131 phosphor layer 131R red phosphor layer
131G green phosphor layer
140 Diffuser 141 Diffusion layer
150 collimator lens
153a First convex lens 153b Second convex lens
153c Third convex lens 153d Fourth convex lens
154 Light guiding device incident lens 155 Condensing lens group

Claims (10)

The substrate has a plurality of segment regions, and at least one of the plurality of segment regions is a reflection portion, and a phosphor layer that receives excitation light and emits light of a predetermined wavelength band is formed on the reflection portion, At least one of the plurality of segment regions is a disc-shaped light emitting plate that is a transmission part that transmits light,
A light source for irradiating the phosphor layer of the light emitting plate with excitation light;
A dichroic mirror disposed between the light source and the light-emitting plate to transmit excitation light and reflect fluorescent light from the phosphor;
A plurality of reflecting mirrors and dichroic mirrors that collect the excitation light transmitted through the transmission part of the light emitting plate and the fluorescent light reflected by the dichroic mirror on the same optical path and irradiate in the same direction;
A driving device for rotating the light emitting plate in a circumferential direction;
Have
The plurality of segment regions are arranged in a circumferential direction,
The light source for irradiating the light emitting plate with the excitation light is a blue band laser emitter,
2. A light source device comprising: a plurality of phosphors forming the phosphor layer, at least a phosphor emitting red band light and a phosphor emitting green band light.   The light source device according to claim 1, wherein a diffusion layer that diffuses the excitation light is formed in a transmission portion of the light emitting plate.   A plurality of lenses for condensing light together with a mirror such as the dichroic mirror in the path between the light source and the light emitting plate and the light source light transmitted through the fluorescent light and the light emitting plate from the light emitting plate. The light source device according to claim 1, further comprising a condensing optical system formed by the arranged lens and the mirror. The condensing optical system is disposed between the light emitting plate and the light source, transmits the light source light without changing the optical axis of the light source light emitted from the light source, and the phosphor layer. A first optical axis conversion mirror that is a dichroic mirror that converts the direction of the optical axis of the fluorescent light emitted from
A dichroic mirror or a normal reflection mirror that changes the direction of the optical axis of the light source light that passes through the diffusion layer of the light emitting plate, or a dichroic mirror that transmits the light source light without changing the optical axis of the light source light. A two-optical axis conversion mirror,
By further converting the optical axis of the fluorescent light converted by the first optical axis conversion mirror and the optical axis converted by the second optical axis conversion mirror, the fluorescent light and the light source light are condensed on the same optical path. The light source device according to claim 3, further comprising third and fourth optical axis conversion mirrors. The first optical axis conversion mirror is disposed between the light emitting plate and the light source on the optical axis of the light source,
The second optical axis conversion mirror is disposed on a position opposite to the light source with respect to the light emitting plate on the optical axis of the light source,
The third optical axis conversion mirror is disposed on the optical axis of the fluorescent light converted by the first optical axis conversion mirror,
The light source device according to claim 4, wherein the fourth optical axis conversion mirror is disposed to face the second optical axis conversion mirror and the third optical axis conversion mirror.   The second to fourth optical axis conversion mirrors include two reflecting mirrors that convert the optical axis of the light source light or fluorescent light, and the other without converting any one of the optical axes of the light source light and fluorescent light. The light source device according to claim 4, wherein the light source device comprises: one dichroic mirror that converts The second optical axis conversion mirror is a reflection mirror that converts the optical axis of the light source light transmitted through the diffusion layer of the light emitting plate by 90 degrees,
The third optical axis conversion mirror is a reflection mirror that converts the optical axis of the fluorescent light converted by the first optical axis conversion mirror by 90 degrees,
The fourth optical axis conversion mirror changes the optical axis of the fluorescent light converted by the third optical axis conversion mirror without changing the optical axis of the light source light converted by the second optical axis conversion mirror. The light source device according to claim 6, wherein the light source device is a dichroic mirror that converts 90 degrees. The second optical axis conversion mirror is a reflection mirror that converts the optical axis of the light source light transmitted through the diffusion layer of the light emitting plate by 90 degrees,
The fourth optical axis conversion mirror is a reflection mirror that converts the optical axis of the light source light converted by the second optical axis conversion mirror by 90 degrees,
The third optical axis conversion mirror changes the optical axis of the light source light converted by the fourth optical axis conversion mirror without changing the optical axis of the fluorescent light converted by the first optical axis conversion mirror. The light source device according to claim 6, wherein the light source device is a dichroic mirror that converts 90 degrees.   6. The light source device according to claim 4, wherein the second to fourth optical axis conversion mirrors are three reflection mirrors that convert an optical axis of the light source light. A light source device, a display element, a light source side optical system that guides light from the light source device to the display element, a projection side optical system that projects an image emitted from the display element onto a screen, and the light source device And a projector control means for controlling the display element,
The projector according to claim 1, wherein the light source device is the light source device according to claim 1.

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