JP2010085740A - Light source device and projector - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a light source device having high luminance efficiency and achieving power saving, and a projector including the light source device. <P>SOLUTION: The projector includes: the light source device 63; a display element; a cooling fan; a light source side optical system for guiding light from the light source device 63 to the display element; a projection side optical system for projecting an image emitted from the display element to a screen; and a projector control means for controlling the light source device 63 and the display element. The light source device 63 includes: a rotating plate having a plurality of segment areas in which a phosphor layer 131 receiving exciting light and emitting light of a predetermined wavelength band is arranged on a circular base material 130 which can be rotated and controlled; and an exciting light source 70 including two or more light source bodies 72 emitting the exciting light of the predetermined wavelength band so as to project at least two kinds of light of different wavelength bands. Two or more kinds of phosphor layers 131 are arranged in the rotating plate, and the exciting light source 70 is turned on or off to be linked with rotation of the base material 130 so that each of the light source bodies 72 may radiate the exciting light only to the corresponding phosphor layer 131. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

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

  2. Description of the Related Art Today, a projector as an image projection apparatus that projects 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 is widely used. 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.

In the past, projectors using a high-intensity discharge lamp as the light source have been the mainstream, but in recent years, development has been made to use solid-state light emitting elements such as red, green, and blue light emitting diodes and organic EL as the light source. Many proposals have been made. For example, Japanese Patent Application Laid-Open No. 2004-341105 (Patent Document 1) proposes a light source device including a phosphor layer that converts ultraviolet light emitted from a solid light source into visible light, a transparent substrate, and a solid light source. .
JP 2004-341105 A

  In the proposal of Patent Document 1, in consideration of characteristics of phosphors of different types, the wavelength band light of each color emitted from the light source device obtains a predetermined light emission amount, so that the excitation light of one type of wavelength band is characterized. Since the phosphor layers irradiate different layers, there is a problem in that the light emission efficiency of the light source device is low and it is difficult to save power. Further, there are cases where the output of the light source body of excitation light is insufficient, and there is a problem that increasing the number of light source bodies in order to obtain a predetermined luminance increases power consumption and heat generation.

  The present invention has been made in view of such problems of the prior art, and has an excitation light source including two or more light source bodies and capable of emitting at least two different wavelength band lights. The light emission of each phosphor layer is controlled by switching on and off in conjunction with the rotation of the rotating plate so that each of the light source bodies constituting the excitation light source emits excitation light only to the corresponding phosphor layer. Therefore, the present invention aims to provide a light source device that has high luminous efficiency and can save power, and a projector including the light source device.

  A light source device of the present invention includes a rotary plate having a plurality of segment regions in which a phosphor layer that receives excitation light and emits light of a predetermined wavelength band is disposed on a circular base material capable of rotation control, An excitation light source including two or more light source bodies that emit excitation light in a wavelength band and capable of emitting at least two different wavelength band lights, and the rotating plate includes two or more kinds of phosphors. Layers are arranged, and the excitation light source is turned on or off in conjunction with the rotation of the substrate so that each of the light source bodies emits excitation light only to the corresponding phosphor layer.

  This base material is formed of a glass base material or a transparent resin base material.

  The base material has a dichroic layer that transmits the excitation light and reflects the wavelength band light emitted from the phosphor on the surface on which the phosphor layer is disposed. is there.

  The base material may have a non-reflective coating layer on the surface opposite to the side where the phosphor layer is disposed.

  Then, an auxiliary base material that can be rotated in synchronization with the base material is arranged coaxially with the base material, and the auxiliary base material reflects the excitation light on the surface on the base material side and emits a phosphor. An excitation light reflecting layer that transmits wavelength band light is formed corresponding to each segment region of the substrate.

  The base material may be formed of a heat transfer member, and a reflective layer may be formed on the surface on which the phosphor layer is disposed.

  At least one of the plurality of light source bodies emits blue wavelength band light, and the other light source bodies emit ultraviolet wavelength band light.

  The base material includes a segment region in which a phosphor layer emitting red wavelength band light is disposed, a segment region in which a phosphor layer emitting green wavelength band light is disposed, and a blue wavelength A segment region in which a phosphor layer that emits band light is disposed, and at least one of the light source bodies is a phosphor that emits blue wavelength band light and red and green wavelength band light. The layer is irradiated, and at least one of the light source bodies irradiates the phosphor layer emitting the blue wavelength band light with the wavelength band light in the ultraviolet region.

  The projector of the present invention includes a light source device, a display element, a cooling fan, 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. And a projector control means for controlling the light source device and the display element. The light source device is the light source device described above.

  According to the present invention, there is provided an excitation light source including two or more light source bodies and capable of emitting light of at least two different wavelength bands, and each of the light source bodies constituting the excitation light source corresponds to a corresponding phosphor. Since only the excitation light necessary for light emission of each phosphor layer can be irradiated by controlling switching between lighting and extinction in conjunction with the rotation of the rotating plate so that only the layer is irradiated with excitation light, light emission It is possible to provide a light source device that can achieve high efficiency, save power, and obtain a predetermined light emission amount, and a projector including the light source device.

  The projector 10 according to the best mode for carrying out the present invention includes a light source device 63, a display element 51, a cooling fan, and a light source side optical system 61 that guides light from the light source device 63 to the display element 51. And a projection-side optical system 62 that projects an image emitted from the display element 51 onto a screen, and a projector control unit that controls the light source device 63 and the display element 51.

  The light source device 63 includes a rotary plate having a plurality of segment regions in which a phosphor layer 131 that receives excitation light and emits light in a predetermined wavelength band is disposed on a circular base material 130 that can be rotated and controlled, An excitation light source 70 that includes two or more light source bodies 72 that emit excitation light in the wavelength band of the light source and that can emit light of at least two different wavelength band, and the rotating plate includes two or more types of light sources. A phosphor layer 131 is disposed, and the excitation light source 70 is turned on or off in conjunction with the rotation of the substrate 130 so that each of the light source bodies 72 emits excitation light only to the corresponding phosphor layer 131. It is turned off.

  The substrate 130 is formed of a glass substrate or a transparent resin substrate, and the entire surface on the side where the phosphor layer 131 is disposed transmits the excitation light, and the phosphor is A dichroic layer 134 that reflects the emitted wavelength band light is formed by coating, and a non-reflective coating layer 133 is formed by coating on the entire surface opposite to the side where the phosphor layer 131 is disposed. is there.

  The substrate 130 includes a segment region in which a red phosphor layer 131R that emits a red wavelength band light that is a primary color and a green phosphor layer 131G that emits a green wavelength band light that is a primary color. And a segment region in which a blue phosphor layer 131B that emits blue wavelength band light, which is the primary color, is disposed.

  Further, as the plurality of light source bodies 72 constituting the excitation light source 70, the four light source bodies 72 have a blue wavelength shorter than the red and green wavelength band lights emitted by the red and green phosphor layers 131R and 131G. A light emitting diode or laser emitter that emits band light, and a plurality of light source bodies 72 are made of three light source bodies 72 having a shorter wavelength than the blue wavelength band light emitted by the blue phosphor layer 131B. A light-emitting diode or a laser emitter that emits light in the wavelength band of the region is used.

  Then, the light source device 63 emits blue light from the blue light source 72B when the red and green phosphor layers 131R and 131G are positioned on the optical axis of the blue light source 72B. Irradiate 131G, turn off the ultraviolet light source 72U, and when the blue phosphor layer 131B is positioned on the optical axis of the ultraviolet light source 72U, emit ultraviolet light from the ultraviolet light source 72U of the blue phosphor. The excitation light source 70 is controlled to be switched in conjunction with the rotation of the rotating plate so that the layer 131B is irradiated and the blue light source 72B is turned off.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. As shown in FIG. 1, a projector 10 according to one embodiment of the present invention has a substantially rectangular parallelepiped shape, and a lens cover 19 that covers a projection port on the side of a front plate 12 that is a side plate in front of a main body case. The front plate 12 is provided with a plurality of exhaust holes 17.

  The top plate 11 which is a main body case has a key / indicator unit 37. The key / indicator unit 37 includes a power switch key, a power indicator for notifying power on / off, a light source device, and the like. It is provided with keys and indicators such as an overheat indicator for notifying when overheated.

  Further, on the back of the main body case, various terminals 20 such as an input / output connector portion and a power adapter plug, etc., which are provided with a USB terminal, a D-SUB terminal for inputting image signals, an S terminal, an RCA terminal, etc. on the back plate, a memory not shown A card slot and an Ir receiver for receiving control signals from the remote controller are provided.

  The rear plate, the right side plate which is a side plate of the main body case (not shown), and the lower portion of the left side plate 15 which is the side plate shown in FIG. It is.

  As shown in FIG. 2, the projector control means of the projector 10 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. The image signals of various standards input from the connector unit 21 are converted so as to be unified into an image signal of a predetermined format suitable for display by the image conversion unit 23 via the input / output interface 22 and the system bus (SB). Thereafter, it is sent to the display encoder 24.

  The display encoder 24 develops and stores the transmitted 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.

  A display drive unit 26 to which a video signal is input from the display encoder 24 drives a display element 51, which is a spatial light modulation element (SOM), at an appropriate frame rate corresponding to the image signal sent. Yes, the light from the light source device 63 is incident on the display element 51 through the illumination unit that forms the light source side optical system, thereby forming a light image with the reflected light of the display element 51 and forming the projection side optical system. The movable lens group 97 of the projection side optical system is driven for zoom adjustment and focus adjustment by a lens motor 45. .

  In addition, the image compression / decompression unit 31 performs a recording process for sequentially writing a luminance signal and a color difference signal of an image signal to a memory card 32 that is a removable recording medium by performing data compression by processing such as ADTC and Huffman coding. In the mode, the image data recorded on the memory card 32 is read, and individual image data constituting a series of moving images is expanded in units of one frame and sent to the display encoder 24 via the image conversion unit 23. A moving image or the like can be displayed based on the stored image data.

  The control unit 38 controls the 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. ing.

  Further, the operation signal of the key / indicator unit 37 composed of the main key and the indicator provided on the upper surface plate 11 of the main body case is directly sent to the control unit 38, and the key operation signal from the remote controller is received by Ir. The code signal received by the unit 35 and demodulated by the Ir processing unit 36 is sent to the control unit 38.

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

  The control unit 38 controls the power supply control circuit 41. The power supply control circuit 41 turns on the light source device 63 when the power switch key is operated. Further, the control unit 38 also controls a cooling fan drive control circuit 43. The cooling fan drive control circuit 43 performs temperature detection by a plurality of temperature sensors provided in the light source device 63, etc. The rotation speed is controlled, and the rotation of the cooling fan is continued even after the light source device 63 is turned off by a timer or the like. Further, depending on the result of temperature detection by the temperature sensor, the light source device 63 is stopped and the projector main body is stopped. Control such as turning off the power is also performed.

  Further, as shown in FIG. 3, the projector 10 has an internal structure in which a power supply control circuit board 102 to which a light source power supply circuit block 101 and the like are attached is disposed in the vicinity of the right side plate 14 and the inside of the casing is divided into partition walls 120 The air intake side space chamber 121 on the back plate 13 side and the exhaust side space chamber 122 on the front plate 12 side are formed in an airtight manner, and a sirocco fan type blower 110 is arranged as a cooling fan near the center of the projector 10, The suction port 111 of the blower 110 is positioned in the space chamber 121, and the discharge port 113 of the blower 110 is positioned in the exhaust side space chamber 122.

  Further, a light source device 63 is disposed in the exhaust side space 122, and an optical unit block 77 including an illumination side block 78, an image generation block 79, and a projection side block 80 is disposed along the left side plate 15. 77. The illumination side block 78 is communicated with the exhaust side space chamber 122 so that a part of the illumination unit provided in the illumination side block 78 is located in the exhaust side space chamber 122. An exhaust temperature reducing device 114 is disposed along the face plate 12.

  The blower 110 as a cooling fan for cooling the light source device 63 and the like has a suction port 111 in the center, the discharge port 113 has a substantially square cross section, and is connected to the partition partition 120, and the partition partition 120 Exhaust air from the blower 110 is discharged into the exhaust-side space chamber 122 partitioned by the control circuit board 103 in the vicinity of the suction port 111 of the blower 110.

  The optical unit block 77 is disposed in the vicinity of the light source device 63, and includes an illumination side block 78 that includes a part of the illumination unit and emits light emitted from the light source device 63 toward the image generation block 79, and illumination. An image generation block 79 that includes a part of the display unit 51 and the display element 51 and reflects the emitted light from the illumination side block 78 to the projection side block 80 in accordance with the image data, and a projection unit of the left side plate 15 It is composed of three blocks, a projection side block 80 which is arranged in the vicinity and projects the light reflected by the image generation block 79.

  As a part of the illumination unit forming the light source side optical system 61 provided in the illumination side block 78, there is a light guide device 75 that uses light emitted from the light source device 63 as a light flux having a uniform intensity distribution.

  Further, as a part of the illumination unit forming the light source side optical system 61 included in the image generation block 79, the reflection mirror 74 that changes the direction of the light emitted from the light guide device 75, and the reflection mirror 74 reflects the light. There is a condensing lens group 83 that condenses the emitted light on the display element 51 and an irradiation mirror 84 that irradiates the display element 51 with light transmitted through the condensing lens group 83 at a predetermined angle. The image generation block 79 also includes a display element 51, and the display element 51 employs DMD. Further, a display element heat dissipation plate 53 for cooling the display element 51 is disposed on the back plate 13 side of the display element 51.

  In this DMD, a plurality of micromirrors are arranged in a matrix, and light incident from an incident direction inclined in one direction with respect to the front direction is converted into an on-state light beam in the front direction by switching the tilt direction of the plurality of micromirrors. The image is displayed by being reflected separately from the off-state light beam in the oblique direction, and the light incident on the micromirror tilted in one tilt direction is reflected in the front direction by this micromirror and turned on. The light incident on the micromirror tilted in the other tilt direction is reflected by the micromirror in an oblique direction to form an off-state light beam, and the off-state light beam is absorbed by the light absorption plate and reflected in the front direction. The image is generated by the bright display by and the dark display by reflection in the oblique direction.

  The projection-side block 80 includes a projection unit having a fixed lens group 93 and a movable lens group 97 that form a projection-side optical system 62 that irradiates a screen or the like (not shown) with a brightly displayed light beam that forms an image. Is. The lens group of these projection-side optical systems 62 is a variable-focus lens having a zoom function, and is described above by the optical system control board 86 disposed between the optical unit block 77 and the left side plate 15. The lens motor 45 is controlled to move the movable lens group 97 along the optical axis, thereby enabling zoom adjustment and focus adjustment.

  The light source device 63 includes two or more light source bodies 72 that emit excitation light of a predetermined wavelength band, and can emit at least two different wavelength band lights. The fluorescent wheel 71 is configured to receive the excitation light of each color and emit the wavelength band light of each color to the light guide device 75. The fluorescent wheel 71 is formed at the center of the base material 130 made of a disc-shaped transparent material. A wheel motor 73 that is attached and driven and controlled by the control unit 38 of the projector control means is rotatably arranged.

  As shown in FIGS. 4 to 6, the light source device 63 includes a rotating plate having a plurality of segment regions in which a phosphor layer 131 that receives excitation light and emits light of a predetermined wavelength band is disposed, and the rotation plate. A fluorescent wheel 71 comprising a wheel motor 73 for rotating the plate, and an excitation light source 70 comprising a plurality of light source bodies 72 for irradiating the phosphor contained in the phosphor layer 131 with excitation light, When excitation light is emitted from the excitation light source 70 to the fluorescent wheel 71, light of a predetermined wavelength band is emitted from the phosphor of the phosphor layer 131, and the emitted light is incident on the light guide device 75. Is.

  The fluorescent wheel 71 is composed of a rotating plate having a phosphor layer 131 on a circular base material 130 and a wheel motor 73, and a circle serving as a connection portion with the wheel motor 73 at the center of the base material 130. A circular opening corresponding to the shape of the columnar rotor is formed, and the rotor is inserted into the circular opening to be integrated. As a result, the rotating plate of the fluorescent wheel 71 is rotated by the wheel motor 73 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 three segment regions of the rotating plate are formed in a fan shape, and the substrate 130 of the rotating plate is formed of a glass substrate or a transparent resin substrate. In each segment region of the base material 130, a phosphor layer 131 is disposed. Each phosphor layer 131 receives excitation light emitted from the excitation light source 70 and emits light in a predetermined wavelength band.

  The base material 130 includes first to third three segment regions 141 to 143, and one surface of the first region 141 emits red (R) wavelength band light which is a primary color. The phosphor layer 131R is fixed, and one surface of the second region 142 is fixed with the green phosphor layer 131G that emits green (G) wavelength band light as a primary color. A blue phosphor layer 131B that emits blue (B) wavelength band light, which is the primary color, is fixed to the surface.

  The base material 130 can also be formed with three filter pieces corresponding to the three segment regions 141 to 143. The phosphor layer 131 is fixed with each filter piece, and then bonded in a circular shape. Alternatively, it may be integrated by a mounting member or the like. The phosphor layer 131 is composed of a phosphor crystal and a binder.

  The substrate 130 transmits excitation light to the entire surface on the side where the phosphor layer 131 is disposed, and reflects other wavelength band light other than excitation light such as wavelength band light emitted from the phosphor. The dichroic layer 134 is formed by coating, and the phosphor layer 131 is formed on the dichroic layer 134.

  In this embodiment, the excitation light is transmitted through the entire surface of the substrate 130 on the side where the phosphor layer 131 is disposed, and other than the excitation light including red, green, and blue wavelength bands emitted from the phosphor. Although the dichroic layer 134 that reflects light in other wavelength bands is formed, the dichroic layer 134 having different characteristics may be formed in each segment region. For example, the entire surface of the first region 141 is coated with a coating that transmits other wavelength band light other than red light including excitation light and reflects red light, and the entire region of the second region 142 is green light including excitation light. A coating that transmits green light and reflects green light is applied, and the entire surface of the third region 143 transmits light of other wavelength bands other than blue light including excitation light, and reflects blue light. A coating may be applied.

  In addition, in the base material 130, a non-reflective coating layer 133 is formed by coating on the entire surface opposite to the side on which the phosphor layer 131 is disposed.

  The excitation light source 70 irradiates each segment area of the rotating plate with excitation light, and includes seven light source bodies 72. Four of the light source bodies 72 constituting the excitation light source 70 have wavelengths longer than the red and green wavelength band lights emitted from the red and green phosphor layers 131R and 131G in the first region 141 and the second region 142. Light emitting diodes or laser light emitters as blue light source bodies 72B that emit blue wavelength band light, which is short visible light, and the remaining three light source bodies 72 are blue phosphors in the third region 143 The light emitting diode or laser light emitter as the ultraviolet light source 72U that emits light in the ultraviolet wavelength band, which is invisible light having a shorter wavelength than the blue wavelength light emitted from the layer 131B, is used.

  As shown in FIG. 3, in the excitation light source 70, the optical axis of each light source 72, the optical axis of the light guide device 75, and the rotation axis of the fluorescent wheel 71 are parallel to each other on the front side of the projector 10. The excitation light condensing lens 139 is disposed on the optical axis of each light source body 72 and so that the excitation light is condensed on the phosphor layer 131 attached to the fluorescent wheel 71. It is what.

  Further, in order to increase the amount of monochromatic light emitted from the phosphor of one phosphor layer 131 by the excitation light from the excitation light source 70 and improve the utilization efficiency of the effective light, it is shown in FIGS. As described above, the incident mask 136 having an opening formed corresponding to the shape of the light guide device 75 is disposed between the excitation light source 70 and the fluorescent wheel 71.

  Each light source body 72 of the excitation light source 70 is controlled to blink by the control unit 38 of the projector control means in conjunction with the rotation of the rotating plate. The blue light source body 72B is emitted from the blue light source body 72B. Is turned on only when the red and green phosphor layers 131R and 131G of the rotating plate are positioned on the optical path of the excitation light, and the blue phosphor layer 131B is on the optical path of the emitted light from the blue light source 72B. The UV light source 72U is turned on only when the blue phosphor layer 131B of the rotating plate is positioned on the optical path of the ultraviolet light emitted from the UV light source 72U. When the red and green phosphor layers 131R and 131G are positioned on the optical path of the light emitted from the ultraviolet light source 72U, the light is controlled to be turned off.

  In this way, the blue and ultraviolet light source bodies 72B and 72U are controlled to blink every time each segment region of the rotating plate that rotates on the optical axis of the excitation light source 70 is positioned. Wavelength band lights are sequentially switched and emitted, and red, green, and blue wavelength band lights are sequentially generated from the phosphor that has absorbed the excitation light. Then, the DMD that is the display element 51 of the projector 10 displays the data in a time-sharing manner in accordance with the irradiation timing of the excitation light source 70, thereby generating a color image on the screen.

  In addition, when the light source body 72 that emits the excitation light in the same wavelength band is irradiated on the plurality of types of phosphor layers 131, the excitation light in a plurality of different wavelength bands is applied to the phosphor having relatively low wavelength conversion efficiency. It is good also as making it irradiate. For example, when the red phosphor and the green phosphor are irradiated with blue excitation light having the same wavelength band, if the wavelength conversion efficiency of the red phosphor is lower than the wavelength conversion efficiency of the green phosphor, the green phosphor Is irradiated with blue excitation light only by the blue light source 72B, and the red phosphor is emitted by emitting excitation light from not only the blue light source 72B but also several ultraviolet light sources 72U to the red phosphor. The amount of light emitted from each of the phosphors can be increased so that the light generated from each phosphor layer 131 is uniformly incident on the light guide device 75. Conversely, it is also possible to perform control such as improving the luminance of only one color by intentionally increasing the amount of light emitted from a predetermined phosphor.

  Next, light emitted from the fluorescent wheel 71 and incident on the light guide device 75 will be described. When blue excitation light is irradiated to the first region 141 from the excitation light source 70, the excitation light passes through the non-reflective coating layer 133 on the incident surface of the first region 141 with almost no reflection toward the excitation light source 70 side. Incident on the substrate 130. Then, the excitation light transmitted through the substrate 130 passes through the dichroic layer 134 and is irradiated to the red phosphor layer 131R. The phosphor of the red phosphor layer 131R absorbs the excitation light and emits red wavelength band light in all directions. Among these, the red light emitted toward the light guide device 75 enters the light guide device 75 as it is, and the red light emitted toward the base material 130 is reflected by the dichroic layer 134, and most of the reflected light is fluorescent. The light emitted from the wheel 71 is incident on the light guide device 75.

  Similarly, when blue excitation light is irradiated from the excitation light source 70 to the second region 142, green wavelength band light is generated by the phosphor of the green phosphor layer 131G in the second region 142, and the green light is guided. It will be incident on the device 75.

  When the third region 143 is irradiated with ultraviolet light as excitation light from the excitation light source 70, blue wavelength band light is generated by the phosphor of the blue phosphor layer 131B in the third region 143, as described above. Then, the blue light enters the light guide device 75.

  As shown in FIGS. 5 and 6, the light guide device 75 in the present embodiment is a tapered light tunnel formed in a hollow, substantially quadrangular pyramid shape. This tapered light tunnel has four trapezoidal plates that form the top, bottom, left, and right surfaces with an entrance surface and an exit surface perpendicular to the optical axis, and by bonding and fixing each in the vicinity of the ridgeline of each plate It is formed in a substantially quadrangular frustum shape whose cross-sectional area expands from the entrance surface to the exit surface, and the inner surface is a reflection surface. Then, by making the length and width of the exit surface approximately twice the length and width of the entrance surface of the tapered light tunnel, the incident diffused light is transferred from the exit surface to the optical axis. On the other hand, it can be set as a light beam having a spread of about 30 degrees.

  The light guide device 75 is not a tapered light tunnel, but the length of the entrance surface and the exit surface are the same length and the length of the width is the same, and a condenser lens group is arranged on the entrance surface side of the light tunnel. The diffused light emitted from the fluorescent wheel 71 may be condensed by the condenser lens group and incident on the light tunnel. The light guide device 75 is not limited to the light tunnel, and a solid glass rod may be used.

  As a result, while rotating the rotating plate of the fluorescent wheel 71, the excitation light emitted from the excitation light source 70 so that each of the light source bodies 72 constituting the excitation light source 70 emits excitation light only to the corresponding phosphor layer 131. When the switching is controlled, red, green, and blue wavelength band lights are sequentially incident on the light guide device 75 from the fluorescent wheel 71, and the DMD, which is the display element 51 of the projector 10, adjusts the data according to the irradiation timing of the excitation light source 70. By performing the division display, a color image is generated on the screen.

  In this way, two or more different phosphor layers 131 that generate excitation light in a predetermined wavelength band upon receiving excitation light are arranged on a circular substrate 130 that can be rotated and emit excitation light in a predetermined wavelength band Two or more different types of light such as ultraviolet light or blue light having higher energy than the wavelength band light generated by the phosphor from the excitation light source 70 that can emit at least two different wavelength band lights. By sequentially switching the wavelength band light as excitation light and irradiating the phosphors of the phosphor layers 131, light of a predetermined wavelength band such as red, green, and blue can be generated.

  Thus, each of the light source bodies 72 is necessary for light emission of each phosphor layer 131 by turning on or off according to the rotation of the base material 130 so that the excitation light is irradiated only to the corresponding phosphor. Therefore, the excitation light source 70 can be configured with a plurality of types of light source bodies 72 that match the characteristics of each phosphor. Therefore, it is possible to provide the light source device 63 capable of obtaining a predetermined light emission amount without increasing the number of light source bodies 72 more than necessary, and the projector 10 including the light source device 63.

  Further, rigidity can be provided by using the base material 130 as a glass base material, or weight reduction and cost reduction can be achieved by using the base material 130 as a transparent resin base material.

  Since the surface of the base material 130 on which the phosphor layer 131 is disposed has the dichroic layer 134, the light emitted to the base material 130 side is reflected to the light guide device 75 side to guide the light. The amount of light incident on the device 75 can be increased.

  Furthermore, since the non-reflective coating layer 133 is provided on the surface of the substrate 130 opposite to the side where the phosphor layer 131 is disposed, the utilization efficiency of excitation light emitted from the excitation light source 70 can be improved. You can also.

  Further, by employing a light emitting diode or laser light emitter as the excitation light source 70, power consumption can be suppressed and downsizing can be achieved as compared with a projector using a conventional discharge lamp or the like as a light source device.

  And, for the combination of the predetermined wavelength band light emitted from the excitation light source 70 and the predetermined wavelength band light emitted from the plurality of phosphor layers 131, the excitation light is a wavelength band light in the blue and ultraviolet regions, Various modes can be adopted without being limited to the case where the light emitted from the fluorescent wheel 71 is the primary wavelength band light.

  For example, a phosphor layer 131 that emits a yellow wavelength band light that is a complementary color may be disposed in each segment region in addition to a phosphor layer 131 that emits a primary wavelength band light. Thereby, the luminance of the light source device 63 can be increased to improve the color reproducibility.

  In addition, as a constant arrangement pattern in the circumferential direction of the phosphor layer 131, light of three wavelength bands is repeatedly emitted from the six segment regions so as to be red, green, blue, red, green, and blue. May be. As a result, color separation due to the color braking phenomenon can be prevented without changing the rotation speed of the fluorescent wheel 71.

  Further, the excitation light source 70 is not limited to the case where the excitation light source 70 is composed of the ultraviolet light source 72U that emits light in the wavelength band of the ultraviolet region and the blue light source 72B that emits light in the blue wavelength band. Various light source bodies 72 that can emit light having a wavelength band higher in energy than the wavelength band light generated by each phosphor can also be incorporated. For example, red and green are emitted by the excitation light source 70 that emits purple wavelength band light. The red wavelength band light can be emitted by the light source 72 that emits the blue phosphor or emits the green wavelength band light.

  As shown in FIG. 7, the light source device 63 includes an auxiliary base material 137 made of a transparent material formed in a circular shape corresponding to the shape of the base material 130 on the side opposite to the excitation light source 70 side of the base material 130. May be arranged. The auxiliary base material 137 has a segment area having the same shape as the base material 130. Further, since it is fixed to the wheel motor 73 like the base material 130, the auxiliary base material 137 rotates synchronously with the base material 130 at the same speed.

  The auxiliary base material 137 reflects the excitation light, which is the wavelength band light in the blue or ultraviolet region, and the other wavelength band light other than the excitation light such as the wavelength band light emitted from the phosphor of the phosphor layer 131. The excitation light reflecting layer 132 that passes through is formed in a segment region on the surface on the base material 130 side by coating, and the non-reflective coating layer 133 is formed on the entire surface opposite to the base material 130 side by coating. .

  The excitation light reflecting layer 132 is formed as a reflecting layer having different characteristics depending on the type of the phosphor layer 131 of the base material 130 disposed to face the auxiliary base material 137 in each segment region. It reflects the excitation light irradiated to the phosphor layer 131 facing it and transmits the other wavelength band light. Specifically, the red and green phosphor layers 131R and 131G are irradiated to the segment region of the auxiliary base material 137 facing the segment region of the base material 130 on which the red and green phosphor layers 131R and 131G are formed. Of the auxiliary substrate 137 facing the segment region of the substrate 130 on which the blue excitation light reflecting layer 132B that reflects the blue excitation light and transmits the other wavelength band light is formed, and the blue phosphor layer 131B is formed. In the segment region, an ultraviolet excitation light reflecting layer 132U that reflects the ultraviolet light irradiated on the blue phosphor layer 131B and transmits light in other wavelength bands is formed.

  6, three segment regions are formed on the rotating plate of the fluorescent wheel 71, the red phosphor layer 131 </ b> R is fixed to the first region 141, and the green fluorescence is formed to the second region 142. When the body layer 131G is fixed, the blue phosphor layer 131B is fixed to the third region 143, and the first region 141 is irradiated with excitation light that is blue wavelength band light from the blue light source 72B, the excitation is performed. The light passes through the non-reflective coating layer 133 on the incident surface of the first region 141 with almost no reflection to the excitation light source 70 side and enters the substrate 130.

  Then, as shown in FIG. 7, the excitation light that has passed through the substrate 130 passes through the dichroic layer 134 and is applied to the red phosphor layer 131R. The red phosphor layer 131R absorbs the excitation light and emits red wavelength band light in all directions. Of these, the light emitted toward the light guide device 75 enters the auxiliary base material 137 as it is, and the light emitted to the base material 130 side is reflected by the dichroic layer 134, and most of the reflected light is the auxiliary base material. 137 is incident. However, at this time, there is also blue excitation light that passes through the red phosphor layer 131R without being absorbed and enters the auxiliary base material 137.

  Then, when red light and blue excitation light are incident on the auxiliary base material 137 side, the blue excitation light is reflected by the excitation light reflecting layer 132 of the auxiliary base material 137 and is incident on the red phosphor layer 131R again, and is absorbed. The red wavelength band light is generated by the phosphor of the phosphor layer 131R, and the red light is incident on the auxiliary base material 137. The red light incident on the auxiliary base material 137 passes through the excitation light reflecting layer 132, the auxiliary base material 137, and the non-reflective coating layer 133, is emitted from the fluorescent wheel 71, and enters the light guide device 75. Become.

  Similarly, when the second region 142 is irradiated with excitation light from the blue light source 72B, green wavelength band light is generated by the phosphor of the green phosphor layer 131G, and the green light is incident on the light guide device 75. The Rukoto. Then, when the third region 143 is irradiated with excitation light that is ultraviolet wavelength band light from the ultraviolet light source 72U, the excitation light is absorbed by the phosphor of the blue phosphor layer 131B in the third region 143, and the blue region Wavelength band light is generated. Similarly to the above, the ultraviolet light that is transmitted without being absorbed by the blue phosphor layer 131B and is incident on the auxiliary base material 137 is reflected by the ultraviolet excitation light reflecting layer 132U of the auxiliary base material 137 and is again blue. Incident and absorbed by the phosphor layer 131B, blue light is generated.

  In the case where the red and green phosphor layers 131R and 131G are irradiated with excitation light from the ultraviolet light source 72U as well as the blue light source 72B, the base material 130 on which the red and green phosphor layers 131R and 131G are formed. The excitation light reflecting layer 132 that reflects the blue light and the ultraviolet light irradiated to the red and green phosphor layers 131R and 131G and transmits the other wavelength band light to the segment region of the auxiliary base material 137 facing the segment region of By reflecting the blue light and ultraviolet light, which are excitation light transmitted through the red and green phosphor layers 131R and 131G, the red light and green light are incident on the red and green phosphor layers 131R and 131G. Light can be generated.

  Thus, by arranging the auxiliary base material 137 in which the shape and the segment region corresponding to the shape of the base material 130 are formed on the side opposite to the excitation light source 70 side of the base material 130, the phosphor layer 131 is arranged. The excitation light that has passed through is reflected to the base material 130 side, is incident on the phosphor layer 131 again, is absorbed by the phosphor, and can generate light of a predetermined wavelength band. The amount of light to be increased can be increased. Further, since the non-reflective coating layer 133 is formed on the surface opposite to the substrate 130 side, the utilization efficiency of the emitted light can be improved.

  The light source device 63 of the present invention increases the amount of light incident on the light guide device 75, and as shown in FIG. 8, the rotating plate is composed of an excitation light source 70 and an ultraviolet light source body 72U each composed of a blue light source body 72B. In some cases, it is arranged between the excitation light source 70 and the excitation light is emitted from the front-rear direction of the rotating plate to generate light of a predetermined wavelength band and enter the light guide device 75. This light source device 63 is provided with a plurality of ultraviolet light source bodies 72U on the side opposite to the exit surface of the base material 130, and is arranged so that the optical axis of the ultraviolet light source bodies 72U is parallel to the rotation axis of the fluorescent wheel 71. The plurality of blue light source bodies 72B are arranged such that the excitation light emitted from the blue light source body 72B passes through the excitation light condensing lens 139 on the emission surface side of the base material 130, and the fluorescence of the base material 130 At a position away from the optical axis of the excitation light source 70 by a predetermined distance so as to irradiate the body layer 131 and not to block the light emitted from the fluorescent wheel 71 and entering the light guide device 75. It is arranged at a predetermined angle.

  As shown in the figure, the excitation light source 70, which is an assembly of the blue light source bodies 72B, and the excitation light source 70, which is an assembly of the ultraviolet light source bodies 72U, are not limited to the case where they are arranged at different positions. The light source 70 may be arranged only on the emission surface side of the fluorescent wheel 71, or an assembly in which blue and ultraviolet light source bodies 72B and 72U are mixed is used as the excitation light source 70 and arranged in the front-rear direction of the fluorescent wheel 71. The phosphor may be irradiated with excitation light.

  When the excitation light source 70 is disposed only on the light exit surface side of the rotating plate, as shown in FIG. 9, the rotating plate base 130 is not formed of a transparent material such as a glass base or a transparent resin base, but a copper plate It may be formed of a heat transfer member such as. At this time, the phosphor layer 131 is attached to the disk-shaped base material 130 in the same manner as described above, and the excitation light source 70 is disposed only on the emission surface side to which the phosphor layer 131 is attached. A reflective layer 138 is formed on the entire surface to reflect each color light generated by the excitation light and the phosphor by silver deposition or the like.

  As a result, the excitation light emitted from the excitation light source 70 is absorbed by the phosphor of the phosphor layer 131, the wavelength band light of each color is generated by the phosphor, and the color light emitted from the phosphor is guided. The light can be sequentially incident on the optical device 75. The excitation light transmitted through the phosphor layer 131 and emitted toward the substrate 130 is reflected by the reflecting layer 138 and is absorbed again by the phosphor layer 131, and is generated by the phosphor and is emitted toward the substrate 130. Each emitted color light can also be reflected by the reflective layer 138 and incident on the light guide device 75.

  As described above, the excitation light source 70 may be arranged only on the emission surface side of the fluorescent wheel 71, and the optical axis of the excitation light source 70 is not necessarily arranged so as to be parallel to the rotation axis of the fluorescent wheel 71. I don't need it. Therefore, since a plurality of excitation light sources 70 can be employed and the degree of freedom of arrangement can be given, the amount of light can be increased and the size can be reduced easily. Further, by using a heat transfer member such as a copper plate as the base material 130, heat can be distributed to the entire heat transfer member to effectively dissipate heat.

  The present invention is not limited to the above-described embodiments, and can be freely changed and improved without departing from the gist of the invention. For example, the segment region in which the phosphor layer 131 is disposed is not limited to the fan shape as shown in the drawings, and may have other shapes such as an oval having the rotation circumferential direction as a major axis.

  The base material 130 made of a transparent material is coated with the dichroic layer 134 on the surface on which the phosphor layer 131 is disposed as described above, and on the side on which the phosphor layer 131 is disposed. Is not limited to the case where the non-reflective coating layer 133 is coated on the opposite surface, and conversely, the non-reflective coating layer 133 is coated on the surface on which the phosphor layer 131 is disposed, A dichroic layer 134 may be coated on the surface. As a result, the light emitted from the phosphor layer 131 to the substrate 130 side can be reflected by the dichroic layer 134 toward the light guide device 75 side, and the amount of light incident on the light guide device 75 can be increased. The utilization efficiency of the excitation light emitted from 70 can be improved.

1 is a perspective view showing an external appearance of a projector according to an embodiment of the invention. FIG. 3 is a diagram illustrating a functional circuit block of the projector according to the embodiment of the invention. FIG. 2 is a plan view of the projector according to the embodiment of the present invention with the top plate removed. The perspective view which shows the external appearance of the light source device which concerns on the Example of this invention. The front sectional view of the light source device concerning the example of the present invention. The top view of the light source device which concerns on the Example of this invention. The front sectional view of the light source device concerning the example of the present invention. The front sectional view of the light source device concerning the example of the present invention. The front sectional view of the light source device concerning the example of the present invention.

Explanation of symbols

10 Projector 11 Top plate
12 Front plate 13 Back plate
14 Right side plate 15 Left side plate
17 Exhaust hole 18 Intake hole
19 Lens cover 20 Various terminals
21 I / O connector 22 I / O interface
23 Image converter 24 Display encoder
25 Video RAM 26 Display driver
31 Image compression / decompression unit 32 Memory card
35 Ir receiver 36 Ir processor
37 Key / Indicator section 38 Control section
41 Power supply control circuit 43 Cooling fan drive control circuit
45 Lens motor 47 Audio processor
48 Speaker 51 Display element
53 Display element heat sink 61 Light source side optical system
62 Projection-side optical system 63 Light source device
70 Excitation light source 71 Fluorescent wheel
72 Light source 72B Blue light source
72U Ultraviolet light source 73 Wheel motor
74 Reflection mirror 75 Light guide device
77 Optical unit block 78 Illumination side block
79 Image generation block 80 Projection side block
83 Condensing lens group 84 Irradiation mirror
86 Optical system control board 93 Fixed lens group
97 Movable lens group 101 Power supply circuit block for light source
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 Base material
131 phosphor layer 131R red phosphor layer
131G green phosphor layer 131B blue phosphor layer
132 Excitation light reflection layer 132B Blue excitation light reflection layer
132U UV excitation light reflecting layer 133 Non-reflective coating layer
134 Dichroic layer 136 Incident mask
137 Auxiliary substrate 138 Reflective layer
139 Excitation light condensing lens 141 First area
142 Second area 143 Third area

Claims (9)

A rotary plate having a plurality of segment regions in which a layer of a phosphor that receives excitation light and emits light of a predetermined wavelength band is disposed on a circular base material capable of rotation control,
An excitation light source including two or more light source bodies that emit excitation light of a predetermined wavelength band, and capable of emitting at least two different wavelength band lights; and
Two or more types of phosphor layers are disposed on the rotating plate,
The light source device is characterized in that the excitation light source is turned on or off in conjunction with rotation of the base material so that each of the light source bodies emits excitation light only to a corresponding phosphor layer.   The light source device according to claim 1, wherein the base material is formed of a glass base material or a transparent resin base material.   The base material has a dichroic layer that transmits the excitation light and reflects the wavelength band light emitted from the phosphor on the surface on which the phosphor layer is disposed. The light source device according to claim 2.   4. The light source device according to claim 2, wherein the base has a non-reflective coating layer on a surface opposite to a side on which the phosphor layer is disposed. 5. Auxiliary base material that can be rotated and synchronized with the base material as coaxial with the base material is arranged,
In the auxiliary base material, an excitation light reflecting layer that reflects the excitation light on the surface on the base material side and transmits the wavelength band light emitted from the phosphor is formed corresponding to each segment region of the base material. The light source device according to claim 2, wherein the light source device is a light source device.   The light source device according to claim 1, wherein the base material is formed of a heat transfer member, and a reflective layer is formed on a surface on which the phosphor layer is disposed.   7. The light source body according to claim 1, wherein at least one of the plurality of light source bodies emits a blue wavelength band light, and the other light source bodies emit a wavelength band light in an ultraviolet region. The light source device according to any one of the above.   The base material includes a segment region in which a phosphor layer emitting red wavelength band light is disposed, a segment region in which a phosphor layer emitting green wavelength band light is disposed, and a blue wavelength band light. A segment region in which a phosphor layer emitting light is disposed, and at least one of the light source bodies emits blue wavelength band light to the phosphor layer emitting red and green wavelength band light. 8. The light source body according to claim 1, wherein at least one of the light source bodies irradiates an ultraviolet wavelength band light to a phosphor layer that emits the blue wavelength band light. The light source device according to 1. A light source device, a display element, a cooling fan, a light source side optical system that guides light from the light source device to the display element, and a projection side optical system that projects an image emitted from the display element onto a screen; A projector control means for controlling the light source device and 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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