JP2013007966A - Image display apparatus - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an image display apparatus with a laser light source device capable of enhancing heat radiation performance and miniaturization thereof.SOLUTION: A green laser light source device 22, which generates green light by converting wavelength of infrared light, and which generates a heat value larger than that from other laser light source devices 23 and 24, is provided with a heat sink 85. The heat sink is formed including a cylindrical portion 85a and an L-shaped portion 85b to receive cooling air with a vertical wall 87b of the L-shaped portion and guides the air to the cylindrical portion to thereby obtain a large heat releasing effect and the cooling performance of a heat radiation member is increased. Accordingly, following constitution is possible; that is, for example, a heat radiation member is provided to a laser light source device of red, green or blue, which generates the largest heat amount, and cooling air is fed to the other laser light source devices. Since the cooling air is guided to flow through the cylindrical portion, unlike a heat radiation member provided with fins, since no protrusion is formed, the constitution is easily miniaturized.

Description

  The present invention relates to an image display device in which a heat radiating member is provided in a laser light source device.

  2. Description of the Related Art In recent years, a technique that uses a semiconductor laser as a light source of a projection-type image display device that projects a screen on a screen has attracted attention. This semiconductor laser has better color reproducibility, instantaneous lighting, longer life, and higher power consumption compared to mercury lamps that have been widely used in image display devices. There are various advantages such as the ability to reduce the size and the ease of miniaturization.

  In addition, in an image display device using a semiconductor laser, in order to form a color image, three laser light source devices of red, green and blue and a spatial light modulation element made up of one liquid crystal display element are used. A technique using a time-division display method (field sequential method) in which laser beams of respective colors emitted from a light source device are sequentially incident on a spatial light modulator is known (see Patent Document 1). In this time division display method, each color image projected on the screen is recognized as a color image by a visual afterimage effect, and only one spatial light modulation element is required. Convenient for planning.

JP 2007-316393 A

  As each of the red and blue laser light source devices, a semiconductor laser configured with a so-called CAN package in which a semiconductor laser that outputs laser light is arranged can be used, but a green laser light source device is a semiconductor that outputs pure green laser light. Since it is difficult to mass-produce lasers, for example, a fixed laser element that outputs infrared laser light and a wavelength conversion element that converts the wavelength of the infrared laser light and outputs half-wave laser light that becomes green laser light are provided. Some of them are used to output green laser light.

  Since the green laser light source device having such a configuration generates green light by wavelength conversion from infrared light as described above, it generates a larger amount of heat than other red and blue semiconductor lasers. Therefore, it is conceivable to provide a heat radiating member in the green laser light source device to enhance the heat radiation property. Arise.

  The present invention has been devised to solve such problems of the prior art, and its main object is to provide an image display device that can improve the heat dissipation of the laser light source device and can be miniaturized. It is in.

  An image display device of the present invention includes a first laser light source device that outputs one of red, green, and blue color laser beams, and a second laser light source device that outputs the other one of the color laser beams. A third laser light source device that outputs the remaining one of the laser light beams of each color, and a cooling device that blows cooling air that cools the laser light source devices, and radiates heat to the first laser light source device. A member is provided, and the heat dissipating member extends from the tubular portion to receive the cooling air blown from the cooling device and guide the cooling air to the tubular portion. It is set as the structure which has a wall part integrally.

  According to the present invention, the tubular portion that passes the cooling air and the wall portion that guides the cooling air to the tubular portion are integrally provided on the heat dissipation member that blows the cooling air from the cooling fan that cools the laser light source device. Therefore, the cooling performance of the heat radiating member is improved. For example, among the red, green and blue laser light source devices, the heat radiating member is provided in the one having the largest heat generation amount, and cooling air is blown to the other laser light source devices. In addition, by adopting a shape that allows cooling air to pass through the cylindrical portion, there is no protruding portion unlike the heat dissipating member provided with the fins, and therefore, compactization is easy.

The perspective view which shows the example which incorporated the image display apparatus 1 by this invention in the portable information processing apparatus 2. FIG. FIG. 3 is an exploded perspective view of the optical engine unit 13. FIG. 3 is a schematic configuration diagram of an optical engine unit 21 built in the optical engine unit 13. 2 is a functional block diagram of the image display device 1. FIG. The figure which shows the waveform of the electric current applied to the semiconductor laser of each laser light source apparatus 22-24. The figure which shows the relationship between the use temperature T of each laser light source apparatus 22-24, and the optical output P. FIG. (A) is a figure which shows the change condition according to the temperature of the light quantity output from a semiconductor laser, (b) is a figure which shows the change condition according to the temperature of the drive current applied to a semiconductor laser. The top view of the image display apparatus of a state which removed the top plate. FIG. 6 is a flowchart showing a procedure for controlling the current of the semiconductor laser 50 of the blue laser light source device 24. The figure which shows the temperature coefficient table for calculating | requiring the largest electric current value I2. The exploded assembly perspective view of the red laser light source device 23 and the windshield cover 81. FIG. The perspective view which attached the windshield cover 81 to the red laser light source device 23. FIG. (A) is a front view of the windshield cover 81 in the state attached to the red laser light source apparatus 23, (b) is sectional drawing seen along the arrow XIIIb-XIIIb line of (a), (c). Sectional drawing seen along the arrow XIIIc-XIIIc line | wire of (a). The exploded assembly perspective view of the green laser light source device 22 and the heat sink 85. FIG. The perspective view which attached the heat sink 85 to the green laser light source apparatus 22. FIG. Sectional drawing of the cylindrical part 85b of the heat sink 85. FIG.

  A first invention made to solve the above-described problems is a first laser light source device that outputs one of red, green, and blue color laser beams, and another one of the laser beams of each color. A second laser light source device; a third laser light source device that outputs the remaining one of the laser light beams of each color; and a cooling device that blows cooling air that cools the laser light source devices. The laser light source device is provided with a heat radiating member, and the heat radiating member receives the cooling air blown from the cooling device and guides the cooling air to the cylindrical portion. And a wall portion extending from the shape portion.

  According to this, the cylindrical part through which the cooling air passes and the wall part that guides the cooling air to the cylindrical part are integrally provided on the heat radiating member that blows the cooling air from the cooling fan that cools the laser light source device The cooling performance of the heat radiating member is improved, for example, a structure in which a heat radiating member is provided in the red, green and blue laser light source devices having the largest heat generation amount and cooling air is blown to the other laser light source devices. In addition, by adopting a shape that allows cooling air to pass through the cylindrical portion, there is no projecting portion unlike the heat dissipating member provided with the fins, so that compactness is easy.

  According to a second aspect of the present invention, in the first aspect, the cylindrical portion has an axial length that is substantially the same length as the first laser light source device, and the wall portion is the first portion. The length is formed so as to protrude from the laser light source device.

  According to this, when a heat radiating member is attached to the first laser light source device, the cooling air can be received by the wall portion protruding from the first laser light source device, and the received cooling air flows along the wall portion. Thus, it can be suitably guided toward the cylindrical portion.

  According to a third aspect of the present invention, in the first or second aspect of the invention, the second or third laser light source device is disposed on the downstream side of the cooling air of the heat radiating member.

  According to this, the structure in which the cooling air is passed through the cylindrical portion of the heat radiating member causes a flow of the cooling air on the downstream side of the cylindrical portion. Therefore, the ventilation to the laser light source device provided on the downstream side can be stabilized and the cooling performance can be improved.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings.

  FIG. 1 is a perspective view showing an example in which an image display device 1 according to the present invention is built in a portable information processing device 2. The portable information processing device 2 includes a main body 3 in which a control board (not shown) on which a CPU, a memory, and the like are mounted, and a display unit 4 including a liquid crystal panel. The display unit 4 is connected to the hinge unit 5 so that portability is enhanced by folding the main body unit 3 and the display unit 4. As an example of the portable information processing apparatus 2, a commercially available notebook personal computer can be applied.

  A keyboard 6 and a touch pad 7 are provided on the upper surface 8 a of the housing 8 of the main body 3. Also, on the back side of the keyboard 6 in the housing 8 of the main body 3, peripheral devices such as an optical disk device (one that reproduces or records and reproduces information on an optical disk such as a Blu-ray disc, DVD, and CD) are replaced. An accommodation space that can be accommodated, that is, a so-called drive bay is formed, and the image display device 1 is attached to the drive bay.

  The image display device 1 includes a housing 11 and a movable body 12 provided so as to be able to be taken in and out of the housing 11. When the image display device 1 is not used, the movable body 12 is located inside the housing 11. Stored in The movable body 12 accommodates an optical engine unit (projection unit) 13 in which optical components for projecting laser light on a screen 15 are accommodated, and a substrate for controlling the optical components in the optical engine unit 13. And a control unit 14 having a drive control circuit.

  The optical engine unit 13 is supported by the control unit 14 so as to be pivotable in the vertical direction via the hinge portion 12a, and laser light is emitted to the end of the optical engine unit 13 opposite to the hinge portion 12a. The exit window 16 is provided, the optical engine unit 13 is rotated, and the projection angle of the laser light from the optical engine unit 13 is adjusted, so that the laser light is appropriately projected on the screen 15, and the screen An image 17 can be displayed on the screen 15.

  FIG. 2 is an exploded perspective view of the optical engine unit 13. As shown in the figure, a rectangular plate-like bottom plate 101, a frame 102 corresponding to the outer peripheral portion of the bottom plate 101, and a top plate 103 that covers the bottom plate 101 and the upper surface of the frame 102 constitute a casing. In addition, a unit main body 104 and a cooling fan 105 constituting an optical engine unit are accommodated.

  FIG. 3 is a schematic configuration diagram of the optical engine unit 21 built in the optical engine unit 13. The optical engine unit 21 includes a green laser light source device 22 that outputs green laser light, a red laser light source device 23 that outputs red laser light, a blue laser light source device 24 that outputs blue laser light, and a video signal. The spatial light modulation element 25 that modulates the laser light from each of the laser light source devices 22 to 24 and the laser light from each of the laser light source devices 22 to 24 are reflected and irradiated to the spatial light modulation element 25 and the spatial light modulation. A polarized beam splitter 26 that transmits the modulated laser light emitted from the element 25, a relay optical system 27 that guides the laser light emitted from each of the laser light source devices 22 to 24 to the polarized beam splitter 26, and the polarized beam splitter 26. And a projection optical device 28 having a lens group for projecting the modulated laser beam onto the screen. Each of these components is assembled to the casing 41 of the unit main body 104.

  The optical engine unit 21 displays a color image by a so-called field sequential method. Laser beams of each color are sequentially output from the laser light source devices 22 to 24 in a time-sharing manner, and an image by the laser beam of each color is visually displayed. It is recognized as a color image by the afterimage effect.

  The relay optical system 27 includes collimator lenses 31 to 33 that convert the laser beams of the respective colors emitted from the laser light source devices 22 to 24 into parallel beams, and the laser beams of the respective colors that have passed through the collimator lenses 31 to 33 in a predetermined direction. First and second dichroic mirrors 34 and 35 guided to, a diffusion plate 36 for diffusing the laser light guided by the dichroic mirrors 34 and 35, and a field lens for converting the laser light that has passed through the diffusion plate 36 into a convergent laser 37.

  Assuming that the side from which the laser light is emitted from the projection optical device 28 toward the screen is the front side, a holder 46 is attached to the outer surface of the front wall portion 43 of the housing 41, and the electric circuit of the blue laser light source device 24 is attached by the holder 46. Parts are held. Note that the holder 46 also serves as a casing of the blue laser light source device 24. Blue laser light is emitted backward from the blue laser light source device 24 in the housing 41, and the optical axis of the green laser light and the optical axis of the red laser light are orthogonal to the optical axis of the blue laser light. As described above, the green laser light source device 22 and the red laser light source device 23 are provided.

  The green laser light source device 22 is provided on a plate-like attachment portion 42 that extends from a corner portion of a front side wall 43 of the housing 41 and a side wall 44 orthogonal to the front side wall 43 toward the side. A holder 45 is attached to the outer surface of the side wall 44 at a position behind the green laser light source device 22, and the electric circuit components of the red laser light source device 23 are held by the holder 45. Note that the holder 45 also serves as a casing of the red laser light source device 23.

  With such a layout, the green laser light and the red laser light are emitted from the green laser light source device 22 and the red laser light source device 23 in directions orthogonal to the blue laser light, respectively, and the blue laser light, the red laser light, and the green laser light are emitted. However, the two dichroic mirrors 34 and 35 are guided to the same optical path. That is, the blue laser light and the green laser light are guided to the same optical path by the first dichroic mirror 34, and the blue laser light, the green laser light, and the red laser light are guided to the same optical path by the second dichroic mirror 35.

  The first and second dichroic mirrors 34 and 35 are formed with films for transmitting and reflecting laser light of a predetermined wavelength on the surface, and the first dichroic mirror 34 transmits blue laser light. At the same time, it is inclined by 45 degrees with respect to both optical paths at the intersection of the blue laser light and the green laser light so as to reflect the green laser light. The second dichroic mirror 35 is inclined 45 degrees with respect to both optical paths at the intersection of the blue laser light and the red laser light so as to transmit the red laser light and reflect the blue laser light and the green laser light. It is arranged.

  Each optical member is supported by the casing 41 via a positioning and fixing member (not shown). The casing 41 functions as a radiator that dissipates the heat generated in each of the laser light source devices 22 to 24, and is formed of a material having high thermal conductivity such as aluminum or copper.

  The red laser light source device 23 and the blue laser light source device 24 are configured by a so-called CAN package, and the semiconductor lasers 49 and 50 that output laser light are light beams on the central axis of the can-shaped exterior portion while being supported by the stem. A laser beam is emitted from a glass window provided in the opening of the exterior portion. The red laser light source device 23 and the blue laser light source device 24 are fixed to the holders 45 and 46 by, for example, press-fitting into the mounting holes 47 and 48 formed in the holders 45 and 46. A part of the heat generated by the laser chips of the blue laser light source device 24 and the red laser light source device 23 is transmitted to the housing 41 through the holders 45 and 46 to be radiated. Each holder 45, 46 is made of a material having high thermal conductivity such as aluminum or copper.

  The green laser light source device 22 includes a semiconductor laser 51 that outputs excitation laser light, a FAC (Fast-Axis Collimator) lens 52 that is a condensing lens that condenses the excitation laser light output from the semiconductor laser 51, and a rod. A lens 53, a solid-state laser element 54 that outputs a basic laser beam (infrared laser beam) when excited by an excitation laser beam, and converts a wavelength of the basic laser beam to output a half-wavelength laser beam (green laser beam) A wavelength conversion element 55, a concave mirror 56 that constitutes a resonator together with the solid-state laser element 54, a glass cover 57 that prevents leakage of excitation laser light and fundamental wavelength laser light, and a base 58 that supports each part, And a cover body 59 that covers each part.

  The green laser light source device 22 is fixed by attaching the base 58 to the mounting portion 42, and has a required width (for example, 0.5 mm or less) between the green laser light source device 22 and the side wall 44 of the housing 41. It arrange | positions so that it may have a clearance gap. This gap makes it difficult for the heat of the green laser light source device 22 to be transmitted to the red laser light source device 23 through the side wall 44, and the temperature rise of the red laser light source device 23 is suppressed, resulting in poor temperature characteristics (light output at high temperature). The red laser light source device 23 can be stably operated on the low temperature side. Further, in order to secure a required optical axis adjustment allowance (for example, about 0.3 mm) of the red laser light source device 23, a required width (for example, 0.3 mm or more) is provided between the green laser light source device 22 and the red laser light source device 23. ) Is provided.

  FIG. 4 is a block diagram illustrating functions of the image display device 1. The optical engine unit 21 provided in the optical engine unit 13 includes, in addition to the laser light source devices 22 to 24 and the light modulation element 25 for each color, a photosensor 61 that detects the amount of light incident on the light modulation element 25, and a red laser. And a temperature sensor 62 that detects the temperature of the light source device 23.

  The control unit 14 includes a laser light source control unit 71 that controls the laser light source devices 22 to 24 for each color, and an image display control that controls the spatial light modulator 25 based on the video signal input from the portable information processing device 2. A power supply unit 73 that supplies power supplied from the portable information processing apparatus 2 to the laser light source control unit 71 and the image display control unit 72, and a main control unit 74 that comprehensively controls each unit. doing.

  Based on the image display signal input from the image display control unit 72, the main control unit 74 generates a lighting signal as a control signal for controlling the lighting of the laser light source devices 22 to 24 of the respective colors and supplies the laser light source control unit 71 with the lighting signal. Output. The lighting signals are red, green and blue signals for lighting the red, green and blue laser light source devices 22 to 24, respectively.

  The laser light source control unit 71 sequentially applies drive currents (Ig, Ir, and Ib) to the semiconductor lasers of the laser light source devices 22 to 24 on the basis of the lighting signal input from the main control unit 74, thereby The light source devices 22 to 24 are turned on in a time division manner. At this time, each drive current (Ig, Ir, and Ib) is controlled so as not to exceed an upper limit value determined according to the temperature indicated by the output signal of the temperature sensor 62. This will be described in detail later.

  The image display control unit 72 generates control signals (reference voltage signal and pixel voltage signal) for controlling the operation of the spatial light modulator 25 based on the video signal input from the portable information processing device 2, and A control signal is output to the spatial light modulator 25.

  The spatial light modulation element 25 is a reflection type liquid crystal display element, so-called LCOS (Liquid Crystal On Silicon), and the laser beam transmitted through the liquid crystal layer formed on the silicon substrate is reflected by the reflection layer on the silicon substrate and emitted. It is the thing of the structure to make it. In this spatial light modulator 25, the output (luminance) of the laser light increases or decreases in accordance with the control signal input from the image display control unit 72, and the lasers of the respective colors input in a time-sharing manner from the laser light source devices 22-24. The required hue can be displayed by increasing or decreasing the light output.

  The control unit 14 is provided with an operation instruction unit 75, and the operation instruction unit 75 is provided with operation buttons for brightness adjustment. The operation instruction unit 75 is also provided with an operation button for power supply, an operation button for correcting trapezoidal distortion, and the like.

  As shown in FIG. 5, in this embodiment, a drive current is sequentially applied to the semiconductor lasers 49 to 51 of the red, green, and blue laser light source devices 22 to 24 to time-divide the laser light source devices 22 to 24. Light up. In particular, here, one frame is divided into four lighting sections (subframes), and each laser light source device 22 to 24 is lit in the order of red, green, blue, and green in one frame.

  FIG. 6 shows the relationship between the operating temperature T and the light output P of each laser light source device 22-24. The temperature T0 may be a lower limit value of the usable range in the design of the image display apparatus 1. As shown in the figure, the light output P of the green laser light source device 22 gradually increases as the temperature rises from the low temperature side to the temperature T1, and gradually decreases as the temperature rises from the temperature T1 to the high temperature side. On the other hand, the light output P of the red laser light source device 23 is high on the low temperature side, decreases as the temperature increases, and further decreases as the temperature increases. The light output P of the blue laser light source device 24 is also high on the low temperature side, decreases as the temperature rises, and further decreases as the temperature increases, but the reduction rate is smaller than that of the red laser light source device 23.

  The level of the light output P that has no problem in use in each of the laser light source devices 22 to 24 having such characteristics is G in the drawing for the green laser light source device 22, and R in the drawing for the red laser light source device 23. The blue laser light source device 24 is B in the figure. The temperature range in which the light output P is higher than each of the levels G, R, and B is the use range of each laser light source device 22 to 24, and the upper limit value of the use temperature T of the red laser light source device 23 is T2 in the figure, and green. The upper limit value of the use temperature T of the laser light source device 22 and the blue laser light source device 24 is T3 in the figure.

  FIG. 7 is a diagram showing waveforms of drive currents applied to the semiconductor lasers of the laser light source devices 22 to 24. FIG. 7A is a diagram illustrating a change state according to the temperature of the light amount output from the semiconductor laser. FIG. 7B is a diagram showing a change state according to the temperature of the drive current applied to the semiconductor laser.

  In the present image display device 1, the amount of light is limited so as to conform to the class 1 of IEC 60825-1 which is a safety standard related to laser products. In the embodiment, the amount of blue laser light is limited. Note that white balance adjustment is performed after the light amount adjustment process for limiting the amount of blue laser light, and the amounts of red and green laser light are also adjusted as necessary.

  The amount of light of the blue laser light source device 24 is adjusted in the output adjustment process. In this output adjustment process, the photosensor 61 detects the light amount of the blue laser light, and the drive current that becomes the maximum within the range in which the output light amount does not exceed the light amount stipulated in the safety standard is the reference current value I0 (FIG. 7B). Set as)). The same output adjustment can be performed for the green and red laser light source devices 22 and 23.

  As shown in FIG. 7A, the semiconductor laser 50 of the blue laser light source device 24 has a characteristic that the amount of light output increases as the temperature decreases even if the drive current is the same. For this reason, if the temperature of the semiconductor laser 50 in the use state is lower than the temperature in the output adjustment process (for example, 25 degrees, hereinafter referred to as the adjustment temperature), the amount of light output may deviate from the safety standard.

  Therefore, as shown in FIG. 7B, when the temperature is lower than the adjustment temperature, the drive current applied to the semiconductor laser 50 of the blue laser light source device 24 is set to the reference current value I0, that is, the amount of light output at the adjustment temperature. It is necessary to limit the current lower than the maximum current value that satisfies the safety standard. Further, the drive current may be limited so that the difference from the reference current value I0 gradually increases as the temperature of the semiconductor laser 50 decreases. Thereby, even if the temperature of the semiconductor laser 50 of the blue laser light source device 24 is lowered, it is possible to prevent the output light quantity from deviating from the safety standard. Note that, at a temperature exceeding the adjustment temperature, the amount of light output is reduced as the temperature rises, so the drive current applied to the semiconductor laser 50 remains at the reference current value I0.

  Further, the semiconductor laser 50 of the blue laser light source device 24 has a light amount variation due to individual differences, and this light amount variation increases as the temperature of the semiconductor laser 50 decreases. Therefore, in the present embodiment, as shown in FIG. 7A, as the temperature of the semiconductor laser 50 decreases, the difference between the output light amount and the target light amount that satisfies the safety standard gradually increases. However, the drive current is limited. As a result, it is possible to reliably prevent the light quantity from deviating from the safety standard due to variations in the light quantity due to individual differences.

  In the present invention, the reference temperature for controlling the drive current of the blue laser light source device 24 is determined by the temperature of the red laser light source device 23. As shown in FIG. 62 is attached.

  As described with reference to FIG. 6 above, changes in the light outputs with respect to the temperatures of the red laser light source device 23 and the blue laser light source device 24 show the same tendency, and therefore the detected temperature t of the red laser light source device 23 is detected. Can be used to determine the light output Pb of the blue laser light source device 24 (Pb = f (t)). For example, it can be obtained by using a quadratic function of the detected temperature t or making a map.

  In the small and high-luminance image display device 1 as in the present embodiment, there are layout restrictions and it is difficult to attach a plurality of temperature sensors. On the other hand, as described above, the temperature of the blue laser light source device 24 can be controlled simply by attaching the temperature sensor 62 to the red laser light source device 23, and it is not necessary to attach a temperature sensor to the blue laser light source device 24, thereby ensuring compactness. Is done.

  As described above, since the red laser light source device 23 has a problem that the decrease rate of the light output increases as the temperature increases, the temperature upper limit value T2 for securing the rated light output is blue as shown in FIG. The temperature is lower than the upper temperature limit T3 for ensuring the rated light output of the laser light source device 24. Therefore, when the temperature of the red laser light source device 23, which is more severely restricted on the high temperature side, is detected and the blue laser light source device 24 is controlled based on the detected temperature, the temperature of the blue laser light source device 24 exceeds the upper limit value T3. The blue laser light source device 24 can be controlled only by providing the temperature sensor 62 in the red laser light source device 23, and the number of temperature sensors attached can be minimized.

  Further, for the red laser light source device 23, from the above temperature-light output characteristics, the cooling performance is enhanced in order to control at the temperature upper limit value T2 or less. In the illustrated example, as shown in FIGS. 3 and 10, the cooling fan 105 is disposed in a space surrounded by the green laser light source device 22 and the red laser light source device 23. As a result, the cooling fan can be attached using the space generated by the green laser light source device 22 and the red laser light source device 23 that have a difference in the amount of protrusion from the left side wall portion 44 of the housing 41.

  Note that the temperature used for controlling the green laser light source device 22 is also determined using the detection value of the temperature sensor 62. The change of the light output with respect to the temperature of the green laser light source device 22 does not change as much as the red laser light source device 23 as described above, and is not a characteristic that the light output increases on the low temperature side. The temperature control reference value may be a value obtained by a simple expression such as applying a coefficient as it is or a detection value of the temperature sensor 62 attached to the sensor.

  On the other hand, since each laser light source device 22 to 24 tends to reduce the light output on the high temperature side, it is necessary to suppress the temperature rise in order to ensure the rated output, and the cooling fan 105 described above is provided for cooling. Yes. In order to reduce the size of the image display device 1, it is required to reduce the number of built-in components as much as possible. Therefore, only one cooling fan 105 is provided, and the flow of the cooling air is directed to each of the laser light source devices 22-24. I have to.

  In FIG. 8, the casing of the cooling fan 105 is formed in a rectangular shape in plan view. The cooling fan 105 may be a fan that sucks in from the back side (bottom plate 101 side) in the drawing and discharges it from the side surface of the cooling fan 105.

  The red laser light source device 23 is blown as indicated by an arrow W1 in FIG. 8, and the green laser light source device 22 is blown as indicated by an arrow W2 in the drawing. The cooling air W2 that has passed through the green laser light source device 22 changes its direction toward the blue laser light source device 24 and flows as indicated by an arrow W3 in the figure.

  By disposing the cooling fan 105 in this manner, the light output is greatly reduced on the high temperature side, so that the cooling air is blown from the nearest to the red laser light source device 23 that needs to prevent the high temperature preferentially. The cooling effect on the red laser light source device 23 can be increased.

  FIG. 8 shows a state in which the top plate 103 is removed. In the illustrated example, the attachment portion 42 that supports the green laser light source device 22 extends in parallel with the opposing wall portion 102 a of the frame body 102. The green laser light source device 22 is disposed on the side opposite to the wall portion 102 a of the mounting portion 42. By assembling the top plate 103, a space surrounded by the frame body 102 and sandwiched between the bottom plate 101 and the top plate 103 is formed, so that a gap generated between the frame body 102 and the unit main body 104 is formed. Thus, a flow path can be formed. Thereby, the flow W2 of the cooling air blown to the green laser light source device 22 passes from the rear (left side in FIG. 8) portion to the side (front side in FIG. 8) portion of the green laser light source device 22, It can flow as shown by the broken arrow W3.

  The wall 102a is continuously formed up to the front of the projection optical device 28 beyond the blue laser light source device 24 on the right side of FIG. By the end of the wall portion 102a, an opening 102b for passing an optical path projected by the projection optical device 28 is formed. Further, as shown in FIG. 2, the wall portion 102a is provided with an exhaust port 102c in which a plurality of openings are arranged, and the bottom plate 101 is also evacuated to a cut and raised piece cut and raised so as to overlap the wall portion 102a. An exhaust port 101a in which a plurality of openings communicating with the port 102c are arranged is provided. The blue laser light source device 24 is provided on the flow path through which the cooling air W3 flows. The cooling air W3 is shown in W4 of FIGS. 2 and 8 from both exhaust ports 101a and 102c after the blue laser light source device 24 is cooled. It is discharged outward as is.

  FIG. 9 is a flowchart showing a procedure of current control of the semiconductor laser 50 of the blue laser light source device 24. Here, the drive current applied to the semiconductor laser 50 of the blue laser light source device 24 is controlled so as not to exceed the upper limit value (maximum current value I2) determined according to the temperature indicated by the output signal of the temperature sensor 62.

  Specifically, first, a control current value I1 corresponding to the target light amount is calculated (ST101). The target light amount is set according to the brightness specified by operating the brightness adjustment operation button provided in the operation instruction section 75 (see FIG. 3). Next, the temperature is estimated using the function or the like based on the output signal of the temperature sensor 62 (ST102), and the maximum current value I2 corresponding to the temperature is calculated (ST103).

  Then, the control current value I1 is compared with the maximum current value I2 (ST104), and if the control current value I1 is equal to or less than the maximum current value I2, the semiconductor laser 50 is driven with the control current value I1 (ST105). If I1 is larger than the maximum current value I2, the semiconductor laser 50 is driven with the maximum current value I2 (ST106).

Here, the control current value I1 is obtained by the following equation from the threshold current Ith of the semiconductor laser 50, the target light amount L0, and a constant E representing the light emission efficiency of the semiconductor laser 50.
I1 = L0 / E + Ith

FIG. 10 is a diagram showing a temperature coefficient table for obtaining the maximum current value I2. In this temperature coefficient table, the temperature coefficient K is determined for each predetermined temperature region, and the temperature coefficient K corresponding to the measured temperature is output at the reference current value I0, that is, the adjusted temperature, as in the following equation. The maximum current value I2 is obtained by multiplying the maximum current value by which the light quantity satisfies the safety standard. In the temperature coefficient table, the temperature coefficient decreases as the temperature decreases, and the maximum current value I2 decreases as the temperature decreases.
I2 = I0 × K

  Note that the maximum current value I2 may be calculated by a mathematical formula using temperature as a parameter. It is also possible to directly use a table in which the maximum current value I2 is determined according to the temperature.

  In this way, the blue laser light source device 24 can be controlled. In addition, the blue laser light source device 24 is located farther from the cooling fan 104 than the red laser light source device 23 when viewed from the flow of the cooling air. However, as described above, there is little decrease in light output on the high temperature side. Insufficient cooling can be avoided.

  On the other hand, for the red laser light source device 23 that needs to suppress the temperature rise from the relationship between the temperature and the light output, the cooling fan 104 is arranged in the vicinity as described above and the cooling air is blown to increase the air volume. is doing. However, when the cooling air is blown also to the temperature sensor 62, the temperature sensor 62 itself is cooled, and the temperature gradient between the red laser light source device 23 and the temperature sensor 62 on the holder 45 in which it is stored. Will grow. As a result, the temperature sensor 62 cannot detect the accurate temperature of the red laser light source device 23.

  As shown in FIG. 11, the windbreak cover 81 is attached to the surface 45 a (the surface facing the flow of the cooling air W <b> 1) of the holder 45 of the red laser light source device 23. As shown in FIG. 12, the windshield cover 81 is integrally attached to the holder 45 using, for example, two screws 82. In the present embodiment, the windshield cover 81 is provided as a separate body so as to be attached to the holder 45, but may be formed integrally with the holder 45. In that case, an opening due to die cutting occurs, but this can be dealt with by making the opening direction a direction orthogonal to the direction in which the cooling air W1 flows.

  In the illustrated example, three pin terminals 23a protrude from the surface 45a of the holder 45, and one end 83a of a flexible cable 83 is soldered to the pin terminals 23a. A temperature sensor 62 is attached to the surface of one end 83 a of the flexible cable 83. The temperature sensor 62 may be a thermistor, for example. As a result, the temperature sensor 62 and the holder 45 of the red laser light source device 23 are insulated from each other by the interposition of the flexible cable 83, and the temperature sensor 62 is adhered to the surface 45a of the holder 45 by soldering with the pin terminal 23a. Increases nature. Further, the back surface of the soldered portion with the pin terminal 23a and the mounting portion of the temperature sensor 62 in the one end 83a of the flexible cable 83 is reinforced by a reinforcing member. The other end of the flexible cable 83 is connected to the control unit 14. In the flexible cable 83, wirings connected to the electrodes at both ends of the temperature sensor 62 and the three pin terminals 23a of the red laser light source device 23 are formed. Thus, the temperature sensor 62 and the red laser light source device 23 are connected to the control unit 14.

  By attaching the windbreak cover 81 to the holder 45 of the red laser light source device 23, one end 83a of the flexible cable 83 is sandwiched and fixed between the surface 45a of the holder 45 and the windbreak cover 81. As shown in FIG. 13 (a), the windbreak cover 81 is formed with an opening 81 a that surrounds the three pin terminals 23 a in an inserted state and a recessed portion 81 b that receives the temperature sensor 62. Has been. As shown in FIG. 13B, the recessed portion 81 b is formed in a hole shape having a bottom when viewed from the back side (temperature sensor 62 side) of the windshield cover 81.

  The holder 45 is formed with a pair of recesses 45b formed as shelves by dropping two corners at diagonal positions of the rectangular surface 45a as portions to be screwed to the housing 41 using screws 84. Yes. Further, as shown in FIG. 13C, recesses 81 d are formed at positions corresponding to the respective recesses 45 b of the windshield cover 81. The hole provided in the holder 45 for passing the screw 84 is formed to be larger than the diameter of the screw 84, and thereby the optical axis of the red laser light source device 23 can be adjusted two-dimensionally. On the other hand, the screw 82 is for fixing the windshield cover 81 to the holder 45, and is arranged at a diagonal position opposite to the screw 84.

  In the illustrated example, as shown in FIGS. 13A and 13C, a part of the inner peripheral wall in the hole shape of the recessed portion 81b is cut away, so that the recessed portion 81b and the recessed portion 81d are formed. Although it communicates, it is because it became difficult to ensure the thickness between the recessed part 81b and the recessed part 81d for compactness. The recessed portion 81b may have a shape that surrounds the entire circumference of the temperature sensor 62 even if there is a portion that partially communicates with the outside as described above. Is not to be excluded. However, when it is necessary to provide a part that communicates with the outside due to a design problem in this way, there are many components in which the opening direction of the communication part is orthogonal to the cooling air flow W1 (see FIG. 8). It is desirable to have. Alternatively, it is desirable that the communication portion has its opening direction oriented in the same direction as the rotation normal direction of the cooling fan 105 (see FIG. 8) facing it. As a result, the temperature sensor 62 is less likely to directly receive the cooling air blown from the cooling fan 105, so that the temperature sensor 62 can detect the temperature of the red laser light source device 23 more accurately.

  Since the wind shield cover 81 is formed and attached in this way, the flow of the cooling air W1 toward the red laser light source device 23 is blocked by the wind shield cover 81 as shown in FIG. The cooling air W1 is not directly blown on the surface. Further, since the recessed portion 81b is secured sufficiently wide with respect to the temperature sensor 62, the contact portion of the windshield cover 81 with the one end portion 83a of the flexible cable 83 is small, and the windshield cover 81 is cooled to be one end. The part 83a is also cooled, and the temperature detection by the temperature sensor 62 is not adversely affected. As a result, the temperature sensor 62 is not forcibly cooled by the cooling air W1, and can accurately detect the temperature of the red laser light source device 23.

  As described above, the cooling air W1 traveling toward the temperature sensor 62 is blocked by the wind shield cover 81, but a part thereof flows into the recess 81d and further flows through the side surface of the red laser light source device 23 through the recess 45b. The heat generated by the red laser light source device 23 is transmitted to the holder 45 and is transferred from the portion in contact with the holder 45 to the wind shield cover 81. However, since the wind shield cover 81 is cooled by the cooling air W1, the red laser light source device 23 Coolability can be ensured. In addition, although there exists a possibility that the air in the recessed part 81b which covers the temperature sensor 62 may be cooled in contact with the cooling air W1, it is only a part and does not cool the temperature sensor 62.

  On the other hand, as described above, the heat sink 85 is attached to the attachment portion 42 that supports the green laser light source device 24 with screws 86 as shown in FIGS. The heat sink 85 is located at a position adjacent to the blue laser light source device 24 from the rear side (left side in FIG. 8) of the green laser light source device 22 along the outer surface (front wall surface in FIG. 8) of the plate-like mounting portion 42. It is provided in a wide range. Further, the heat sink 85 includes a rectangular cylindrical cylindrical portion 85a provided so as to extend with the same length in the axial direction as the mounting portion 42, that is, the green laser light source device 22, and the green laser light source of the cylindrical portion 85a. An L-shaped portion formed by an outer wall portion 87a far from the device 22 and a portion along the bottom plate 101 has an L-shaped portion 85b formed extending from the cylindrical portion 85a to the rear of the green laser light source device 22. .

  Thus, since the heat sink 85 is provided, the heat generated in the green laser light source device 22 is transmitted to the heat sink 85 via the mounting portion 42. The temperature rise of 22 can be suppressed. As described above, since the green laser light source device 22 generates green light by converting the wavelength from infrared light, it generates a larger amount of heat than the other laser light source devices 23 and 24. On the other hand, since the heat sink 85 is provided, a great heat dissipation effect can be achieved.

  Further, as shown in FIG. 8, the cooling air W <b> 2 flows across the back of the green laser light source device 22 (left side in the drawing) and reaches the L-shaped portion 85 b of the heat sink 85, and the L-shaped portion. In 85b, the flow direction is changed to the cylindrical portion 85a side by the standing wall portion 87b as a wall portion extended from the outer wall portion 87a of the cylindrical portion 85a, and the cooling air W3 passes through the cylindrical portion 85a. As a result, the green laser light source device 22 is cooled by the cooling air W2, and the heat sink 85 is cooled by the cooling air W3 and the heat dissipation action of the heat sink 85 is promoted. Can be suppressed.

  The cooling air W3 passes through a flow path 88 having a rectangular cross-sectional space defined by the cylindrical portion 85a and extending along the longitudinal direction of the green laser light source device 22, and the blue laser light source It flows across the rear end (front side in the figure) of the device 24 and is discharged outwardly from both the exhaust ports 101a and 102c as indicated by W4 in FIGS. The blue laser light source device 24 is cooled by this flow.

  By the way, the cooling air flows so as to draw a curve when the direction is changed from the arrow W2 to W3 in FIG. In that portion, the flow passing near the rear end of the green laser light source device 22 flows on the inner peripheral side of the curve, and the flow passing through a place far from the green laser light source device 22 flows on the outer peripheral side of the curve. Therefore, in the cylindrical portion 85a of the heat sink 85, as shown in FIG. 16, the relatively low-temperature cooling air W3c flows on the side far from the green laser light source device 22, and the relatively high-temperature cooling air W3h is green laser. It becomes easy to flow on the side close to the light source device 22.

  By forming the rectangular cylindrical portion 85a as in the illustrated example, the low-temperature cooling air W3c comes into contact with the outer wall 87a far from the green laser light source device 22, and the heat sink by the cooling air W3. 85 cooling can be increased. Further, in the illustrated example, the standing wall portion 87b in the L-shaped portion 85a is formed continuously with the outer wall portion 87a of the cylindrical portion 85a, and the standing wall portion 87 of the L-shaped portion 85b is the portion where the cooling air W2 first comes into contact. Therefore, a wide heat transfer area for the low-temperature cooling air W3c is secured.

  In addition, the shape of the part extended from the cylindrical part 85a is not restricted to the L shape of this example of illustration. For example, as shown by a two-dot chain line in FIG. 14, the ceiling member 88 is assembled or formed into an integral U-shape, and the guide has an arcuate curved surface so as to guide the flow of wind to the heat sink 85. The member 89 may be assembled to the end portion of the L-shaped portion 85b. As a result, the flow of the cooling air W2 can be changed to the flow of the cooling air W3 with higher efficiency.

  The image display device according to the present invention can be configured such that a heat radiation member is provided in a laser light source device having the largest amount of heat generation, and cooling air is blown to the other laser light source devices, and the image display device is required to be downsized. Useful in.

DESCRIPTION OF SYMBOLS 1 Image display apparatus 2 Portable information processing apparatus 22 Green laser light source apparatus 23 Red laser light source apparatus 24 Blue laser light source apparatus 85 Heat sink 85a Cylindrical part 85b L-shaped part 87a Outer side wall part 87b Standing wall part

An image display device of the present invention includes a first laser light source device that outputs one of red, green, and blue color laser beams, and a second laser light source device that outputs the other one of the color laser beams. A third laser light source device that outputs the remaining one of the laser light beams of each color and a cooling device that blows cooling air that cools the laser light source devices, and radiates heat to the first laser light source device. A member is provided, and the heat dissipating member extends from the tubular portion to receive the cooling air blown from the cooling device and guide the cooling air to the tubular portion. The cooling air blown from the cooling device flows across the rear of the first laser light source device in the optical axis direction, and reaches the wall portion. Before positioned on the side of the optical axis direction of the first laser light source device A structure for changing the flow toward the tubular portion.

A first invention made to solve the above-described problems is a first laser light source device that outputs one of red, green, and blue color laser beams, and another one of the laser beams of each color. A second laser light source device; a third laser light source device that outputs the remaining one of the laser light beams of each color; and a cooling device that blows cooling air that cools the laser light source devices. The laser light source device is provided with a heat radiating member, and the heat radiating member receives the cooling air blown from the cooling device and guides the cooling air to the cylindrical portion. And the cooling air blown from the cooling device flows across the rear in the optical axis direction of the first laser light source device and reaches the wall portion. After that, the light of the first laser light source device by the wall portion A structure for changing the flow toward the cylindrical portion positioned in the direction of the side.

The cooling air W3 has a rectangular cross-sectional space defined by the cylindrical portion 85a and passes through a flow path extending along the longitudinal direction of the green laser light source device 22, and the blue laser light source device. 24 flows across the rear end portion (front side in the figure) and is discharged outward from both exhaust ports 101a and 102c as indicated by W4 in FIGS. The blue laser light source device 24 is cooled by this flow.

By forming the rectangular cylindrical portion 85a as in the illustrated example, the low-temperature cooling air W3c comes into contact with the outer wall 87a far from the green laser light source device 22, and the heat sink by the cooling air W3. 85 cooling can be increased. Further, in the illustrated example has the vertical wall 87b of L-shaped portion 85 b is formed continuously with the outer wall portion 87a of the cylindrical portion 85a, the vertical wall of the L-shaped portion 85b as a portion cooling air W2 is first in contact with 87 is provided, and a wide heat transfer area for the low-temperature cooling air W3c is secured.

Claims (3)

A first laser light source device that outputs one of the red, green, and blue color laser beams; a second laser light source device that outputs the other one of the color laser beams; A third laser light source device that outputs one; and a cooling device that blows cooling air that cools each of the laser light source devices,
A heat radiating member is provided in the first laser light source device,
The heat dissipating member integrally includes a cylindrical portion that passes the cooling air and a wall portion that extends from the cylindrical portion so as to receive the cooling air blown from the cooling device and guide the cooling air. An image display device comprising: The cylindrical portion has an axial length substantially the same length as the first laser light source device;
The image display device according to claim 1, wherein the wall portion is formed to have a length protruding from the first laser light source device.   3. The image display device according to claim 1, wherein the second or third laser light source device is disposed on a downstream side of the cooling air of the heat radiating member.

Images