JP5103144B2 - How to start up a projection display - Google Patents

Description

  The present invention relates to a projection-type image display apparatus that projects image light onto a screen to display an image on a screen. In particular, the present invention relates to a projection display apparatus including a semiconductor laser as a light source.

  In recent years, it has been proposed to use a high-power semiconductor laser as a light source in a projection display apparatus. On the other hand, when the temperature of the semiconductor laser rises, the output and the life of the semiconductor laser are reduced. Therefore, it is necessary to perform temperature control.

In order to solve the above problems, various apparatuses and methods have been proposed. For example, an image display that detects the temperature of the semiconductor laser and feeds back a drive current to the Peltier element according to a signal corresponding to a difference between the detected temperature and a predetermined temperature (for example, 25 ° C.) to feedback control the temperature of the semiconductor laser An apparatus is disclosed (see Patent Document 1).
JP 2004-356579 A

  However, in the conventional projection type video display device such as the above video display device, it is possible to control the temperature of the semiconductor laser. However, when the semiconductor laser is cooled, dew condensation occurs and the output and the life may be reduced. There is. That is, when water droplets adhere to the semiconductor laser and the laser beam irradiated from the semiconductor laser hits the water droplets, the optical energy of the laser beam is converted into thermal energy, and the output and life are reduced (= performance is reduced). Deteriorated).

  The present invention has been made in view of the above problems, and an object of the present invention is to provide a projection display apparatus that can reliably prevent deterioration of the performance of a laser light source with a simple configuration.

  In order to achieve the above object, one feature of the present invention is that a projected image generating means comprising a laser light source and a light modulation unit that modulates light from the laser light source to generate image light, and the projected image generating means And a first air conditioner having a dehumidifying function for dehumidifying the air in the first housing.

  Here, dehumidifying refers to reducing the absolute amount of moisture present in the space. According to this feature, it is possible to prevent performance degradation of the laser light source without causing condensation even when the laser light source is cooled.

  In the above feature, it is preferable that the apparatus further includes a second housing that houses the air conditioning unit, and the second housing is disposed below the first housing. According to this, even when refrigerant or lubricating oil leaks from the air-conditioning means, it is possible to prevent the refrigerant or lubricating oil from flowing down to the laser light source and the like, and to reduce the cause of failure of the laser light source. The air conditioning means may have a cooling function for cooling the air in the first housing. According to this, the temperature in the 1st housing | casing in which the laser light source was accommodated can be reduced, and it becomes easy to control the temperature of a laser light source. Furthermore, it is preferable to provide a cooling means for liquid-cooling the projection image generating means. According to this, the noise can be suppressed smaller than the air-cooling cooling means, and the projection image generating means including the laser light source can be efficiently cooled.

  One feature of the present invention is a projection video generation unit including a laser light source and a light modulation unit that modulates light from the laser light source to generate video light, and a first housing that houses the projection video generation unit. A refrigerant circuit in which a compressor, a heat radiator, an expansion valve, and a heat absorber are connected via a refrigerant pipe, a second housing that houses the refrigerant circuit, and air in the first housing is the second A gist is provided with a blowing means for sending air into the housing and exchanging heat with the heat absorber, and sending air exchanged with the heat absorber into the first housing.

  According to this feature, the air in the first housing containing the laser light source is taken into the second housing and exchanged with the heat absorber of the second housing, so that moisture in the air is condensed and removed. Can do. And the moisture content of a 1st housing | casing can be reduced by returning the air which removed the water | moisture content to a 1st housing | casing. At this time, if the air returned to the first housing is heat exchanged with the heat radiator of the second housing, the temperature in the first housing can be kept constant, and the first heat can be exchanged with the heat radiator. If it returns to a housing | casing, the temperature in a 1st housing | casing can be lowered | hung. That is, the air in the first housing can be efficiently dehumidified and cooled with a simple configuration.

  One feature of the present invention is a projection video generation unit including a laser light source and a light modulation unit that modulates light from the laser light source to generate video light, and a first housing that houses the projection video generation unit. In the method of starting the projection display apparatus, the projection display apparatus dehumidifies the air in the first casing and first detection means for detecting the temperature or humidity in the first casing. An air conditioning unit having a dehumidifying function, and controlling activation of the air conditioning unit and the projection image generation unit based on a detection result of the first detection unit.

  According to such a feature, for example, when it is determined that the humidity of the air in the first housing is higher than the result detected by the first detection unit, the projection image generation unit is activated after dehumidification by the air conditioning unit. The performance degradation of the laser light source due to condensation can be prevented.

  Specifically, in the above feature, after the dehumidification step of operating the dehumidification function of the air conditioning unit for the operation time set based on the detection result detected by the first detection unit, and after the dehumidification step ends, And a projection step of activating the projection image generating means. According to this, since the dehumidification is performed based on the preset operation time, it is possible to easily realize the control for the start-up operation. Furthermore, the projection display apparatus includes a second detection unit that detects a temperature of the laser light source, and a cooling unit that cools the projection image generation unit, and the temperature detected by the second detection unit. It is preferable to have a cooling step of starting the cooling means when is below a preset first threshold temperature. For example, when it is determined by the second detection means that the temperature of the laser light source is high, the amount of saturated water vapor around the laser light source is also large, and there is a risk of condensation on the laser light source when the cooling means is activated. On the other hand, if the temperature of the laser light source is equal to or lower than a predetermined threshold value, the possibility of dew condensation is low even if the cooling means is activated to cool the laser light source. In other words, it is possible to prevent performance degradation of the laser light source due to condensation with a simple configuration.

  According to the present invention, with a simple configuration, it is possible to prevent condensation when the laser light source is cooled to the operating temperature, and to prevent deterioration of the performance of the laser light source.

  Embodiments of the present invention will be described below with reference to the drawings. FIG. 1 is a side configuration diagram showing an example of a configuration of a liquid crystal projector according to the present invention. In FIG. 1, the X axis is set in the front direction of the drawing, the Y axis is set in the upward direction, and the Z axis is set in the left direction. The XZ plane is a plane substantially parallel to the plane on which the projector is placed. A liquid crystal projector (corresponding to a projection display apparatus) 100 includes a first housing 101 and a second housing 102. The first housing 101 houses the laser light source 1 and the light modulation unit 2, and the projection optical unit 3 is erected on the left side surface of the first housing 101. The second housing 102 is disposed below the first housing 101 and houses the air conditioning unit 4 and the water cooling unit 5. Further, the liquid crystal projector 100 includes an unillustrated CPU (see FIG. 4) at an appropriate place.

  The laser light source 1 (corresponding to a part of the projection image generation means) includes a semiconductor laser and the like, and converts the laser light corresponding to the three primary colors R (red), G (green), and B (blue) to the light modulation unit. It emits toward 2. The light modulation unit 2 (corresponding to a part of the projection image generation means) performs modulation corresponding to the image on the laser light corresponding to the three primary colors from the laser light source 1, generates image light, and performs projection optics. The light is emitted toward the unit 3. The projection optical unit 3 projects the image light from the light modulation unit 2 onto a screen (not shown).

  FIG. 2 is a plan configuration diagram showing an example of the configuration of the laser light source 1 and the light modulation unit 2. In FIG. 2, an X axis is set in the left direction of the drawing, a Y axis is set in the forward direction of the drawing, and a Z axis is set in the upward direction. The XZ plane is a plane substantially parallel to the plane on which the projector is placed. The laser light source 1 includes laser arrays 11, 12, 13 and a light guide unit 14.

  In the laser arrays 11, 12, and 13, a plurality of semiconductor lasers are two-dimensionally arranged on a plane so as to emit R (red), G (green), and B (blue) laser beams, respectively. The piping 111, 121, 131 of the cooling water from the water cooling unit 5 is arrange | positioned in order to cool a semiconductor laser. The light guide unit 14 guides the laser light emitted from the laser arrays 11, 12, and 13 to the light modulation unit 2. Here, when the semiconductor laser is arranged, the light emitted from the laser arrays 11, 12, and 13 is arranged so that the R light is S-polarized light, the G light is P-polarized light, and the B light is S-polarized light.

  The light modulation unit 2 performs modulation corresponding to an image on the laser light corresponding to the three primary colors from the laser light source 1, generates image light, and emits the image light toward the projection optical unit 3, Polarization beam splitters (PBS) 21, 22, 23, 24, and liquid crystal panels 222, 223, 232 corresponding to the three primary colors are provided. The image light synthesized by the PBS 24 is emitted toward the projection optical unit 3.

  Further, in the first housing 101 in which the laser light source 1 and the light modulation unit 2 are housed, a temperature sensor SA is disposed in the vicinity of the laser light source 1, and the temperature sensor SB is disposed in the cooling water pipe of the laser light source 1. A temperature sensor SC is provided on the back side of the liquid crystal panels 222, 223, and 232 provided in the light modulation unit 2. The temperature sensor SA (corresponding to the first detection means) is composed of a thermistor or the like, and detects the temperature of air in the first housing 101. The temperature sensor SB (corresponding to the second detection means) is provided on the upstream side and the downstream side of the cooling water piping of the laser arrays 11, 12, and 13 and includes six temperature sensors SB1 to SB6 including thermistors and the like. The temperature TA of the laser light source 1 is detected. The temperature sensor SC is disposed on the back side of each of the liquid crystal panels 222, 223, and 232 disposed in the light modulation unit 2, and includes three temperature sensors SC1 to SC3 including thermistors and the like. The temperature TB is detected.

  FIG. 3 is a plan configuration diagram showing an example of a detailed configuration of the light modulation unit 2. With respect to the light emitted from the light guide unit 14, R light is S-polarized light, G light is P-polarized light, and B light is S-polarized light with respect to the polarization plane of the PBS 211. Accordingly, the G light is transmitted through the PBS 211, and the B light and the R light are reflected by the PBS 211. Of the B light and R light reflected by the PBS 211, the R light is converted to P-polarized light by the wavelength selective half-wave plate 214. Accordingly, of the B light and the R light, the B light is reflected by the PBS 231 and the R light is transmitted through the PBS 231.

  The B light reflected by the PBS 231 is converted into circularly polarized light by the quarter-wave plate 222 ′ and then enters the reflective liquid crystal panel 222. Here, the B light reciprocates through the liquid crystal panel 222, so that, for example, the turning direction of the circularly polarized light is reversed only at the pixel position in the ON state. Accordingly, by passing through the quarter-wave plate 222 'again, the B light becomes P-polarized light at the pixel position in the ON state and S-polarized light at the pixel position in the OFF state. Of these, only the P-polarized light for the pixel position in the ON state is transmitted through the PBS 231 and enters the PBS 241 via the half-wave plate 242 that is wavelength selective to the R light.

  Similarly, the R light transmitted through the half-wave plate 214 and then through the PBS 231 reciprocates between the quarter-wave plate 232 ′ and the reflective liquid crystal panel 232, thereby corresponding to the pixel position in the ON state. Only is reflected by the PBS 231 and guided to the wavelength selective half-wave plate 242. The R light is converted into P-polarized light by the wavelength-selective half-wave plate 242 and then enters the PBS 241. In this way, both the B light and the R light modulated by the liquid crystal panels 222 and 232 are incident on the PBS 241 with the same P polarization.

  The G light that has passed through the PBS 211 passes through the PBS 221, and then reciprocates between the quarter-wave plate 223 ′ and the reflective liquid crystal panel 223, so that only the portion corresponding to the pixel position in the ON state reflects the PBS 221. Incident on PBS 241. Since this G light is incident on the PBS 241 in the S-polarized state, it is reflected by the PBS 241.

  As described above, the B light, the G light, and the R light modulated by the liquid crystal panels 222, 223, and 232 are combined through the PBS 241 to be color image light, which is emitted to the projection optical unit 3.

  The air conditioning unit 4 and the water cooling unit 5 that can cool the liquid crystal projector 100 having the above-described configuration of the laser light source 1 and the light modulation unit 2 with a simple configuration will be described in detail below.

(First embodiment)
Returning to FIG. 1, the air conditioning unit 4 (corresponding to air conditioning means) has a dehumidifying function for dehumidifying the air in the first housing 101 and a cooling function for cooling the air in the first housing 101. The compressor 41, the heat exchangers 42, 43, 44, 45, the expansion valves 46, 47, 48, the electromagnetic valves EV1, EV2, the fans F1, F2, F3, and the like are provided.

  The compressor 41 (corresponding to a part of the refrigerant circuit) compresses the refrigerant (for example, R134a, R744, etc.) and discharges it from the pipe on the left side of the drawing to the heat exchanger 42. A heat exchanger 42 is connected to the discharge side (left side in the figure) of the compressor 41 via a refrigerant pipe.

  The heat exchanger 42 (corresponding to a part of the refrigerant circuit) functions as a radiator that receives the refrigerant from the compressor 41 and cools the refrigerant. The refrigerant cooled (condensed) by the heat exchanger 42 flows into the heat exchanger 44 through the expansion valve 46. In the vicinity of the heat exchanger 42, a fan F1 for discharging the air in the second housing 102 heat-exchanged (= heated) by the heat exchanger 42 to the outside is disposed. A heat exchanger 44 is connected to the downstream side of the heat exchanger 42 via an expansion valve 46, and a heat exchanger 43 is connected via an expansion valve 48.

  A heat exchanger 45 is connected to the downstream side of the heat exchanger 44 via an expansion valve 47, and the downstream side of the heat exchanger 45 is connected to the suction side of the compressor 41. The expansion valve 46 is connected to the inflow side of the heat exchanger 45 via the electromagnetic valve EV2, and the outflow side of the heat exchanger 44 is connected to the suction side of the compressor 41 via the electromagnetic valve EV1. Yes. The downstream side of the heat exchanger 43 is connected to the suction side of the compressor 41.

  A fan F3 is disposed in the vicinity of the heat exchanger 44 (here, the upper side). The fan F3 (corresponding to a part of the air blowing means) discharges the air in the second housing 102 heat-exchanged (= heated or cooled) by the heat exchanger 44 into the first housing 101. A fan F2 is disposed near the heat exchanger 45 (here, on the upper side). The fan F <b> 2 (corresponding to a part of the blowing unit) sucks the air in the first housing 101 that is heat-exchanged (= cooled) by the heat exchanger 45 into the second housing 102.

  The expansion valves 46 and 47 and the electromagnetic valves EV1 and EV2 are a dehumidifying function for dehumidifying the air in the first housing 101 with respect to the fans F2 and F3 and the heat exchangers 44 and 45, and the first housing. Switching is performed so that one of the cooling functions for cooling the air in 101 is performed. The expansion valves 46 and 47 and the electromagnetic valves EV1 and EV2 are switched in accordance with instructions from the CPU 6 described later. The heat exchanger 45 corresponds to a first heat exchanger, and the heat exchanger 44 corresponds to a second heat exchanger.

  First, the case where the air-conditioning unit 4 exhibits the dehumidifying function will be described. With the solenoid valves EV1 and EV2 closed, the heat exchanger 44 and the heat exchanger 45 are connected in series, and the expansion valve 46 is turned off (= the valve is fully opened and does not function as an expansion valve). By turning on the valve 47 (= a state in which the valve is opened to function as an expansion valve), the heat exchanger 44 functions as a heat radiator and the heat exchanger 45 functions as a heat absorber. In such a state, the air in the first housing 101 sucked by the fan F2 is cooled by the heat exchanger 45, and the moisture is condensed and removed. And it is heated to normal temperature by the heat exchanger 44, and is returned in the 1st housing | casing 101 by the fan F3. As the air flow circulates, the air in the first housing 101 is dehumidified.

  Next, the case where the air conditioning unit 4 exhibits the cooling function will be described. By opening the solenoid valves EV1 and EV2 and turning on the expansion valve 46 and closing the expansion valve 47 with the heat exchanger 44 and the heat exchanger 45 connected in parallel, the heat exchanger 44 and The heat exchanger 45 is caused to function as a heat absorber. In such a state, the air in the first housing 101 sucked by the fan F2 is cooled by the heat exchanger 45 and the heat exchanger 44, and returned to the first housing 101 by the fan F3. Thereby, the air in the first housing 101 is cooled.

  The heat exchanger 43 (corresponding to a third heat exchanger) functions as a heat absorber when the expansion valve 48 is turned on according to an instruction from the CPU 6 described later, and is a cooling water that is a heat transfer medium of the water cooling unit 5 Cool down. Here, in this embodiment, a water cooling unit using water (cooling water) as a heat transfer medium will be described. However, the heat transfer medium may be a fluid, and the temperature range of heat to be transferred and the liquid crystal projector 100 are installed. Depending on the ambient temperature, ethanol or glycol may be used.

  The water cooling unit 5 (corresponding to the cooling means) cools the laser light source 1 and the light modulation unit 2 by a liquid cooling (water cooling in the present embodiment), and includes a water storage tank 51, pumps P1, P2, And it has electromagnetic valves EV3 and EV4.

  The water storage tank 51 stores cooling water that functions as a heat transfer medium. The pump P <b> 1 discharges the cooling water from the water storage tank 51 toward the heat exchanger 43. The pump P <b> 2 discharges cooling water from the water storage tank 51 toward the laser light source 1 and the light modulation unit 2. The electromagnetic valves EV3 and EV4 are opened when the laser light source 1 and the light modulation unit 2 are cooled, respectively. Further, the electromagnetic valve EV3 is connected to the cooling water pipes 111, 121, 131 of FIG.

  FIG. 4 is a block diagram illustrating an example of the functional configuration of the CPU 6. A CPU (Central Processing Unit) 6 (corresponding to an activation control unit) of the liquid crystal projector 100 controls the entire operation of the liquid crystal projector 100, and functionally, a dehumidifying time setting unit 61, an initial setting unit 62, A dehumidifying instruction unit 63, a cooling instruction unit 64, a cooling instruction unit 65, and a projection instruction unit 66 are provided. In particular, the CPU 6 controls activation of the laser light source 1, the light modulation unit 2, the air conditioning unit 4, and the water cooling unit 5 based on the detection results of the temperature sensor SA and the temperature sensor SB. The CPU 6 reads out and executes a control program stored in advance in a ROM (Read Only Memory) or the like (not shown), thereby performing a dehumidifying time setting unit 61, an initial setting unit 62, a dehumidifying instruction unit 63, a cooling instruction unit 64, a cooling unit It functions as functional units such as an instruction unit 65 and a projection instruction unit 66.

  Of various data stored in an unillustrated RAM (Random Access Memory), ROM, etc., data that can be stored in a removable recording medium includes, for example, a hard disk drive, an optical disk drive, a flexible disk drive, and a silicon disk drive. In this case, the recording medium is, for example, a hard disk, an optical disk, a flexible disk, a CD (Compact Disk), a DVD (Digital Versatile Disk), a semiconductor memory, or the like.

  The dehumidifying time setting unit 61 determines whether or not the power is turned on, and when the power is turned on, the air conditioning unit is based on the temperature TA of the air in the first housing 101 detected by the temperature sensor SA. The operation time T1 of the dehumidifying function 4 is set. Specifically, the dehumidifying function operating time T1 is stored in advance in a RAM (not shown) in association with the temperature TA, and the dehumidifying time setting unit 61 is detected by the temperature sensor SA when the power is turned on. The operating time T1 is set by reading out the operating time T1 of the dehumidifying function corresponding to the temperature TA of the air in the first housing 101 from the RAM or the like.

  When the dehumidifying time setting unit 61 determines that the power is turned on, the initial setting unit 62 activates the refrigerant circuit of the air conditioning unit 4 (= activates the compressor 41 and the fans F1 to F3 (see FIG. 1)). At the same time, temperature control of the cooling water in the water storage tank 51 (see FIG. 1) of the water cooling unit 5 is started.

  Here, as the temperature of the cooling water stored in the water storage tank 51 of the water cooling unit 5, the temperature TW of the cooling water detected by a temperature sensor (not shown) provided in the water storage tank 51 is preset. When the temperature is equal to or higher than a predetermined threshold temperature (for example, 10 ° C.), the expansion valve 48 is turned on and the pump P1 is activated to control the cooling water through the heat exchanger 43.

  The dehumidifying instruction unit 63 operates the dehumidifying function of the air conditioning unit 4 for the operation time T1 set by the dehumidifying time setting unit 61, starting from the time when the power is turned on. Specifically, the dehumidification instructing unit 63 closes the solenoid valves EV1 and EV2 for the operation time T1 set by the dehumidifying time setting unit 61, and turns off the expansion valve 46, starting from when the power is turned on. By turning on the valve 47, the air conditioning unit 4 is caused to exhibit a dehumidifying function (see FIG. 1).

  The cooling instruction unit 64 operates after the dehumidifying function of the air conditioning unit 4 is operated by the dehumidifying instruction unit 63 for the operation time T1, and then the temperature TB detected by the temperature sensor SB is set to a first threshold temperature SH1 (for example, 20) set in advance. The cooling function of the air conditioning unit 4 is operated until the temperature becomes equal to or lower than (° C.).

  Here, as shown in FIG. 2, since the temperature sensor SB is composed of six temperature sensors SB1 to SB6, the temperature TB used for control by the cooling instruction unit 64, the cooling instruction unit 65, and the projection instruction unit 66 is controlled. The highest temperature among the temperatures detected by the six temperature sensors SB1 to SB6. Further, the cooling instruction unit 64 opens the electromagnetic valves EV1 and EV2, turns on the expansion valve 46, and closes the expansion valve 47 until the temperature TB becomes equal to or lower than the first threshold temperature SH1 set in advance. As a result, the air conditioning unit 4 is allowed to exhibit a cooling function (see FIG. 1).

  The cooling instructing unit 65 activates the water cooling unit 5 when it is determined that the temperature TB detected by the temperature sensor SB by the cooling instructing unit 64 is equal to or lower than the first threshold temperature SH1 set in advance (that is, the pump P2 (see FIG. 1) is turned ON).

  When the temperature TB detected by the temperature sensor SB is set in advance and becomes equal to or lower than the second threshold temperature SH2 (for example, 18 ° C.) lower than the first threshold temperature SH1, the projection instruction unit 66 outputs the laser light source 1 and the light. The modulation unit 2 is activated.

  5 and 6 are flowcharts showing an example of the operation of the liquid crystal projector 100 (mainly the CPU 6). First, as shown in FIG. 5, the dehumidifying time setting unit 61 determines whether or not the main power supply of the liquid crystal projector 100 is turned on (S101). If it is determined that the main power is not turned on (NO in S101), the process is set to a standby state. If it is determined that the main power supply is turned on (YES in S101), the refrigerant circuit of the air conditioning unit 4 is activated by the initial setting unit 62 (= compressor 41, fans F1 to F3 (see FIG. 1) are activated). (S103).

  Then, the initial setting unit 62 detects the temperature TW of the cooling water in the water storage tank 51, and determines whether the temperature TW is less than 10 ° C. (S105). When it is determined that the temperature TW is less than 10 ° C. (YES in S105), the expansion valve 48 is closed and the pump P1 is stopped, and cooling of the cooling water is stopped (S107). Is returned to step S105. If it is determined that the temperature TW is 10 ° C. or higher (NO in S105), the expansion valve 48 is turned on and the pump P1 is activated to start cooling the cooling water (S109). The process returns to S105.

  When the process of step S103 is completed, the dehumidifying time setting unit 61 detects the temperature TA of the air in the first housing 101 via the temperature sensor SA (S111). Next, the dehumidifying time setting unit 61 sets the operating time T1 of the dehumidifying function of the air conditioning unit 4 based on the temperature TA detected in step S111 (S113). Next, the dehumidifying operation of the air conditioning unit 4 is executed by the dehumidifying instruction unit 63 (S115).

  Then, the dehumidifying instruction unit 63 determines whether or not the operating time T1 set in step S113 has elapsed (S117). If it is determined that the operating time T1 has not elapsed (NO in S117), the process returns to step S115, and the processes after step S115 are repeatedly executed.

  If it is determined that the operation time T1 has elapsed (YES in S117), the cooling instruction unit 64 performs the cooling operation of the air conditioning unit 4 as shown in FIG. 6 (S119). Then, the cooling instruction unit 64 detects the temperature TB via the temperature sensor SB (S121). Next, the cooling instruction unit 64 determines whether the temperature TB detected in step S121 is equal to or lower than the first threshold temperature SH1 (S123). If it is determined that the temperature is not equal to or lower than the first threshold temperature SH1 (= higher than the first threshold temperature SH1) (NO in S123), the process is returned to step S119, and the processes after step S119 are repeatedly executed.

  If it is determined that the temperature is equal to or lower than the first threshold temperature SH1 (YES in S123), the water cooling unit 5 is activated by the cooling instruction unit 65 (S125). Then, the projection instruction unit 66 detects the temperature TB via the temperature sensor SB (S127). Next, the projection instruction unit 66 determines whether the temperature TB detected in step S127 is equal to or lower than the second threshold temperature SH2 (S129). If it is determined that the temperature is not lower than the second threshold temperature SH2 (higher than the second threshold temperature SH2) (NO in S129), the process returns to step S127, and the processes after step S127 are repeatedly executed. If it is determined that the temperature is equal to or lower than the second threshold temperature SH2 (YES in S129), the projection instruction unit 66 activates the laser light source 1 and the light modulation unit 2 (S131), and the process is terminated.

  In this way, the laser light source 1 and the light modulation unit 2 that generate image light to be displayed on the screen are housed in the first housing 101, and the air in the first housing 101 is dehumidified by the air conditioning unit 4. Therefore, the performance of the laser light source 1 can be reliably prevented from being deteriorated with a simple configuration.

  That is, since the air in the first housing 101 in which the laser light source 1 is housed is dehumidified by the air conditioning unit 4, it is possible to prevent water droplets from adhering to the laser light source 1 due to condensation, and the laser light source with a simple configuration. 1 can be reliably prevented from degrading. Further, since the air conditioning unit 4 is disposed below the laser light source 1 and the light modulation unit 2, even when refrigerant or lubricating oil leaks from the air conditioning unit 4, the refrigerant or lubricating oil flows down to the laser light source 1 or the like. This can prevent the failure of the laser light source 1 and the like. Further, since the air conditioning unit 4 has a cooling function for cooling the air in the first housing 101 in which the laser light source 1 is housed, the temperature of the laser light source 1 can be controlled, and the performance of the laser light source 1 can be controlled. It is possible to more reliably prevent the deterioration. In addition, since the air conditioning unit 4 is constituted by a refrigerant circuit including the compressor 41 and realizes dehumidification and cooling of the air in the first housing 101, the operation states of the heat exchanger 44 and the heat exchanger 45 are changed. The air in the first housing 101 can be efficiently dehumidified and cooled with a simple configuration simply by (= operating as a heat absorber or operating as a radiator).

  Since the laser light source 1 and the light modulation unit 2 are cooled by the water cooling method by the water cooling unit 5 sharing the refrigerant circuit with the air conditioning unit 4, the water cooling unit 5 can be realized with a simple configuration. Further, since the laser light source 1 and the light modulation unit 2 are cooled by the water cooling method by the water cooling unit 5, the laser light source 1 and the light modulation unit 2 can be efficiently cooled, and the performance of the laser light source 1 is deteriorated. Can be prevented more reliably. Furthermore, the temperature of the air in the first housing 101 is detected by the temperature sensor SA, and the air conditioning unit 4, the laser light source 1, the light modulation unit 2, and the water cooling unit 5 are activated based on the detection result of the temperature sensor SA. Since it is controlled, it is possible to prevent the deterioration of the performance of the laser light source 1 more reliably.

  For example, if the temperature sensor SA detects that the temperature TA of the air in the first housing 101 is high, the laser light source 1 and the light modulation unit 2 are activated after cooling by the air conditioning unit 4, thereby The deterioration of the performance of the light source 1 can be prevented more reliably. In addition, since the temperature sensor SA detects the temperature of the air in the first housing 101, the performance of the laser light source 1 can be reliably prevented from being deteriorated with a simpler configuration. In addition, the operating time T1 of the dehumidifying function of the air conditioning unit 4 is set based on the temperature TA of the air in the first housing 101 detected by the temperature sensor SA when the power is turned on. Since the dehumidifying function of the air conditioning unit 4 is operated for the set operation time T1 and the operation of the dehumidifying function of the air conditioning unit 4 is finished, the laser light source 1 and the light modulation unit 2 are activated. It is possible to more reliably prevent the deterioration.

  Further, the temperature sensor SB detects the temperature TB of the laser light source 1, and the activation of the air conditioning unit 4, the laser light source 1, the light modulation unit 2 and the water cooling unit 5 is controlled based on the detection result of the temperature sensor SB. Further, it is possible to prevent the deterioration of the performance of the laser light source 1 more reliably. For example, when it is detected by the temperature sensor SB that the temperature of the laser light source 1 is high, the laser light source 1 and the like are started after cooling by the water cooling unit 5, thereby further reliably degrading the performance of the laser light source 1. Can be prevented.

  Further, after the dehumidifying function of the air conditioning unit 4 is operated for the set operation time T1, the air conditioning unit until the temperature of the laser light source 1 detected by the temperature sensor SB becomes equal to or lower than a first threshold temperature SH1 set in advance. 4 cooling function is activated. When it is determined that the temperature TB of the laser light source 1 detected by the temperature sensor SB has become equal to or lower than the first threshold temperature SH1 set in advance, the water cooling unit 5 is activated and the laser detected by the temperature sensor SB. When the temperature TB of the light source 1 is set in advance and becomes equal to or lower than the second threshold temperature SH2 that is lower than the first threshold temperature SH1, the laser light source 1 and the like are activated, so the deterioration of the performance of the laser light source 1 is further ensured Can be prevented.

  Further, when it is determined that the temperature TB of the laser light source 1 detected by the temperature sensor SB is equal to or lower than a first threshold temperature SH1 set in advance, the water cooling unit 5 is activated and the laser detected by the temperature sensor SB. When the temperature TB of the light source 1 is set in advance and becomes equal to or lower than the second threshold temperature SH2 less than the first threshold temperature SH1, the laser light source 1 and the like are activated, so the second threshold temperature SH2 is set to an appropriate value. By doing so, the temperature of the laser light source 1 can be lowered to an appropriate temperature, and the deterioration of the performance of the laser light source 1 can be more reliably prevented.

(Second Embodiment)
In the first embodiment, the case where the cooling unit is the water cooling unit 5 has been described. However, the cooling unit may cool the laser light source 1 by other methods. A mode in which the cooling means has a Peltier element will be described with reference to FIGS. FIG. 7 is a side configuration diagram showing an example of a configuration different from FIG. 1 of the liquid crystal projector according to the present invention. FIG. 8 is a plan configuration diagram showing an example of a configuration different from that of FIG. 2 of the laser light source. In the following description, only portions different from the configuration described with reference to FIGS. 1 and 2 will be described, and common portions will be denoted by the same reference numerals and description thereof will be omitted.

  As shown in FIG. 7, the air conditioning unit 4 </ b> A is different from the air conditioning unit 4 shown in FIG. 1 in that it does not include the heat exchanger 43 and the expansion valve 48. That is, the air conditioning unit 4A does not have a function of cooling the cooling water that is the heat transfer medium of the water cooling unit 5A. The water cooling unit 5A is different from the water cooling unit 5 shown in FIG. 1 in that it includes a radiator 51A and a fan F4A instead of the water storage tank 51. The radiator 51A air-cools the cooling water that is the heat transfer medium of the water cooling unit 5A. According to this configuration, the compressor 41A of the air conditioning unit 4A can be used with a smaller capacity than the compressor 41 of the air conditioning unit 4 shown in FIG.

  As shown in FIG. 8, in the laser light source 1A, Peltier elements 111A, 121A, 131A and cooling water pipes 112A, 122A, 132A from the water cooling unit 5A are arranged on the back side of the laser arrays 11A, 12A, 13A, respectively. This is different from the laser light source 1 shown in FIG. Further, the temperature sensor SBA (corresponding to the second detection means) is disposed in the vicinity of the laser arrays 11A, 12A, and 13A, and includes three temperature sensors SB1A to SB3A including thermistors and the like in FIG. This is different from the temperature sensor SB shown. The Peltier elements 111A, 121A, and 131A absorb the heat of the laser arrays 11A, 12A, and 13A and dissipate the heat to the pipes 112A, 122A, and 132A, respectively. According to this configuration, since the heat of the laser arrays 11A, 12A, and 13A is absorbed through the Peltier elements 111A, 121A, and 131A, the laser arrays 11A, 12A, and 13A can be rapidly cooled.

The present invention can also be applied to the following forms.
(A) In the present embodiment, the case where the light modulation unit generates (= modulates) image light via the reflective liquid crystal panel has been described. However, the light modulation unit passes through the transmissive liquid crystal panel. An image light may be generated (= modulated), or DMD (Digital Mirror Devices) may be used.

  (B) In this embodiment, although the case where the 1st detection means was a temperature sensor which detects the temperature of the air in a 1st housing | casing was demonstrated, a 1st detection means detects the humidity of the air in a 1st housing | casing. The form which is a humidity sensor may be sufficient. In this case, the dehumidifying time setting unit can set the operation time T1 of the dehumidifying function of the air conditioning unit to a more appropriate time.

  (C) In the present embodiment, the case where the dehumidification instruction unit operates the dehumidification function of the air conditioning unit for the operation time set by the dehumidification time setting unit has been described. However, the first detection unit detects the air in the first housing. When the humidity sensor detects humidity, the dehumidifying instruction unit determines that the air humidity in the first housing detected by the first detection means is equal to or lower than a predetermined threshold humidity. The form which operates a dehumidification function may be sufficient.

  (D) In the present embodiment, the case where the CPU functionally includes a dehumidifying time setting unit, an initial setting unit, a dehumidifying instruction unit, a cooling instruction unit, a cooling instruction unit, a projection instruction unit, and the like has been described. Of the setting unit, the initial setting unit, the dehumidifying instruction unit, the cooling instruction unit, the cooling instruction unit, and the projection instruction unit, at least one functional unit may be configured by hardware such as a circuit.

  (E) In the first embodiment, the case where the second detection means includes the six temperature sensors SB1 to SB6 has been described. However, the second detection means includes three pieces arranged on the downstream side of the cooling water pipe. The form which consists of temperature sensor SB2, SB4, SB6 may be sufficient. Usually, the detected temperatures of the three temperature sensors SB2, SB4, and SB6 disposed downstream of the cooling water pipe are higher than the detected temperatures of the temperature sensors SB1, SB3, and SB5 disposed upstream of the cooling water pipe. In this case, the number of temperature sensors can be reduced without reducing the control accuracy. In addition, one of the three temperature sensors SB2, SB4, and SB6 may be provided with one temperature sensor having the highest probability of temperature rise. In this case, the number of temperature sensors can be further reduced.

These are side surface block diagrams which show an example of a structure of the liquid crystal projector which concerns on this invention. These are plane | planar block diagrams which show an example of the structure of a laser light source and a light modulation unit, and the arrangement | positioning position of a sensor. These are plane | planar block diagrams which show an example of a detailed structure of a light modulation unit. These are block diagrams which show an example of a function structure of CPU. These are the flowcharts which show an example of operation | movement of a liquid crystal projector (mainly CPU). These are the flowcharts which show an example of operation | movement of a liquid crystal projector (mainly CPU). These are side surface block diagrams which show an example of a structure different from FIG. 1 of the liquid crystal projector which concerns on this invention. These are the plane block diagrams which show an example of a structure different from FIG. 2 of a laser light source.

Explanation of symbols

100 Liquid crystal projector (projection display device)
101 First housing 102 Second housing 1 Laser light source (part of projection image generating means)
11 Laser array 14 Light guide 2 Light modulation unit (part of projection image generation means)
DESCRIPTION OF SYMBOLS 21 Separation part 22 1st modulation part 23 2nd modulation part 24 Synthesis | combination part 3 Projection optical unit 4 Air-conditioning unit (air-conditioning means)
41 Compressor (part of refrigerant circuit)
42 Heat exchanger (part of refrigerant circuit)
43 Heat exchanger (3rd heat exchanger)
44 Heat exchanger (second heat exchanger)
45 Heat exchanger (first heat exchanger)
46-48 expansion valve F1 fan F2 fan (air blowing means)
F3 fan (air blowing means)
5 Water cooling unit (cooling means)
51 Water storage tank 6 CPU (startup control means)
61 Dehumidification time setting unit 62 Initial setting unit 63 Dehumidification instruction unit 64 Cooling instruction unit 65 Cooling instruction unit 66 Projection instruction unit SA Temperature sensor (first detection means)
SB temperature sensor (second detection means)

Claims (1)

A projection image generation means comprising: a laser light source; and a light modulation unit that modulates light from the laser light source to generate image light;
A first housing that houses the projection image generating means;
An air conditioning unit having a dehumidifying function for dehumidifying the air in the first casing and a cooling function for cooling the air in the first casing;
Cooling means for liquid-cooling the projection image generating means;
A refrigerant circuit in which a compressor, a radiator, an expansion valve, and a heat absorber are connected via a refrigerant pipe;
A second housing disposed below the first housing and housing the air conditioning means and the refrigerant circuit;
Blower means for sending air in the first housing into the second housing and exchanging heat with the heat absorber, and for sending air exchanged in heat with the heat absorber into the first housing;
First detection means for detecting temperature or humidity in the first housing;
Second detecting means for detecting the temperature of the laser light source,
Based on the detection result of the first detection means, the activation of the air conditioning means and the projection image generation means is controlled,
A dehumidifying step of operating the dehumidifying function of the air conditioning means for an operating time set based on the detection result detected by the first detecting means;
A projection step of activating the projection image generating means after the dehumidification step is completed,
A startup method for a projection display apparatus, comprising: a cooling step of starting the cooling means when the temperature detected by the second detection means is equal to or lower than a preset first threshold temperature.

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