JP2013047843A - Projector - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a projector which can be driven with an accurate rotational frequency.SOLUTION: A projector 1 includes: a liquid crystal panel-cooling fan 26A which outputs a signal for rotational frequency detection; a fan driving unit 23A which drives the liquid crystal panel-cooling fan 26A; a rotational frequency detection unit which detects a rotational frequency as a detected rotational frequency N1 by the signal for rotational frequency detection from the liquid crystal panel-cooling fan 26A; a rotational frequency storage unit 21 in which a prescribed rotational frequency N of the liquid crystal panel-cooling fan 26A, which is set for cooling a liquid crystal panel 52, is stored; a rotational frequency comparison unit which compares the detected rotational frequency N1 with the prescribed rotational frequency N; and a cooling control unit 20 which controls a cooling operation. On the basis of the comparison and determination result between the detected rotational frequency N1 and the prescribed rotational frequency N by the rotational frequency comparison unit, the cooling control unit 20 causes the fan driving unit 23A to perform prescribed processing to drive the liquid crystal panel-cooling fan 26A.

Description

  The present invention relates to a projector.

  Conventionally, when it is necessary to cool the internal components of the projector, the projector is cooled by driving (rotating) a cooling fan installed inside the projector. Further, the thermistor is used as a detection unit for detecting the component temperature, and the temperature of the internal component is managed. When the temperature of the component detected by the thermistor is equal to or lower than a predetermined temperature, the cooling fan is driven with a constant driving voltage applied to the cooling fan.

  In Patent Document 1, data for correcting a circuit error of a drive circuit (a drive signal is supplied to a cooling unit (cooling fan)) is stored in a memory, and a drive signal is generated based on the detection result of the temperature detection unit. It is proposed that an error of an output signal of a drive circuit is corrected in advance based on circuit error correction data in which the generated drive signal is stored in a memory and output to the drive circuit.

JP 2006-154460 A

  According to the above-mentioned Patent Document 1, even if the stored circuit error is corrected to the drive signal generated based on the detection result of the temperature detector and output to the drive circuit, the cooling fan that is actually driven has itself. Due to the variation in characteristics, the rotational speed varies with respect to the drive (applied) voltage, and thus there is a problem that driving at an accurate rotational speed cannot be performed. When the cooling fan is rotating more than necessary, the noise of the projector becomes high, and some internal parts are overcooled.

  SUMMARY An advantage of some aspects of the invention is to solve at least a part of the problems described above, and the invention can be implemented as the following forms or application examples.

  Application Example 1 A projector according to this application example is a projector that has a cooling fan that outputs a signal for detecting a rotation speed and cools internal components, and includes a fan driving unit that drives the cooling fan, A rotational speed detection unit that detects the rotational speed of the cooling fan as a detected rotational speed based on a rotational speed detection signal output from the fan, and a rotational speed storage that stores a predetermined rotational speed of the cooling fan that is set when cooling the internal components A rotation number comparison unit that compares the detected rotation number detected by the rotation number detection unit with a predetermined rotation number stored in the rotation number storage unit, and a cooling control unit that controls the cooling operation. And the cooling control unit drives the cooling fan by causing the fan driving unit to perform a predetermined process based on a comparison determination result between the rotation speed detected by the rotation speed comparison unit and the predetermined rotation speed. And

  According to such a projector, the projector includes a cooling fan, a fan driving unit, a rotation number detection unit, a rotation number storage unit, a rotation number comparison unit, and a cooling control unit. The cooling control unit drives the cooling fan by causing the fan drive unit to perform a predetermined process based on a comparison determination result between the rotation speed detected by the rotation speed comparison unit and the predetermined rotation speed. And Thereby, the cooling fan rotates at a rotation speed corresponding to a predetermined process. Therefore, the variation of the driving (applied) voltage due to the characteristic variation of the circuit components for generating the driving voltage to the conventional cooling fan, the variation of the rotation speed with respect to the driving (applied) voltage due to the characteristic variation of the cooling fan itself, etc. Is corrected, and the cooling fan can be rotated at an accurate rotational speed corresponding to a predetermined process. Further, the noise level of the projector can be reduced by rotating at an accurate rotational speed corresponding to a predetermined process. Moreover, it is possible to prevent the internal components from being cooled more than necessary (supercooled). The predetermined number of rotations indicates the number of rotations set as a cooling target when cooling the internal components with the cooling fan.

  Application Example 2 In the projector described above, a component temperature detection unit that detects a component temperature of an internal component of the projector as a detection component temperature, and a temperature storage unit that stores a predetermined temperature that is set when the internal component is cooled And a temperature comparison unit that compares the detected component temperature detected by the component temperature detection unit with a predetermined temperature stored in the temperature storage unit, and the cooling control unit is a detection component at the temperature comparison unit When it is determined that the temperature is equal to or lower than the predetermined temperature, it is preferable to operate the rotation speed detection unit and the rotation speed comparison unit.

  According to such a projector, the projector further includes a component temperature detection unit, a temperature storage unit, and a temperature comparison unit. The cooling control unit operates the rotation speed detection unit and the rotation speed comparison unit when the temperature comparison unit determines that the detected component temperature is equal to or lower than the predetermined temperature. As a result, it is possible to reduce the load on interrupt processing and the like of the control unit that controls the projector including the cooling control unit. The predetermined temperature refers to a temperature set as a cooling target when cooling the internal components with the cooling fan.

  Application Example 3 In the projector described above, when the rotation speed comparison unit determines that the detected rotation speed is higher than the predetermined rotation speed, the cooling control section detects the fan drive section as a predetermined process. It is preferable to drive the cooling fan by performing correction processing for setting the rotation speed to a rotation speed in the vicinity of the predetermined rotation speed.

  According to such a projector, when the rotational speed comparison unit determines that the detected rotational speed is higher than the predetermined rotational speed, the cooling control unit performs the predetermined processing on the fan drive unit as the detected rotational speed. By performing correction processing for setting the rotation speed around the predetermined rotation speed and driving the cooling fan, the cooling fan rotates at a rotation speed around the predetermined rotation speed. Thereby, when the detected rotational speed is higher than the predetermined rotational speed (when the cooling fan rotates more than necessary), the noise level of the projector can be reduced. Moreover, it is possible to prevent the internal components from being cooled more than necessary.

  Application Example 4 In the projector described above, when the rotation control unit determines that the detected rotation number is equal to or lower than the predetermined rotation number, the cooling control unit detects the detected rotation as a predetermined process for the fan drive unit. It is preferable to drive the cooling fan so as to maintain the number.

  According to such a projector, the cooling control unit maintains the detected rotation number as a predetermined process for the fan drive unit when the rotation number comparison unit determines that the detected rotation number is equal to or less than the predetermined rotation number. As described above, the noise level of the projector can be kept low by driving the cooling fan.

  Application Example 5 In the projector described above, when the temperature comparison unit determines that the detected component temperature is higher than the predetermined temperature, the cooling control unit detects the detected component temperature as a predetermined process for the fan drive unit. It is preferable to perform a correction process for reducing the temperature to a predetermined temperature or less and drive the cooling fan.

  According to such a projector, when it is determined that the detected component temperature is higher than the predetermined temperature, the fan driving unit is subjected to a correction process for setting the detected component temperature to be equal to or lower than the predetermined temperature as a predetermined process. By driving the fan, the cooling control unit supervises the cooling control unit and the projector by controlling the component temperature without detecting the rotation speed when it is determined that the detected component temperature is higher than the predetermined temperature. Thus, it is possible to reduce the load on the processing accompanying the rotation speed detection of the control unit or the like to be controlled.

1 is a circuit block diagram of a projector according to a first embodiment. The flowchart which shows the process sequence regarding the cooling control in the cooling control part of a projector. The circuit block diagram of the projector which concerns on 2nd Embodiment. The flowchart which shows the process sequence regarding the cooling control in the cooling control part of a projector.

Hereinafter, embodiments will be described with reference to the drawings.
(First embodiment)

  FIG. 1 is a circuit block diagram of the projector according to the first embodiment. The configuration and operation of the projector 1 will be described with reference to FIG.

  The projector 1 modulates a light beam emitted from a lamp 51 as a light source device with a liquid crystal panel 52 as a light modulation device according to image information, forms an optical image, and projects the optical image as a projection optical device. The image is projected onto the screen 500 or the like through the lens 53 as an image (for example, a color image). Note that the optical system 50 of the projector 1 includes the lamp 51, the liquid crystal panel 52, the projection lens 53, and the like described above.

First, the configuration of the projector 1 will be described.
The projector 1 includes an A / D converter 11, a video decoder 12, an image processing circuit 13, an image correction circuit 14, a liquid crystal panel drive circuit 15, a lamp drive unit 16, a power supply unit 17, and the like. The projector 1 includes a cooling control unit 20, a rotation speed storage unit 21, a temperature storage unit 22, a fan drive unit 23A, a lamp cooling fan 25A, a liquid crystal panel cooling fan 26A, a lamp thermistor (TH) 27, a liquid crystal panel. Thermistor (TH) 28 is used.

  Further, the projector 1 is comprehensively controlled by the control unit 10. And the control part 10 is comprised by CPU (Central Processing Unit). This CPU has a ROM (Read Only Memory) and a RAM (Random Access Memory).

  The cooling control unit 20 performs control related to the cooling operation inside the projector 1. The cooling control unit 20 is configured in the same manner as the control unit 10. The cooling control unit 20 may be configured as a part of the function in the control unit 10.

  In the present embodiment, the fan drive unit 23A is configured by a PWM (Pulse Width Modulation) unit 24A. Details of the fan drive unit 23A will be described later. Further, the thermistor 27 for the lamp and the thermistor 28 for the liquid crystal panel are configured as a component temperature detector, and measure the temperature of the lamp 51 and the temperature of the liquid crystal panel 52, respectively. Details of the lamp thermistor 27 and the liquid crystal panel thermistor 28 will be described later.

Next, the operation of the projector 1 will be described with reference to the operation of each part.
The A / D converter 11 converts the PC image data input to the PC image signal input terminal 40 into a digital signal and outputs the digital signal to the image processing circuit 13. The video decoder 12 converts the moving image data input to the video signal input terminal 41 into a digital signal, separates it into R, G, and B color signals, and outputs them to the image processing circuit 13.

  The image processing circuit 13 converts frame rate conversion and scaling processing into PC image data or moving image data (hereinafter referred to as PC image data or moving image data) input from the A / D converter 11 or the video decoder 12. To do. Then, the image processing circuit 13 outputs the image data subjected to frame rate conversion, scaling processing, and the like to the image correction circuit 14.

The image correction circuit 14 performs brightness adjustment, contrast adjustment, gamma correction processing, and the like on the image data based on the contents of the input image data. The image data processed in this way is output to the liquid crystal panel drive circuit 15 as a projection video signal.
The liquid crystal panel drive circuit 15 outputs and drives the projection video signal input from the image correction circuit 14 to each liquid crystal panel 52.

  The lamp driving unit 16 causes the lamp 51 to be turned on / off by a control signal from the control unit 10. The power supply unit 17 guides AC power from a commercial power supply outside the projector 1 through a power cable (not shown), and performs processing such as transformation, rectification, and smoothing by a built-in AC / DC conversion unit (not shown). The stabilized DC voltage is supplied to each part constituting the projector 1.

  As described above, the cooling control unit 20 performs control related to the cooling operation inside the projector 1. Specifically, the cooling control unit 20 controls the temperature of the lamp 51 and the liquid crystal panel 52 due to heat generation within a predetermined temperature range (within a proper temperature range) as a set cooling target. 25A and the liquid crystal panel cooling fan 26A are controlled.

  In the present embodiment, the fan drive unit 23A is configured by the PWM unit 24A as described above, and changes the duty ratio of the pulse wave and outputs it as a drive signal. Then, the fan driving unit 23A outputs a predetermined driving signal that is set for driving the lamp cooling fan 25A, the liquid crystal panel cooling fan 26A, and the like in response to an instruction signal from the cooling control unit 20.

  In this embodiment, the lamp cooling fan 25A is configured to output a signal for detecting the rotational speed and include a DC fan motor for PWM control. The lamp cooling fan 25 </ b> A is driven (rotated) by a drive signal output from the fan drive unit 23 </ b> A, and cools the heat generated by the lamp 51. The lamp cooling fan 25A outputs a pulse signal proportional to the rotational speed to the cooling control unit 20 as a rotational speed detection signal. In this embodiment, the lamp cooling fan 25A is supplied with 12V DC voltage generated from the power supply unit 17, and the fan drive unit 23A receives a drive signal with a variable duty ratio. The

  In the present embodiment, the liquid crystal panel cooling fan 26A also outputs a rotation speed detection signal and has a DC fan motor for PWM control. The liquid crystal panel cooling fan 26 </ b> A is driven (rotated) by the drive signal output from the fan drive unit 23 </ b> A, and cools the heat generated by the liquid crystal panel 52. Further, the liquid crystal panel cooling fan 26A outputs a pulse signal proportional to the rotational speed to the cooling control unit 20 as a rotational speed detection signal. In the present embodiment, the liquid crystal panel cooling fan 26A is supplied with a DC voltage of 12V generated from the power supply unit 17, and a drive signal with a variable duty ratio is input from the fan drive unit 23A. Is done.

  The lamp thermistor 27 is configured as a component temperature detection unit, is installed in the vicinity of the lamp 51, and measures the temperature of the lamp 51 due to light emission. Further, the measured temperature data is output to the cooling control unit 20. The thermistor 28 for liquid crystal panel is similarly configured as a component temperature detection unit, is installed in the vicinity of the liquid crystal panel 52, and measures the temperature of the liquid crystal panel 52 that generates heat by the light beam emitted from the lamp 51. Further, the measured temperature data is output to the cooling control unit 20.

  In the present embodiment, the rotation speed storage unit 21 is configured such that when the lamp cooling fan 25A and the liquid crystal panel cooling fan 26A cool the lamp 51 and the liquid crystal panel 52, the lamp cooling fan 25A corresponding to a predetermined temperature as a cooling target. And a predetermined number of revolutions of the liquid crystal panel cooling fan 26A.

  In the present embodiment, when the lamp cooling fan 25A and the liquid crystal panel cooling fan 26A cool the lamp 51 and the liquid crystal panel 52, the temperature storage unit 22 stores respective predetermined temperatures as cooling targets.

  Further, the cooling control unit 20 operates as a rotation speed detection unit, and inputs the pulse signals output from the lamp cooling fan 25A and the liquid crystal panel cooling fan 26A described above as rotation speed detection signals and reads the read pulses. The signal is counted and detected as each detected rotation speed. The rotation speed detection unit is constructed by executing a program corresponding to the rotation speed detection unit stored in the cooling control unit 20.

  The cooling control unit 20 operates as a component temperature detection unit, inputs each temperature data detected by the lamp thermistor 27 and the liquid crystal panel thermistor 28, and detects each temperature based on the input temperature data. Detect as. The component temperature detector is constructed by executing a program corresponding to the component temperature detector stored in the cooling controller 20.

  The cooling control unit 20 operates as a temperature comparison unit, acquires the predetermined temperatures of the lamp 51 and the liquid crystal panel 52 stored in the temperature storage unit 22, and detects the predetermined temperatures and the component temperature detection unit. Each detected component temperature is compared to determine whether the detected component temperature is higher than a predetermined temperature. Then, when the temperature comparison unit determines that the detected component temperature is equal to or lower than the predetermined temperature, the cooling control unit 20 operates the rotation number detection unit and a rotation number comparison unit described later.

  In particular, in the present embodiment, when the temperature comparison unit determines that the component temperature is higher than the predetermined temperature, the cooling control unit 20 sets the detected component temperature below the predetermined temperature as a predetermined process for the fan drive unit 23A. Then, the lamp cooling fan 25A and the liquid crystal panel cooling fan 26A are driven. The temperature comparison unit is constructed by executing a program corresponding to the temperature comparison unit stored in the cooling control unit 20.

  Further, the cooling control unit 20 operates as a rotation number comparison unit, acquires a predetermined rotation number corresponding to each predetermined temperature of the lamp 51 and the liquid crystal panel 52 stored in the rotation number storage unit 21, and each predetermined rotation The number is compared with the detected rotational speeds of the cooling fan for lamp 25A and the cooling fan for liquid crystal panel 26A. Then, the cooling control unit 20 causes the fan drive unit 23A to perform a predetermined process based on the comparison determination result between the detected rotation speed and the predetermined rotation speed in the rotation speed comparison unit, and the lamp cooling fan 25A and The liquid crystal panel cooling fan 26A is driven.

  In particular, in the present embodiment, the cooling control unit 20 determines whether the detected temperature is lower than a predetermined temperature in the determination by the temperature comparison unit described above, and if the detected rotational speed is higher than the predetermined rotational speed, On the other hand, as a predetermined process, a correction process is performed so that the detected rotational speed is a rotational speed in the vicinity of the predetermined rotational speed, and the lamp cooling fan 25A and the liquid crystal panel cooling fan 26A are driven. In the present embodiment, the cooling control unit 20 performs the predetermined processing when the detected component temperature is equal to or lower than the predetermined temperature and the detected rotational speed is equal to or lower than the predetermined rotational speed in the determination by the temperature comparison unit described above. By maintaining the detected rotational speed, the lamp cooling fan 25A and the liquid crystal panel cooling fan 26A are driven. The rotation speed comparison unit is constructed by executing a program corresponding to the rotation speed comparison unit stored in the cooling control unit 20.

  The cooling control unit 20 also controls cooling of other components (not shown), but the description thereof is omitted in this embodiment.

Next, the configuration and operation of the optical system 50 of the projector 1 will be briefly described.
The optical system 50 includes a light source device, an illumination optical system, a light modulation device, a color synthesis optical system, and a projection optical device.

  In this embodiment, the light source device uses a discharge-type lamp 51, and the light beam emitted from the arc tube is reflected by a reflector and emitted as parallel light to the next illumination optical system. The lamp 51 is driven by the lamp driving unit 16 that has received a control signal from the control unit 10. Further, the lamp 51 of the present embodiment uses an ultra high pressure mercury lamp.

The illumination optical system (not shown) equalizes the illuminance of the light beam emitted from the light source device (lamp 51) and separates it into each color light (red light, green light, and blue light).
In this embodiment, the light modulation device uses the liquid crystal panel 52, and modulates the light beams of the respective color lights separated by the illumination optical system in accordance with the projection video signal to form an optical image. The liquid crystal panel 52 is driven by the liquid crystal panel drive circuit 15 described above. Moreover, the liquid crystal panel 52 of this embodiment uses the three liquid crystal panels 52 corresponding to each color light.

The color synthesis optical system (not shown) synthesizes optical images of the respective color lights that are color-separated by the illumination optical system and modulated by the light modulation device (liquid crystal panel 52).
In the present embodiment, the projection optical apparatus uses the projection lens 53, and is composed of various lens groups, and projects an optical image synthesized by the color synthesis optical system. With the configuration and operation of the optical system 50, an optical image is projected as an image on a screen 500 installed outside the projector 1.

  FIG. 2 is a flowchart showing a processing procedure related to cooling control in the cooling control unit of the projector. Note that FIG. 2 shows a processing procedure particularly when cooling control is performed on the liquid crystal panel 52. A processing procedure related to cooling control in the cooling control unit 20 will be described with reference to FIG.

The cooling control unit 20 starts this routine and proceeds to step S100.
In step S100, the cooling control unit 20 operates as a component temperature detection unit. The cooling control unit 20 causes the liquid crystal panel thermistor 28 to detect the temperature around the liquid crystal panel 52 as a component temperature corresponding to the temperature of the liquid crystal panel 52. The cooling control unit 20 detects the detected component temperature T1 of the liquid crystal panel 52 based on the detected temperature data of the component temperature. Next, the process proceeds to step S101.

  In step S101, the cooling control unit 20 operates as a temperature comparison unit. The cooling control unit 20 reads the predetermined temperature T of the liquid crystal panel 52 from the temperature storage unit 22 and compares the detected component temperature T1 with the predetermined temperature T. Specifically, it is determined by comparing whether or not the detected component temperature T1 is equal to or lower than a predetermined temperature T. When it is determined that the detected component temperature T1 is equal to or lower than the predetermined temperature T, the process proceeds to step S102. When it is determined that the detected component temperature T1 is higher than the predetermined temperature T, the process proceeds to step S105.

  In step S102, the cooling control unit 20 operates as a rotation speed detection unit. The cooling control unit 20 inputs the pulse signal output from the liquid crystal panel cooling fan 26A as a rotation speed detection signal, counts the read pulse signal, and detects it as the detected rotation speed N1 of the liquid crystal panel cooling fan 26A. . Next, the process proceeds to step S103.

  In step S101, if the temperature comparison unit determines that the detected component temperature T1 is higher than the predetermined temperature T and proceeds to step S105, the cooling control unit 20 performs a correction process on the fan drive unit 23A in step S105. Make it. Specifically, control is performed to vary the duty ratio of the drive signal (pulse wave). In the present embodiment, the cooling control unit 20 executes a control program stored therein, and outputs an instruction signal to the fan drive unit 23A. Then, the fan drive unit 23A (PWM unit 24A) performs a correction process by performing a process of increasing the duty ratio by a predetermined value set with respect to the current duty ratio in response to an instruction signal from the cooling control unit 20. A drive signal with a duty ratio is output. The liquid crystal panel cooling fan 26A is driven by a drive signal output from the fan drive unit 23A. In addition, after performing step S105, it returns to step S100.

  In step S103, the cooling control unit 20 operates as a rotation speed comparison unit. The cooling control unit 20 reads the predetermined rotational speed N of the liquid crystal panel cooling fan 26A corresponding to the predetermined temperature T of the liquid crystal panel 52 from the rotational speed storage unit 21, and compares the detected rotational speed N1 with the predetermined rotational speed N. . Specifically, it is determined by comparing whether or not the detected rotation speed N1 is equal to or less than a predetermined rotation speed N. If it is determined that the detected rotational speed N1 is equal to or lower than the predetermined rotational speed N, the process proceeds to step S104. If it is determined that the detected rotational speed N1 is higher than the predetermined rotational speed N, the process proceeds to step S106.

In step S104, the cooling control unit 20 outputs an instruction signal that causes the fan driving unit 23A to maintain the current detected rotation speed N1 of the liquid crystal panel cooling fan 26A, so that the fan driving unit 23A outputs the current Maintain the duty ratio of the drive signal (pulse wave). Accordingly, the liquid crystal panel cooling fan 26A is driven while maintaining the current rotational speed.
After step S104, in step S107, it is confirmed whether or not the power switch (SW) of the projector 1 is OFF. If the power SW is not OFF, the process returns to step S100 and the same processing is repeated. When the power is turned off, the routine described above is terminated.

  In step S103, when the rotational speed comparison unit determines that the detected rotational speed N1 is higher than the predetermined rotational speed N and proceeds to step S106, the cooling control unit 20 performs a correction process on the fan drive unit 23A in step S106. To do. Specifically, control is performed to vary the duty ratio of the drive signal (pulse wave). In the present embodiment, the cooling control unit 20 executes a control program stored therein, and outputs an instruction signal to the fan drive unit 23A. Then, the fan drive unit 23A (PWM unit 24A) performs a correction process by performing a process of reducing the duty ratio by a predetermined value set with respect to the current duty ratio in accordance with an instruction signal from the cooling control unit 20. A drive signal with a duty ratio is output. The liquid crystal panel cooling fan 26A is driven by a drive signal output from the fan drive unit 23A. After executing step S106, the process returns to step S100, and the same processing as described above is performed. By repeating this routine, the detected rotational speed N1 can be adjusted to a rotational speed in the vicinity of the predetermined rotational speed N.

  FIG. 2 shows the processing procedure when the cooling control is performed on the liquid crystal panel 52, but the same processing procedure can be performed when the cooling control is performed on the lamp 51.

According to the embodiment described above, the following effects can be obtained.
(1) According to the projector 1 of the present embodiment, the liquid crystal panel cooling fan 26A, the fan driving unit 23A, the rotation number detection unit, the rotation number storage unit 21, the rotation number comparison unit, the cooling control unit 20, and the component temperature detection unit A temperature storage unit 22 and a temperature comparison unit are provided. In addition, the component temperature detection unit, the rotation number detection unit, the temperature comparison unit, the rotation number comparison unit, and the like are constructed by executing the corresponding program of the cooling control unit 20. When the temperature comparison unit determines that the detected component temperature T1 of the liquid crystal panel 52 is equal to or lower than the predetermined temperature T, the cooling control unit 20 operates the rotation speed detection unit to detect the liquid crystal panel cooling fan 26A. The rotation speed N1 is detected. Then, the rotational speed comparison unit is operated to compare the detected rotational speed N1 with the predetermined rotational speed N. When the detected rotational speed N1 is higher than the predetermined rotational speed N, a drive signal is sent to the fan drive unit 23A. By performing correction processing such as reducing the duty ratio of (pulse wave) by a predetermined value, the rotation of the cooling fan 26A for the liquid crystal panel is set to a rotation speed around a predetermined rotation speed N.
Therefore, the variation of the drive voltage generated due to the characteristic variation of the circuit components for generating the drive voltage to the conventional cooling fan, the variation of the rotation speed with respect to the drive voltage due to the characteristic variation of the cooling fan itself, etc. are corrected. The liquid crystal panel cooling fan 26A can be rotated at a substantially accurate rotational speed. In addition, the liquid crystal panel 52 can be prevented from being overcooled because it is corrected to rotate at a rotational speed in the vicinity of the predetermined rotational speed N.
Further, when the detected rotational speed N1 is higher than the predetermined rotational speed N (when the liquid crystal panel cooling fan 26A rotates more than necessary), the noise of the projector 1 is adjusted to the rotational speed near the predetermined rotational speed N. The level can be reduced.

  (2) According to the projector 1 of the present embodiment, when the temperature comparison unit determines that the detection component temperature T1 of the liquid crystal panel 52 is higher than the predetermined temperature T, the cooling control unit 20 By performing control not to operate the rotation speed comparison unit, it is possible to reduce a load on interrupt processing of the control unit 10 including the cooling control unit 20 that controls the projector 1 in an integrated manner.

  (3) According to the projector 1 of the present embodiment, the cooling control unit 20 determines that the rotation number comparison unit determines that the detected rotation number N1 is equal to or less than the predetermined rotation number N, the fan driving unit 23A includes a liquid crystal panel. By causing the cooling fan 26A to be driven at the current rotational speed (detected rotational speed N1), the noise level of the projector 1 can be kept low.

  (4) According to the projector 1 of the present embodiment, the cooling control unit 20 determines that the temperature comparison unit determines that the detected component temperature T1 of the liquid crystal panel 52 is higher than the predetermined temperature T, with respect to the fan drive unit 23A. The fan drive unit 23A performs correction processing such as reducing the duty ratio of the drive signal (pulse wave) by a predetermined value, drives the cooling fan 26A for the liquid crystal panel, and sets the detected component temperature T1 to a predetermined value. Temperature T or lower. Therefore, when it is determined that the detected component temperature T1 of the liquid crystal panel 52 is higher than the predetermined temperature T, the cooling control unit 20 does not detect the number of rotations and controls the component temperature of the liquid crystal panel 52 to control the cooling. It is possible to reduce a load on processing associated with rotation speed detection of the control unit 20 and the control unit 10 that controls the projector 1 in an integrated manner.

The above-described effects are also the same when the cooling control unit 20 controls the cooling of the lamp 51 using the lamp cooling fan 25A and the lamp thermistor 27.
(Second Embodiment)

  FIG. 3 is a circuit block diagram of the projector according to the second embodiment. The configuration and operation of the projector 2 will be described with reference to FIG.

  The present embodiment is different from the circuit block of the first embodiment only in a fan driving unit 23B, a lamp cooling fan 25B as a cooling fan, and a liquid crystal panel cooling fan 26B, and other circuit configurations. Is the same as in the first embodiment. In FIG. 3, the same reference numerals are given to the same components as those in the first embodiment. Therefore, a different part from 1st Embodiment is demonstrated.

  The fan drive unit 23B according to the present embodiment includes a drive voltage generation unit 24B, generates a predetermined constant voltage to be set according to an instruction signal from the cooling control unit 20, and uses the lamp cooling fan 25B and the liquid crystal panel as drive voltages. Output to the cooling fan 26B.

  In the present embodiment, the lamp cooling fan 25B includes a DC fan motor that outputs a signal for detecting the rotational speed. The lamp cooling fan 25B is driven (rotated) by the drive voltage output from the fan drive unit 23B, and cools the heat generated by the lamp 51. The lamp cooling fan 25B outputs a pulse signal proportional to the rotation speed to the cooling control unit 20 as a rotation speed detection signal.

  In the present embodiment, the liquid crystal panel cooling fan 26B is also configured to include a DC fan motor that outputs a signal for detecting the rotational speed. The liquid crystal panel cooling fan 26 </ b> B is driven (rotated) by the drive voltage output from the fan drive unit 23 </ b> B to cool the heat generated by the liquid crystal panel 52. The liquid crystal panel cooling fan 26B outputs a pulse signal proportional to the rotational speed to the cooling control unit 20 as a rotational speed detection signal.

  FIG. 4 is a flowchart illustrating a processing procedure related to cooling control in the cooling control unit of the projector. FIG. 4 shows a processing procedure particularly when cooling control is performed on the liquid crystal panel 52. A processing procedure related to cooling control in the cooling control unit 20 will be described with reference to FIG.

  In the present embodiment, compared to the flowchart of the first embodiment, only the processing contents in step S108 and step S109 in the processing procedure of the cooling control unit 20 are different. This is the same as the processing procedure in one embodiment. In addition, the same code | symbol is attached | subjected to the part of the processing procedure similar to 1st Embodiment. Therefore, a different part from 1st Embodiment is demonstrated.

  In the present embodiment, in step S101, when the temperature comparison unit determines that the detected component temperature T1 is higher than the predetermined temperature T and proceeds to step S108, the cooling control unit 20 corrects the fan drive unit 23B in step S108. Allow processing to occur. Specifically, control for varying the drive voltage is performed. In the present embodiment, the cooling control unit 20 executes a control program stored therein, and outputs an instruction signal to the fan drive unit 23B. Then, the fan drive unit 23B (drive voltage generation unit 24B) performs a process of increasing the drive voltage by a predetermined value set with respect to the current drive voltage as a correction process in accordance with an instruction signal from the cooling control unit 20, and performs correction. Output the processed drive voltage. The liquid crystal panel cooling fan 26B is driven by the drive voltage output from the fan drive unit 23B. In addition, after performing step S108, it returns to step S100.

  In the present embodiment, in Step S103, when the rotational speed comparison unit determines that the detected rotational speed N1 is higher than the predetermined rotational speed N, and proceeds to Step S109, the cooling control unit 20 performs fan driving in Step S109. The unit 23B performs correction processing. Specifically, control for varying the drive voltage is performed. In the present embodiment, the cooling control unit 20 executes a control program stored therein, and outputs an instruction signal to the fan drive unit 23B. Then, the fan drive unit 23B (drive voltage generation unit 24B) performs a process of reducing the drive voltage by a predetermined value set with respect to the current drive voltage as a correction process in accordance with an instruction signal from the cooling control unit 20, and performs correction. Output the processed drive voltage. The liquid crystal panel cooling fan 26B is driven by the drive voltage output from the fan drive unit 23B. After executing step S109, the process returns to step S100, and the same operation process as in the first embodiment is performed. By repeating this routine, the detected rotational speed N1 can be adjusted to a rotational speed in the vicinity of the predetermined rotational speed N.

  FIG. 4 shows the processing procedure when the cooling control is performed on the liquid crystal panel 52, but the same processing procedure can also be performed when the cooling control is performed on the lamp 51.

  According to the above-described embodiment, when the cooling fan for lamp 25B and the cooling fan for liquid crystal panel 26B as cooling fans use a DC fan motor for constant voltage instead of a DC fan motor for PWM control, By configuring the drive voltage generation unit 24B as the fan drive unit 23B and generating a predetermined drive voltage, the same effects as in the first embodiment can be obtained.

  In addition, it is not limited to embodiment mentioned above, It is possible to add and implement various changes, improvements, etc. A modification will be described below.

  (Modification 1) In the above embodiment, when the detection component temperature T1 is determined to be equal to or lower than the predetermined temperature T in the determination by the temperature comparison unit, the rotation number detection unit and the rotation number comparison unit are operated. However, the present invention is not limited to this, and even when the detected component temperature T1 is higher than the predetermined temperature T, the rotational speed detection unit and the rotational speed comparison unit may be operated. Thereby, although the load to the cooling control unit 20 and the control unit 10 is applied, accurate rotation can be performed.

  (Modification 2) In the above embodiment, the temperature of the lamp 51 and the liquid crystal panel 52 is detected using two thermistors, the lamp thermistor 27 and the liquid crystal panel thermistor 28, and the lamp cooling fans 25A and 25B and the liquid crystal panel are detected. However, the present invention is not limited to this, and the lamp cooling fans 25A and 25B and the liquid crystal panel cooling fans 26A and 26B may be controlled using one of the thermistors. In that case, it implement | achieves by setting each correction | amendment process corresponding to the detected component temperature of the thermistor to be used.

  (Modification 3) In the above embodiment, the projectors 1 and 2 using the three liquid crystal panels 52 in the light modulation device have been described. However, the present invention is not limited to this. For example, the invention can be applied to a projector using only one liquid crystal panel, a projector using two liquid crystal panels, or a projector using four or more liquid crystal panels.

  (Modification 4) Although the transmissive liquid crystal panel 52 is used in the above embodiment, a reflective light modulation device such as a reflective liquid crystal panel may be used.

  (Modification 5) In the embodiment, the liquid crystal panel 52 is used in the light modulation device. However, the present invention is not limited to this, and in general, any device that modulates incident light according to image information may be used, and a micromirror light modulator or the like may be used. For example, a DMD (Digital Micromirror Device) can be used as the micromirror type light modulation element.

  (Modification 6) In the above embodiment, a discharge lamp is used as the lamp 51 as the light source device. However, the present invention is not limited to this, and the light source device may be an LED (Light Emitting Diode) element, an LD (Laser Diode) element, or the like. Can be used.

  (Modification 7) Although the projectors 1 and 2 of the embodiment are applied as front-type projectors, they can also be applied to rear-type projectors integrally having a screen as a projection target surface.

  DESCRIPTION OF SYMBOLS 1, 2 ... Projector, 20 ... Cooling control part, 21 ... Rotation speed memory | storage part, 22 ... Temperature storage part, 23A, 23B ... Fan drive part, 24A ... PWM part, 24B ... Drive voltage generation part, 25A, 25B ... Lamp Cooling fan for liquid crystal, 26A, 26B ... Cooling fan for liquid crystal panel, 27 ... Thermistor for lamp, 28 ... Thermistor for liquid crystal panel, 50 ... Optical system, 51 ... Lamp, 52 ... Liquid crystal panel, 53 ... Projection lens, 500 ... Screen, N: predetermined rotational speed, N1: detected rotational speed, T: predetermined temperature, T1: detected component temperature.

(Application Example 1) The projector according to this application example, the cooling and outputs a signal for rotation speed detection, and a cooling fan for cooling the cooling target, and a fan driving portion for driving the cooling fan, the rotation speed detection signal a rotation speed detector which detect the rotational speed of the fan, the rotation speed storing section for storing a predetermined number of revolutions of the cooling fan that is set for the cooling target cooled, a cooling control unit for controlling the cooling operation, the provided, the cooling control unit on the basis of the ratio 較結 results of the detected rotational speed and a predetermined rotational speed, against the fan drive, characterized in that make driving a cooling fan to perform the predetermined processing .

(Application Example 2) in the above-described projector, comprising: a component temperature detection unit that detect the component temperature of the cooling target, and the temperature storage unit for storing a predetermined temperature set for the cooling target cooled, and cooling control unit, when the detected component temperature is below a predetermined temperature, the rotation speed detector is detecting the rotational speed of the cooling fan, it is preferable to compare the detected rotational speed and a predetermined rotational speed.

(Application Example 3) in the above-described projector, the cooling control unit, when the rotation speed detected is larger than a predetermined rotational speed, with respect to the fan driving unit, performing correction processing for driving the cooling fan in the vicinity predetermined rotational speed it is preferred that to Ru.

(Application Example 4) in the above-described projector, the cooling control unit, when the rotation speed detected is less than a predetermined rotational speed, with respect to the fan drive unit, preferably a benzalkonium to maintain the rotational speed of the cooling fan .

A (Application Example 5) above projector, the cooling control unit, when the detected component temperature is greater than a predetermined temperature, to the fan driving unit, cooling at a rotation speed to the component temperature of the cooling target is the predetermined temperature or less It is preferable to drive the fan .
Further, in the projector described above, the fan driving unit outputs a driving signal to the cooling fan to drive the cooling fan, and the cooling control unit sets the duty ratio of the driving signal to the fan driving unit as a correction process. It is preferable to perform a process of increasing by a predetermined value.

Claims (5)

A projector for cooling internal components having a cooling fan that outputs a signal for detecting the number of revolutions,
A fan driving unit for driving the cooling fan;
A rotational speed detection unit that detects the rotational speed of the cooling fan as a detected rotational speed based on the rotational speed detection signal output by the cooling fan;
A rotational speed storage unit for storing a predetermined rotational speed of the cooling fan set when cooling the internal components;
A rotation number comparison unit that compares the detected rotation number detected by the rotation number detection unit with the predetermined rotation number stored in the rotation number storage unit;
A cooling control unit for controlling the cooling operation,
The cooling control unit drives the cooling fan by causing the fan driving unit to perform a predetermined process based on a comparison determination result between the detected rotation number and the predetermined rotation number in the rotation number comparison unit. A projector characterized by that. The projector according to claim 1,
A component temperature detector for detecting a component temperature of the internal component of the projector as a detected component temperature;
A temperature storage unit for storing a predetermined temperature set when cooling the internal components;
A temperature comparison unit that compares the detected component temperature detected by the component temperature detection unit with the predetermined temperature stored in the temperature storage unit;
The cooling control unit operates the rotation number detection unit and the rotation number comparison unit when the temperature comparison unit determines that the detected component temperature is equal to or lower than the predetermined temperature. The projector according to claim 2,
When the rotation speed comparison unit determines that the detected rotation speed is higher than the predetermined rotation speed, the cooling control section performs the predetermined processing on the detected rotation speed as the predetermined processing for the fan drive section. A projector characterized in that correction processing is performed to obtain a rotational speed in the vicinity of the rotational speed, and the cooling fan is driven. The projector according to claim 3, wherein
The cooling control unit causes the fan driving unit to maintain the detected rotational speed as the predetermined processing when the rotational speed comparison unit determines that the detected rotational speed is equal to or less than the predetermined rotational speed. And a cooling fan that drives the cooling fan. The projector according to claim 2,
When the temperature comparison unit determines that the detected component temperature is higher than the predetermined temperature, the cooling control unit is configured to reduce the detected component temperature to the predetermined temperature or less as the predetermined process for the fan drive unit. And a correction process for driving the cooling fan.

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