JP5011505B2 - Projection apparatus, operation control method and program for projection apparatus - Google Patents

Description

  The present invention relates to a projection apparatus suitable for a projector using a high-intensity light source lamp, an operation control method for the projection apparatus, and a program.

  Conventionally, in a projector apparatus, in order to prevent deterioration of a light source lamp such as a high-pressure mercury lamp that becomes extremely high temperature, a control that detects a state in which the lamp temperature is abnormal and stops the light emission driving is generally performed. It has been implemented.

In particular, in order to provide a liquid crystal projector that achieves low power consumption and long lamp life and secures safety, a temperature sensor and a rotation detector that detect abnormality of the device, and a set time when the sleep timer operates A stop control signal generator generates a stop control signal in response to various detection signals such as a timer that detects that a few minutes have passed and an input detector that detects that a video signal is not input for a certain period of time. A technology that displays a warning on the liquid crystal display panel by the warning display control unit in accordance with the stop control signal, displays a warning by blinking the light emitting element in the warning display unit, and further shuts off the power source of the light source by the power control unit Is considered. (For example, Patent Document 1)
JP 07-333571 A

  In a conventional general projector apparatus including the technique described in the above-mentioned patent document, a temperature abnormality is determined by detecting whether or not a preset state is exceeded.

  Therefore, it can be recognized for the first time when the temperature is in an abnormal state, and a state that is likely to be abnormal in temperature cannot be detected in advance.

  For example, if the air inlet of the cooling fan for cooling the light source lamp is blocked with paper, the rotational speed of the cooling fan itself will not change, but the temperature of the light source lamp will increase rapidly because efficient cooling is not possible. However, it is not determined to be abnormal until the temperature of the light source lamp exceeds a preset value, and it is not abnormal until the temperature exceeds the preset temperature and there is a risk of deterioration of the light source lamp. A decision will be made.

  The present invention has been made in view of the above circumstances, and the object of the present invention is to detect a temperature abnormality of the light source lamp in an earlier state, and reliably and reliably prevent the deterioration of the light source lamp and the stop of the projection operation. It is an object of the present invention to provide a projection apparatus, a projection apparatus operation control method, and a program that can be prevented in advance.

First aspect of the present invention, a projection means for using the light emitted from the light source to form to project an optical image corresponding to an input image signal, a temperature detecting means for detecting the temperature of the upper Symbol light source, a determining means for the degree of change in temperature of the light source detected by the temperature detecting means to determine the temperature anomaly by whether exceeds a predefined value, a warning notification when judging that a temperature abnormality in this determination means Alarm means for performing, counting means for counting a state in which temperature abnormality is determined by the determination means, and operation control means for stopping the projection operation of the projection means when the count value of the count means reaches a predetermined value; It is characterized by comprising.

The invention according to claim 4 is an operation control method of a projection apparatus including a projection unit that forms and projects a light image corresponding to an input image signal using light emitted from a light source, and the temperature of the light source A temperature detecting step for detecting the temperature, a determining step for determining whether or not the temperature change of the light source detected in the temperature detecting step exceeds a predetermined value, and a temperature abnormality in the determining step. A warning process that gives a warning notification when it is determined, a counting process that counts a state in which a temperature abnormality has been determined in the determination process, and a projection operation in the projection unit when the count value of the count process reaches a predetermined value And an operation control step for stopping.

According to a fifth aspect of the present invention, there is provided a program executed by a computer built in a projection apparatus including a projection unit that forms and projects a light image corresponding to an input image signal using light emitted from a light source. A temperature detection step for detecting the temperature of the light source, a determination step for determining a temperature abnormality based on whether or not the degree of change in temperature of the light source detected in the temperature detection step exceeds a predetermined value, and this determination A warning step for providing a warning when a temperature abnormality is determined in step, a counting step for counting the state in which the temperature abnormality is determined in the determination step, and the projection unit when the count value of the count step reaches a predetermined value And an operation control step for stopping the projection operation in the computer.

Claim 1, according to the invention described 4,5, since in the case where rapid temperature rise of the light source occurs and continues for a predetermined period of time is assumed to automatically stop the projection operation by counting this Even when the user has overlooked the warning notification, it is possible to reliably avoid deterioration or damage of the light source.

  Hereinafter, an embodiment when the present invention is applied to a DLP (Digital Light Processing) (registered trademark) projector apparatus will be described with reference to the drawings.

  FIG. 1 is an external perspective view of the projector apparatus in use, and FIG. 2 is a cross-sectional plan view of the projector apparatus.

  The projector device has a light source device 17 and a display area in which a plurality of pixels are arranged in a matrix in the row direction and the column direction in a projector case 1 having a rectangular planar shape, and is incident on the plurality of pixels. The display element 28 that controls the emission of the emitted light to display an image, the light source side optical system 29 that makes the emitted light from the light source device 17 incident on the display element 28, and the emitted light from the display element 28 are shown in the figure. And a projection lens 45 that projects onto a projection surface such as a screen that is not.

  The projector case 1 includes a case main body 1a constituting both side surfaces, a rear surface, and a bottom surface, an upper panel 1b, and a front panel 1c. On the rear surface of the projector case 1, a personal computer USB terminal and a color image signal are provided. An audio signal input terminal, a video signal input terminal, and a power connector (both not shown) are provided, and a power key 2 on the upper surface, a lamp indicator 3 for displaying the lighting of the light source device 17, and the light source device The overheat indicator 4 that displays 17 overheat, the automatic image quality adjustment key 5 and the silent mode setting key 6, the standby state in which the power connector is connected to a commercial power source, and the power color of the power key 2 are turned on. A changing power / standby indicator 7, various adjustment keys (not shown) operated by opening the opening / closing lid 8, and a speaker sound emitting unit 9 are provided. Is, on the front, the remote control receiving unit 10 for receiving an infrared signal from a remote control device (not shown) provided.

  Further, on the bottom surface of the projector case 1, a pair of left and right rear foot members 14a disposed on both sides of the rear region, and a position slightly rearward from the front edge of the case near the center of the front region. One forefoot member 14b is provided.

  The rear foot member 14a and the front foot member 14b support the projector case 1 in an obliquely upward state with the front side raised when the projector is used (during projection). It is fixed to the lower end of a screw leg (not shown) screwed to the bottom of the projector case 1, and the forefoot member 14b is held by a leg lock mechanism (not shown) provided in the projector case 1 so as to be slidable in the vertical direction. It is fixed to the lower end of the rod leg 15 and is provided so that the protruding height from the bottom surface of the case can be adjusted.

  Next, the light source device 17 will be described. As shown in FIG. 2, the light source device 17 has a light source lamp 18 and an open surface for emitting light, reflects the emitted light from the light source lamp 18 disposed inside, and emits the light from the open surface. The reflector 21 is provided.

  The light source lamp 18 is a short arc lamp such as a high-pressure mercury lamp whose middle portion swells in a spherical shape. One reflector 21 is an ellipsoidal reflector having a focal point at a point in the reflector on the axis and a point in front of the open surface, and an ultraviolet transmissive reflective film is provided on the entire inner surface of the heat-resistant glass body. The cylindrical explosion-proof cover 25 and the explosion-proof glass 24 are fitted to the front side of the open surface.

  The display element 28 is a display element that does not include a means for coloring incident light such as a color filter. In this embodiment, the display element 28 is a micromirror display element (registered trademark) generally abbreviated as DMD. Is used. Hereinafter, the display element 28 is referred to as a micromirror display element.

  Although the configuration of the micromirror display element 28 is not shown, each pixel is arranged in an array in which each pixel is tilted in one tilt direction and the other tilt direction by a CMOS-based mirror driving element. These micromirrors are made of ultrathin metal pieces (for example, aluminum pieces) having a vertical and horizontal width of 10 [μm] to 20 [μm].

  The micromirror display element 28 is arranged on one side of the rear region in the projector case 1 with its front direction facing the projection port 11 provided on one side of the front surface of the projector case 1. .

  The light source side optical system 29 that causes the light emitted from the light source device 17 to enter the micromirror display element 28 is for sequentially coloring the light emitted from the light source device 17 into three colors of red, green, and blue. Color wheel 30, light guide rod 33 for making the intensity distribution of light emitted from light source device 17 uniform, and light colored by color wheel 30 and made uniform in intensity distribution by light guide rod 33 Is composed of a lens support cylinder 36 and a mirror 37 incorporating two front and rear light source side lenses for projecting toward the front surface of the micromirror display element 28.

  The color wheel 30 is composed of a rotating plate in which fan-shaped red, green and blue color filters are arranged in the circumferential direction, and is fixed to the rotating shaft of the color wheel rotating motor 32. Are arranged in the optical path of the outgoing light from the light source device 17, and the three color filters are rotated at high speed by the motor 32 so as to sequentially traverse the optical path of the outgoing light from the light source device 17. .

  The light guide rod 33 has a cross-sectional shape similar to the outer shape of a display area in which a plurality of pixels of the micromirror display element 28 are arranged in a matrix shape, and has a reflection film provided on the entire inner peripheral surface. An incident surface for entering light is formed at one end of the cylindrical body, an exit surface for light incident from the incident surface is formed at the other end, and the light incident from the incident surface is transmitted to the inner peripheral surface of the rod. The light is guided while being reflected by the reflective film, and light having a uniform intensity distribution is emitted from the emission surface.

  The reflector 21 of the light source device 17, the color wheel rotation motor 32 of the light source side optical system 29, and the lens support cylinder 36 incorporating the light guide rod 33 and two light source side lenses are open on the light source side. The housing 38 is fixed in a predetermined positional relationship.

  The mirror 37 of the light source side optical system 29 is a plane mirror. The mirror 37 has openings 40, 41, and 42 on one side, the rear surface, and the front surface. The exit end of the lens support tube 36 is inserted into the opening 40 on one side surface, and the rear surface opening 41 is displayed on the micromirror display. In the mirror housing 39 installed in the projector case 1 so as to face the element 28, the light source device is made to face the emission end of the lens support tube 36 across the front area of the micromirror display element 28. 17, the light transmitted through the color wheel 30, the light guide rod 33, and the lens support tube 36 is reflected toward the micromirror display element 28, and the reflected light is reflected on the micromirror display element 28. It arrange | positions so that it may project from the direction inclined in one direction with respect to the direction.

  A cover glass 43 that protects the micromirror display element 28 is disposed on the front surface of the micromirror display element 28. The cover glass 43 is provided on the front surface side of the opening on the rear surface of the mirror housing 39 and is emitted from the light source device 17. Then, the light projected on the micromirror display element 28 by the light source side optical system 29 is corrected to parallel light along a direction inclined by a predetermined angle with respect to the front direction of the micromirror display element 28, and the micromirror display element A relay lens 44 is provided that collects the image light emitted from the micromirror display element 28 and enters the projection lens 45.

  The relay lens 44 emits the light reflected on the surface of the relay lens surface out of the projection light from the light source side optical system 29 in a direction other than the projection direction by the projection lens 45.

  The projection lens 45 includes an incident-side fixed barrel 46 and an emission-side movable barrel 47 that is engaged with the fixed barrel 46 and moves forward and backward in the axial direction by a rotation operation. 47 is a variable focus lens provided with lens groups 48 and 49 each composed of a combination of a plurality of lens elements, and the incident end of the fixed barrel 46 is connected to the micromirror display via the relay lens 44. Opposite to the element 28, the exit end of the movable lens barrel 47 is movably fitted to the projection port 11 provided on one side of the front surface of the projector case 1, and is disposed in the projector case 1.

  On the side surface of the projector case 1 on the side where the projection lens is disposed, the movable lens barrel 47 of the projection lens 45 is manually rotated and moved in the axial direction to adjust the focus of the projection lens 45. Is provided.

  In the projector case 1, a display / audio circuit board 51 connected to a USB terminal (not shown) provided on the rear surface of the projector case 1, an input terminal for color image signals and audio signals, and a video signal input terminal is provided. Further, the projector case 1 is disposed in a standing state between the rear surface portion of the projector case 1 and the light source side housing 38, the micromirror display element 28 is provided on the circuit board 51, and a speaker is provided on the upper surface portion in the projector case 1. A speaker (not shown) arranged to face the sound emission unit 9 is connected.

  Further, a power system circuit board 52 connected to a power connector (not shown) provided on the rear surface of the projector case 1 is horizontally disposed in a space on the front side of the light source side housing 38 in the projector case 1. The light source lamp 18 of the light source device 17 is connected to the circuit board 52 via a lead wire (not shown), and the color wheel rotation motor 32 is also connected via a lead wire (not shown).

  In the projector case 1, a projector control circuit board 54 is horizontally disposed between the upper surface portion of the projector case 1 and the light source side housing 38 and the mirror housing 39. An audio system circuit board 51 and a power system circuit board 52, a lamp indicator 3 and an overheat indicator 4 provided on the upper surface of the projector case 1, an automatic image quality adjustment key 5 and a silent mode setting key 6, and a power / standby indicator 7. Various adjustment keys operated by opening the opening / closing lid 8, a receiving element (not shown) provided in the projector case 1 facing the remote control receiving unit 10 on the front surface thereof, and the reflector 21 in the light source side housing 38. A light source temperature measurement sensor (not shown) arranged in the vicinity is connected.

  Further, the bottom surface of the projector case 1, the side surface on the side where the projection lens 45 is disposed, and the rear surface are respectively provided with a plurality of long hole-like intake holes 55, 56, 57 for air-cooling the inside of the projector case 1. Is provided.

  The light source side housing 38 and the power supply system circuit board 52 are arranged with a ventilation space between the bottom surface portion of the projector case 1 and the plurality of air intake holes 55 on the bottom surface of the case are formed on the light source side housing. 38 and the power system circuit board 52.

  The projection lens 45 is disposed with a ventilation space between the side surface portion of the projector case 1 and the plurality of air intake holes 56 on the side surface of the case have projection lens focus adjustment openings 50 on the side surface of the case. It is provided over substantially the entire region of the rear portion.

  Further, the display / audio system circuit board 51 is disposed with a ventilation space between the upper surface portion of the projector case 1 and a plurality of air intake holes 57 on the rear surface of the case are formed on the micromirror display element 28. It is provided in a part corresponding to the arrangement part.

  Among the plurality of intake holes 55 on the bottom surface of the case, an intake hole (not shown) provided on the lower side of the power circuit board 52 and an intake hole 56 on the right side surface of the case are natural intake holes. An air intake hole 55 provided in a lower part of the light source side housing 38 and an air intake hole 57 provided in a part corresponding to the arrangement portion of the micromirror display element 28 on the rear surface of the case are forced air intake holes. 1, intake fans 58 and 59 are arranged to face the forced intake holes 55 and 57, respectively.

  A plurality of elongated exhaust holes 61 are provided on substantially the entire left side surface of the projector case 1 where the light source device 17 is disposed.

  Note that the side surface of the projector case 1 on the side where the light source device 17 is disposed is configured by a fitting panel 60, and the plurality of exhaust holes 61 are provided in substantially the entire area of the fitting panel 60.

  These exhaust holes 61 are all forced exhaust holes. In the projector case 1, a plurality of units, for example, three units are provided in correspondence with the region where the exhaust holes 61 are formed, that is, substantially the entire region of the fitting panel 60. Large wind exhaust fans 62, 63, 64 are arranged.

  The intake fans 58 and 59 and the exhaust fans 62, 63 and 64 are connected to the power supply system circuit board 52.

  The projector device emits light from the light source device 17 and rotates the color wheel 30 of the light source side optical system 29 at a high speed to emit light from the light source device 17 and enter the light source side optical system 29. Are sequentially colored in three colors of red, green, and blue by the color wheel 30, and the light intensity distribution is made uniform by the light guide rod 33, and the micromirror display element is formed by the light source side lenses 34 and 35 and the mirror 37. The micromirror display is performed by sequentially writing red, green and blue monochromatic image data to the micromirror display element 28 in synchronization with the projection period of the red, green and blue light. Red, green, and blue monochromatic images are sequentially displayed on the element 28, and red, green, and blue monochromatic image lights that are sequentially emitted from the micromirror display element 28 are projected onto the projection light. Is intended to be projected on the projection surface is enlarged by FIG. 45, in the projection surface, to display red, green, full-color images that appear to overlap each other monochromatic image of three colors of blue.

  The projector is used by turning on the power by operating the power key 2, and when the power is turned on, the light source lamp 18 of the light source device 17 is turned on and the color wheel 30 is rotated. When driven, red, green, and blue light are sequentially projected onto the micromirror display element 28, and red, green, and blue light sequentially emitted from the micromirror display element 28 are projected by the projection lens 45 and the intake air. The fans 58 and 59 and the exhaust fans 62, 63, and 64 are driven, and air cooling in the projector case 1 is started.

  Further, the posture adjustment of the projector case 1 that matches the projection direction of the projection lens 45 with the projection surface is performed by adjusting the protrusion height of the forefoot member 14b in a state where the red, green, and blue light is projected by the projection lens 45. Is done.

  When an image signal or a video signal is not input from an external device such as a personal computer, red, green and blue lights are sequentially emitted in full gradation from the entire display area of the micromirror display element 28, and the light is emitted. Projected by the projection lens 45. Therefore, the projection area of the projection surface at this time is white throughout.

  When the image signal or video signal is input, red, green, and blue single-color image data are sequentially written in the micromirror display element 28, and three colors of red, green, and blue are displayed on the projection surface. Images are sequentially projected to display a full color image.

  Further, after the image projection is finished, the input of the image signal or video signal is stopped and the power key 2 is operated to turn off the power. The light source of the light source device 17 is turned off by the power key 2 being operated. The lamp 18 is turned off, the rotational driving of the color wheel 30 is stopped, and after a certain time after the after cooling is completed, or when the light source temperature becomes a certain temperature or less, the intake fans 58 and 59 and the exhaust fan 62. , 63, 64 are stopped.

Next, the functional configuration of the main electronic circuit of the projector apparatus will be described with reference to FIG.
In the figure, image signals of various standards including RGB video signals input from the input / output connector unit 71 are converted into images of a predetermined format by the image conversion unit 73 via the input / output interface (I / F) 72 and the system bus SB. After being unified into a signal, it is sent to the projection encoder 74.

  The projection encoder 74 develops and stores the transmitted image signal in the video RAM 75, generates a video signal from the stored contents of the video RAM 75, and outputs the video signal to the projection processing unit 76.

  The projection processing unit 76 appropriately speeds up time division by multiplying an appropriate frame rate, for example, 60 [frames / second], the number of color component divisions, and the number of display gradations in accordance with the transmitted image signal. The micromirror display element 28 is driven to display by driving.

  High-luminance white light emitted from the light source lamp 18 disposed in the reflector 21 is appropriately colored to the primary color via the color wheel 30 with respect to the micromirror display element 28, and the light guide rod 33, mirror By irradiating through 37 etc., an optical image is formed by the reflected light, and projected and displayed on a screen (not shown) through the projection lens 45 etc.

  However, the lighting driving of the light source lamp 18 and the color wheel rotation motor (M) 32 for rotating the color wheel 30 operate based on the supply voltage from the projection drive unit 77.

  The projection drive unit 77 also receives a detection signal from a light source temperature measurement sensor 78 attached in the vicinity of the light source lamp 18 of the reflector 21, digitizes it, and outputs it to the control unit 80.

  The control unit 80 controls all the operations of the above circuits. The control unit 80 includes a CPU and a non-volatile memory, a work memory, a timer, and the like that store an operation program executed by the CPU including processes such as a projection operation and a power control operation described later.

  The control unit 80 is also connected to an indicator unit 81, an audio processing unit 82, and a fan control unit 83 via the system bus SB.

  The indicator unit 81 is a drive circuit for the lamp indicator 3, the overheat indicator 4, and the power / standby indicator 7 disposed on the top panel 1b, and drives them to light / flash.

  The sound processing unit 82 includes a sound source circuit such as a PCM sound source, converts the sound data given at the time of the projection operation into an analog signal, and drives the speaker 84 provided in the speaker sound emitting unit 9 of the case main body 1a to generate a loud sound emission. Or beep if necessary.

  The fan control unit 83 controls and controls the cooling fans 87 including the intake fans 58 and 59 and the large wind exhaust fans 62, 63, and 64 to cool the light source lamp 18. It is detected that the rotational speed is reduced or stopped by the pulse signal output in synchronization with the rotation of the fans 58, 59, 62 to 64.

  It should be noted that the key switch unit 85 is configured by various adjustment keys for opening the opening / closing lid 8 provided in the projector device, the power key 2, the automatic image quality adjustment key 5, and the silent mode setting key 6. Signals from the switch unit 85 and the Ir receiving unit 86 are directly input to the control unit 80.

  The Ir receiving unit 86 includes the remote control receiving unit 10 provided on the front surface of the projector device, and a remote control receiving unit (not shown) provided on the back surface in the same manner as the remote control receiving unit 10, and the infrared light reception signal is coded. The signal is converted and sent to the control unit 80.

Next, the operation of the above embodiment will be described.
FIG. 4 relates to processing contents of a first operation example relating to blinking / lighting display on the overheat indicator 4 with respect to a temperature abnormality of the light source lamp 18 that is executed in parallel with the projection operation at all times when the power of the projector apparatus is turned on. Therefore, all control operations are executed by the control unit 80 based on an operation program stored in an internal nonvolatile memory.

  At the beginning of the process, the temperature T1 of the light source lamp 18 at that time is acquired by the light source temperature measuring sensor 78 and held in the internal work memory (step S01).

  Next, the control unit 80 waits for a certain time, for example, 5 [seconds] to elapse (step S02).

  When a certain time has elapsed, the temperature T2 of the light source lamp 18 at that time is again acquired by the light source temperature measurement sensor 78 and held in the internal work memory (step S03).

  Then, a temperature increase “ΔT = T2−T1” per unit time is calculated based on the held temperatures T1 and T2 (step S04), and the calculated temperature increase ΔT is stored in the control unit 80. By comparing and determining whether or not a predetermined threshold value Tmax is exceeded, it is determined whether or not temperature abnormality has occurred in the light source lamp 18 (step S05).

  Here, if the calculated temperature rise ΔT is equal to or less than the threshold value Tmax, it is assumed that there is no temperature abnormality in the light source lamp 18 at the present time, and the temperature T2 is changed to the temperature T1 in preparation for the next detection. After resetting (step S06), the process returns to step S02 again.

  However, when the temperature abnormality ΔT per unit time exceeds the threshold value Tmax, it is possible to continuously detect the occurrence of temperature abnormality in the light source lamp 18 by repeatedly executing the processes in steps S02 to S06. In step S05, this is determined, and the indicator section 81 causes the overheat indicator 4 to be driven to blink, for example, to display a warning that a temperature abnormality has occurred (step S07). Is temporarily stopped, the warning display is continued, and the user waits for the cause of the temperature abnormality in the light source lamp 18 to be removed by the user.

  In addition, regarding the warning display of the temperature abnormality, a loudspeaking sound such as a beep sound for warning may be generated by the speaker 84 at the same time.

  As described above, according to the first operation example, the temperature rise of the light source lamp 18 is determined based on the degree per unit time. For example, the bottom surface of the projector case 1 or the side surface on the side where the projection lens 45 is disposed, Even when any of the plurality of long hole-like intake holes 55, 56, 57 provided on the rear surface is temporarily blocked by paper or the like and a sufficient amount of cooling fan cannot be introduced, it is low. Even if there is a sudden temperature rise even in the temperature range, this can be judged reliably and a warning is notified, so that the user of the apparatus can recognize in advance that a serious abnormality will occur, and the projection operation can be continued safely.

  Next, a second operation example that replaces the first operation example will be described.

  FIG. 5 relates to the processing contents of the first operation example relating to the blinking / lighting display on the overheat indicator 4 for the temperature abnormality of the light source lamp 18, which is executed in parallel with the projection operation at all times when the power of the projector apparatus is turned on. Therefore, all control operations are executed by the control unit 80 based on an operation program stored in an internal nonvolatile memory.

  At the beginning of the process, after the counter value set in the work memory in the control unit 80 is initially set to “0”, which counts the time during which a temperature abnormality warning is displayed (step S21), the light source temperature measuring sensor 78 is set. Thus, the temperature T1 of the light source lamp 18 at that time is acquired and held in the internal work memory (step S22).

  Next, the control unit 80 waits for a certain time, for example, 5 [seconds] to elapse (step S23).

  When a certain time has elapsed, the temperature T2 of the light source lamp 18 at that time is again acquired by the light source temperature measurement sensor 78 and stored in the internal work memory (step S24).

  Then, a temperature increase per unit time “ΔT = T2−T1” is calculated from the held temperatures T1 and T2 (step S25), and the calculated temperature increase ΔT is stored in the controller 80. By comparing and determining whether or not a predetermined threshold value Tmax is exceeded, it is determined whether or not a temperature abnormality has occurred in the light source lamp 18 (step S26).

  Here, if the calculated temperature rise ΔT is equal to or less than the threshold value Tmax, it is assumed that no temperature abnormality has occurred in the light source lamp 18 at this time, and the value of the counter is set to “0” in preparation for the next detection. ”(Step S27), the temperature T2 is reset to the temperature T1 (step S28), and the process returns to step S23 again.

  However, when the temperature abnormality ΔT per unit time exceeds the threshold value Tmax, it is possible to continuously detect the occurrence of temperature abnormality in the light source lamp 18 by repeatedly executing the processing of steps S23 to S28. After determining this in step S26 and updating the counter value by “+1” (step S29), whether or not the updated counter value exceeds a constant N representing a preset time value. (Step S30).

  Here, if it is determined that the counter value is N or less, that is, it is determined that the temperature abnormality warning display of the light source lamp 18 has not been performed for a certain period of time, the overheat indicator 4 is flashed by the indicator unit 81 again. For example, a warning that a temperature abnormality has occurred is displayed (step S31), the temperature T2 is reset to the temperature T1 in the warning display state as it is (step S32), and the process returns to step S23 again.

  At this time, regarding the temperature abnormality warning display, a loudspeaker sound such as a beep sound for warning may be generated by the speaker 84.

  If the temperature of the light source lamp 18 continues to rise sequentially at a value exceeding the threshold value Tmax per unit time due to some factor, the processing of the steps S23 to S26 and S29 to S32 is repeatedly executed to cause a temperature abnormality. While the warning display is continued, the counter value is continuously updated by “+1”.

  When the value of the counter inside the control unit 80 exceeds a constant N representing a preset time value, that is, when the temperature abnormality warning display of the light source lamp 18 is performed for a predetermined time, this is performed in step S30. In order to avoid damage to the light source lamp 18 and lifetime deterioration, a shutdown operation for stopping the projection operation of the image from the projection lens 45 is executed except for the driving of the cooling fan 87 by the fan control unit 83 (step). S33), the state is shifted to the after-cooling state, and the series of processes shown in FIG.

  As described above, according to the second operation example, in addition to the effects described in the first operation example, when a rapid temperature rise of the light source lamp 18 continuously occurs for a certain period of time, this is counted. Therefore, even when the user has overlooked the warning notification by the overheat indicator 4 or a beep sound, the light source lamp 18 can be reliably prevented from being deteriorated or damaged. it can.

  Next, a third operation example that replaces the first and second operation examples will be described.

  FIG. 6 relates to the processing contents of the first operation example related to the blinking / lighting display on the overheat indicator 4 for the temperature abnormality of the light source lamp 18, which is executed in parallel with the projection operation at all times when the power of the projector apparatus is turned on. Therefore, all control operations are executed by the control unit 80 based on an operation program stored in an internal nonvolatile memory.

  At the beginning of the process, the value of the counter set in the work memory inside the control unit 80 that counts the time during which the temperature abnormality warning is displayed is initially set to “0” (step S41), and then the light source temperature measurement sensor 78. Thus, the temperature T1 of the light source lamp 18 at that time is acquired and held in the internal work memory (step S42).

  Next, the control unit 80 waits for a certain time, for example, 5 [seconds] to elapse (step S43).

  When a certain time has elapsed, the temperature T2 of the light source lamp 18 at that time is again acquired by the light source temperature measurement sensor 78 and held in the internal work memory (step S44).

  Then, a temperature increase “ΔT = T2−T1” per unit time is calculated from the held temperatures T1 and T2 (step S45), and the calculated temperature increase ΔT is stored in the control unit 80. It is determined whether or not at least a mild temperature abnormality has occurred in the light source lamp 18 by comparing whether or not the first threshold value Tmax1 defined in advance is exceeded (step S46).

  Here, if the calculated temperature increase ΔT is equal to or less than the first threshold value Tmax1, it is assumed that no temperature abnormality has occurred in the light source lamp 18 at the present time, and the counter of the counter is ready for the next detection. The value is initialized to “0” (step S47), the temperature T2 is reset to the temperature T1 (step S48), and the process returns to step S43 again.

  However, by repeatedly executing the processing of steps S43 to S48, it is possible to continue detecting the occurrence of temperature abnormality in the light source lamp 18, and the temperature increase ΔT per unit time becomes equal to the first threshold value Tmax1. If exceeded, this is determined in step S46, and then a comparison is made to determine whether the temperature rise ΔT exceeds a second threshold value Tmax2 (Tmax2> Tmax1) defined in advance. Then, it is determined whether or not at least a moderate temperature abnormality has occurred in the light source lamp 18 (step S49).

  Here, when the temperature increase ΔT is equal to or smaller than the second threshold value Tmax2, it is assumed that the temperature abnormality of the light source lamp 18 is relatively mild, and the value of the counter is updated by “+1”. (Step S50), it is determined whether or not the updated counter value exceeds a constant N representing a preset time value (Step S51).

  Here, if it is determined that the counter value is N or less, that is, it is determined that the temperature abnormality warning display of the light source lamp 18 has not been performed for a certain period of time, the overheat indicator 4 is flashed by the indicator unit 81 again. For example, a warning is displayed that a temperature abnormality has occurred (step S52), the temperature T2 is reset to the temperature T1 in the warning display state as it is (step S53), and the process returns to step S43 again.

  At this time, regarding the temperature abnormality warning display, a loudspeaker sound such as a beep sound for warning may be generated by the speaker 84.

  If it is determined in step S49 that the temperature increase ΔT exceeds the second threshold value Tmax2, the temperature abnormality of the light source lamp 18 is assumed to be at least moderate, and then the temperature increase By comparing whether or not the minute ΔT exceeds a predetermined third threshold value Tmax3 (Tmax3> Tmax2), it is determined whether or not a severe temperature abnormality has occurred in the light source lamp 18 ( Step S54).

  Here, when the temperature increase ΔT is equal to or less than the third threshold value Tmax3, it is assumed that the temperature abnormality of the light source lamp 18 is moderate, and the value of the counter is updated by “+2” ( In step S55, it is determined whether or not the updated counter value exceeds a constant N representing a preset time value (step S51).

  Here, if it is determined that the counter value is N or less, that is, it is determined that the temperature abnormality warning display of the light source lamp 18 has not been performed for a certain period of time, the overheat indicator 4 is flashed by the indicator unit 81 again. For example, a warning is displayed that a temperature abnormality has occurred (step S52), the temperature T2 is reset to the temperature T1 in the warning display state as it is (step S53), and the process returns to step S43 again.

  Therefore, if the temperature of the light source lamp 18 continues to rise sequentially at a value exceeding the threshold value Tmax1 or Tmax2 per unit time due to some factor, the above steps S43 to S46, S49 to S53 (or steps S43 to S46, The processing of S49, S54, S55, S51 to S53) is repeatedly executed, and the counter value is continuously updated by “+1” or “+2” while continuing the warning display of the temperature abnormality.

  When the counter value in the control unit 80 exceeds a constant N representing a preset time value, that is, when the temperature abnormality warning display of the light source lamp 18 is performed for a certain period of time, this is changed in step S51. In order to avoid the damage and the life deterioration of the light source lamp 18, a shutdown operation for stopping the projection operation of the image from the projection lens 45 is executed except for the driving of the cooling fan 87 by the fan control unit 83 (step S56). ), The state is shifted to the after cooling state, and the series of processes shown in FIG.

  If it is determined in step S54 that the temperature increase ΔT exceeds the third threshold value Tmax3, it is assumed that a severe temperature abnormality has occurred, and the value of the counter at that time is Regardless, the process immediately proceeds to step S56, the projection operation is shut down, the process of FIG. 6 is terminated, and the process proceeds to the after-cooling state.

  As described above, according to the third operation example, in addition to the effects described in the second operation example, a rapid temperature rise of the light source lamp 18 is determined step by step using a plurality of threshold values. Since the count operation is weighted, the stop timing of the projection operation can be set appropriately.

  Further, in the third operation example, when the plurality of threshold values are set, a more rapid temperature rise occurs in which the projection operation including the light emission driving of the light source lamp 18 must be stopped immediately. Even if it exists, the value which can judge it can be set beforehand, and it can cope with such a situation and can avoid beforehand that the light source lamp 18 is damaged or deteriorated.

  In the third operation example, it has been described that the predetermined threshold value stored in advance has three steps Tmax1 to Tmax3 (Tmax1 <Tmax2 <Tmax3). However, the present invention is not limited to this and has two steps. It is possible to set any four or more stages, or four or more stages, and according to the number of settings, detailed operation control can be performed as necessary.

  Although the above embodiment is applied to a DLP (registered trademark) projector device, the present invention is not limited to this, and may be applied to a liquid crystal projector using a transmissive color liquid crystal panel, for example. Is possible.

  In addition, the present invention is not limited to the above-described embodiment, and various modifications can be made without departing from the scope of the invention.

  Further, the above embodiments include inventions at various stages, and various inventions can be extracted by appropriately combining a plurality of disclosed constituent elements. For example, even if some constituent elements are deleted from all the constituent elements shown in the embodiment, at least one of the problems described in the column of the problem to be solved by the invention can be solved, and described in the column of the effect of the invention. In a case where at least one of the obtained effects can be obtained, a configuration in which this configuration requirement is deleted can be extracted as an invention.

1 is a perspective view showing an external configuration of a projector apparatus according to an embodiment of the present invention. The cross-sectional top view of the projector apparatus which concerns on the same embodiment. 2 is a block diagram showing a functional configuration of the electronic circuit according to the embodiment. FIG. The flowchart which shows the processing content regarding the temperature abnormality as a 1st operation example which concerns on the embodiment. The flowchart which shows the processing content regarding the temperature abnormality as a 2nd operation example which concerns on the embodiment. The flowchart which shows the processing content regarding the temperature abnormality as a 3rd operation example which concerns on the embodiment.

Explanation of symbols

  DESCRIPTION OF SYMBOLS 1 ... Projector case, 2 ... Power key, 3 ... Lamp indicator, 4 ... Overheat indicator, 5 ... Automatic image quality adjustment key, 6 ... Silent mode setting key, 7 ... Power / standby indicator, 10 ... Remote control receiver, 15 ... Rod Leg, 17 ... Light source device, 18 ... Light source lamp, 19 ... Glass bulb, 21 ... Reflector, 22 ... Motor, 24 ... Explosion-proof glass, 25 ... Explosion-proof cover, 28 ... Micromirror display element, 29 ... Light source side optical system, 30 ... Color wheel, 32 ... Color wheel rotation motor, 33 ... Light guide rod, 36 ... Lens support tube, 37 ... Mirror, 38 ... Light source side housing, 43 ... Cover glass, 44 ... Relay lens, 45 ... Projection lens, 52 ... Power supply system circuit board, 58, 59 ... intake fan, 62-64 ... large wind exhaust fan, 71 ... input / output connector section, 72 Input / output interface, 73 ... Image conversion unit, 74 ... Projection encoder, 75 ... Video RAM, 76 ... Projection processing unit, 77 ... Projection drive unit, 78 ... Light source temperature measurement sensor, 80 ... Control unit, 81 ... Indicator unit, 82 DESCRIPTION OF SYMBOLS ... Voice processing part, 83 ... Fan control part, 84 ... Speaker, 85 ... Key switch part, 86 ... Ir receiving part, 87 ... Cooling fan, SB ... System bus, W ... Cooling air.

Claims (5)

Projecting means for forming and projecting a light image corresponding to the input image signal using light emitted from the light source;
Temperature detecting means for detecting the temperature of the light source;
A judging means for judging a temperature abnormality based on whether or not the degree of change in temperature of the light source detected by the temperature detecting means exceeds a predetermined value;
Warning means for giving a warning notification when a temperature abnormality is judged by the judging means;
Counting means for counting the state where the temperature abnormality is judged by the judgment means;
A projection apparatus comprising: operation control means for stopping the projection operation of the projection means when the count value of the count means reaches a predetermined value. The determination means determines the temperature abnormality step by step by comparing with a plurality of predetermined values,
The projection apparatus according to claim 1, wherein the counting unit varies an update value of the count according to a stepwise determination result of the determination unit. The determination means determines the temperature abnormality step by step by comparing with a plurality of predetermined values,
The projection apparatus according to claim 1, wherein the operation control unit stops the projection operation of the projection unit when the determination unit determines that the degree of temperature abnormality is greatest. An operation control method for a projection apparatus including a projection unit that forms and projects a light image corresponding to an input image signal using light emitted from a light source,
A temperature detecting step for detecting the temperature of the light source;
A determination step of determining a temperature abnormality depending on whether or not the degree of change in temperature of the light source detected in the temperature detection step exceeds a predetermined value;
An alarm process for informing a warning when temperature abnormality is determined in this determination process;
A counting step for counting the state where the temperature abnormality is determined in the determination step ;
An operation control method for a projection apparatus, comprising: an operation control step for stopping a projection operation in the projection unit when a count value in the count step reaches a predetermined value. A program executed by a computer incorporated in a projection apparatus including a projection unit that forms and projects a light image corresponding to an input image signal using light emitted from a light source,
A temperature detection step for detecting the temperature of the light source;
A determination step of determining a temperature abnormality based on whether or not the degree of change in the temperature of the light source detected in the temperature detection step exceeds a predetermined value;
A warning step for providing a warning when a temperature abnormality is determined in this determination step; a counting step for counting a state in which the temperature abnormality is determined in the determination step;
A program for causing a computer to execute an operation control step of stopping a projection operation in the projection unit when a count value of the count step reaches a predetermined value.

Images