JP2006098979A - Projector - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a projector capable of reliably protecting a color wheel even when a failure occurs on a part of a control circuit with respect to the projector provided with the control circuit for controlling lighting operation of a lamp in accordance with the rotation state of the color wheel. <P>SOLUTION: The projector 1 is provided with the lamp 21 which is turned on by a prescribed lighting signal and the color wheel 30 arranged on a position adjacent to the lamp 21. The projector 1 is further provided with a main CPU 61 which outputs a first signal for lighting the lamp 21 when the rotation state of the color wheel 30 is detected, a sub CPU 62 which outputs a second signal for lighting the lamp 21 when the rotation state of the color wheel 30 is detected and an AND gate 63 which outputs a lighting signal only when both of the first signal and second signal are inputted. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a projector.

  In recent years, projection light from a light source such as a lamp is transmitted or reflected on a color wheel, and the transmitted light or reflected light is reflected on a DMD (Digital Micromirror Device) which is a digital reflection integrated element to generate a color image. A DLP (Digital Light Processor) projector that displays an image by enlarging and projecting the image on a predetermined screen using a projection lens has been proposed (for example, see Patent Document 1).

  In such a DLP projector, the lamp, which is a heat generating component, is disposed adjacent to the color wheel, and therefore, if the lamp is lit with the color wheel stopped, the color wheel may be damaged by the heat of the lamp. There is. For this reason, a technique for protecting the color wheel by controlling the lighting operation of the lamp according to the rotation state of the color wheel has been proposed.

For example, as shown in FIG. 6, when one CPU 100 mounted on the projector determines whether or not the color wheel 300 is rotating via the photo interrupter 200, the color wheel 300 is rotating. A control technique for outputting a lamp ON signal and lighting the lamp via a lamp lighting circuit 400 has been proposed.
JP 2001-109068 A

  However, in the above-described conventional control technology, the rotation determination of the color wheel 300 and the lighting operation of the lamp are controlled by one CPU 100. Therefore, when this CPU 100 breaks down and runs away, There has been a problem that it is impossible to detect the rotation state and control the lighting operation of the lamp. Further, when a failure such as disconnection or short circuit occurs in the signal input / output path from the photo interrupter 200 to the lamp lighting circuit 400 via the CPU 100, the rotation state of the color wheel 300 cannot be detected, Even if the rotation state of the color wheel 300 is detected, a situation may occur in which the lamp cannot be turned off at an appropriate timing.

  An object of the present invention is to reliably protect a color wheel even when a malfunction occurs in a part of the control circuit in a projector including a control circuit that controls the lighting operation of a lamp according to the rotation state of the color wheel. It is.

In order to solve the above problems, the invention described in claim 1
In a projector including a lamp that is turned on by a predetermined lighting signal, and a color wheel that is disposed adjacent to the lamp,
First rotation determination means for determining whether or not the color wheel is rotating;
Second rotation determining means for determining whether or not the color wheel is rotating;
First signal output means for outputting a first signal for lighting the lamp when the first rotation determination means determines that the color wheel is rotating;
Second signal output means for outputting a second signal for turning on the lamp when the second rotation determining means determines that the color wheel is rotating;
A lighting signal output means for outputting the lighting signal only when both the first signal and the second signal are input;
It is characterized by providing.

The invention described in claim 2
In a projector comprising a lamp that is extinguished by a predetermined extinction signal and a color wheel that is disposed at a position adjacent to the lamp,
First rotation determination means for determining whether or not the color wheel is rotating;
Second rotation determining means for determining whether or not the color wheel is rotating;
First signal output means for outputting a first signal for lighting the lamp when the first rotation determination means determines that the color wheel is rotating;
Second signal output means for outputting a second signal for turning on the lamp when the second rotation determining means determines that the color wheel is rotating;
A turn-off signal output means for outputting the turn-off signal when the first signal is not inputted and / or when the second signal is not inputted;
It is characterized by providing.

  According to the first or second aspect of the present invention, the first signal output means is configured to turn on the lamp when the first rotation determination means determines that the color wheel is rotating. 1 signal "is output. The second signal output means outputs a “second signal” for turning on the lamp when the second rotation determining means determines that the color wheel is rotating. Then, the lighting signal output means outputs the lighting signal only when both of these “first signal” and “second signal” are input, thereby lighting the lamp. The turn-off signal output means outputs a turn-off signal to turn off the lamp when the “first signal” is not input and / or when the “second signal” is not input.

  For this reason, since any one of the first rotation determination unit, the second rotation determination unit, the first signal output unit, and the second signal output unit does not function normally, the “first signal” and / or Alternatively, when the “second signal” is not output, or when a failure occurs in the signal input / output path from each rotation determination unit to each lighting signal output unit via each signal output unit, the “first signal” and / or When the “second signal” is not normally transmitted, the lighting signal is not output (or the extinguishing signal is output), and thus the lamp does not light up. Therefore, when the color wheel is stopped, the lamp can be prevented from being turned on accidentally, and the color wheel can be reliably protected.

The invention according to claim 3 is the projector according to claim 1 or 2,
The second signal output means includes
The output signal from the first signal output means is monitored, and the second signal is output only when the first signal is output from the first signal output means.

  According to the invention described in claim 3, the second signal output means monitors the output signal from the first signal output means, and the "first signal" is output from the first signal output means. Since the “second signal” is output only in such a case, it is possible to more reliably prevent the malfunction of the lamp when the first signal output means does not function normally.

According to a fourth aspect of the present invention, in the projector according to any one of the first to third aspects,
The first signal output means includes:
The output signal from the second signal output means is monitored, and the first signal is output only when the second signal is output from the second signal output means.

  According to the invention described in claim 4, the first signal output means monitors the output signal from the second signal output means, and the "second signal" is output from the second signal output means. Since the “first signal” is output only in such a case, it is possible to more reliably prevent the malfunction of the lamp when the second signal output means does not function normally.

The invention described in claim 5
In a projector including a lamp that is turned on by a predetermined lighting signal, and a color wheel that is disposed adjacent to the lamp,
Rotation determination means for determining whether or not the color wheel is rotating;
Preliminary signal output means for outputting a preliminary lighting signal for lighting the lamp when it is determined by the rotation determination means that the color wheel is rotating;
Monitoring means for monitoring whether the preliminary signal output means is functioning normally, and outputting a normal signal only when the preliminary signal output means is functioning normally;
A lighting signal output means for outputting the lighting signal only when both the preliminary lighting signal and the normal signal are input;
It is characterized by providing.

The invention described in claim 6
In a projector comprising a lamp that is extinguished by a predetermined extinction signal and a color wheel that is disposed at a position adjacent to the lamp,
Rotation determination means for determining whether or not the color wheel is rotating;
Preliminary signal output means for outputting a preliminary lighting signal for lighting the lamp when the rotation determination means determines that the color wheel is rotating;
Monitoring means for monitoring whether the preliminary signal output means is functioning normally, and outputting a normal signal only when the preliminary signal output means is functioning normally;
A turn-off signal output means for outputting the turn-off signal when the preliminary turn-on signal is not inputted and / or when the normal signal is not inputted;
Characterized by comprising

  According to the fifth or sixth aspect of the invention, the preliminary signal output means outputs the “preliminary lighting signal” for lighting the lamp when the rotation determining means determines that the color wheel is rotating. I do. In addition, when the spare signal output means functions normally, the monitoring means outputs a “normal signal”. The lighting signal output means outputs the lighting signal and lights the lamp only when both the “preliminary lighting signal” and the “normal signal” are input. The turn-off signal output means outputs a turn-off signal to turn off the lamp when the “preliminary turn-on signal” is not input and / or when the “normal signal” is not input.

  For this reason, if the “preliminary lighting signal” and / or “normal signal” is not output because the rotation determining means and the standby signal output means do not function normally, or if the rotation determining means passes through the preliminary signal output means and the monitoring means. If the signal input / output path leading to the lighting signal output means fails and the “preliminary lighting signal” and / or “normal signal” is not normally transmitted, the lighting signal output means does not output the lighting signal (or extinguishes) Signal is output), the lamp will not light up. Therefore, when the color wheel is stopped, the lamp can be prevented from being turned on accidentally, and the color wheel can be reliably protected.

  According to the first or second aspect of the present invention, when the first rotation determination unit determines that the color wheel is rotating, the first signal output unit causes the lamp to light “first”. Of the “second signal” for turning on the lamp when the second rotation determining means determines that the color wheel is rotating. Output. The lighting signal output means outputs a lighting signal only when both of these “first signal” and “second signal” are input, and lights the lamp. The turn-off signal output means outputs a turn-off signal to turn off the lamp when the “first signal” is not input and / or when the “second signal” is not input. For this reason, if each rotation determination means or each signal output means fails or a failure occurs in the signal input / output path, the lighting signal is not output (or the extinguishing signal is output), so that the lamp malfunctions. And the color wheel can be reliably protected.

  According to the invention described in claim 5 or 6, when the rotation determining means determines that the color wheel is rotating, the preliminary signal output means outputs the “preliminary lighting signal” for lighting the lamp. Do. Further, when the spare signal output means functions normally, the monitoring means outputs a “normal signal”. The lighting signal output means outputs the lighting signal and lights the lamp only when both the “preliminary lighting signal” and the “normal signal” are input. The turn-off signal output means outputs a turn-off signal to turn off the lamp when the “preliminary turn-on signal” is not input and / or when the “normal signal” is not input. For this reason, if the rotation determination means or the spare signal output means fails or a failure occurs in the signal input / output path, the lighting signal is not output (or the extinguishing signal is output), so that the lamp malfunctions. Can be prevented and the color wheel can be reliably protected.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. In this embodiment, a single-plate DLP projector using a single DMD will be described as an example of a projector according to the present invention.

[First embodiment]
First, the configuration of the projector 1 according to the first embodiment of the present invention will be described with reference to FIGS. 1 and 2.

  As shown in FIG. 1, the projector 1 according to the present embodiment includes a rectangular parallelepiped housing 10, a lamp unit 20, a transmissive color wheel 30 that transmits light emitted from the lamp unit 20, and a color wheel 30. It includes a photo interrupter 40 that detects a rotation state, a lens unit 50 that generates an image and projects it in a predetermined direction, a power supply board 60 on which various circuit components and a battery are mounted, and the like.

  As shown in FIG. 1, the housing 10 includes a rectangular upper surface 11 and a lower surface 12 having a relatively large area, and four side surfaces 13 connected to the sides of the upper surface 11 and the lower surface 12. ing. The lamp unit 20 includes a lamp 21 that emits light, a reflector 22 that reflects light from the lamp 21 and focuses the light in a predetermined direction, a cover glass 23 that protects the front surface of the lamp 21, and the like. As shown to a), it arrange | positions in the position near the center part inside the left-right direction inside the housing | casing 10. FIG. The lighting operation of the lamp unit 20 is controlled by a control circuit mounted on the power supply board 60.

  The color wheel 30 is rotated by being driven by a predetermined motor, transmits light emitted from the lamp unit 20, and sequentially converts the light from the lamp unit 20 into red, green, and blue light. As shown in FIG. 1, the color wheel 30 is disposed at a position adjacent to the left side of the lamp unit 20, and its rotation operation is controlled by a control circuit mounted on the power supply board 60. In the vicinity of the outer edge of the color wheel 30, holes are provided at regular intervals in the circumferential direction. These holes are used for detecting the rotation state of the color wheel 30.

  As shown in FIG. 2, the photo interrupter 40 includes an LED (Light Emitting Diode) 41 that is a light emitting element, and a phototransistor 42 that receives projection light from the LED 41, and is supplied from a power supply substrate 60. Driven by electric power. The LED 41 and the phototransistor 42 are arranged at positions facing each other with the vicinity of the outer edge of the color wheel 30. When the color wheel 30 rotates, the light projected from the LED 41 is intermittently generated by the vicinity of the outer edge of the color wheel 30. Will be blocked. The phototransistor 42 receives light projected from the LED 41 and passed through a hole provided in the color wheel 30 and generates a light reception signal. The light reception signal generated by the phototransistor 42 is transmitted to the main CPU 61 and the sub CPU 62 mounted on the power supply substrate 60.

  The lens unit 50 controls the operation of DMD and DMD that are angle-controllable digital reflection integrated elements that generate light by reflecting a light guide tube that guides light transmitted through the color wheel 30 and light passing through the color wheel 30. And a projection lens that projects light (image) generated by the DMD in a predetermined direction. As shown in FIG. 1, the lens unit 50 is disposed in a space between the color wheel 30 and the left side surface 13 of the housing 10 and projects an image in front of FIG. 1.

  As shown in FIG. 1, the power supply board 60 is disposed in front of the lamp unit 20 and includes a control circuit that controls the lighting operation of the lamp unit 20 based on the rotation state of the color wheel 30 and various electronic devices. A battery for supplying power to the battery is provided.

  As shown in FIG. 2, the control circuit of the power supply board 60 receives a main CPU 61 and a sub CPU 62 that integrally control various electronic devices mounted on the projector 1 and signals output from the main CPU 61 and the sub CPU 62. An AND gate 63 for generating the output signal, an LED circuit 64, and a lamp lighting circuit 65.

  The main CPU 61 and the sub CPU 62 mounted on the power supply substrate 60 determine the rotation state of the color wheel 30 according to the light reception time of the phototransistor 42 and the like. For example, when the light reception by the phototransistor 42 is intermittent and the light reception time is shorter than a predetermined set value, the main CPU 61 and the sub CPU 62 determine that the color wheel 30 is in a rotating state. On the other hand, when light reception by the phototransistor 42 is not detected or when the light reception time is longer than a predetermined set value, the main CPU 61 and the sub CPU 62 determine that the color wheel 30 is in a stopped state. That is, the main CPU 61 and the sub CPU 62 are a first rotation determination unit and a second rotation determination unit in the present invention, respectively.

  Further, when the main CPU 61 determines that the color wheel 30 is in a rotating state, the main CPU 61 outputs a lamp ON signal (a signal for lighting the lamp 21). The lamp ON signal output from the main CPU 61 is the first signal in the present invention, and the main CPU 62 is the first signal output means in the present invention. On the other hand, the sub CPU 62 also outputs a lamp ON signal (a signal for lighting the lamp 21) when it is determined that the color wheel 30 is in a rotating state. The lamp ON signal output from the sub CPU 62 is the second signal in the present invention, and the sub CPU 62 is the second signal output means in the present invention.

  The AND gate 63 performs the ramp only when both the lamp ON signal (first signal) output from the main CPU 61 and the lamp ON signal (second signal) output from the sub CPU 62 are input. Outputs the ON signal. The AND gate 63 receives the lamp OFF signal when the lamp ON signal (first signal) from the main CPU 61 is not input and / or when the lamp ON signal (second signal) from the sub CPU 62 is not input. Output.

  As shown in FIG. 2, the LED circuit 64 includes a transistor 64a connected to the AND gate 63 and an LED 64b. The lamp ON signal output from the AND gate 63 is input to the base of the transistor 64a. In this case, the LED 64b is lit.

  As shown in FIG. 2, the lamp lighting circuit 65 includes a phototransistor 65a that receives projection light from the LED 64a, and generates a lamp ON signal when the phototransistor 65 receives projection light from the LED 64b. On the other hand, when the phototransistor 65 does not receive the projection light from the LED 64b, the lamp OFF signal is generated. The lamp 21 of the lamp unit 20 is turned on by the lamp ON signal generated by the lamp lighting circuit 65, while the lamp 21 of the lamp unit 20 is turned off by the lamp OFF signal generated by the lamp lighting circuit 65.

  The lamp ON signal output from the AND gate 63, the projection light of the LED 64b that is lit based on the lamp ON signal, and the lamp ON signal that is generated by the lamp lighting circuit 65 based on the projection light from the LED 64b are: It is a lighting signal in the present invention. The AND gate 63, the LED circuit 64, and the lamp lighting circuit 65 constitute a lighting signal output means in the present invention. On the other hand, the lamp OFF signal output from the AND gate 63 and the lamp OFF signal generated by the lamp lighting circuit 65 are extinguishing signals in the present invention. The AND gate 63, the LED circuit 64, and the lamp lighting circuit 65 constitute a turn-off signal output means in the present invention.

  In the projector 1 according to the embodiment described above, the main CPU 61 that has detected the rotation state of the color wheel 30 outputs a lamp ON signal (first signal) and also detects the rotation state of the color wheel 30. The CPU 62 outputs a lamp ON signal (second signal). Only when both the lamp ON signal output from the main CPU 61 and the lamp ON signal output from the sub CPU 62 are input to the AND gate 63, the lamp ON signal (lighting signal) is output from the AND gate 63. The lamp 21 of the lamp unit 20 is lit through the LED circuit 64 and the lamp lighting circuit 65.

  For this reason, when either the main CPU 61 or the sub CPU 62 fails and does not function normally, the lamp ON signal (first signal and / or second signal) is not output, or the phototransistor 42 outputs the main CPU 61. Alternatively, if a failure occurs in the signal input / output path to the AND gate 63 via the sub CPU 62 and the lamp ON signal (the first signal and / or the second signal) is not normally transmitted, the AND gate 63 The lamp ON signal (lighting signal) is not output, and the lamp 21 of the lamp unit 20 is not lit. Therefore, when the color wheel 30 is stopped, the lamp 21 can be prevented from being turned on accidentally, and the color wheel 30 can be reliably protected.

[Second Embodiment]
Next, the configuration of the projector according to the second embodiment of the present invention will be described with reference to FIG. The projector according to the present embodiment is obtained by partially changing the configuration of the control circuit of the power supply board of the projector according to the first embodiment. The other configurations are substantially the same as those of the first embodiment. Are the same. For this reason, only the changed configuration will be described, and the description of the overlapping configuration will be omitted. In addition, when substantially the same configuration as that of the first embodiment is used in the description, the same reference numerals as those of the first embodiment are given.

  As shown in FIG. 3, the control circuit of the power supply board of the projector according to the present embodiment includes a transistor 66a connected to the main CPU 61, a transistor 66b connected to the sub CPU 62, and these two transistors 66a and 66b. And an LED circuit 66 having an LED 66c connected to the collector.

  The LED 66c of the LED circuit 66 has a lamp ON signal (first signal) output from the main CPU 61 input to the base of the transistor 66a, and a lamp ON signal (second signal) output from the sub CPU 62 is a transistor. It is lit only when it is input to the base 66b. The lamp lighting circuit 65 generates a lamp ON signal when the phototransistor 65a receives the projection light from the LED 66c of the LED circuit 66, and the lamp OFF circuit when the phototransistor 65a does not receive the projection light from the LED 66c. It is configured to generate a signal. The lamp 21 of the lamp unit 20 is turned on by the lamp ON signal generated by the lamp lighting circuit 65, while the lamp 21 of the lamp unit 20 is turned off by the lamp OFF signal generated by the lamp lighting circuit 65.

  Based on the projection light of the LED 66c that is turned on based on the lamp ON signal (first signal) output from the main CPU 61 and the lamp ON signal (second signal) output from the sub CPU 62, and on the basis of the projection light from the LED 66c. The lamp ON signal generated by the lamp lighting circuit 65 is a lighting signal in the present invention. Further, the LED circuit 66 and the lamp lighting circuit 65 constitute a lighting signal output means in the present invention. On the other hand, the lamp OFF signal generated by the lamp lighting circuit 65 is a turn-off signal in the present invention. Further, the LED circuit 66 and the lamp lighting circuit 65 constitute a turn-off signal output means in the present invention.

  In the projector according to the embodiment described above, the main CPU 61 that detects the rotation state of the color wheel 30 outputs the lamp ON signal (first signal), and the sub CPU 62 detects the rotation state of the color wheel 30. Outputs a lamp ON signal (second signal). When the lamp ON signal output from the main CPU 61 is input to the base of the transistor 66a of the LED circuit 66, and the lamp ON signal output from the sub CPU 62 is input to the base of the transistor 66b of the LED circuit 66. Only the LED 66 c of the LED circuit 66 is lit, and the lamp 21 of the lamp unit 20 is lit via the lamp lighting circuit 65.

  For this reason, when either the main CPU 61 or the sub CPU 62 fails and does not function normally, the lamp ON signal (first signal and / or second signal) is not output, or the phototransistor 42 outputs the main CPU 61. Alternatively, if a problem occurs in the signal input / output path to the LED circuit 66 via the sub CPU 62 and the lamp ON signal (the first signal and / or the second signal) is not normally transmitted, the LED circuit 66 The LED 66c is not lit (no lighting signal is output), and the lamp 21 of the lamp unit 20 is not lit. Therefore, when the color wheel 30 is stopped, the lamp 21 can be prevented from being turned on accidentally, and the color wheel 30 can be reliably protected.

  In the projector according to the embodiment described above, the main CPU 61 and the sub CPU 62 are directly connected to the LED circuit 66 without the AND gate 63 as employed in the first embodiment. The signal input / output path from the main CPU 61 and the sub CPU 62 to the LED circuit 66 is simplified. Therefore, problems such as disconnection and short circuit of the signal input / output path can be reduced.

[Third embodiment]
Next, the configuration of the projector according to the third embodiment of the present invention will be described with reference to FIG. In the projector according to the present embodiment, the sub CPU 62 of the control circuit of the power supply board 60 of the projector 1 according to the first embodiment is changed to “Watch Dog Timer” (hereinafter referred to as “WDT”). The configuration is substantially the same as that of the first embodiment. For this reason, only the changed configuration will be described, and the description of the overlapping configuration will be omitted. In addition, when substantially the same configuration as that of the first embodiment is used in the description, the same reference numerals as those of the first embodiment are given.

  As shown in FIG. 4, the control circuit of the power supply board of the projector according to the present embodiment includes a main CPU 61 that integrally controls various electronic devices mounted on the projector, a WDT 67 that monitors the operation of the main CPU 61, and these It has an AND gate 63 that receives signals output from the main CPU 61 and WDT 67 and generates one output signal, an LED circuit 64, and a lamp lighting circuit 65.

  When determining that the color wheel 30 is rotating, the main CPU 61 outputs a lamp ON signal (a signal for turning on the lamp 21) to the AND gate 63, and the rotation determination in the present invention. And function as a preliminary signal output means. The lamp ON signal output from the main CPU 61 is a preliminary lighting signal in the present invention.

  The WDT 67 is a monitoring unit in the present invention, and is a timer that monitors whether the main CPU 61 is functioning normally and automatically resets the main CPU 61 when a predetermined designated time has elapsed. While the main CPU 61 is functioning normally, the main CPU 61 restarts the WDT 67 every predetermined time (a time shorter than the specified time) and restarts the counting by the WDT 67. While the counting by the WDT 67 continues, an ON signal (normal signal) is output from the WDT 67 to the AND gate 63. On the other hand, when the main CPU 61 fails and does not function normally, the WDT 67 automatically resets the main CPU 61 after the specified time has elapsed. When the main CPU 61 is reset by the WDT 67, the output of the lamp ON signal from the main CPU 61 is cut off. Further, unless the WDT 67 is restarted by the main CPU 61, the output of the ON signal from the WDT 67 is also blocked.

  The AND gate 63 outputs the lamp ON signal only when both the lamp ON signal (preliminary lighting signal) output from the main CPU 61 and the ON signal (normal signal) output from the WDT 67 are input. Do. The AND gate 63 outputs a lamp OFF signal when the lamp ON signal (preliminary lighting signal) from the main CPU 61 is not input and / or when the ON signal (normal signal) from the WDT 67 is not input.

  As in the first embodiment, the LED circuit 64 is configured such that the LED 64b is turned on when the lamp ON signal output from the AND gate 63 is input to the base of the transistor 64a. Similarly to the first embodiment, the lamp lighting circuit 65 generates a lamp ON signal when the phototransistor 65 receives the projection light from the LED 64b, while the phototransistor 65 generates the projection light from the LED 64b. A lamp OFF signal is generated when no light is received. The lamp 21 of the lamp unit 20 is turned on by the lamp ON signal generated by the lamp lighting circuit 65, while the lamp 21 of the lamp unit 20 is turned off by the lamp OFF signal generated by the lamp lighting circuit 65.

  The lamp ON signal output from the AND gate 63, the projection light of the LED 64b that is lit based on the lamp ON signal, and the lamp ON signal that is generated by the lamp lighting circuit 65 based on the projection light from the LED 64b are: It is a lighting signal in the present invention. The AND gate 63, the LED circuit 64, and the lamp lighting circuit 65 constitute a lighting signal output means in the present invention. On the other hand, the lamp OFF signal output from the AND gate 63 and the lamp OFF signal generated by the lamp lighting circuit 65 are extinguishing signals in the present invention. The AND gate 63, the LED circuit 64, and the lamp lighting circuit 65 constitute a turn-off signal output means in the present invention.

  In the projector according to the embodiment described above, the main CPU 61 that detects the rotation state of the color wheel 30 outputs a lamp ON signal (preliminary lighting signal). Further, when the main CPU 61 functions normally, the WDT 67 outputs an ON signal (normal signal). The AND gate circuit 63 outputs a lamp ON signal (lighting signal) only when both the lamp ON signal output from the main CPU 61 and the ON signal output from the WDT 67 are input to the AND gate 63. Then, the lamp 21 of the lamp unit 20 is turned on.

  For this reason, when the main CPU 61 fails and does not function normally, the lamp ON signal (preliminary lighting signal) or the ON signal from the WDT 67 is not output, or the phototransistor 42 reaches the AND gate 63 via the main CPU 61. If a failure occurs in the signal input / output path and the lamp ON signal (preliminary lighting signal) is not normally transmitted, the lamp ON signal (lighting signal) is not output from the AND gate 63, and the lamp 21 of the lamp unit 20 is lit. There is nothing to do. Therefore, when the color wheel 30 is stopped, the lamp 21 can be prevented from being turned on accidentally, and the color wheel 30 can be reliably protected.

[Fourth embodiment]
Next, the configuration of the projector according to the fourth embodiment of the invention will be described with reference to FIG. In the projector according to the present embodiment, the sub CPU 62 of the control circuit of the power supply board of the projector according to the second embodiment is changed to WDT, and other configurations are substantially the same as those of the second embodiment. Are identical. For this reason, only the changed configuration will be described, and the description of the overlapping configuration will be omitted. In addition, when substantially the same configuration as that of the second embodiment is used in the description, the same reference numerals as those of the second embodiment are given.

  As shown in FIG. 5, the control circuit of the power supply board of the projector according to the present embodiment includes a main CPU 61 that integrally controls various electronic devices mounted on the projector, a WDT 67 that monitors the operation of the main CPU 61, and these An LED circuit 66 connected to the main CPU 61 and the WDT 67 and a lamp lighting circuit 65 are included. The LED circuit 66 includes a transistor 66a connected to the main CPU 61, a transistor 66b connected to the WDT 67, and an LED 66c connected to the collectors of these two transistors 66a and 66b.

  When the main CPU 61 determines that the color wheel 30 is rotating, the main CPU 61 outputs a lamp ON signal (a signal for lighting the lamp 21) to the transistor 66a of the LED circuit 66. Functions as rotation determination means and preliminary signal output means. The lamp ON signal output from the main CPU 61 is a preliminary lighting signal in the present invention.

  The WDT 67 is a monitoring unit in the present invention, and is a timer that monitors whether the main CPU 61 is functioning normally and automatically resets the main CPU 61 when a predetermined designated time has elapsed. While the main CPU 61 is functioning normally, the main CPU 61 restarts the WDT 67 every predetermined time (a time shorter than the specified time) and restarts the counting by the WDT 67. While the counting by the WDT 67 continues, an ON signal (normal signal) is output from the WDT 67 to the transistor 66b of the LED circuit 66. On the other hand, when the main CPU 61 fails and does not function normally, the WDT 67 automatically resets the main CPU 61 after the specified time has elapsed. When the main CPU 61 is reset by the WDT 67, the output of the lamp ON signal from the main CPU 61 is cut off. Further, unless the WDT 67 is restarted by the main CPU 61, the output of the ON signal from the WDT 67 is also blocked.

  In the LED 66c of the LED circuit 66, the lamp ON signal (preliminary lighting signal) output from the main CPU 61 is input to the base of the transistor 66a, and the ON signal (normal signal) output from the WDT 67 is input to the base of the transistor 66b. It is designed to light up only when The lamp lighting circuit 65 generates a lamp ON signal when the phototransistor 65a receives the projection light from the LED 66c of the LED circuit 66, and the lamp OFF circuit when the phototransistor 65a does not receive the projection light from the LED 66c. It is configured to generate a signal. The lamp 21 of the lamp unit 20 is turned on by the lamp ON signal generated by the lamp lighting circuit 65, while the lamp 21 of the lamp unit 20 is turned off by the lamp OFF signal generated by the lamp lighting circuit 65.

  Based on the lamp ON signal (preliminary lighting signal) output from the main CPU 61 and the ON signal (normal signal) output from the WDT 67, the projection light of the LED 66c, and the lamp lighting circuit 65 based on the projection light from the LED 66c. The lamp ON signal generated by the above is a lighting signal in the present invention. Further, the LED circuit 66 and the lamp lighting circuit 65 constitute a lighting signal output means in the present invention. On the other hand, the lamp OFF signal generated by the lamp lighting circuit 65 is a turn-off signal in the present invention. Further, the LED circuit 66 and the lamp lighting circuit 65 constitute a turn-off signal output means in the present invention.

  In the projector according to the embodiment described above, the main CPU 61 that detects the rotation state of the color wheel 30 outputs a lamp ON signal (preliminary lighting signal). Further, when the main CPU 61 functions normally, the WDT 67 outputs an ON signal (normal signal). Only when the lamp ON signal output from the main CPU 61 is input to the base of the transistor 66a of the LED circuit 66 and the ON signal output from the WDT 67 is input to the base of the transistor 66b of the LED circuit 66, The LED 66c of the LED circuit 66 is turned on, and the lamp 21 of the lamp unit 20 is turned on.

  For this reason, when the main CPU 61 fails and does not function normally, the lamp ON signal (preliminary lighting signal) or the ON signal from the WDT 67 is not output, or the phototransistor 42 reaches the LED circuit 66 via the main CPU 61. When a problem occurs in the signal input / output path and the lamp ON signal (preliminary lighting signal) is not transmitted normally, the LED 66c of the LED circuit 66 is not lit, and the lamp 21 of the lamp unit 20 is not lit. Therefore, when the color wheel 30 is stopped, the lamp 21 can be prevented from being turned on accidentally, and the color wheel 30 can be reliably protected.

  Further, in the projector according to the embodiment described above, the main CPU 61 and the WDT 67 are directly connected to the LED circuit 66 without interposing the AND gate 63 as employed in the third embodiment. The signal input / output path from the main CPU 61 and the WDT 67 to the LED circuit 66 is simplified. Therefore, problems such as disconnection and short circuit of the signal input / output path can be reduced.

  In the first and second embodiments, an example in which the main CPU 61 and the sub CPU 62 are operated independently without being connected is shown. However, the main CPU 61 and the sub CPU 62 are connected, and the main CPU 61 The sub CPU 62 can also monitor whether or not it is functioning normally. For example, as indicated by a dotted arrow in FIG. 2, the output signal from the main CPU 61 is input to the sub CPU 62, and the output signal from the main CPU 61 matches the signal generated based on the rotation determination of the sub CPU 62. Whether or not the sub CPU 62 determines whether or not both coincide with each other, the signal is output to the AND gate 63. In this way, by monitoring the output signal from the main CPU 61 by the sub CPU 62, the sub CPU 62 itself functions as an AND gate, so that the malfunction of the lamp 21 can be prevented more reliably.

  Also, the main CPU 61 and the sub CPU 62 can be connected, and the main CPU 61 can monitor whether or not the sub CPU 62 is functioning normally. For example, as indicated by a dotted arrow in FIG. 3, the output signal from the sub CPU 62 is input to the main CPU 61, and the output signal from the sub CPU 62 matches the signal generated based on the rotation determination of the main CPU 61. Whether the main CPU 61 determines whether or not the two match, the signal is output to the LED circuit 66. By monitoring the output signal from the sub CPU 62 in this way by the main CPU 61, the main CPU 61 itself functions as an AND gate, so that the malfunction of the lamp 21 can be prevented more reliably. In addition, whether or not the main CPU 61 is functioning normally can be monitored by the sub CPU 62, and whether or not the sub CPU 62 is functioning normally can be monitored by the main CPU 61.

  In the first and third embodiments, the lamp ON signal output from the AND gate 63 is input to the LED circuit 64 to be converted into the projection light of the LED 64a, and this projection light is detected by the phototransistor 65a. In this example, the lamp lighting circuit 65 generates the lamp ON signal again to turn on the lamp 21. However, the lamp output from the AND gate 63 without the LED circuit 64 and the lamp lighting circuit 65 being interposed. The lamp 21 can be turned on directly by the ON signal.

(A) is a perspective view when the projector according to the first embodiment of the present invention is viewed from above, and (b) is the case when the projector according to the first embodiment of the present invention is viewed from the front. FIG. It is a circuit diagram for demonstrating the structure of the control circuit of the power supply board mounted in the projector shown in FIG. It is a circuit diagram for demonstrating the structure of the control circuit of the power supply board mounted in the projector which concerns on the 2nd Embodiment of this invention. It is a circuit diagram for demonstrating the structure of the control circuit of the power supply board mounted in the projector which concerns on the 3rd Embodiment of this invention. It is a circuit diagram for demonstrating the structure of the control circuit of the power supply board mounted in the projector which concerns on the 4th Embodiment of this invention. It is a circuit diagram for demonstrating the structure of the control circuit for lamp lighting control mounted in the conventional projector.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Projector 21 Lamp 30 Color wheel 61 Main CPU (1st rotation determination means, 1st signal output means, preliminary signal output means)
62 Sub CPU (second rotation determination means, second signal output means)
63 AND gate (lighting signal output means, extinguishing signal output means)
64 LED circuit (lighting signal output means, extinguishing signal output means)
65 Lamp lighting circuit (lighting signal output means, extinguishing signal output means)
66 LED circuit (lighting signal output means, extinguishing signal output means)
67 WDT (monitoring means)

Claims (6)

In a projector including a lamp that is turned on by a predetermined lighting signal, and a color wheel that is disposed adjacent to the lamp,
First rotation determination means for determining whether or not the color wheel is rotating;
Second rotation determining means for determining whether or not the color wheel is rotating;
First signal output means for outputting a first signal for lighting the lamp when the first rotation determination means determines that the color wheel is rotating;
Second signal output means for outputting a second signal for turning on the lamp when the second rotation determining means determines that the color wheel is rotating;
A lighting signal output means for outputting the lighting signal only when both the first signal and the second signal are input;
A projector comprising: In a projector comprising a lamp that is extinguished by a predetermined extinction signal and a color wheel that is disposed at a position adjacent to the lamp,
First rotation determination means for determining whether or not the color wheel is rotating;
Second rotation determining means for determining whether or not the color wheel is rotating;
First signal output means for outputting a first signal for turning on the lamp when the first rotation determination means determines that the color wheel is rotating;
Second signal output means for outputting a second signal for turning on the lamp when the second rotation determining means determines that the color wheel is rotating;
A turn-off signal output means for outputting the turn-off signal when the first signal is not inputted and / or when the second signal is not inputted;
A projector comprising: The second signal output means includes
The output signal from the first signal output means is monitored, and the second signal is output only when the first signal is output from the first signal output means. Item 3. The projector according to Item 1 or 2. The first signal output means includes:
The output signal from the second signal output means is monitored, and the first signal is output only when the second signal is output from the second signal output means. Item 4. The projector according to any one of Items 1 to 3. In a projector including a lamp that is turned on by a predetermined lighting signal, and a color wheel that is disposed adjacent to the lamp,
Rotation determination means for determining whether or not the color wheel is rotating;
Preliminary signal output means for outputting a preliminary lighting signal for lighting the lamp when it is determined by the rotation determination means that the color wheel is rotating;
Monitoring means for monitoring whether the preliminary signal output means is functioning normally, and outputting a normal signal only when the preliminary signal output means is functioning normally;
A lighting signal output means for outputting the lighting signal only when both the preliminary lighting signal and the normal signal are input;
A projector comprising: In a projector comprising a lamp that is extinguished by a predetermined extinction signal and a color wheel that is disposed at a position adjacent to the lamp,
Rotation determination means for determining whether or not the color wheel is rotating;
Preliminary signal output means for outputting a preliminary lighting signal for lighting the lamp when it is determined by the rotation determination means that the color wheel is rotating;
Monitoring means for monitoring whether the preliminary signal output means is functioning normally, and outputting a normal signal only when the preliminary signal output means is functioning normally;
A turn-off signal output means for outputting the turn-off signal when the preliminary turn-on signal is not inputted and / or when the normal signal is not inputted;
A projector comprising:

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