JP2016020954A - Image projection device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an image projection device capable of suppressing various kinds of components in the device from being damaged due to the heat of a light source.SOLUTION: The image projection device such as a projector 1 projecting an image by using the light source such as a discharge lamp 21 includes a cooling fan such as a light source fan 62 for cooling the light source. An air volume switch 70 is provided in the vicinity of the fan outflow port 62a of the light source fan 62. The air volume switch 70 includes a rocking electrode 71 provided to be rockable in the fan outflow port 62a of the light source fan 62 and a fixed electrode 72. When the drive of the light source fan 62 is stopped, the rocking electrode 71 is separated from the fixed electrode 72. When the light source fan 62 is driven, the rocking electrode 71 is rocked by the wind pressure of the light source fan 62 and comes into contact with the fixed electrode 72.SELECTED DRAWING: Figure 9

Description

  The present invention relates to an image projection apparatus such as a projector.

  2. Description of the Related Art Conventionally, there has been known an image projection apparatus that forms an image by an image forming unit using light emitted from a light source based on image data from a personal computer or a video camera, and projects and displays the image on a screen or the like. It has been.

  Patent Document 1 describes an image projection apparatus that sends air to a light source by a cooling fan and air-cools the light source. In the image projection apparatus described in Patent Document 1, it is detected by a photodiode whether or not the light source is turned on, and the detection result is input to a fan control circuit that controls the cooling fan. The fan control circuit controls the cooling fan based on the detection result. Specifically, when the photodiode detects light from the light source, the fan control circuit rotates the cooling fan to air-cool the light source. On the other hand, when the photodiode is not detecting light from the light source, the fan control circuit stops the rotation of the cooling fan.

  However, in the image projection apparatus described in Patent Document 1, the main board fails, the fan control circuit incorporated in the main board does not operate normally, and the photodiode detects the lighting of the light source. Therefore, the cooling fan stops rotating and the light source may not be air-cooled. As a result, there is a problem that the light source and the surroundings of the light source become high temperature and various parts of the image projection apparatus are thermally damaged.

  The present invention has been made in view of the above problems, and an object thereof is to provide an image projection apparatus capable of suppressing various parts in the apparatus from being damaged by the heat of the light source.

  In order to achieve the above object, an invention according to claim 1 is an image projection apparatus that includes a light source and a cooling fan for cooling the light source, and projects an image using light of the light source. The light source is provided with a switch for switching the light source from a non-lightable state to a lightable state.

  ADVANTAGE OF THE INVENTION According to this invention, it can suppress that the various components in an apparatus are damaged with the heat | fever of a light source.

The perspective view which shows the projector which concerns on this embodiment. The right view which shows the projector. (A) The perspective view which shows the internal structure and arrangement | positioning of the projector which removed the exterior cover, (b) is a perspective view of the part enclosed by the thick line frame of (a). FIG. 2 is a cross-sectional view showing an internal configuration of the projector with an exterior cover removed. The schematic block diagram which shows the light source unit of the projector. The figure explaining the flow of the exhaust air from the intake air in the projector. The figure explaining the flow of the air around a discharge lamp. FIG. 3 is a control block diagram of the projector. FIG. 3 is a perspective view showing the periphery of an air volume switch in the first embodiment. FIG. 3 is a control block diagram of the first embodiment. FIG. 6 is a perspective view showing the periphery of an air volume switch in the second embodiment. FIG. 6 is a control block diagram of the second embodiment. The perspective view which shows the modification of an air volume switch.

Hereinafter, an embodiment (hereinafter referred to as Embodiment 1) of a projector 1 as an image projection apparatus to which the present invention is applied will be described.
FIG. 1 is a perspective view showing a projector 1 according to the first embodiment. FIG. 2 is a right side view. As shown in FIGS. 1 and 2, an operation unit 11 such as an operation button for a user to operate the projector 1 is provided on the upper surface of the projector 1. A zoom lever 12 is provided for enlarging or reducing the projection screen displayed on the screen 200. On the front side of the projector 1, a power switch 13 for turning on / off the apparatus power, an external input terminal 14 for connecting to an external device such as a personal computer or a video camera, a projection lens 15 for emitting light of a projected image, an apparatus environment A sensor 16 for detecting the illuminance is provided. An exhaust port 18 is provided in front of the projector 1. An intake port 17 for taking in cooling air is provided on the right side surface of the exterior cover in the projector 1.

  1a shown in FIG. 1 is a light source cover. When the light source lid 1a is removed, a light source holder 2 that holds a discharge lamp described later is exposed. The user grasps and lifts the exposed light source holder 2 to remove the light source unit 20 a having the light source holder 2 and the discharge lamp from the projector 1.

FIG. 3A is a perspective view showing the internal configuration and arrangement of the projector 1 with the exterior cover removed, and FIG. 3B is a perspective view of a portion surrounded by a thick line frame in FIG. FIG. 4 is a cross-sectional view of the light source unit, the image generation unit, and the projection optical unit that constitute the projection mechanism unit.
As shown in FIGS. 3 and 4, the projector 1 includes a light source unit 20 including a discharge lamp 21 such as a halogen lamp, a metal halide lamp, or a high-pressure mercury lamp. Moreover, the image generation part 30 which produces | generates an image using the light from the discharge lamp 21, and the projection optical part 40 which radiate | emits a projection image are provided. The light source unit 20 includes a light source unit 20 a having a discharge lamp 21 and an image illumination optical system 20 b having a color wheel 22, a light tunnel 23, and two relay lenses 24. The light from the discharge lamp 21 is separated into R, G, and B light in a time-division manner by passing through the rotating color wheel 22 as indicated by arrows in FIG. The color wheel 22 has a disk shape, is fixed to the motor shaft of the wheel motor 25, and is provided with filters such as R (red), G (green), and B (blue) in the rotation direction. The light separated by the color wheel 22 enters the light tunnel 23. The light tunnel 23 has a rectangular tube shape, and its inner peripheral surface is a mirror surface. The light incident on the light tunnel 23 is reflected by the mirror surface on the inner periphery of the light tunnel 23 a plurality of times and is emitted to the two relay lenses 24 as a uniform surface light source. As shown by the arrows in FIG. 4, the light passes through the two relay lenses 24, is reflected by the plane mirror 31 and the concave mirror 32 of the next-stage image generation unit 30, and is collected on the image generation surface of the DMD 33 which is an image display element. The light is imaged.

  Here, a plurality of movable micromirrors are arranged in a grid pattern on the image generation surface of the DMD 33. Each micromirror can incline the mirror surface by a predetermined angle around the twist axis, and can have two states of “ON” and “OFF”. When the micromirror is “ON”, the light from the discharge lamp 21 of the light source unit 20 is reflected toward the projection lens of the projection optical unit 40. When “OFF”, the light from the discharge lamp 21 is reflected toward an OFF light plate (not shown) held on a side surface such as an illumination bracket. Therefore, by driving each mirror individually, light projection can be controlled for each pixel of the image data, and an image can be generated. In addition, the light reflected toward the OFF light plate (not shown) is absorbed as heat and cooled by the flow of outside air.

  A projector 1 shown in FIG. 1 generates an image based on image data input from a personal computer, a video camera, or the like, and projects and displays the image on a screen 200 as a projection surface in FIG. A liquid crystal projector widely known as the projector 1 has recently been improved in the resolution, the price, and the like with an increase in the resolution of the liquid crystal panel, the efficiency of the light source lamp. In addition, a compact and lightweight projector 1 using a DMD that is an image display element has become widespread and has been widely used not only in offices and schools but also at home. Light emitted from the discharge lamp 21 is split into RGB by the color wheel 22 in the light source unit 20 and the emitted white light is guided to the DMD 33 of the image generation unit 30 and forms an image according to the modulation signal. The image is enlarged and projected by the projection optical unit 40.

FIG. 5 is a schematic configuration diagram showing the light source unit 20a.
The discharge lamp 21 includes a discharge tube 201 having a light emitting part 201c in which high-pressure gas is confined. A first electrode 201a and a second electrode 201b extending in the left-right direction in the drawing are disposed in the discharge tube. In the light emitting part 201c provided in the center of the discharge tube, one end of the first electrode 201a is disposed to face one end of the second electrode 201b, and the other end of each electrode is exposed from the discharge tube 201. ing. The other end of the first electrode 201a is exposed from the light emission side of the discharge lamp 21 in the discharge tube 201, and the second electrode 201b is exposed from the non-light emission side of the discharge lamp 21 in the discharge tube 201. One end of the first conductive line 202 is connected to the other end of the first electrode 201a, and the other end is connected to the first terminal 206 connected to the lamp driving power supply circuit 52a (see FIG. 8) of the ballast unit 52. Has been. One end of the second conductive line 204 is connected to the other end of the second electrode 201b, and the other end is connected to the second terminal 205 connected to the lamp drive power supply circuit 52a (see FIG. 8) in the apparatus. It is connected. Further, the discharge lamp 21 has a reflector 203 as a reflecting member that reflects light emitted from the light emitting unit 201c.

  The discharge lamp 21 is held by the light source holder 2 as a shielding member. The light source holder 2 has a shielding part 2a on which the reflector 203 is held. The substantially central portion of the shielding portion 2a has an opening for allowing light emitted from the discharge lamp 21 to pass therethrough, and the glass plate 3 is fitted into the opening. The light emitted from the light emitting part 201c of the discharge lamp 21 is collected by the reflector 203 at the opening of the shielding part 2a and emitted from the opening.

  The light source holder 2 is provided with positioning protrusions 2b and positioning holes 2c. The positioning protrusion 2b is provided in the lower part of the shielding part 2a, and the positioning hole 2c is provided in the upper surface part 2d of the light source holder. The positioning projection 2b is fitted into a positioning hole 4b provided in the illumination bracket 4 that holds the light tunnel 23 and the like, and the positioning projection 4a of the illumination bracket 4 is fitted into the positioning hole 2c. Thereby, the discharge lamp 21 is positioned on the illumination bracket 4 via the light source holder 2.

  The light source holder 2 is provided with a through hole 2e through which the stepped screw 5 passes. The light source holder 2 is fastened to the illumination bracket 4 by passing the stepped screw 5 through the through hole 2 e and screwing the stepped screw 5 into the screw hole provided in the illumination bracket 4.

FIG. 6 is a diagram for explaining the flow of intake to exhaust in the projector 1.
As shown in FIG. 6, an intake fan 61 is provided inside the apparatus so as to face the intake port 17. In addition, a light source fan 62 as a cooling fan that sends cooling air to the discharge tube 201 and two exhaust fans 63a and 63b that exhaust the air in the apparatus from the exhaust port 18 are provided.

  As shown in FIG. 6, the cooling air taken in from the intake port 17 by the intake fan 61 cools the power supply unit 51 disposed on the air flow path from the intake fan 61 to the light source fan 62. Thereafter, a part of the air is sucked by the light source fan 62 and flows to the discharge tube 201, and the rest flows to the ballast unit 52 for supplying stable electric power (current) to the discharge lamp 21 disposed opposite to the power supply unit 51. .

FIG. 7 is a diagram for explaining the flow of air in the vicinity of the discharge lamp 21.
As shown in FIG. 7, the air taken in by the light source fan 62 flows into the space surrounded by the reflector 203 and the shielding portion 2 a through the inlet 210 a provided in the shielding portion 2 a of the light source holder 2. . And after cooling the discharge tube 201, it passes through the outflow port 210b provided in the shielding part 2a, and is exhausted from the exhaust port 18 by the exhaust fan 63a. Further, part of the air taken in by the light source fan 62 flows on the back surface of the reflector 203 and cools the reflector 203. Thereafter, the air is exhausted from the exhaust port 18 by the exhaust fan 63b through the outlet 211b provided in the light source housing 211 that houses the light source unit 20a.

  Further, the cooling air taken in from the intake port 17 by the intake fan 61 that has flowed into the ballast unit 52 shown in FIG. 6 cools the ballast unit 52 and then flows into the inlet 211 a of the light source housing 211. . And after cooling the light source unit 20a, it passes through the outflow port 211b of the light source housing 211, and is exhausted from the exhaust port 18 by the exhaust fan 63b.

FIG. 8 is a control block diagram of the projector 1. The thin arrows in the figure indicate the flow of electricity, and the thick arrows indicate the flow of wind.
As shown in FIG. 9, the power supply unit 51 has a power supply circuit 51a for supplying a predetermined voltage to the control unit 100 or the like by converting the AC voltage supplied from the power cable 53 into a DC voltage. doing. The ballast unit 52 has a lamp driving power supply circuit 52a that controls so that stable electric power (current) is supplied to the discharge lamp 21. The image illumination optical system 20b is provided with an image illumination optical system drive circuit 101 for controlling the drive of the wheel motor 25 (see FIG. 3).

  The control unit 100 includes a CPU (Central Processing Unit) that is a calculation unit, a RAM (Random Access Memory) that is a storage unit, a RAM (Read Only Memory), and the like. Various components are electrically connected to the control unit 100 that controls the entire projector so that they can communicate with each other. The control unit 100 controls driving of the intake fan 61, the light source fan 62, and the exhaust fans 63a and 63b. Specifically, the intake fan 61, the light source fan 62, and the exhaust fans 63a and 63b are each provided with a rotation speed detection sensor that detects the rotation speed. The control unit 100 controls the driving of the intake fan 61, the light source fan 62, and the exhaust fans 63a and 63b so that the set rotational speed is achieved based on the detection results of these rotational speed detection sensors.

  In addition, the control unit 100 generates a modulation signal based on image data input from an external device such as a personal computer or a video camera via the external input terminal 14 (see FIG. 1), and outputs the modulation signal to the DMD 33 serving as an image display element. . The control unit 100 also controls the image illumination optical system drive circuit 101 and the DMD 33 so that the timing of color separation by the color wheel 22 and the timing of light modulation by the DMD 33 are synchronized.

  Further, the control unit 100 controls the lamp driving power supply circuit 52 a to control the lighting of the discharge lamp 21. The lamp drive power supply circuit 52 a supplies a voltage to the discharge lamp 21 when receiving a lighting signal from the control unit 100, and stops supplying a voltage to the discharge lamp 21 when receiving a turn-off signal from the control unit 100. .

  The control unit 100 also controls the lamp driving power supply circuit 52a to control the light emission amount (brightness) of the discharge lamp 21. The control of the light emission amount (brightness) of the discharge lamp 21 is control for adjusting the brightness of the discharge lamp 21 according to the color of the projected image. When the discharge lamp 21 is an AC lighting type, the control unit 100 controls the lamp driving power supply circuit 52a so that the waveform of the AC current applied to the discharge lamp is synchronized with the timing of color separation by the color wheel 22. The amplitude is changed. When the discharge lamp 21 is a direct current lighting type, the control unit 100 controls the lamp driving power supply circuit 52a to synchronize with the timing of color separation by the color wheel 22 to be applied to the discharge lamp 21 (current). Control the value of.

  Normally, when the discharge lamp 21 is turned on, the control unit 100 starts driving the light source fan 62 and controls the discharge lamp 21 to be air-cooled. Then, while the discharge lamp 21 is lit, the light source fan 62 is continuously driven and the discharge lamp 21 is controlled to be air-cooled. After the discharge lamp 21 is extinguished, the light source fan 62 is driven for a certain period of time, and the discharge lamp 21 is sufficiently air-cooled, and then the drive of the light source fan 62 is stopped. However, for example, if the fan control circuit that controls the driving of the light source fan 62 of the control unit 100 or the light source fan 62 fails, the light source fan 62 may stop driving while the discharge lamp 21 is lit.

  Even if the driving of the light source fan 62 is stopped, if the discharge lamp 21 continues to be lit, the temperature in the apparatus rises, the temperature around the discharge lamp 21 and the discharge lamp 21 becomes high, and various components in the projector Takes thermal damage. Therefore, when the driving of the light source fan 62 is stopped, control is performed to turn off the discharge lamp 21 as a fan error. However, when a substrate incorporating a control circuit that performs control to turn off the discharge lamp 21 fails as a fan error, the fan error cannot be output and control to turn off the discharge lamp 21 cannot be performed. As a result, the discharge lamp 21 may continue to be lit even though the operation of the light source fan 62 is stopped.

  For this reason, a thermal switch that cuts off the supply of voltage to the discharge lamp 21 is provided when its own temperature exceeds a predetermined level, and the lamp is forcibly turned off when the temperature in the apparatus exceeds a threshold value. However, for example, if the exhaust port 18 is blocked for a short time due to some reason, and the thermal switch is activated with only a slight increase in the temperature in the apparatus, the discharge lamp 21 is frequently forcedly forced. It turns off and becomes an inconvenient device. Therefore, there is a margin in the operating temperature of the thermal switch. If the driving of the light source fan 62 is stopped and the discharge lamp 21 is not air-cooled, the temperature around the discharge lamp 21 rises very quickly. Therefore, if there is a margin in the operating temperature of the thermal switch, when the discharge lamp is forcibly turned off by the thermal switch, the surroundings of the light source are already very hot, and the parts around the light source are thermally damaged. There was a risk of receiving it.

  Therefore, in the present embodiment, an air volume switch that mechanically cuts off the supply of voltage to the discharge lamp 21 when the wind of the light source fan 62 disappears is provided. This will be specifically described below using examples.

[Example 1]
FIG. 9 is a perspective view illustrating the periphery of the air volume switch 70 according to the first embodiment.
As shown in FIG. 9, the air volume switch 70 is provided in the vicinity of the fan outlet 62 a of the light source fan 62. The air volume switch 70 is provided on a swing electrode 71 swingably provided at the fan outlet 62 a of the light source fan 62 and an upper surface which is a surface orthogonal to the opening surface of the fan outlet 62 a of the light source fan 62. And a fixed electrode 72. The swing electrode 71 is made of sheet metal, and closes the fan outlet 62 a when the driving of the light source fan 62 is stopped. The swing electrode 71 is separated from the fixed electrode 72.

  When the light source fan 62 starts driving and air flows in the direction of the arrow in the figure from the fan outlet 62a, the swing electrode 71 swings so that the free end of the swing electrode 71 is separated from the fan outlet 62a by the wind pressure. Move. Then, it comes into contact with the fixed electrode 72 arranged on the downstream side of the swinging electrode 71 in the air flow direction. As a result, power (current) can be supplied to the discharge lamp 21. On the other hand, when the driving of the light source fan 62 is stopped, the air flow from the fan outlet 62a disappears. Then, the wind pressure applied to the swing electrode 71 from the light source fan 62 disappears, and the swing electrode 71 swings so that the free end of the swing electrode 71 is separated from the fixed electrode 72 by its own weight. Thereby, the voltage supply to the discharge lamp 21 is interrupted.

FIG. 10 is a control block diagram of the first embodiment.
As shown in FIG. 10, the swing electrode 71 of the air volume switch 70 is connected to the lamp drive power supply circuit 52 a, and the fixed electrode 72 of the air volume switch 70 is connected to the AND circuit 102. The lamp driving power supply circuit 52 a is connected to the discharge tube 201 through the AND circuit 102. Therefore, power is supplied to the discharge tube 201 and the discharge lamp 21 is lit only when the AND circuit 102 has outputs from both the route via the air volume switch 70 and the direct route.

  As a result, when the oscillating electrode 71 of the air volume switch 70 is not receiving wind from the light source fan 62 and the oscillating electrode 71 is separated from the fixed electrode 72, the lamp drive power supply circuit 52 a supplies the discharge lamp 21. Power cannot be supplied, and the discharge lamp 21 is not lit. As a result, when the driving of the light source fan 62 is stopped and the light source fan 62 is not cooling the discharge lamp 21 with air, the discharge lamp 21 is not lit. Thereby, it can suppress that the member around the discharge lamp 21 becomes high temperature with the heat | fever of the discharge lamp 21, and the damage by the heat of the member around the discharge lamp 21 can be suppressed.

  Further, when there is no wind from the light source fan 62 and the discharge lamp 21 is not cooled, the discharge lamp 21 is forcibly turned off. Thus, the discharge lamp 21 can be turned off before the components around the discharge lamp 21 are thermally damaged. In addition, even when the exhaust port 18 is temporarily blocked and the temperature in the apparatus is temporarily increased, the swing electrode 71 is provided when the discharge lamp 21 can be cooled sufficiently by the light source fan 62. The discharge lamp 21 keeps lighting because it is in contact with the fixed electrode 72. Thereby, it is possible to prevent the discharge lamp 21 from forcibly turning off frequently and the projection image from disappearing. When the exhaust port 18 is blocked for a long period of time and the temperature inside the apparatus reaches a predetermined temperature, the discharge lamp 21 is forcibly turned off by a thermal switch (not shown).

  Further, the swing electrode 71 is swung by the wind of the light source fan 62, and the switch is mechanically turned on / off. Thereby, even when the main board breaks down, the discharge lamp 21 can be forcibly turned off.

[Example 2]
FIG. 11 is a perspective view showing the periphery of the air volume switch 70 in the second embodiment, and FIG. 12 is a control block diagram in the second embodiment.
In the second embodiment, the air volume switch 70 is disposed in the discharge lamp 21. Specifically, the air volume switch 70 is disposed between the first terminal 206 (see FIG. 5) of the discharge lamp 21 and the first electrode 201a.
As shown in FIG. 11, the first conductive line 202 connected to the first terminal 206 is connected to the fixed electrode 72 of the air flow switch 70. The swing electrode 71 is swingably supported by the discharge tube 201 and is connected to the first electrode 201a. When the light source fan 62 is stopped and the wind of the light source fan 62 is not sent to the discharge tube 201, the oscillating electrode 71 is separated from the fixed electrode 72, and conduction to the first electrode 201a is not performed. Disconnected. For this reason, when the light source fan 62 is stopped, the discharge lamp 21 does not light even if power is supplied to the discharge lamp 21 from the lamp drive power supply circuit 52a.

  On the other hand, when the light source fan 62 is driven and air is sent from the light source fan 62 toward the discharge tube 201 in the direction of the arrow in the figure, the swing electrode 71 is swung by the wind of the light source fan 62, and the swing electrode 71 is It contacts the fixed electrode 72. As a result, the first electrode 201a is brought into conduction with the lamp driving power supply circuit 52a, and when electric power is supplied from the lamp driving power supply circuit 52a to the discharge lamp 21, the discharge lamp 21 is turned on. When the driving of the light source fan 62 stops, the swing electrode 71 swings by its own weight, moves away from the fixed electrode 72, and the conduction to the first electrode 201a is cut off. Thereby, even if electric power is supplied to the discharge lamp 21, the discharge lamp 21 is forcibly turned off.

  Also in the second embodiment, when the driving of the light source fan 62 is stopped and the light source fan 62 is not air-cooling the discharge lamp 21, the discharge lamp 21 is not lit. Thereby, it can suppress that the member around the discharge lamp 21 becomes high temperature with the heat | fever of the discharge lamp 21, and the damage by the heat of the member around the discharge lamp 21 can be suppressed.

FIG. 13 is a perspective view showing a modification of the air volume switch.
In the air volume switch 70a of this modification, the first conductive wire 202 is spirally wound around the discharge tube 201 to be a coil spring, and is opposed to the first electrode 201a at a predetermined distance on the windward side. A plate-like wind receiving portion 73 that receives the wind of the light source fan 62 is provided at the tip of the first conductive wire 202.

When the light source fan 62 is driven and air is sent from the light source fan 62 toward the discharge tube 201 in the direction of arrow A in the figure, the wind receiving portion 73 receives the wind and swings in the direction of arrow B in the figure. Then, the first conductive line 202 comes into contact with the first electrode 201a, and the first electrode 201a is electrically connected to the lamp driving power supply circuit 52a. Thereby, when electric power is supplied to the discharge lamp 21 from the lamp drive power supply circuit 52a, the discharge lamp 21 is turned on. On the other hand, when the driving of the light source fan 62 stops, the wind receiving portion 73 swings in the direction opposite to the arrow B direction in the drawing due to its own weight, and the first conductive wire 202 is separated from the first electrode 201a. Thereby, even if the electrical connection to the 1st electrode 201a is cut off and electric power is supplied to the discharge lamp 21, the discharge lamp 21 is forcibly turned off.
In the air flow switch 70a of this modification, the first electrode 201a functions as a fixed electrode, and the first conductive line 202 functions as a counter electrode.

What has been described above is an example, and the present invention has a specific effect for each of the following aspects.
(Aspect 1)
In an image projection apparatus such as a projector 1 that includes a light source such as a discharge lamp 21 and a cooling fan such as a light source fan 62 for cooling the light source, and projects an image using light from the light source, the wind from the cooling fan And a switch such as an air volume switch 70 for switching the light source from a non-lightable state to a lightable state.
According to (Aspect 1), when air is cooled to the light source such as the discharge lamp 21 by the cooling fan such as the light source fan 62 and the light source is air-cooled, the switch such as the air volume switch 70 can be lit with the wind of the cooling fan. When the power is supplied to the light source, the light source is turned on. On the other hand, when the cooling fan stops, the switch does not receive the wind of the cooling fan, switches from the lit state to the unlit state, and the light source is turned off. Thereby, when the cooling fan is stopped, the light source is surely turned off, and the heat of the light source can prevent the light source and the surroundings of the light source from becoming high temperature.
Also, when the light source is turned on / off based on the cooling fan operation signal (fan error) by the control circuit (software) mounted on the main board, if the main board fails, the cooling fan operation signal will be normal. The light source may remain unlit even though the cooling fan is stopped.
On the other hand, in (Aspect 1), even if the operation of the cooling fan cannot be normally detected due to a failure of the main board, if the cooling fan stops, the light source can be turned on and the light source cannot be turned on, and the light source is forced. Can be turned off automatically.

(Aspect 2)
In (Aspect 1), a switch such as the air flow switch 70 is provided in a light source driving circuit such as a lamp driving circuit that supplies power from a power source such as the power supply unit 51 to a light source such as the discharge lamp 21 to turn on the light source. The switch switches from a state in which power cannot be supplied to the light source to a state in which power can be supplied to the light source by wind from the cooling fan.
According to this, as described in the first embodiment, when driving of the cooling fan such as the light source fan 62 is stopped, power is not supplied to the light source such as the discharge lamp 21 and the discharge lamp 21 can be turned off.

(Aspect 3)
In (Aspect 1), the light source such as the discharge lamp 21 has a discharge portion such as the discharge tube 201, and the air taken in by the cooling fan such as the light source fan 62 is configured to flow to the discharge portion. A switch such as an air flow switch 70 is provided in the discharge unit, and the switch connects / disconnects energization to the discharge unit.
According to this, as described in the second embodiment, when driving of the cooling fan such as the light source fan 62 is stopped, power is not supplied to the discharge unit such as the discharge tube 201 and the discharge lamp 21 can be turned off. .

(Aspect 4)
In any one of (Aspect 1) to (Aspect 3), the switch such as the air volume switch 70 includes an oscillating electrode 71 that oscillates with the wind of a cooling fan such as the light source fan 62, and a fixed electrode 72. The electrode 71 swings from a separated position away from the fixed electrode 72 to a contact position in contact with the fixed electrode 72 by the wind of the cooling fan.
According to this, as described in the embodiment, when the cooling fan such as the light source fan 62 is driven and the swing electrode 71 receives the wind of the cooling fan, the swing electrode 71 is connected to the fixed electrode 72. The light source such as the discharge lamp 21 can be turned on at the contact position where it comes into contact. On the other hand, when the driving of the cooling fan is stopped and the swinging electrode 71 stops receiving the wind of the cooling fan, the swinging electrode swings from the contact position in contact with the fixed electrode to the separated position, and the light source cannot be turned on. . Thereby, when the drive of the cooling fan is stopped, the light source can be surely turned off.
In addition, the number of parts can be reduced and the cost of the apparatus can be reduced as compared with the case where a wind receiving portion for receiving the cooling fan air is provided separately from the electrodes.

(Aspect 5)
In any one of (Aspect 1) to (Aspect 3), the switch is disposed on the windward side of the fixed electrode such as the first electrode 201a and is opposed to the fixed electrode with a predetermined gap. When a counter electrode such as the first conductive wire 202 and a wind receiving portion 73 fixed to the counter electrode and receiving a wind of a cooling fan such as the light source fan 62 are received, the wind receiving portion 73 receives the wind of the cooling fan. The image projection apparatus, wherein the counter electrode moves and contacts the fixed electrode.
According to this, as described with reference to FIG. 13, when the wind receiving portion 73 receives wind from a cooling fan such as the light source fan 62, the wind receiving portion 73 moves downwind due to wind pressure. Then, the counter electrode such as the first conductive line 202 moves and contacts the fixed electrode such as the first electrode 201a, and the light source such as the discharge lamp 21 can be turned on. When driving of the cooling fan is stopped and the wind receiving portion 73 stops receiving the wind of the cooling fan, the wind receiving portion 73 returns to the original position, the swing electrode is separated from the fixed electrode, and the light source cannot be turned on. Thereby, when the drive of the cooling fan is stopped, the light source can be surely turned off.

1: Projector 17: Intake port 18: Exhaust port 20a: Light source unit 21: Discharge lamp 51: Power supply unit 51a: Power supply circuit 52: Ballast unit 52a: Lamp drive power supply circuit 61: Intake fan 62: Light source fans 63a, 63B: Exhaust Fan 70, 70a: Air volume switch 71: Swing electrode 72: Fixed electrode 73: Air receiving unit 100: Control unit 101 Image illumination optical system drive circuit 201: Discharge tube 201a: First electrode 201c: Light emitting unit 201b: Second electrode 202: First conductive wire 203: Reflector 204: First conductive wire

JP 2002-156704 A

Claims (5)

A light source;
An image projection apparatus comprising a cooling fan for cooling the light source and projecting an image using light from the light source;
An image projection apparatus comprising: a switch that switches the light source from a state in which the light source cannot be turned on to a state in which the light source can be turned on by wind from the cooling fan. The image projection apparatus according to claim 1,
The switch is provided in a light source driving circuit that supplies power to the light source from a power source to turn on the light source,
The switch is configured to switch from a state in which power cannot be supplied to the light source to a state in which power can be supplied to the light source by wind from the cooling fan. The image projection apparatus according to claim 1,
The light source has a discharge part,
The air taken in by the cooling fan is configured to flow to the discharge part,
The switch is provided in the discharge part,
The image projection apparatus, wherein the switch connects / disconnects energization to the discharge unit. The image projection apparatus according to any one of claims 1 to 3,
The switch includes a swing electrode that swings due to the wind of the cooling fan, and a fixed electrode,
The image projection device, wherein the swing electrode swings from a separated position away from the fixed electrode to a contact position in contact with the fixed electrode by wind of the cooling fan. The image projection apparatus according to any one of claims 1 to 3,
The switch is disposed on the windward side of the fixed electrode, the counter electrode facing the fixed electrode with a predetermined gap, and fixed to the counter electrode. And a wind receiving part
When the wind receiving portion receives wind from the cooling fan, the counter electrode moves and contacts the fixed electrode.

Images