JP2008060108A - Electronic apparatus - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an electronic apparatus capable of preventing deterioration of a filter by enabling removal of dust adhering on the filter. <P>SOLUTION: The electronic apparatus is provided with an enclosure 1 constituting an exterior of the electronic apparatus; opening (air inlet port 2) provided on the enclosure 1; fan (air intake fan 120) for sucking an ambient air into the enclosure 1 by a regular rotation operation, and exhausting the air in the enclosure 1 by a reverse rotation operation, to the outside of the electronic apparatus through the opening; filter 121 disposed between the opening and the fan, and preventing dust from infiltrating the inside of the enclosure 1; filter holding member 122 for holding the filter 121; and movable portion (vibration element 123) for making the filter holding member 122 move. The movable portion makes the filter holding portion 122 movable interlockingly with the reverse rotation operation of the fan. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to an electronic device including a fan that sucks outside air into a housing of the electronic device and a filter that prevents dust from entering.

  Some electronic devices are provided with an internal cooling device that includes a cooling fan that cools the inside of the electronic device and a filter that is attached to the cooling fan and prevents dust from entering from outside. However, when dust is accumulated in the filter, the amount of air sent into the electronic device is reduced, and the cooling effect is reduced. Therefore, the cooling fan of the internal cooling device is provided with a cleaning means that mechanically operates on the filter surface to remove dust adhering to the filter, and the cooling fan performs an intake operation by normal rotation during the cooling operation, An internal cooling device is disclosed in which an exhaust operation by reverse rotation is performed in the cleaning mode and the cleaning means is activated (Patent Document 1).

JP 2006-41097 A

  However, in Patent Document 1, since the cleaning unit mechanically operates on the filter surface to remove dust attached to the filter, friction is generated between the filter surface and the cleaning unit to accelerate the deterioration of the filter. There was a high possibility that the performance of removing dust would deteriorate. In addition, the cleaning means scratches the filter surface due to friction generated when operating the filter surface, and the filter itself generates fine dust, which is likely to become a dust source. .

  SUMMARY An advantage of some aspects of the invention is that it provides an electronic device that can remove dust attached to a filter and suppress deterioration of the filter.

  In order to achieve the above object, an electronic device according to the present invention has a casing that constitutes an exterior of the electronic device, an opening that is installed in the casing, and a case in which outside air is moved by forward rotation through the opening. A fan that sucks into the interior and exhausts the air inside the housing to the outside of the electronic device by reverse rotation operation, a filter that is disposed between the opening and the fan and prevents dust from entering the housing, and a filter And a movable part that moves the filter holding member. The movable part moves the filter holding member in conjunction with the reverse rotation operation of the fan.

  According to such an electronic device, the fan blows away dust adhering to the filter by discharging the air inside the housing to the outside of the electronic device by a reverse rotation operation. Furthermore, since the filter can be moved by moving the filter holding member by the movable portion, and dust attached to the filter can be easily peeled off, dust removal efficiency can be improved. At this time, the filter is indirectly moved through the filter holding member. Therefore, in the past, a member that directly contacts the surface of the filter was used. However, there is no electronic device that directly contacts the surface of the filter, and the deterioration of the filter itself can be suppressed. it can.

  In the electronic apparatus, it is preferable that the movable portion includes a vibration member that generates vibration, and the filter holding member vibrates in response to vibration generated by the vibration member.

  According to such an electronic device, the dust attached to the filter can be shaken off by the vibration of the vibration member. Therefore, dust removal efficiency can be improved.

  In the electronic apparatus, the frequency of vibration is preferably proportional to the reverse rotation speed of the fan.

  According to such an electronic device, it is possible to effectively give vibration to various types and sizes of dust by changing the frequency at which the filter vibrates via the filter holding member. Further, the reverse rotation speed of the fan is proportionally increased in accordance with the vibration frequency. That is, it is possible to effectively remove dust by giving effective vibration to various types and sizes of dust accumulated in the filter and determining the reverse rotation speed of the fan.

  In the electronic apparatus, the amplitude of vibration is preferably proportional to the reverse rotation speed of the fan.

  According to such an electronic apparatus, the amplitude with which the filter vibrates via the filter holding member is proportional to the reverse rotation speed of the fan. Therefore, by determining the reverse rotation speed of the intake fan according to the amount of dust accumulated in the filter, the vibration amplitude of the filter is uniquely determined to an optimum value, and suitable dust removal can be performed. .

  The electronic device further includes a timer unit for measuring the reverse rotation operation time of the fan, and the timer unit measures the reverse rotation operation time of the fan, and when the predetermined time has elapsed, the reverse rotation operation of the fan is performed. Is preferably stopped.

  According to such an electronic device, the reverse rotation operation of the fan stops at a predetermined time. Therefore, it is possible to minimize the time for dust removal processing, and it is possible to achieve dust removal without impairing the operation response of the electronic device.

  In the electronic device, the reverse rotation operation of the fan is preferably performed intermittently.

  According to such an electronic device, during the reverse rotation operation, the fan alternately repeats the reverse rotation operation and stops. Thus, when the fan performs an intermittent operation, the dust accumulated in the filter can be easily peeled off, and the dust removal efficiency can be improved.

  Also, in the electronic device, power is supplied to the entire electronic device and the normal functional operation is being performed, and power is supplied to a part of the electronic device. It is preferable that one of a standby state in which the standby function is operated and a stop state in which power is not supplied to the electronic device can be taken.

  According to such an electronic device, there are three states: an operation state, a standby state, and a stop state. In the stop state, the power consumption is 0 (zero). In the standby state, power is supplied to only a part of the electronic device, and power consumption is kept low. In the operating state, power is supplied to the entire electronic device, and the power consumption is consumed for the normal function operation. In the standby state, for example, a part of a user operation such as a main power-on operation by a remote controller can be accepted and the operation state can be changed. In this way, necessary functional operations can be realized without consuming unnecessary power consumption in accordance with each state of the electronic device.

  Further, in the electronic device, it is preferable that the fan is reversely rotated when transitioning from the operating state to the standby state.

  According to such an electronic device, dust is removed from the filter when transitioning from the operating state to the standby state. Here, the transition from the operating state to the standby state indicates, for example, a case where an operation to turn off the main power is performed. Therefore, the electronic device can suppress clogging of the filter by removing dust every time the main power is turned off. Here, the dust removal of the filter is performed after the forward rotation operation of the fan for cooling the inside of the electronic device is completed. Therefore, even if the fan is reversely rotated by the dust removal process, there is no influence on the electronic device.

  In the electronic device, it is preferable that the fan is reversely rotated when a specific key switch input signal is received when transitioning from the standby state to the operating state.

  According to such an electronic device, when a specific key switch input signal is received when transitioning from the standby state to the operating state, dust is removed from the filter. The transition from the standby state to the operation state indicates, for example, when an operation to turn on the main power is performed. The reception of a specific key switch input signal indicates, for example, that a specific key switch is pressed by the user. Therefore, the electronic device can perform dust removal when the main power is turned on by pressing a specific key switch according to the user's request, and can suppress clogging of the filter. Here, the dust removal of the filter is performed before starting the forward rotation operation of the fan for cooling the inside of the electronic device. Also, the dust removal of the filter is performed before the lamp is lit. Therefore, even if the fan is reversely rotated by the dust removal process, there is no influence on the electronic device.

  Moreover, in the said electronic device, when changing from a stop state to a standby state, it is preferable to reversely rotate the fan.

  According to such an electronic device, dust is removed from the filter when transitioning from the stopped state to the standby state. The transition from the stop state to the standby state indicates, for example, that the AC adapter of the electronic device is inserted into an outlet (AC power is supplied). Therefore, the electronic device can suppress clogging of the filter by removing dust every time the AC adapter is inserted into the outlet. Here, in the stop state and the standby state, the forward rotation operation of the fan for cooling the inside of the electronic device is unnecessary. Therefore, when the state transitions from the stop state to the standby state, the electronic device is not affected even if the fan is reversely rotated by the dust removal process.

  In the electronic device, the electronic device is preferably a projector.

  By doing so, it is possible to provide a projector in which the above-described effects are obtained, the dust removal effect is high, and the filter is not easily clogged. In particular, in the case of a projector, it may be used suspended from the ceiling, and it may take time to clean and replace the filter. Therefore, it is useful to apply the present invention having a dust removal function. Is expensive.

(First embodiment)
Hereinafter, the first embodiment of the present invention will be described with reference to FIGS. 1 to 10, 12, and 13.

FIG. 1 is a schematic perspective view of a projector as an electronic apparatus according to the first embodiment of the present invention. With reference to FIG. 1, an external configuration of projector 100 will be described.
The projector 100 includes a housing 1 that forms the exterior of the projector 100, an air inlet 2, an air outlet 3, an operation unit 4, a remote control light receiving unit 5, a projection lens 6, a sound report hole 7, An LED (Light Emitting Diode) display unit 8 and a foot 9 are provided.

  The intake port 2 is an opening provided in the housing 1, and an intake fan 120, a filter 121, a filter holding member 122, a vibration element 123, and the like, which will be described later, are installed inside the intake port 2. The air inlet 2 sucks outside air into the housing 1. The exhaust port 3 is an opening provided in the housing 1, and an exhaust fan 130 is installed inside the exhaust port 3. The exhaust port 3 exhausts the air sucked from the intake port 2 to the outside of the housing 1. The operation unit 4 includes a key switch and accepts a function operation of the projector 100 by the user. The remote control light receiving unit 5 receives a functional operation of the projector 100 by the user using the remote controller. The projection lens 6 is a lens that projects the video signal input to the projector 100 as an image. The sound notification hole 7 has a speaker installed therein and outputs the sound input to the projector 100. The LED display unit 8 displays the functional operation state of the projector 100 with each color, lighting / flashing, and the like using the LED. The foot 9 supports the projector 100 and adjusts the height of the projector 100. In addition, a video and audio input unit (not shown) is provided on the rear surface of the projector 100, and inputs a video signal and an audio signal.

  FIG. 2 is a configuration diagram showing an air inlet of the projector as the electronic apparatus according to the first embodiment of the present invention and the inside thereof. With reference to FIG. 2A and FIG. 2B, the air inlet 2 of the projector 100 and the internal configuration thereof will be described.

  FIG. 2A shows a case where outside air is sucked into the housing 1 of the projector 100 by forwardly rotating the intake fan 120 as a fan in claims. As shown in the drawing, the air inlet 2 of the projector 100 and the inside thereof are provided with an air intake fan 120, a filter 121, a filter holding member 122, and a vibration element 123 as a vibration member. The vibration element 123 may be, for example, a piezoelectric element or an ultrasonic motor. Here, a slight gap is provided between the filter holding member 122 and the housing 1. Moreover, the arrow in a figure has shown the flow of air.

  FIG. 2B shows a case where the air inside the housing 1 is exhausted to the outside of the projector 100 by reversely rotating the intake fan 120 as a fan in the claims. The configuration is the same as in FIG. 2A, but the air flow is in the opposite direction.

  In FIG. 2A, the intake fan 120 is rotated forward so that outside air is sent through the filter 121 and cools the inside of the housing 1. At this time, the filter 121 receives dust on the surface of the filter 121 so that external dust does not enter the inside of the housing 1. In FIG. 2B, the air inside the housing 1 is exhausted to the outside of the projector 100 by the reverse rotation operation of the intake fan 120. As the intake fan 120 rotates in the reverse direction, the dust accumulated in the filter 121 is blown out. At this time, the vibration element 123 vibrates in conjunction with the reverse rotation operation of the intake fan 120. When the vibration element 123 vibrates, the connected filter holding member 122 vibrates. As described above, since there is a slight gap between the filter holding member 122 and the housing 1, the filter holding member 122 can vibrate between the gap regions. When the filter holding member 122 vibrates, the filter 121 vibrates. Through such a series of operations, dust adhering to the filter 121 is shaken off from the surface of the filter 121 and peeled off.

  Thereby, by vibrating the filter 121, a higher dust removal effect can be obtained as compared with the case where only the intake fan 120 is rotated backward. Further, the filter 121 is vibrated by the vibration element 123 through the filter holding member 122. Therefore, since this dust removal method does not directly contact the surface of the filter 121, the filter 121 can be prevented from being worn out or damaged, and deterioration can be suppressed. That is, the lifetime of the filter 121 can be improved.

FIG. 3 is a functional block diagram showing the functional configuration of the projector. A functional configuration of the projector 100 will be described with reference to FIG.
The projector 100 includes a video input unit 110, a video signal processing unit 111, a video projection unit 112, an operation unit 4, a remote control light receiving unit 5, an operation reception unit 113, a control unit 114, a timer unit 115, A fan control unit 116, a temperature detection unit 117, a vibration control unit 118, an intake fan 120, a filter 121, a filter holding member 122, a vibration element 123, and an exhaust fan 130 are provided.

Next, the operation of the projector 100 will be described using the functional configuration.
The video input unit 110 inputs a video signal from an external video output device (not shown). The input video signal is processed by the video signal processing unit 111 as necessary. Video processing refers to, for example, image processing such as enlargement or reduction, trapezoid correction processing, color correction processing, and the like. The video signal subjected to the video processing is projected as a video by the video projection unit 112. Operation accepting unit 113 accepts a function operation instruction to projector 100 by the user from operation unit 4 or remote control light receiving unit 5. The control unit 114 performs a functional operation corresponding to the functional operation instruction received by the operation receiving unit 113, a functional operation corresponding to the time measurement result from the timer unit 115, and the like, and performs overall control of the projector 100. As other control contents, for example, control regarding video signal processing, control of a lamp unit (not shown), fan control, and the like are performed. In addition, the timer unit 115 performs various timing processes according to instructions from the control unit 114.

  The fan control unit 116 performs fan-related control according to an instruction from the control unit 114. The fan control unit 116 inputs temperature information from the temperature detection unit 117. Further, the fan control unit 116 inputs the time measurement information from the timer unit 115 and the function operation information from the operation reception unit 113 via the control unit 114. The fan control unit 116 controls the rotation direction (forward / reverse rotation), rotation start operation, rotation stop operation, rotation speed, rotation time, and the like of the fan using these pieces of information. The fan control unit 116 outputs these fan rotation information to the vibration control unit 118. The fans controlled by the fan control unit 116 are the intake fan 120 and the exhaust fan 130. One or a plurality of intake fans 120 and exhaust fans 130 exist, and it is desirable to control them individually.

  The temperature detection unit 117 measures the temperature of the heat generating portion that needs to be cooled in the projector 100 and outputs the temperature to the fan control unit 116. The vibration control unit 118 controls the vibration of the vibration element 123 based on the fan rotation information from the fan control unit 116. As vibration control, vibration start, vibration stop, vibration frequency and amplitude, and the like are controlled. Here, the control unit 114, the fan control unit 116, and the vibration control unit 118 are different functional components, but the circuit configuration may be configured by one CPU (Central Processing Unit).

  The intake fan 120 operates under the control of the fan control unit 116. The filter 121 is held by a filter holding member 122. The filter 121 prevents dust from entering the housing 1 of the projector 100. The filter holding member 122 holds the filter 121 and is connected to the vibration element 123. The vibration element 123 operates under the control of the vibration control unit 118. When the vibration element 123 vibrates, the filter holding member 122 vibrates, and further, the filter 121 vibrates. The exhaust fan 130 operates under the control of the fan control unit 116.

  With such a configuration, the projector 100 can control the temperature inside the housing 1 using the intake fan 120 and the exhaust fan 130 while projecting an image. Further, the dust attached to the filter 121 can be removed by interlocking the intake fan 120 and the vibration element 123 with each other.

  Next, as a first embodiment of the present invention, state transition of the projector 100 and dust removal processing will be described using Examples 1 to 4. As shown in the state transition diagram of FIG. 4, the projector 100 can take three states: an operation state ST12, a standby state ST11, and a stop state ST10. The operation state ST12 indicates a normal function operation state in which power is supplied to the entire projector 100 apparatus and a lamp as a light source is turned on to project an image. The standby state ST11 indicates a state in which power is supplied to a part of the projector 100 device, but the lamp is turned off and no image is projected. The standby state ST11 waits for a function operation instruction of the projector 100 from the user. The stopped state ST10 indicates a stopped state in which power is not supplied to the projector 100 device. It should be noted that here, the stop state ST10 and the standby state ST11 are assumed to change states by, for example, AC adapter insertion / extraction, and the standby state ST11 and the operation state ST12 are, for example, from a user such as a main power key switch on / off. It is assumed that the state transitions in response to the operation instruction. In the following description, the symbols for the respective states are omitted.

  (Embodiment 1) FIG. 5 is a flowchart of processing when a projector according to Embodiment 1 transitions from an operating state to a standby state. In the present embodiment, the operation for causing the projector 100 to transition from the operating state to the standby state is a main power-off operation by the user. The present embodiment shows a transition process when dust is removed after the cool-down operation. Here, the cool-down operation indicates that, at the end of the normal function operation, the intake fan and the exhaust fan are rotated forward for a predetermined time in order to lower the temperature inside the projector 100. The dust removal process is a subroutine, and details will be described with reference to FIG. A process when projector 100 transitions from the operating state to the standby state will be described with reference to FIG.

  First, the control unit 114 turns off the lamp of the projector 100 (step S100). Next, fan control unit 116 starts a cool-down operation (step S110). During the cool-down operation, the intake fan 120 performs a normal rotation operation. Further, the exhaust fan 130 also performs a forward rotation operation. Next, the control unit 114 causes the timer unit 115 to start a cool-down timer (step S120). The cool-down timer is a timer that measures the time for performing the cool-down operation (hereinafter referred to as “cool-down time”). The timer unit 115 determines whether or not the cool-down time has elapsed (step S130). While the cool-down time has not elapsed (step S130: NO), step S130 is looped to wait for the passage of time. When the timer unit 115 determines that the cool-down time has elapsed (step S130: YES), the fan control unit 116 stops the rotation operation of the intake fan 120 and the exhaust fan 130, and stops the cool-down operation (step S130). S140).

  Next, fan control unit 116 and vibration control unit 118 execute a dust removal processing subroutine (step S150). Here, the dust removing process refers to a process of removing dust attached to the filter 121 by rotating the intake fan 120 in the reverse direction, and the details will be described later with reference to the flowchart of FIG. Further, the dust removal processing subroutine can be replaced with the intermittent operation dust removal subroutine described with reference to FIG. Next, control unit 114 executes various processes associated with the transition from the operating state to the standby state (step S160), and projector 100 transitions to the standby state. Here, the various processing refers to data storage processing related to various functions of the projector 100.

  FIG. 6 is a flowchart of the dust removal processing subroutine. A series of processing related to dust removal of the projector 100 will be described with reference to FIG.

  The fan control unit 116 determines the reverse rotation speed of the intake fan 120 (step S200). Here, the reverse rotation speed is set in advance. It is desirable that the reverse rotation speed can be changed by the user according to the degree of dust adhesion on the surface of the filter 121. For example, a fan reverse rotation speed setting item may be provided as one of the function setting tables in the projector 100 so that the user can set using the operation unit 4 or the remote controller. At this time, if the user feels that the dust on the surface of the filter 121 is less attached, the reverse rotation speed of the intake fan 120 is lowered, and if the user feels that the dust is much attached, the reverse rotation speed is increased. Thus, efficient dust removal can be performed. It is also possible to automatically determine the reverse rotation speed of the intake fan 120. For example, by installing a wind pressure measuring element inside the filter 121 and measuring the wind pressure when the intake air of the filter 121 is sucked when the intake fan 120 is rotating forward, the dust adhesion state of the filter 121 is determined. . The fan control unit 116 may determine the reverse rotation speed of the intake fan 120 in accordance with the determination result. Here, when there are a plurality of intake fans 120, it is desirable to individually determine the reverse rotation speed for each. Next, the fan control unit 116 causes the intake fan 120 to start a reverse rotation operation based on the reverse rotation speed determined in step S200 (step S210).

  Next, the vibration control unit 118 determines the frequency and amplitude of vibration of the vibration element 123 based on the reverse rotation speed of the intake fan 120 (step S220). As a method for determining the frequency of vibration, for example, the vibration control unit 118 uses a linear function as shown in FIG. FIG. 12 is a relationship diagram between the reverse rotation speed of the fan and the frequency of vibration. A straight line A represents a linear function in which the reverse rotation speed of the fan and the frequency of vibration are in a proportional relationship. Using this linear function, the vibration control unit 118 can uniquely determine the value of the vibration frequency as b when the value of the reverse rotation speed of the fan is a. Here, the vibration frequency is determined based on the reverse rotation speed of the fan. However, the vibration frequency is first determined according to the type and size of dust, and the fan is determined based on the vibration frequency. It is good also as what determines the reverse rotation speed of.

  As a method for determining the amplitude of vibration, for example, the vibration control unit 118 uses a linear function as shown in FIG. FIG. 13 is a relationship diagram between the reverse rotation speed of the fan and the amplitude of vibration. A straight line B represents a linear function in which the reverse rotation speed of the fan and the amplitude of vibration are in a proportional relationship. Using this linear function, the vibration control unit 118 can uniquely determine the value of the vibration amplitude as c when the value of the reverse rotation speed of the fan is a. In this way, using these functions, the vibration control unit 118 can determine the frequency and amplitude of vibration from the reverse rotation speed of the intake fan 120. Next, the vibration control unit 118 causes the vibration element 123 to start vibration based on the frequency and amplitude of vibration determined in step S220 (step S230).

  Next, the control unit 114 causes the timer unit 115 to start an intake fan reverse rotation timer (step S240). The intake fan reverse rotation timer is a timer that measures a predetermined time for the reverse rotation operation of the intake fan 120. The intake fan reverse rotation timer measures the passage of a predetermined time. Here, the predetermined time is set in advance. Moreover, it is desirable that the user can change the predetermined time. For example, a fan reverse rotation operation time setting item may be provided as one of the function setting tables of the projector 100 so that the user can set using the operation unit 4 or the remote controller. At this time, when the user feels that the dust on the surface of the filter 121 is little attached, the reverse rotation operation time of the intake fan 120 is shortened, and when the user feels that much dust is attached, the reverse rotation operation time is lengthened. Thus, efficient dust removal can be performed. It is also possible to automatically determine a predetermined time. For example, by installing a wind pressure measuring element inside the filter 121 and measuring the wind pressure when the intake air of the filter 121 is sucked when the intake fan 120 is rotating forward, the dust adhesion state of the filter 121 is determined. . A predetermined time that is the reverse rotation operation time of the intake fan 120 may be determined based on the determination result.

  The timer unit 115 determines whether or not a predetermined time has elapsed (step S250). While the predetermined time has not elapsed (step S250: NO), the process continues to wait for the elapse of time. When the predetermined time has elapsed (step S250: YES), fan control unit 116 stops the reverse rotation operation of intake fan 120 (step S260). Next, the vibration control unit 118 stops the vibration of the vibration element 123 (step S270). Thus, a series of processing (subroutine) related to dust removal ends, and the process returns.

  Next, a dust removal processing (hereinafter referred to as “intermittent operation dust removal processing”) subroutine when the fan reverse rotation operation is performed intermittently will be described. FIG. 7 is a flowchart of the intermittent operation dust removal processing subroutine. The intermittent operation dust removal processing subroutine is obtained by adding processing for intermittently performing the fan reverse rotation operation to the dust removal processing subroutine shown in FIG. Therefore, the dust removal processing subroutine portion of the first embodiment and the second to fourth embodiments described later can be replaced with an intermittent operation dust removal processing subroutine. The intermittent operation dust removal processing of the projector 100 will be described with reference to FIG. In this description, differences from the dust removal processing subroutine of FIG. 6 are mainly described.

  In FIG. 7, the process from the determination of the reverse rotation speed of the intake fan (step S300) to the start of the intake fan reverse rotation timer (step S340) corresponds to the process from step S200 to step S240 in FIG. I do. That is, step S300 corresponds to step S200, step S310 corresponds to step S210, step S320 corresponds to step S220, step S330 corresponds to step S230, and step S340 corresponds to step S240. Next, the control unit 114 causes the timer unit 115 to start an intermittent intake fan operation timer (step S350). The intake fan intermittent operation timer is a timer that measures the time (hereinafter referred to as “intermittent operation time”) in which the intake fan 120 repeats reverse rotation operation and stop alternately. Here, the intermittent operation time is set in advance. Further, it is desirable that the intermittent operation time can be changed by the user. For example, a fan intermittent operation time setting item may be provided as one of the function setting tables of the projector 100 so that the user can set using the operation unit 4 or the remote controller.

  Next, the timer unit 115 determines whether or not the predetermined time has elapsed in the intake fan reverse rotation timer (step S360). When the predetermined time has not elapsed (step S360: NO), the timer unit 115 determines whether the intermittent operation time of the intake fan intermittent operation timer has elapsed (step S370). If the intermittent operation time has not elapsed (step S370: NO), the process returns to step S360. If the intake fan intermittent operation timer has passed the intermittent operation time (step S370: YES), the fan control unit 116 switches between reverse rotation operation and stop of the intake fan 120 (step S380). That is, if the intake fan 120 is rotating in the reverse direction, it stops, and if the intake fan 120 is stopped, the reverse rotation operation is started. Next, the vibration control unit 118 switches between vibration operation and stop of the vibration element 123 (step S390). That is, if the vibration element 123 is oscillating, it stops, and if the vibration element 123 is suspending, the vibration operation is started. Next, the control unit 114 causes the timer unit 115 to restart the intake fan intermittent operation timer (step S400). This is because the intake fan intermittent operation timer has timed out at this time, and is restarted to continue the intermittent operation. Next, the process returns to step S360.

  When the timer unit 115 determines in step S360 that the intake fan reverse rotation timer has passed a predetermined time (step S360: YES), the fan control unit 116 stops the reverse rotation operation of the intake fan 120 ( Step S410). Next, the vibration control unit 118 stops the vibration of the vibration element 123 (step S420). Thus, the intermittent operation dust removal processing subroutine is completed, and the process returns.

According to Example 1 mentioned above, the following effects are acquired.
(1) When the operation state transitions to the standby state, the lamp is turned off and after the cool-down operation is completed, the inside of the housing 1 is in a state that does not require cooling. The reverse rotation operation does not affect the functional operation of the projector 100. Therefore, the dust removal process can be executed. Thus, clogging of the filter can be suppressed by removing the dust every time the operation state transits to the standby state. That is, the number of cleaning and replacement of the filter can be reduced. Moreover, since the efficiency of sucking air into the housing 1 can be maintained, it is possible to suppress a decrease in the cooling capacity during the forward rotation operation of the intake fan 120.

  (2) In addition, by making the reverse rotation speed of the intake fan 120 and the vibration frequency of the vibration element 123 proportional, in the case where dust adheres little to the surface of the filter 121 or dust that can be easily removed, the intake fan 120 The reverse rotation speed can be lowered and the vibration frequency of the vibration element 123 can be lowered. In addition, when there is much dust adhesion or dust that is difficult to remove, the reverse rotation speed can be increased and the vibration frequency of the vibration element 123 can be increased. Here, when the frequency of vibration is low, it is possible to apply vibration to the entire surface of the filter 121, and even when the reverse rotation speed of the intake fan 120 is low, dust adheres little or is easy to remove. In the case of fine dust, dust can be removed efficiently. Further, when the frequency of vibration is high, the directivity of vibration is high, so that it is possible to concentrate and apply the vibration to the central portion of the filter 121, and to increase the reverse rotation speed of the intake fan 120. Thus, dust can be efficiently removed when there is a lot of dust adhering or when it is difficult to remove dust. Thus, dust removal can be performed by a combination of the efficient reverse rotation speed of the intake fan 120 and the vibration frequency of the vibration element 123 reflecting the user's intention. In addition, by setting the minimum reverse rotation speed of the intake fan 120 and the vibration frequency of the vibration element 123, the rotation sound of the intake fan 120 when dust is removed, the vibration element 123, the filter holding member 122, Vibration noise of the filter 121 and the like can be suppressed.

  (3) Similarly, by making the reverse rotation speed of the intake fan 120 and the amplitude of vibration of the vibration element 123 proportional, when the amount of dust on the surface of the filter 121 is small, the reverse rotation speed of the intake fan 120 is reduced and The amplitude of vibration of the vibration element 123 can be reduced. In addition, when there is a lot of dust adhesion, the reverse rotation speed can be increased and the vibration amplitude of the vibration element 123 can be increased. Thus, dust removal can be performed by a combination of an efficient reverse rotation speed of the intake fan 120 reflecting the user's intention and an amplitude of vibration of the vibration element 123. Also, by setting the minimum reverse rotation speed of the intake fan 120 and the vibration amplitude of the vibration element 123, the rotation sound of the intake fan 120 when dust is removed, the vibration element 123, the filter holding member 122, Vibration noise of the filter 121 and the like can be suppressed.

  (4) In addition, when the intermittent operation dust removing process is used, the following effects are obtained. By performing the fan reverse rotation operation intermittently, wind pressure is intermittently applied to the dust adhering to the filter 121, so that the dust is easily pulled away from the filter 121. Therefore, efficient dust removal can be performed.

  (Embodiment 2) FIG. 8 is a flowchart of processing when a projector according to Embodiment 2 transitions from an operating state to a standby state. In the present embodiment, the operation for causing the projector 100 to transition from the operating state to the standby state is a main power-off operation by the user. The present embodiment shows a transition process in the case where dust removal is performed without executing the cool-down operation. FIG. 8 is substantially the same as the transition process of FIG. 5 except for the cool-down operation. A process when projector 100 transitions from the operating state to the standby state will be described with reference to FIG.

  Control unit 114 turns off the lamp of projector 100 (step S500). Next, fan control unit 116 stops the forward rotation operation of intake fan 120 and exhaust fan 130 (step S510). Next, the fan control unit 116 and the vibration control unit 118 execute a dust removal processing subroutine (S520). The dust removal processing subroutine is the same as the flowchart shown in FIG. 6, but can be replaced with the intermittent operation dust removal subroutine described in FIG. Next, control unit 114 executes various processes associated with the transition from the operating state to the standby state (step S530), and projector 100 transitions to the standby state. Here, the various processing refers to data storage processing related to various functions of the projector 100.

According to the second embodiment described above, the same effects as the effects (2) to (4) in the first embodiment can be achieved. In addition, the following effects can be obtained.
If the projector 100 does not require a cool-down operation when transitioning from the operating state to the standby state, after the lamp is turned off and the forward fan rotation operation is stopped, the inside of the housing 1 does not need to be cooled. Therefore, even if the intake fan 120 is reversely rotated, the functional operation of the projector 100 is not affected. Therefore, it is possible to execute the dust removal process. Thus, every time when the operation state changes to the standby state, clogging of the filter can be suppressed by removing dust. That is, the number of cleaning and replacement of the filter can be reduced. Moreover, since the efficiency of sucking air into the housing 1 can be maintained, it is possible to suppress a decrease in the cooling capacity during the forward rotation operation of the intake fan 120.

  (Embodiment 3) FIG. 9 is a flowchart of processing when a projector according to Embodiment 3 transitions from a standby state to an operating state. In the present embodiment, the operation for causing the projector 100 to transition from the standby state to the operation state is an operation of turning on the main power by the user. The present embodiment shows a transition process when the dust is removed and when the main power is turned on. With reference to FIG. 9, processing when the projector 100 transitions from the standby state to the operating state will be described.

  The control unit 114 determines whether a specific key switch operation has been performed by the user based on information from the operation reception unit 113 (step S600). The specific key switch operation by the user is an operation for executing dust removal when the main power is turned on. For example, an operation for turning on the main power by pressing a predetermined key switch, which is different from a normal main power on key switch, is shown. As another operation method, an operation in which two key switches of a normal main power-on key switch and another predetermined key switch are simultaneously pressed can be used. When such a specific key switch operation is performed by the user (step S600: YES), the process proceeds to step S610 to execute the dust removal processing subroutine. On the other hand, when the specific key switch operation by the user as described above is not performed (step S600: NO), the dust removal processing subroutine is not performed, and the process proceeds to step S620.

  In step S610, fan control unit 116 and vibration control unit 118 execute a dust removal subroutine. The dust removal processing subroutine is the same as the flowchart shown in FIG. 6, but can be replaced with the intermittent operation dust removal subroutine described in FIG. Next, the fan control unit 116 starts the forward rotation operation of the intake fan 120 and the exhaust fan 130 (step S620), and starts cooling the inside of the housing 1. Next, the control unit 114 turns on the lamp of the projector 100 (step S630). And the control part 114 performs the various processes accompanying the transition from a standby state to an operation state (step S640), and transfers to an operation state. Here, the various processes indicate initialization processes related to various functions performed when the main power of the projector 100 is turned on.

According to the third embodiment described above, the same effects as the effects (2) to (4) in the first embodiment can be achieved. In addition, the following effects can be obtained.
When the user determines that dust has accumulated in the filter 121 of the projector 100, the user performs a specific key switch operation in the embodiment and turns on the main power to remove dust from the filter 121 when desired. be able to. Further, the time point when the dust removal process is performed is before the start of the forward rotation operation of the fan and before the lamp is lit. Therefore, since the inside of the housing 1 is in a state that does not require cooling, even if the intake fan 120 is reversely rotated, the functional operation of the projector 100 is not affected. Therefore, the dust removal process can be executed. In this way, when the main power is turned on, the filter can be prevented from being clogged by removing dust according to the user's request. That is, the number of cleaning and replacement of the filter can be reduced. Moreover, since the efficiency of sucking air into the housing 1 can be maintained, it is possible to suppress a decrease in the cooling capacity during the forward rotation operation of the intake fan 120.

  (Embodiment 4) FIG. 10 is a flowchart of processing when a projector according to Embodiment 4 transitions from a stop state to a standby state. In the present embodiment, the operation for causing the projector 100 to transition from the stop state to the standby state is an operation in which the user inserts the AC adapter into an outlet (supplying AC power). The present embodiment shows a transition process when dust is removed when the AC adapter is plugged into an outlet. A process when the projector 100 transitions from the stopped state to the standby state will be described with reference to FIG.

  Fan control unit 116 and vibration control unit 118 execute a dust removal processing subroutine (step S700). The dust removal processing subroutine is the same as the flowchart shown in FIG. 6, but can be replaced with the intermittent operation dust removal subroutine described in FIG. Next, various processes associated with the transition from the stopped state to the standby state are executed (step S710), and the process shifts to the standby state. Here, the various types of processing indicate initialization processing related to some functions of the projector 100 and the like.

According to Example 4 mentioned above, there can exist an effect similar to effect (2)-(4) in Example 1. FIG. In addition, the following effects can be obtained.
Usually, there is a certain amount of time from when the user plugs in the AC adapter of the projector 100 to the outlet and turns on the main power. Here, the dust can be removed from the filter 121 by using the time. Further, in the stopped state and the standby state, the inside of the housing 1 is in a state that does not require cooling, so that the reverse operation of the intake fan 120 does not affect the functional operation of the projector 100. Therefore, the dust removal process can be executed. In this way, every time the transition from the stopped state to the standby state is performed, the clogging of the filter can be suppressed by removing the dust. That is, the number of cleaning and replacement of the filter can be reduced. Moreover, since the efficiency of sucking air into the housing 1 can be maintained, it is possible to suppress a decrease in the cooling capacity during the forward rotation operation of the intake fan 120.

(Second Embodiment)
Hereinafter, a second embodiment of the present invention will be described with reference to FIG.

FIG. 11 is a functional block diagram showing a functional configuration of an electronic device according to the second embodiment of the present invention. Here, the electronic device 200 of the present embodiment is a device that transmits or receives data with other electronic devices or the like and performs data processing thereof. The functional configuration of the electronic device 200 will be described with reference to FIG.
The electronic device 200 includes an external interface unit 210, a data processing unit 211, a display unit 212, an operation unit 24, a remote control light receiving unit 25, an operation reception unit 213, a control unit 214, a timer unit 215, and a fan. A control unit 216, a temperature detection unit 217, a vibration control unit 218, an intake fan 220, a filter 221, a filter holding member 222, a vibration element 223, and an exhaust fan 230 are provided.

Next, the operation of the electronic device 200 will be described.
The external interface unit 210 transmits / receives data to / from an external electronic device (not shown). The transmitted / received data is processed by the data processing unit 211. The display unit 212 performs information display corresponding to data, status display of the electronic device 200, and the like. The operation receiving unit 213 receives a function operation instruction from the operation unit 24 or the remote control light receiving unit 25 to the electronic device 200 by the user. The control unit 214 performs a functional operation corresponding to the functional operation instruction received by the operation receiving unit 213, a functional operation corresponding to the time measurement result from the timer unit 215, and the like, and performs overall control of the electronic device 200. As other control contents, for example, control relating to data processing, display unit control, fan control, and the like are performed. The timer unit 215 performs various timing processes according to instructions from the control unit 214.

  The fan control unit 216 performs fan-related control according to an instruction from the control unit 214. The fan control unit 216 inputs temperature information from the temperature detection unit 217. Further, the fan control unit 216 inputs the time measurement information from the timer unit 215 and the function operation information from the operation reception unit 213 via the control unit 214. The fan control unit 216 controls the rotation direction (forward / reverse rotation), rotation start operation, rotation stop operation, rotation speed, rotation time, and the like of the fan using these pieces of information. Then, the fan control unit 216 outputs the fan rotation information to the vibration control unit 218. The fans controlled by the fan control unit 216 are an intake fan 220 and an exhaust fan 230. One or a plurality of intake fans 220 and exhaust fans 230 exist, and it is desirable to control them individually.

  The temperature detection unit 217 measures the temperature of a heat generation portion or the like that needs to be cooled in the electronic device 200 and outputs the temperature to the fan control unit 216. The vibration control unit 218 controls the vibration of the vibration element 223 based on the fan rotation information from the fan control unit 216. As vibration control, vibration start, vibration stop, vibration frequency and amplitude, and the like are controlled. Here, the control unit 214, the fan control unit 216, and the vibration control unit 218 are separate functional components, but the circuit configuration may be configured by one CPU.

  The intake fan 220 operates under the control of the fan control unit 216. The filter 221 is held by a filter holding member 222. The filter 221 prevents dust from entering the housing of the electronic device 200. The filter holding member 222 holds the filter 221 and is connected to the vibration element 223. The vibration element 223 is controlled by the vibration control unit 218. When the vibration element 223 vibrates, the filter holding member 222 vibrates, and further, the filter 221 vibrates. The exhaust fan 230 operates under the control of the fan control unit 216.

  With such a configuration, the electronic device 200 can perform temperature control inside the housing of the electronic device by rotating the intake fan 220 and the exhaust fan 230 in a normal direction while performing data processing. In addition, the dust attached to the filter 221 can be removed by rotating the intake fan 220 in reverse and interlocking with the vibration element 223.

  Here, the state of the electronic device 200 will be described. The electronic device 200 can take three states: an operation state, a standby state, and a stop state. The operation state indicates a state in which power is supplied to the entire apparatus of the electronic device 200 and a normal function as the electronic device 200 is operating. The standby state refers to a state in which power is supplied to a part of the device of the electronic device 200 but the normal function is not operating and the user is waiting for a function operation instruction of the electronic device 200 from the user. . The stopped state indicates a stopped state in which power is not supplied to the device of the electronic device 200. It should be noted that here, the stop state and the standby state are assumed to be changed by, for example, AC adapter insertion / removal, etc., and the standby state and the operation state are in response to an operation instruction from the user such as on / off of the main power key switch. The state is assumed to change.

  Since the electronic device 200 can take these three states, it is possible to realize various functional operations while suppressing power consumption. Further, when the transition is made between the states, the dust removal process can be performed in substantially the same manner as described in Examples 1 to 4 of the first embodiment.

  The first embodiment and the second embodiment of the present invention have been described above. However, the present invention is not limited to these embodiments, and can be implemented in various forms without departing from the gist of the present invention. Of course you can. A modification is described below.

  In the first embodiment, the electronic apparatus is a projector, but the projector may be used by being suspended from the ceiling (hereinafter referred to as “ceiling”). In the case of ceiling suspension, the projector body is installed 180 degrees inverted. Therefore, since the image to be projected needs to be inverted by 180 degrees, a ceiling suspension setting function for inverting the image by 180 degrees exists as a function of the projector. In contrast, when the projector is normally installed on a desk or the like instead of being suspended from a ceiling (hereinafter referred to as “stationary”), the ceiling suspension setting function is canceled and the stationary setting is made. Here, when the above-described ceiling suspension setting function is set, the predetermined time as the reverse rotation operation time of the intake fan in the first to fourth embodiments may be longer than that in the stationary setting. Thereby, the dust removal capability at the time of ceiling suspension use can be improved. When the projector is suspended from the ceiling, dust tends to accumulate in the projector, and since it is suspended from the ceiling, it is difficult to clean and replace the filter. Therefore, it is effective to improve the dust removal capability. Furthermore, when the ceiling suspension setting function is set, the dust removal function according to the first to fourth embodiments can be executed, and when the stationary setting is set, the dust removal function may not be executed.

1 is a schematic perspective view of a projector according to a first embodiment. FIG. 6 is a configuration diagram showing the projector intake port and the interior thereof, (a) is a configuration diagram showing the intake port and the interior when the intake fan is rotated forward, and (b) is a diagram when the intake fan is rotated backward. The block diagram which shows an inlet port and its inside. The functional block diagram which shows the function structure of a projector. The state transition diagram of a projector. 9 is a flowchart of processing when the projector according to the first embodiment transitions from an operation state to a standby state. The flowchart of a dust removal process subroutine. The flowchart of an intermittent operation dust removal process subroutine. 9 is a flowchart of processing when a projector according to a second embodiment transitions from an operation state to a standby state. 10 is a flowchart of processing when a projector according to a third embodiment transitions from a standby state to an operating state. 10 is a flowchart of processing when a projector according to Embodiment 4 transitions from a stopped state to a standby state. The functional block diagram which shows the function structure of the electronic device which concerns on 2nd Embodiment. The relationship figure of the reverse rotation speed of a fan and the frequency of vibration. The relationship figure of the reverse rotation speed of a fan and the amplitude of a vibration.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 ... Housing, 2 ... Intake port, 3 ... Exhaust port, 4 ... Operation part, 5 ... Remote control light-receiving part, 6 ... Projection lens, 7 ... Notification hole, 8 ... LED display part, 9 ... Leg, 24 ... Operation 25, remote control light receiving unit, 100 ... projector, 110 ... video input unit, 111 ... video signal processing unit, 112 ... video projection unit, 113 ... operation accepting unit, 114 ... control unit, 115 ... timer unit, 116 ... fan Control unit, 117 ... temperature detection unit, 118 ... vibration control unit, 120 ... intake fan, 121 ... filter, 122 ... filter holding member, 123 ... vibration element, 130 ... exhaust fan, 200 ... electronic device, 210 ... external interface unit , 211 ... data processing unit, 212 ... display unit, 213 ... operation receiving unit, 214 ... control unit, 215 ... timer unit, 216 ... fan control unit, 217 ... temperature detection unit, 218 ... vibration control unit, 2 0 ... intake fan, 221 ... filter, 222 ... filter holding member, 223 ... vibration device, 230 ... exhaust fan.

Claims (11)

A housing constituting the exterior of the electronic device;
An opening installed in the housing;
A fan that sucks outside air into the housing through a forward rotation operation and exhausts air inside the housing to the outside of the electronic device through a reverse rotation operation through the opening.
A filter disposed between the opening and the fan to prevent dust from entering the housing;
A filter holding member for holding the filter;
A movable part for moving the filter holding member,
The electronic device according to claim 1, wherein the movable portion moves the filter holding member in conjunction with a reverse rotation operation of the fan. The electronic device according to claim 1,
The movable part has a vibration member that generates vibration,
The electronic apparatus according to claim 1, wherein the filter holding member vibrates corresponding to the vibration generated by the vibration member. The electronic device according to claim 2,
The frequency of the vibration is proportional to the reverse rotation speed of the fan. The electronic device according to claim 2 or 3,
The electronic apparatus is characterized in that the amplitude of the vibration is proportional to the reverse rotation speed of the fan. An electronic device according to any one of claims 1 to 4,
The electronic device further includes a timer unit that counts the reverse rotation operation time of the fan,
The electronic device, wherein the timer unit measures a reverse rotation operation time of the fan and stops the reverse rotation operation of the fan when a predetermined time elapses. An electronic device according to any one of claims 1 to 5,
The electronic device is characterized in that the reverse rotation operation of the fan is performed intermittently. The electronic device according to any one of claims 1 to 6,
The power supply is supplied to the whole of the electronic device, the operation state in which the normal function operation is performed, and
Although power is supplied to a part of the electronic device, the normal function operation as the electronic device is not performed, and a standby state in which a standby function operation is performed,
A stopped state in which power is not supplied to the electronic device;
An electronic apparatus characterized by being capable of taking any one of the states. The electronic device according to claim 7,
An electronic device that reversely rotates the fan when the operation state transits to the standby state. The electronic device according to claim 7 or 8,
An electronic device characterized in that, when a transition is made from the standby state to the operation state, when the specific key switch input signal is received, the fan is reversely rotated. An electronic device according to any one of claims 7 to 9,
An electronic device characterized in that the fan is reversely rotated when transitioning from the stopped state to the standby state. The electronic device according to any one of claims 1 to 10,
The electronic device is a projector.

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