JP2005269864A - Power supply unit, and projector and electronic equipment using the power supply unit - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a power supply unit capable of attaining complete cooling and energy saving. <P>SOLUTION: This power supply unit 1 comprises a main power supply section 2 for converting AC power inputted from the outside into various types of DC powers for outputting, a power fan 4 for cooling a main power sction 2, and a power control section 3 for controlling the power suppy unit 1. The power control section 3 includes a timer circuit 311; and when a power output stopping signal is received from the outside, the timer 311 is started or controlled. After the counted time reaches a prescribed time, driving of the electric fan 4 is stopped. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

  The present invention relates to a power supply device cooled by an electric fan and an electronic apparatus using the power supply device.

Conventionally, an electric fan has been used for cooling heat generated by a lamp that is a light source of a projector and a power source that supplies electric power. The fan for cooling the lamp and the fan for cooling the power source are driven by the same operation control, or always rotate without special control. Therefore, the start and stop of both electric fans were synchronized. Further, the driving time of the electric fan after the point when the projection of the projector is finished (lamp is extinguished) is determined according to the time required for cooling the lamp. In this case, since the lamp cooling time was sufficiently longer than the time required for cooling the power source, the power source was sufficiently cooled. For this reason, there has been no particular problem with respect to the heat of the lamp and the power supply after the point when the projection of the projector is terminated.
As for the driving of the electric fan, the electric fan driving device can drive the electric fan for a predetermined time even after the main power supply switch is turned off or the outlet is pulled out by using a capacitor with a large capacitance. Have also been proposed (Patent Document 1).

JP-A-9-151896

However, recently, the cooling time of the lamp after the point when the projection of the projector is finished (the lamp is turned off) has been shortened, and it has become impossible to secure the time required for cooling the power supply. In addition, there is a need for energy saving, and the cooling time tends to be shorter.
The present invention has been made in view of the above problems, and provides a power supply device that can reliably cool the power supply device and realizes energy saving, a projector using the power supply device, and an electronic apparatus. With the goal.

In order to solve the above-described problems and achieve the object, in the present invention, the power supply device converts the AC power input from the outside into various DC power and outputs the power, and the electric power source that cools the main power supply A power supply control unit that controls the fan and the power supply device. The power supply control unit includes a timer circuit, and when receiving a power supply output stop signal input from the outside, activates or controls the timer circuit to measure the time When the predetermined time is reached, the driving of the electric fan is stopped.
According to this invention, the power supply device includes, for example, a main power supply unit that converts and outputs commercial AC power into various DC power, an electric fan that cools the main power supply unit, and a power supply control unit that controls the power supply device. Further, since the power supply control unit includes a timer circuit, the power supply control unit activates the timer circuit to start timing when receiving a power supply output stop signal input from the outside. Then, when the predetermined time set in the timer circuit is reached, the electric fan is stopped. Therefore, when the electric element constituting the main power supply unit generates heat, the electric fan can be driven (rotated) until the time set in the timer circuit is reached, and the electric element can be cooled. As a result, by setting the timer circuit setting time to the time required for the electric elements of the power supply circuit to be sufficiently cooled, regardless of the time required for cooling other components, the electric elements are sufficiently cooled. The reliability of the electric element is improved. In addition, since the time can be set in the power supply circuit, the combination can be easily changed in the combination of the power supply circuit and another circuit to be supplied with power.

According to a preferred aspect of the present invention, the power supply control unit includes a timer circuit and a switch for cutting off power supply from the main power supply unit to the electric fan, and upon receiving a power supply output stop signal, the power supply control unit The timer circuit is activated or controlled, and when the measured time reaches a predetermined time, the driving of the electric fan is stopped by turning off the switch based on the output signal output from the timer circuit. .
With such a power supply device, the power supply control unit receives the power supply output stop signal, drives the electric fan by the timer circuit for a predetermined time, and then outputs a signal that the timer circuit has timed up. And the drive of an electric fan can be stopped by switching off with the signal. Therefore, when the electric element constituting the main power supply unit generates heat, the electric fan can be driven (rotated) until the time set in the timer circuit is reached, and the electric element can be cooled. Thereby, by setting the set time of the timer circuit to a time required for the electric element to be sufficiently cooled, the electric element is sufficiently cooled and the reliability of the electric element is improved.

According to a preferred aspect of the present invention, the power supply control unit includes a timer circuit and a control circuit for controlling the main power supply unit, and upon receiving a power supply output stop signal, the power supply control unit starts or stops the timer circuit. When the time measured reaches a predetermined time, the control circuit stops driving the electric fan by turning off the main power supply unit based on the output signal output from the timer circuit. .
With such a power supply device, the power supply control unit receives the power supply output stop signal, drives the electric fan by the timer circuit for a predetermined time, and then outputs a signal that the timer circuit has timed up. Then, based on the signal, the control circuit switches off the main power supply unit, and the output unit that supplies power to the timer circuit and the electric fan is also cut off, so that the driving of the electric fan can be stopped. Therefore, when the electric element constituting the main power supply unit generates heat, the electric fan can be driven (rotated) until the time set in the timer circuit is reached, and the electric element can be cooled. Thereby, by setting the set time of the timer circuit to a time required for the electric element to be sufficiently cooled, the electric element is sufficiently cooled and the reliability of the electric element is improved.

According to a preferred aspect of the present invention, the power supply control unit includes a timer circuit, a switch that cuts off the power supply from the main power supply unit to the electric fan, and a control circuit that controls the main power supply unit, and stops power output. When receiving the signal, the power supply control unit starts or controls the timer circuit, and when the timed time reaches a predetermined time, the power supply control unit turns off the electric fan by switching off based on the output signal output from the timer circuit. And the control circuit cuts off the main power supply unit.
With such a power supply device, the power supply control unit receives the power supply output stop signal, drives the electric fan by the timer circuit for a predetermined time, and then outputs a signal that the timer circuit has timed up. And the drive of an electric fan can be stopped by switching off with the signal. Further, the control circuit switches off the main power supply unit based on the signal, so that the timer circuit and the output unit that supplies power to the electric fan are also turned off.
Therefore, when the electric element constituting the main power supply unit generates heat, the electric fan can be driven (rotated) until the time set in the timer circuit is reached, and the electric element can be cooled. Thereby, by setting the set time of the timer circuit to a time required for the electric element to be sufficiently cooled, the electric element is sufficiently cooled and the reliability of the electric element is improved.
In addition, since the main power supply unit is not driven by cutting off the main power supply unit, power consumption can be reduced. Therefore, energy saving of the power supply device itself can be realized.

According to a preferred aspect of the present invention, the power supply device further includes a standby power supply unit, and when the power supply control unit receives the power supply output stop signal, the power supply unit starts or controls the timer circuit to measure the time. When the time reaches a predetermined time, the operation of the main power supply unit is stopped and the operation of the sub power supply is started based on an output signal output from the timer circuit.
With such a power supply device, the power supply control unit receives the power supply output stop signal, drives the electric fan by the timer circuit for a predetermined time, and then outputs a signal that the timer circuit has timed up. Then, based on the output signal, the operation of the main power supply unit can be stopped and the operation of the standby sub power supply can be started. Therefore, the necessary minimum power can be output from the sub power supply. In addition, after switching to the sub power supply, the main power supply unit is not driven, so that power consumption can be reduced. Therefore, energy saving can be realized.

According to a preferred aspect of the present invention, the power output stop signal is output from a control unit that controls a device including the power supply device.
With such a power supply device, a power output stop signal can be received from the control unit of the device in which the power supply device is incorporated, so that the power supply device of the device controlled by the control unit can be configured.

According to a preferred aspect of the present invention, there is provided a projector including a power supply device, wherein the projector includes a control unit that controls the projector, a light source for projecting an image, a ballast that drives the light source, and a light source. An electric fan for the light source for cooling, and the control unit stops the output of the ballast in accordance with the output of the power supply output stop signal, and the light source among the outputs of the DC / DC conversion circuit constituting the main power supply unit Turn off the output other than the output that supplies the power required to drive the electric fan, and after driving the electric fan for the light source for a predetermined time to stop, turn off all the output of the DC / DC converter circuit. The timer circuit is activated or controlled based on the output stop signal, and when the measured time reaches a predetermined time, the driving of the electric fan is stopped independently of the control unit.
With such a projector, the control unit that controls the projector stops the output of the ballast together with the output of the power output stop signal, and the light source among the outputs of the DC / DC conversion circuit constituting the main power supply unit The power supply fan is driven for a predetermined time and stopped except for the output for supplying the electric power necessary for driving the electric fan. And after the stop, the output which supplied electric power to the electric fan for light sources can also be cut off. Therefore, the controller does not drive after the light source electric fan is stopped, so that energy saving can be realized.
Further, the power control unit can start or control the timer circuit based on the power output stop signal of the control unit, and can stop the electric fan independently of the control unit after a predetermined time has elapsed. At this time, since the electric fan can be driven with the time required for the main power supply unit to be sufficiently cooled as a predetermined time of the timer, when the electric element constituting the main power supply unit generates heat, The electric element can be sufficiently cooled without being controlled. For this reason, a projector with improved reliability of the main power supply unit can be realized.

According to a preferred aspect of the present invention, the electronic apparatus includes a power supply device and a control unit that outputs a power supply output stop signal.
In such an electronic device, when the power supply device receives the power supply output stop signal from the control unit that controls the electronic device, the power supply control is performed when the power supply device provided in the electronic device and the control unit that outputs the power supply output stop signal are received. The electric fan can be driven by the timer circuit for a predetermined time without being controlled by the controller. Also, the main power supply can be turned off. Moreover, it can switch to a sub power supply.
Therefore, the main power supply unit can be sufficiently cooled. Therefore, the reliability of the power supply device is improved. Further, since the main power supply unit is not driven by switching to the sub power supply, power consumption can be reduced. Therefore, energy saving can be realized. Therefore, an electronic device that improves the reliability of the power supply device and realizes energy saving becomes possible.

DESCRIPTION OF EXEMPLARY EMBODIMENTS Hereinafter, a first embodiment of the invention will be described with reference to the drawings.
(First embodiment)

FIG. 1 is a schematic configuration diagram of a power supply device and a control unit when the projector is equipped with the power supply device of the present invention. The configuration and operation will be described with reference to FIG.
The power supply device 1 includes a main power supply unit 2, a standby sub power supply 5, and a power supply control unit 3 that controls the main power supply unit 2 and the sub power supply 5. A power supply fan 4 as an electric fan connected to the power supply control unit 3 is provided.
In addition, the power supply 1 is connected to an inlet 12 for supplying AC power from an external commercial power source. A ballast 10 is connected from the main power supply unit 2 to supply power to a lamp 11 serving as a light source for projecting an image of the projector.
The control unit 6 that controls the entire projector includes a control CPU 7 and a standby sub CPU 8. A lamp fan 9 as a light source electric fan for cooling the light source is connected to the control unit 6. The main power supply unit 2 supplies various types of power for supplying power to each unit of the projector. In addition, power is supplied from the sub power source 5 to the sub CPU 8 for standby.

In the projector, the power supply device 1 is supplied with AC power from a commercial power supply via an inlet 12, and the AC power is rectified and smoothed, converted into DC power having various voltage values necessary for a predetermined circuit, and output. Yes. Power is also supplied to the control CPU 7 which is the control unit 6 of the projector. Further, when the projector is in a standby state, the power supply device 1 operates the sub power supply 5 and the control unit 6 also operates the sub CPU 8. In that case, the sub power source 5 supplies power to the sub CPU 8.
The ballast 10 connected to the main power supply unit 2 supplies driving power according to the standard of the lamp 11 to be used.

Here, by connecting the inlet 12 of the projector to a commercial power outlet, the projector enters a standby state. The power supply 1 is driven by the sub power supply 5, and the control unit 6 is driven by the sub CPU 8. When the sub CPU 8 outputs a power “ON” signal, the power supply device 1 is switched to the main power supply unit 2 by the power supply control unit 3 and starts driving. Thereby, electric power is supplied to the ballast 10 and various electric power is output including electric power supply for driving the control CPU 7. Then, driving of the power supply fan 4 and the lamp fan 9 is started. The ballast 10 supplies power to the lamp 11 to light the lamp 11. Then, the projector 11 can project an image by the optical system (not shown) and the image control system (not shown) configured after the lamp 11 is turned on and after the lamp 11.
At this time, the power supply fan 4 cools the electric elements constituting the main power supply unit 2 and suppresses the temperature rise. Further, the lamp fan 9 cools the lamp 11 and suppresses an increase in temperature.

FIG. 2 is a schematic configuration diagram of the power supply device 1. The configuration of the power supply device 1 will be described with reference to FIG.
The power supply device 1 has an inlet 12 for supplying AC power from a commercial power supply to the power supply device 1, and an EMC (cutting off low frequency noise and high frequency noise generated in the supplied AC power and circuits connected thereafter. Electro-Magnetic Compatibility) filter 21, rectifying / smoothing circuit 22 that rectifies and smoothes AC power and converts it into DC power, and converts DC power boosted by the rectifying / smoothing circuit 22 into various DC powers, and a projector. The DC / DC conversion circuit 23 that outputs to the control unit 6 and other circuit blocks, the power supply control unit 3 that receives signals from the control unit 6, and the power supply fan 4 that cools the main power supply unit 2. The The power control unit 3 includes a timer unit 31 that operates in response to a power output stop signal from the control unit 6, and a control circuit 32 that controls the rectifying / smoothing circuit 22 and the DC / DC conversion circuit 23. Here, the main power supply unit 2 includes a part constituted by a rectification / smoothing circuit 22 and a DC / DC conversion circuit 23.
Further, a sub power source 5 is provided as a power source when the projector enters the standby mode. The sub power supply 5 is composed of a rectifying / smoothing circuit and a DC / DC conversion circuit (not shown in the configuration diagram of the sub power supply), like the main power supply unit 2, and supplies DC power necessary to drive the sub CPU 8. ing.
Further, the DC power boosted by the rectifying / smoothing circuit 22 is supplied to the ballast 10.

FIG. 3 is a schematic circuit diagram of the power supply device. The circuit configuration and operation of the power supply device 1 will be described with reference to FIG.
The power supply device 1 is supplied with an AC voltage from a commercial power supply by an inlet 12. The EMC filter 21 cuts low-frequency noise and high-frequency noise generated in the supplied AC voltage, a circuit connected thereafter, or the like. For this reason, the EMC filter 21 includes a circuit (not shown) in which a coil and a capacitor are combined, including mounting a ferrite core on the inlet 12.

  The AC voltage that has passed through the EMC filter 21 is converted into a DC voltage by the rectifying / smoothing circuit 22. The rectification / smoothing circuit 22 will be described.

  The AC voltage passed through the EMC filter 21 is rectified by the rectifier 30 and the capacitor C1 and converted into a pulsating flow. Next, a DC boost voltage is generated using the boost chopper circuit. The step-up chopper circuit includes a coil L1, a transistor (FET) T1, a diode D1, and a capacitor C2.

  The coil L1 is an element that generates an induced electromotive force. One end of the coil L1 is connected to the output terminal from the rectifier 30 and the other end is connected to the drain of the transistor T1. The transistor T1 receives a control signal from a control circuit A321 that is a control circuit 32 constituting the power supply control unit 3, and periodically switches on and off based on the input control signal. The diode D1 has an anode connected to the drain of the transistor T1 and a cathode connected to the output side. The capacitor C2 smoothes the boosted voltage generated by the coil L1.

When the voltage generated by the rectifier 30 and the capacitor C1 is input, the transistor T1 is turned on and off based on the control signal of the control circuit A321. During the period when the transistor T1 is ON, the diode D1 is in a non-conductive state, and a current flows from the coil L1 to the transistor T1. At this time, energy for generating an induced electromotive force by the current flowing through the coil L1 is stored in the coil L1.
When the transistor T1 is turned off, the diode D1 becomes conductive, and an induced electromotive force is generated in the coil L1 in the direction of preventing the current. Therefore, the induced electromotive force outputs a boosted voltage via the diode D1. Further, the boosted voltage is smoothed by the capacitor C2, and a stable DC boosted voltage can be output.

  Thereafter, the DC / DC conversion circuit (DC / DC converter) 23 converts the voltage into various DC voltages (Vout 1 and Vout 2 in FIG. 3). Describes the DC / DC converter.

  The output of the generated DC boosted voltage is connected to the primary coil L21 of the transformer L2 and the transistor T2. The transistor T2 receives the control signal from the control circuit B322, which is the control circuit 32 constituting the power supply control unit 3, and inputs the control signal periodically based on the input control signal.

Further, as a circuit for generating various DC output voltages, for example, in order to generate the output voltage Vout1, it is configured by a secondary coil L22 of the transformer L2, a diode D2, and a capacitor C3. Then, one end of the secondary coil L22 is connected to the anode of the diode D2, and the cathode of the diode D2 is connected to the output terminal side. The other end of the secondary coil L22 is connected to the output terminal, and the capacitor C3 is connected between both output terminals. In order to generate the output voltage Vout2, the secondary coil L23 of the transformer L2, the diode D3, and the capacitor C4 are configured with the same connection as that for generating the output voltage Vout1.
Thus, according to the number of necessary DC output voltages, a DC voltage is generated by providing the same configuration, and various DC voltages such as 12V, 5.0V, and 3.3V are output.

  As an operation, for example, in the case of a circuit that generates the output voltage Vout2, when the transistor T2 is turned on, the diode D3 becomes non-conductive, and energy is stored in the primary coil L21 of the transformer L2. Here, when the transistor T2 is turned OFF, the diode D3 becomes conductive, and the energy stored in the transformer L2 outputs a voltage corresponding to the coil L23 via the diode D3. Then, the signal is smoothed by the capacitor C4 and output as a stable DC voltage.

  Further, transistors T3 and T4 are connected in series to the output side of the circuit that generates the DC output voltages Vout1 and Vout2, respectively, and the control signal of the control circuit C40 is input to each gate, and the input control signal Based on this, each DC output voltage is switched ON and OFF. The control circuit C40 operates based on a control signal from the control unit 6 of the projector.

  The control circuit A 321 and the control circuit B 322 change the switching frequency of the transistor T 1 and the transistor T 2 and the duty ratio which is the ON / OFF ratio according to the load state of the circuit thereafter, and stabilize the output voltage. Have control.

  Further, the AC voltage that has passed through the EMC filter 21 is branched and supplied to the sub power source 5. The circuit configuration of the sub power supply 5 is substantially the same as the configuration of the rectifying / smoothing circuit 22 and the DC / DC conversion circuit 23 described above, and is a circuit configuration that can be simplified and output with low power. In addition, as described above, a transistor and a control circuit are provided to control the output voltage. For example, VoutS is output as the output voltage.

Further, the DC boost voltage generated by the rectifying / smoothing circuit 22 is branched for the ballast 10.
Here, in the present embodiment, the ballast 10 includes a starter (igniter) that creates a spark of the discharge path between the electrodes of the lamp 11 and a ballast (ballast) that performs control based on the characteristics of the lamp 11. The ballast 10 is used. In the present embodiment, the lamp 11 is an AC lighting type ultra-high pressure mercury lamp. Therefore, the ballast 10 is composed of a pulse voltage for starting the lamp 11 from the DC boosted voltage and a circuit for generating constant power based on the characteristics of the lamp 11. The output voltage is VoutB.

  The timer unit 31 of this embodiment includes a timer circuit 311 and a switch 312. In the circuit for generating the DC output voltage Vout2, the DC output voltage Vout2 is supplied in parallel to the capacitor C4 from the rear of the capacitor C4 at the front of the transistor T4. The timer unit 31 controls the power supply fan 4 that cools the main power supply unit 2.

  Here, the power supply control unit 3 includes a timer unit 31 and a control circuit 32, and the control circuit 32 includes a control circuit A 321 and a control circuit B 322.

  Here, by connecting the inlet 12 of the projector to a commercial power outlet, the projector enters a standby state. In the standby state, the sub power supply 5 and the sub CPU 8 are operating, and the main power supply unit 2, the control CPU 7 and other circuit units (not shown) are stopped. In terms of circuit, the sub power source 5 is driven to output the output voltage VoutS, and the output voltage VoutS is supplied to the sub CPU 8. The sub CPU 8 performs an operation of waiting for an input signal from an operation unit (not shown) included in the projector or a signal input by a remote control from a remote control light receiving unit (not shown).

In the standby state, when the sub CPU 8 receives a power “ON” operation signal from the projector operation unit or the remote control, the sub CPU 8 outputs a power “ON” signal based on the operation signal.
The control circuit A 321 and the control circuit B 322 as the control circuit 32 receive the signal via the timer unit 31, and each control circuit starts an operation of sending a signal to each of the transistors T 1 and T 2. Similarly, the control circuit C40 receives the signal and starts an operation of sending a signal to the transistors T3 and T4. As a result, the main power supply unit 2 starts driving and outputs various DC voltages. In addition, the timer unit 31 starts driving the power supply fan 4.

  The ballast 10 also receives the power “ON” signal from the sub CPU 8, starts driving, outputs a pulse voltage VoutB for lighting the lamp 11, and discharges and lights the electrode of the lamp 11. Further, the control CPU 7 also starts driving upon receiving power supply from the main power supply 2 and activates the lamp fan 9. Further, the control circuit provided in the sub power supply 5 via the timer unit 31 stops driving the sub power supply 5.

  In this manner, the projector power supply device 1, the control unit 6, the ballast 10, the lamp 11, the lamp fan 9, and the other circuit units of the projector controlled by the control unit 6 start driving. As a result, the projector can project an image by an optical system (not shown) and an image control system (not shown) configured after the lamp 11.

  While the lamp 11 is lit, the electronic components constituting the main power supply unit 2 generate heat, and the lamp 11 also generates heat. For this purpose, the power supply fan 4 is driven (rotated) to suppress an increase in temperature so that the electric elements constituting the main power supply unit 2 are within an allowable temperature range. Further, the lamp fan 9 is driven (rotated) so as to suppress the temperature rise so that the lamp 11 falls within an allowable temperature range.

Here, when the control CPU 7 receives a power “OFF” operation signal from the operation unit of the projector or the remote control, the control CPU 7 outputs a power “OFF” signal (referred to as S1) corresponding to the operation signal.
Based on the signal S1, the ballast 10 turns off the lamp 11 by stopping the operation of the ballast 10 by a control circuit provided therein.
Further, the control circuit C40, based on the signal S1, removes the output of power necessary for driving the lamp fan 9 in the main power supply unit 2, and turns off the supply of other output voltages by turning off the transistors. To do. In this embodiment, since the lamp fan 9 is driven by the 12 V output of Vout2, the output of other output voltages including Vout1 is stopped by the control circuit C40 sending an “OFF” signal to the transistor T3 and the like. .
Then, the control CPU 7 drives the lamp fan 9 for a predetermined time even after the lamp 11 is turned off, and stops the lamp fan 9 after the predetermined time has elapsed. Then, a signal that the time is up is sent to the control circuit C40. Based on the time-up signal, the control circuit C40 turns off the transistor T4 and stops the output of Vout2.

  Then, the control CPU 7 waits for the drive of the sub power supply 5 of the power supply device 1 to start supplying the power VoutS from the sub power supply 5 to the sub CPU 8, and the control CPU 7 switches to the sub CPU 8 to completely wait. It becomes a state.

  In the power supply device 1, the timer unit 31 receives a power “OFF” signal S 1 from the control CPU 7 and activates the timer circuit 311. The timer circuit 311 starts timing, and outputs a signal (S2) that the time is up when the measured time reaches a predetermined time, and turns off the gate of the switch 312 based on the signal S2. The drive of the power supply fan 4 is stopped. Here, the timer circuit 311 always performs a timekeeping operation, and may be controlled to be reset to zero by receiving the signal S1.

  The timer unit 31 outputs a time-up signal S2 of the timer circuit 311 to the control circuit A321 and the control circuit B322. The control circuit A321 turns off the gate of the transistor T1 based on the signal S2, and the control circuit B322 Based on S2, the gate of the transistor T2 is turned OFF, and the operation of the main power supply 2 is stopped.

The time-up signal S2 is also output to the control circuit of the sub power supply 5, and the control circuit activates the sub power supply 5 based on the signal S2 and outputs the voltage VoutS.
In this way, the main power supply unit 2 is switched to the sub power supply 5 and enters a standby state.

According to the first embodiment described above, the following effects can be obtained.
(1) Since the power supply control unit 3 includes the timer unit 31, when a power “OFF” signal that is a power supply output stop signal is received from the control CPU 7, the timer circuit 311 is activated, and the set predetermined time is counted, After the predetermined time elapses, the driving of the power supply fan 4 can be stopped by setting the switch 312 to 0FF. Therefore, the electric elements constituting the main power supply unit 2 can be cooled without being controlled by the control CPU 7. Therefore, the reliability of the main power supply unit 2 is improved.

(2) Upon receiving a power “OFF” signal, which is a power output stop signal, from the control CPU 7, the power control unit 3 activates the timer circuit 311, counts the set predetermined time, and after the predetermined time has elapsed, The circuit 311 outputs a signal S2 indicating that the time is up. Based on the signal S2, the control circuit A321 and the control circuit B322 turn off the transistor T1 and the transistor T2 to stop the driving of the main power supply unit 2, so that power is supplied to the timer circuit 311 and the power supply fan 4. The power supply fan 4 can be stopped by cutting the output unit. In that case, the switch 312 may not be used.
Further, the control circuit of the sub power supply 5 can activate the sub power supply 5 by the signal S2. Therefore, the necessary minimum power can be output by the sub power source 5 and, after switching to the sub power source 5, the main power source unit 2 is not driven, so that power consumption can be reduced. Therefore, energy saving can be realized.

  (3) The control unit 6 that controls the projector stops the output of the ballast 10 together with the output of the power “OFF” signal, which is a power output stop signal, and drives and stops the lamp fan 9 for a predetermined time. . Thereafter, the control circuit C40 can stop the output voltage supply of the DC / DC conversion circuit 23 constituting the main power supply unit 2, so that the control CPU 7 can also be switched to the standby state. Therefore, energy saving can be realized.

  (4) According to the first embodiment, the power supply device 1 has improved reliability and can provide a projector that realizes energy saving of the power supply device 1 and the control unit 6.

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

  FIG. 4 is a schematic configuration diagram when the power supply apparatus of the present invention is mounted on a DVD (Digital Versatile Disk) playback apparatus 100 which is an electronic apparatus. The configuration and operation will be described with reference to FIG.

  The DVD playback device 100 includes a power supply device 1 according to the present invention, a control unit 6, an operation unit 50 that performs an operation, a function operation unit 60 that performs a function as the DVD playback device 100, and a display unit that displays the result. 70 and a speaker unit 80 for outputting sound.

  In addition, the power supply device 1 is a portion that supplies necessary power to each unit constituting the DVD playback device 100. The control unit 6 controls the entire DVD playback device 100. The operation unit 50 includes key switches for performing DVD image operations and setting operations of the DVD playback apparatus 100. It can also be operated with a remote control. The functional operation unit 60 includes a mechanism unit and a circuit unit for reproducing a DVD. The display unit 70 uses a liquid crystal panel to display a reproduced DVD image and a character image for operation. In addition, the speaker unit 80 reports the reproduced DVD sound and music.

  With this configuration, when the power supply device 1 receives a power “OFF” signal, which is a power supply output stop signal, from the control unit 6, the timer circuit 311 of the power supply device 1 is activated and the control unit 6 receives no control for a predetermined time, The power supply fan 4 can be continuously driven. For this reason, the electric elements constituting the main power supply unit 2 of the power supply device 1 can be sufficiently cooled. In addition, after that, the sub power supply is switched to a standby state, so that the power consumption of the main power supply unit 2 can be reduced, thereby realizing energy saving. Therefore, it is possible to improve the reliability of the power supply device 1 and realize the DVD reproducing device 100 that realizes energy saving.

  Further, as in the second embodiment, the DVD playback apparatus 100 can be mounted not only on the power supply apparatus 1 and the control unit that outputs the power supply output stop signal but also on other electronic devices. For example, it can be installed in home appliance-related electronic devices such as a PC (personal computer), a TV (television), and a copying machine. In particular, in an electronic device that is used by being connected to a commercial AC power supply, it is very effective to be mounted on an electronic device in which a power supply unit generates heat.

  The present invention is not limited to the above-described embodiment, and various changes and improvements can be added to the above-described embodiment. A modification will be described below.

  (Modification 1) In each of the above embodiments, when the power supply device 1 receives the power “OFF” signal from the control CPU 7, the timer unit 31 activates the timer circuit 311 and continuously drives the power supply fan 4 for a predetermined time. The control circuit A321 turns off the transistor T1 based on the time-up signal S2. However, the present invention is not limited to this, and when the driving power of the power supply fan 4 is small, when the power supply device 1 receives the power “OFF” signal from the control CPU 7, the timer unit 31 causes the control circuit A 321 to operate the transistor based on the signal. T1 may be turned “OFF”. By doing so, since the main power supply unit 2 can generate the DC output voltage Vout2, the timer unit 31 can start the timer circuit 311 and drive the power supply fan 4 for a predetermined time. Thereby, the main power supply unit 2 is further cooled, and the reliability can be improved. Further, the current consumption of the main power supply unit 2 is further reduced, and energy saving can be realized.

  (Modification 2) In each of the embodiments described above, the timer unit 31 and the power supply fan 4 are connected in parallel with the DC output voltage Vout2 behind the capacitor C4 from the position before the transistor T4. However, the present invention is not limited to this, and as shown in FIG. 5, the timer circuit 311 is connected to the gate of the transistor T4, and the power supply fan 4 branches in parallel at the position before the output terminal behind the transistor T4. You may do it. By doing so, the timer circuit 311 is started based on the power “OFF” signal, and after a predetermined time has elapsed, by inputting the “OFF” signal as a time-up signal to the gate of the transistor T4, the transistor T4 is directly turned on. Can be “OFF”. Therefore, the switch 312 is not required, and the driving of the power supply fan 4 can be stopped, so that the configuration is simplified.

  (Modification 3) In each of the embodiments described above, the timer unit 31 includes one timer circuit 311 to control the power supply fan 4 that is one electric fan. However, the present invention is not limited to this, and by adding another timer circuit or changing to a two-system timer circuit, one more electric fan can be added to control two electric fans. good. Thereby, based on the power “OFF” signal from the control CPU 7, the two electric fans can be individually driven for a predetermined time. By doing so, the two electric fans can be driven without being controlled by the control CPU 7 for cooling the main power supply unit 2 and the lamp 11. Therefore, the reliability of the main power supply unit 2 and the lamp 11 can be further improved by setting the necessary time and sufficiently cooling. Further, since the control circuit C40 can cut all the output terminals of the DC / DC conversion circuit 23 at a time based on the power “OFF” signal from the control CPU 7, the power consumption of the control CPU 7 can be reduced.

The technical ideas other than the claims that can be grasped from the embodiment and the modifications will be described below together with the effects thereof.
(Technical Idea 1) A power supply device for supplying electric power, wherein the power supply device is connected to a main power supply unit that converts AC power input from the outside into various DC powers and outputs, and the main power supply unit. An electric fan that cools the main power supply unit; and a power supply control unit that controls the power supply unit. The main power supply unit rectifies and smoothes AC power input from the outside; A DC / DC conversion circuit that converts the smoothed DC power into various DC power and outputs the DC power, and the power supply control unit receives a power supply output stop signal from a control unit that controls the device including the power supply device. Starting or controlling a timer circuit provided in the power supply control unit, and when the measured time reaches a predetermined time, the rectifying / smoothing circuit is stopped based on an output signal of the timer circuit, or the rectifying・ Smooth times And power supply and performs an operation for stopping the DC / DC converter circuit.
With such a power supply device, the power supply control unit can stop the operation of the rectifying / smoothing circuit based on the output signal of the timer circuit after the electric fan has been driven for a predetermined time, thereby reducing the power consumption of the power supply device it can. Further, since the rectification / smoothing circuit and the DC / DC conversion circuit can be stopped, the power consumption of the power supply device can be further reduced. Therefore, energy saving can be realized.

(Technical Thought 2) A power supply device for supplying power, the power supply device converting AC power input from the outside into various types of DC power and outputting a plurality of DC power, and cooling a predetermined place An electric fan, and a power supply control unit that controls the power supply device, the power supply control unit including a timer circuit that controls the plurality of electric fans separately or the same, and controls the device including the power supply device. When receiving a power output stop signal from the control unit to perform, the timer circuit is started or controlled, and after a predetermined time corresponding to each electric fan is counted, the driving of the corresponding electric fan is stopped. Power supply.
When such a power supply device receives a power output stop signal from the control unit, the timer circuit is activated, and each electric fan can be driven for a predetermined time set separately or the same. Then, for example, the main power supply unit can be cooled at two locations, or a lamp that is a light source of the main power supply unit or the projector can be cooled. In addition, since the time required for cooling the electric element can be set individually, it can be efficiently cooled.

FIG. 2 is a schematic configuration diagram of a power supply device and a control unit when the projector includes the power supply device according to the first embodiment of the present invention. The schematic block diagram of a power supply device. The schematic circuit diagram of a power supply device. The schematic block diagram which mounted the power supply device which concerns on 2nd Embodiment of this invention in the DVD reproducing | regenerating apparatus. The modification of the connection position of a timer circuit.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 ... Power supply device, 2 ... Main power supply part, 3 ... Power supply control part, 4 ... Power supply fan, 5 ... Sub power supply, 6 ... Control part, 7 ... Control CPU, 8 ... Sub CPU, 9 ... Lamp fan, 10 ... Ballast, 11 ... Lamp, 12 ... Inlet, 21 ... EMC filter, 22 ... Rectification / smoothing circuit, 23 ... DC / DC conversion circuit, 30 ... Rectifier, 31 ... Timer part, 32 ... Control circuit, 40 ... Control circuit C , 50 ... operation section, 60 ... function operation section, 70 ... display section, 80 ... speaker section, 100 ... DVD player, 311 ... timer circuit, 312 ... switch, 321 ... control circuit A constituting the control circuit, 322 ... Control circuit B constituting the control circuit.

Claims (8)

A power supply for supplying power,
The power supply device includes a main power supply unit that converts AC power input from the outside into various types of DC power and outputs, an electric fan that cools the main power supply unit, and a power supply control unit that controls the power supply device,
The power supply control unit includes a timer circuit, and upon receiving a power supply output stop signal input from the outside, activates or controls the timer circuit, and stops driving the electric fan when the measured time reaches a predetermined time. A power supply device characterized by that. The power supply device according to claim 1,
The power supply control unit includes the timer circuit and a switch for cutting off power supply from the main power supply unit to the electric fan,
Upon receiving the power output stop signal, the power control unit starts or controls the timer circuit, and when the measured time reaches a predetermined time, based on the output signal output from the timer circuit, A power supply device that stops driving of the electric fan by turning off the switch. The power supply device according to claim 1,
The power supply control unit includes the timer circuit and a control circuit that controls a main power supply unit,
Upon receiving the power output stop signal, the power control unit starts or controls the timer circuit, and when the measured time reaches a predetermined time, based on the output signal output from the timer circuit, The power supply device, wherein the control circuit stops driving the electric fan by turning off the main power supply unit. The power supply device according to claim 1,
The power supply control unit includes the timer circuit, a switch for cutting off power supply from the main power supply unit to the electric fan, and a control circuit for controlling the main power supply unit,
Upon receiving the power output stop signal, the power control unit starts or controls the timer circuit, and when the measured time reaches a predetermined time, based on the output signal output from the timer circuit, The power supply device characterized in that the electric fan is stopped by turning off the switch and the control circuit turns off the main power supply unit. It is a power supply device as described in any one of Claims 1-4, Comprising:
The power supply device further includes a sub power supply unit for standby,
When receiving the power output stop signal, the power controller starts or controls the timer circuit, and when the measured time reaches a predetermined time, based on the output signal output from the timer circuit, A power supply device that stops the operation of the main power supply unit and starts the operation of the sub power supply. It is a power supply device as described in any one of Claims 1-5, Comprising:
The power supply output signal is output from a control unit that controls a device including the power supply device. A projector comprising the power supply device according to any one of claims 1 to 6,
The projector includes a control unit that controls the projector, a light source for projecting an image, a ballast that drives the light source, and an electric fan for a light source that cools the light source,
The control unit stops the output of the ballast in accordance with the output of the power supply output stop signal, and drives the electric fan for the light source among the outputs of the DC / DC conversion circuit constituting the main power supply unit. Turn off the output other than the output that supplies the necessary power, and after driving and stopping the electric fan for the light source for a predetermined time, turn off all the output of the DC / DC conversion circuit,
The power supply control unit starts or controls a timer circuit based on the power supply output stop signal, and stops driving the electric fan independently of the control unit when the measured time reaches a predetermined time. A projector characterized by that. An electronic apparatus comprising: the power supply device according to any one of claims 1 to 6; and a control unit that outputs the power supply output stop signal.

Images