JP5413140B2 - Power supply device and image output device - Google Patents

Description

  The present invention relates to a power supply circuit that supplies power, and more particularly to a power supply circuit that adjusts an output voltage of a primary circuit according to an output voltage of a secondary circuit, and an image output apparatus.

  Conventionally, a power supply device for supplying power is known. In the power supply device, for example, the primary side circuit and the secondary side circuit are insulated and connected by a transformer, and the power generated by the primary side circuit is supplied to the secondary side circuit via the transformer. Further, the primary side circuit includes a bridge circuit that converts the DC power source into AC and an IC that controls oscillation of the bridge circuit. The AC power generated by the IC and the bridge circuit is converted into a secondary side circuit via a transformer. Supply.

  Further, the power supply device includes a feedback circuit and a power reduction detection circuit, and controls the output voltage of the primary side circuit according to the output voltage of the secondary side circuit. Here, the power reduction detection circuit protects the circuit by resetting the driving of the IC when the load of the power supply device decreases due to a temporary supply stop of the commercial power supply (hereinafter referred to as an instantaneous stop). It is a function (for example, refer to Patent Documents 1-4).

JP 2002-17084 A Japanese Patent Laid-Open No. 7-212968 JP 2008-219658 A Registered Utility Model Publication (Utility Model Registration No. 3123106)

  When the power supply device shifts to the standby state, the output voltage of the secondary circuit is switched to reduce power consumption (so-called standby power). In this standby state, the output voltage of the secondary side circuit is low, so the load on the primary side circuit is low, and oscillation may stop in some cases. When the power reducing circuit operates in the above-described state, the IC of the primary side circuit is reset, so that the oscillation is once resumed, but the oscillation is resumed again according to the load. However, since the load on the primary side circuit remains low as before, the power reduction detection circuit resets the IC of the primary side circuit again. Therefore, the restart and stop of the oscillation in the primary side circuit are repeated, and even when the product is switched to the normal operation state, the oscillation of the primary side circuit may not be continued.

  The present invention has been made in view of the above problems, and in a power supply device including a power reducing circuit, the power supply device capable of accurately operating the power supply circuit for any load on the primary side circuit And an image output device.

  In order to solve the above problems, in the present invention, in a power supply apparatus that performs feedback control for controlling oscillation of a primary circuit by an IC according to the output voltage of the secondary circuit, the output voltage of the secondary circuit When the output voltage of the secondary side circuit is less than a predetermined value, the voltage reduction detection circuit that resets the oscillation control by the IC, and when the secondary side circuit shifts to the standby state, the secondary side circuit A standby state transition circuit for controlling the IC so that the output voltage is lowered to a predetermined value, and an operation control circuit for stopping the drive of the power reduction detection circuit during the transition to the standby state are provided.

In the invention configured as described above, the power reduction detection circuit monitors the output voltage of the secondary side circuit, and performs oscillation control by the IC when the output voltage of the secondary side circuit becomes a predetermined value or less. The reset and the standby state transition circuit controls the IC so that the output voltage of the secondary side circuit is lowered to a predetermined value when the standby state transitions, and the operation control circuit decreases during the transition to the standby state. The drive of the electric detection circuit is stopped.
Therefore, in the standby state, the drive of the power reduction detection circuit is stopped, so that the malfunction of the power reduction detection circuit due to the no-load state can be prevented.

As an example of a specific operation of the operation control circuit, the operation control circuit is configured such that when the standby control state shifts to the normal operation state, the drive of the power reduction detection circuit is delayed for a predetermined period and then restarted. Also good.
In the invention configured as described above, it is possible to prevent the power reduction detection circuit from malfunctioning due to a change in the load when shifting from the standby state to the normal operation state.

The voltage reduction detection circuit outputs a reset signal that causes the IC to reset oscillation control by turning on a transistor when the output voltage of the secondary side circuit becomes a predetermined value or less, and the operation control The circuit may be configured to stop the output of the reset signal by maintaining the transistor in an off state when the circuit enters a standby state.
In the invention configured as described above, the present invention can be realized by a simple configuration using a transistor.

The power supply device receives a power-on operation and outputs a high-level start signal to place the power supply device in a normal start state, and has a main controller that changes the start signal to a low level when transitioning to the standby state. The operation control circuit includes a diode connected to the base of the transistor on the anode side and connected to the start signal output terminal of the main controller on the cathode side, and when the start signal is at a low level, A configuration may be employed in which the transistor is maintained in an off state by the breakdown of the diode.
In the invention configured as described above, when the activation signal output from the main controller becomes low level, the transistor breaks down and the transistor is maintained in the off state, so the standby state is detected according to the change in the signal level. As a result, the power reducing circuit can be stopped.

  Furthermore, as another configuration of the present invention, in an image output apparatus including a power supply circuit that performs feedback control for controlling oscillation of the primary circuit by an IC according to the output voltage of the secondary circuit, the power supply circuit includes the power supply circuit, The output voltage of the secondary side circuit is monitored, and when the output voltage of the secondary side circuit falls below a predetermined value, a reset signal is output by turning on the transistor, and the oscillation control by the IC is reset. A power supply detection circuit; a main controller that accepts a power-on operation, outputs a high-level start signal to place the power supply circuit in a normal start state, and changes to the start signal low level when transitioning to the standby state; In accordance with a signal output from the main controller, a stand-alone for controlling the IC so that the output voltage of the secondary circuit is lowered to a predetermined value. A state transition circuit, and a diode connected to the base of the transistor on the anode side and connected to the start signal output terminal of the main controller on the cathode side, the start signal being changed to a low level, the diode The drive of the power reduction detection circuit is stopped by breakdown and maintaining the off state of the transistor, and when the transition from the standby state to the normal operation state is made, the drive of the power reduction detection circuit is delayed for a predetermined period. An operation control circuit that is restarted later may be included.

As described above, according to the present invention, it is possible to prevent malfunction of the power reduction detection circuit due to the no-load state.
According to the second aspect of the present invention, it is possible to prevent the power reduction detection circuit from malfunctioning due to load fluctuations when shifting from the standby state to the normal operation state.
According to the invention of claim 3, the present invention can be realized with a simple configuration using a transistor.
Further, according to the fourth aspect of the present invention, it is possible to detect the standby state according to the change in the signal level and to stop the power reducing circuit.

It is a block diagram explaining the structure of a display apparatus. It is a wave form diagram which shows the change of a starting signal. 3 is a block configuration diagram illustrating a configuration of a power supply circuit 95. FIG.

Hereinafter, embodiments of the present invention will be described in the following order.
(1) First embodiment:
(2) Other embodiments:

(1) First embodiment:
Hereinafter, a display device (image output device) will be described as an example of the power supply device according to the first embodiment. The description of the display device as the image output device is merely an example, and any device may be used as long as the device has the function of the power supply device according to the present invention.

  FIG. 1 is a block diagram illustrating a configuration of a display device. The display device 100 includes the following main parts. Reference numeral 99 denotes a front end unit that demodulates broadcast signals received by various antennas (not shown). Reference numeral 98 denotes a back-end unit that performs descrambling of demodulated data and decoding of compressed video / audio data. Reference numeral 97 denotes a display which displays a video based on the decoded video data. Reference numeral 96 denotes a main controller that controls driving of the display device 100. Reference numeral 95 denotes a power supply circuit, which supplies power to each part constituting the display device 100.

  When the various antennas receive the carrier wave, the front end unit 99 modulates and extracts the broadcast signal superimposed on the carrier wave. The front end unit 99 includes a switching circuit that operates in response to a channel selection signal from the remote control device, and outputs a broadcast signal corresponding to a desired channel to the back end unit 98 by the switching circuit.

  The back-end unit 98 includes a demultiplexing unit that de-scrambles the data demodulated by the front-end unit 99 and decodes video / audio data compressed by the MPEG method. Furthermore, the back end unit 98 includes a video signal processing unit that performs signal processing on the decoded video data.

  The display 97 displays a video based on the video data decoded by the back end unit 98. In the present embodiment, the display 97 is a liquid crystal display, and outputs light by transmitting light from a backlight (not shown).

  The main controller 96 includes a CPU, a ROM, and a RAM, and controls the driving of the display device 100 by various programs stored in the ROM. In addition, when the main controller 96 is turned on by operating the remote controller or the like, the main controller 96 changes the activation signals (P-ON_H1, P-ON_H2) to a high level to bring the display device 100 into a normal operation state. Transition. Here, the P-ON_H1 signal is a signal for switching between a normal operation state and a standby state, and transitions to a normal operation state in which power is supplied to each unit of the display device 100 by changing to a high level. . On the other hand, the P-ON_H2 signal is a signal for switching the power supply circuit 95 from the normal operation state to the standby state.

  FIG. 2 is a waveform diagram showing changes in the activation signal. When the main controller 96 detects an operation of turning on the main power, the P-ON_H2 signal is set to a high level, and after a delay time of several msec has elapsed, the P-ON_H1 signal is changed to a high level. On the other hand, when shifting from the normal startup state to the standby state, the P-ON_H2 signal is set to a low level, and after a delay time of several msec has elapsed, the P-ON_H1 signal is changed to a low level.

  The power supply circuit 95 rectifies and converts a power supplied from a commercial power supply (not shown) into a direct current, and then generates an alternating current power by oscillation control. Further, when the power supply circuit 95 shifts to the standby state by the P-ON_H2 signal output from the main controller 96, the power supply circuit 95 reduces the output voltage and reduces standby power. Further, when the power supply circuit 95 according to the present embodiment shifts to the standby state, the operation of the power reduction detection circuit (described later) is forcibly stopped, and the drive of the power supply circuit 95 during no load is kept normal. The configuration of the power supply circuit 95 according to the present invention will be described in detail below.

=== Configuration of Power Supply Circuit 95 ===
FIG. 3 is a block diagram illustrating the configuration of the power supply circuit 95. The power supply circuit 95 is configured by connecting a primary side circuit 80 and a secondary side circuit 70 via a switching transformer T. Further, the power supply circuit 95 feedback-controls the power supply circuit 95 according to the reduced voltage detection circuit 60 that resets the control IC of the primary side circuit 80 and the output voltage of the secondary side circuit 70 when the power supply circuit stops instantaneously. And the operation control circuit 40 that stops the drive of the power reduction detection circuit 60 in the standby state when the display device 100 shifts to the standby state.

  The primary side circuit 80 includes the following main parts. Reference numeral 81 denotes a control IC, which controls oscillation of the bridge circuit B of the switching transformer T. The bridge circuit B includes a switching element such as a transistor, and oscillates by alternately turning on the switch element by a signal output from the control IC. Further, the control IC 81 detects the load state of the secondary side circuit 70 based on the feedback signal output from the feedback circuit 50, and performs oscillation control according to the detected load. Further, the control IC 81 has a function of temporarily stopping oscillation when the secondary circuit 70 is in a no-load state.

  The secondary side circuit 70 includes the following main parts. Reference numeral 71 denotes a first power supply unit that rectifies and smoothes the voltage supplied from the secondary winding T2 of the switching transformer T by the diode D1 and the smoothing capacitor C1, and outputs a positive voltage. Reference numeral 72 denotes a second power supply unit that rectifies the voltage supplied from the secondary winding T2 of the switching transformer T by the diode D5 and outputs a positive voltage. Reference numeral 73 denotes a regulator IC, which normally supplies power to the main controller 96 by a voltage supplied from the first power supply unit 71 and in a standby state, the main controller 96 supplies voltage from the second power supply unit 72. Power is supplied to 96.

  The first power supply unit 71 is set to supply an output voltage of about 7 volts to the regulator IC 73 in a normal operation state. The second power supply 72 is set to supply an output voltage of about 30 volts to a portion not shown in the normal operation state, and is set to supply an output voltage of about 7 volts to the regulator IC 73 in the standby state. ing.

=== Configuration of the reduced power detection circuit
The voltage reduction detection circuit 60 is connected to the secondary winding T2 of the switching transformer T and connected to the negative voltage line 61 for generating a negative voltage and the main controller 96, and a positive voltage for generating a positive voltage of 3.3 volts. A line 62, and a reset signal output unit 63 that detects that the negative voltage supplied from the negative voltage line 61 fluctuates during an instantaneous power failure and outputs a reset signal to the control IC 81 of the primary circuit 80. Has been.

  The negative voltage line 61 performs rectification based on the negative current generated in the secondary winding T2 of the switching transformer T by the diode D2, and smoothes it by the smoothing diode C2 to generate a negative voltage. The positive voltage line 62 generates a positive voltage by the voltage supplied from the main controller 96.

  The reset signal output unit 63 sends resistances R1, R2 and a Zener diode D3 for setting time constants of the negative voltage generated on the negative voltage line 61 and the positive voltage generated on the positive voltage line 62, and the control IC 81 according to the fluctuation of the negative voltage. And a transistor Q1 for outputting a reset signal.

  The reset signal output unit 63 is set so that the base current does not flow to the base of the transistor Q1 due to the potential difference between the negative voltage line 61 and the positive voltage line 62 in the normal operation state. On the other hand, during the instantaneous power failure, since the driving of the primary side circuit 80 is stopped, the voltage supplied to the negative voltage line 61 is lowered and the negative voltage of the negative voltage line 61 is changed. Therefore, the potential difference between the resistor R2 and the Zener diode D3 increases, and a base current flows through the base of the transistor Q1. Therefore, a reset signal is output to the control IC 81.

=== Configuration of Operation Control Circuit ===
The operation control circuit 40 includes a diode D4. The anode of the diode D4 is connected to the base of the transistor Q1 of the reset signal output unit 63, and the cathode is connected to the P-ON_H1 signal output terminal of the main controller 96 to receive the P-ON_H1 signal from the main controller 96. Therefore, when the P-ON_H1 signal is at a high level, no current flows through the diode D4 due to the potential difference between the anode and the cathode of the diode D4. On the other hand, in the standby state in which the P-ON_H1 signal changes to a low level, the potential difference between the anode and the cathode changes, and a current flows through the diode D4. Therefore, no current flows through the base of the transistor Q1, and the transistor Q1 is maintained in the off state.

  The feedback circuit 50 feedback-controls the control IC 81 of the primary side circuit 80 according to the output voltage of the secondary side circuit 70. The feedback circuit 50 is connected to the P-ON_H2 output terminal of the main controller 96. When the P-ON_H2 signal changes to a low level, the primary circuit 80 is shifted to the standby state.

  The feedback circuit 50 includes a photocoupler 51 that outputs a feedback signal that conveys the load (output voltage) status of the secondary circuit 70 to the control IC 81 of the primary circuit 80, a conduction switching circuit 52 that conducts the photocoupler 51, and a standby When the state shifts to the state, the power supply of the regulator IC 73 is configured to include a supply switching circuit 53 that switches from the first power supply unit 71 to the second power supply unit 72.

The conduction switching circuit 52 is connected to the second power supply unit 72 via the emitter of the transistor Q3, and is connected to the light emitting unit of the photocoupler 51 via the collector of the transistor Q3. The conduction switching circuit 52 is connected to the main controller 96 via the base of the transistor Q2. The collector of the transistor Q2 and the base of the transistor Q3 are connected via a diode D6.
Therefore, in a normal operation state, since the high level P-ON_H2 signal is input to the base of the transistor Q2, the transistor Q3 is turned on, the light emitting unit of the photocoupler 51 is turned on, and the second power supply unit 72 A feedback signal corresponding to the output voltage is output to the control IC 81. On the other hand, in the standby state, since the P-ON_H2 signal is at a low level, the transistor Q3 is turned off, the light emitting unit of the photocoupler 51 is opened, and no feedback signal is output to the control IC 81. As a result, the control IC determines that it has shifted to the standby state, and reduces (in some cases stops) the oscillation of the primary side circuit 80. With the above configuration, the feedback circuit 50 also functions as a standby state transition circuit of the present invention.

The supply switching circuit 53 includes a transistor Q4 and a Zener diode D7 connected between the base of the transistor Q4 and the ground. The collector of the transistor Q4 is connected to the second power supply unit 72 via a resistor, and the emitter is connected to the input side of the regulator IC 73 via a diode D8. The collector and the base are self-biased via a resistor.
Therefore, when the P-ON_H2 signal changes to a low level, the photocoupler 51 is in an open state, so that all the output voltage from the second power supply unit 72 is applied to the supply switching circuit 53, and the Zener diode D7 is broken down. As a result, the transistor Q4 is turned on, and the second power supply 72 and the regulator IC 73 are conducted. Here, in the standby state, the output voltage of the first power supply unit 71 is 7 volts or less, and as a result, the output voltage (7 volts) of the second voltage supply unit 72 functions as the power source of the regulator IC 73.

=== Operation of Operation Control Circuit and Reduced Voltage Detection Circuit in Each State ===
Hereinafter, operations of the operation control circuit 40 and the power reduction detection circuit 60 in the normal operation state and the standby state of the display device 100 will be described.

  When the main power supply of the display device 100 is turned on and the display device 100 shifts from the standby state to the normal operation state, a high-level P-ON_H2 signal is input to the feedback circuit 50, and after a few msec, each part constituting the display device 100 The high-level P-ON_H1 signal is input to the operation control circuit 40. In this state, the transistor Q1 of the power reduction detection circuit 60 is kept off by the potential difference between the negative voltage line 61 and the positive voltage line 62. On the other hand, when a momentary power failure occurs in the normal operation state, the voltage of the negative voltage line 61 changes and the transistor Q1 is turned on, so the power reduction detection circuit 60 outputs a reset signal to the control IC 81 of the primary side circuit 80. Therefore, the control IC 81 resets the oscillation control.

  Next, when the display device 100 shifts to the standby state due to an input from the remote control device or the like, the main controller 96 changes the activation signal to a low level in the order of P-ON_H1 and P-ON_H2 (FIG. 2). For this reason, first, the voltage on the cathode side of the diode D4 of the operation control circuit 40 decreases due to the P-ON_H1 signal changing to a low level. Then, when the P-ON_H2 signal changes to the low level, the feedback signal from the feedback circuit 50 stops, and the control IC 81 stops the oscillation of the primary side circuit. In the secondary circuit 70, the power supply source to the regulator IC 73 is switched from the first power supply unit 71 to the second power supply unit 72. As a result, in the power reduction detection circuit 60, only the voltage of the negative voltage line 61 decreases, and the potential difference applied to the transistor Q1 increases. However, since the P-ON_H1 signal changes to a low level, a breakdown current is caused to flow through the diode D4 due to the potential difference between the anode and the cathode, and the transistor Q1 is not turned on. Therefore, the power reduction detection circuit 60 is kept off.

  Further, when shifting from the standby state to the normal activation state, first, the oscillation control of the controller IC 81 is started when the P-ON_H2 signal changes to the high level, and the output voltage (load) of the secondary circuit 70 is predetermined. Rise to value. Thereafter, the P-ON_H1 signal changes to a high level to increase the cathode side voltage of the diode D4. For this reason, the negative voltage line 61 and the positive voltage line 62 of the power reduction detection circuit 60 return to the normal potential difference, and the load state of the secondary side circuit 70 is not erroneously detected as a momentary power failure.

  As described above, in order to stop the operation of the power reduction detection circuit 60 in the standby state of the display device 100, the power reduction detection circuit 60 does not erroneously detect the no-load state of the secondary side circuit 70 as a momentary power failure. The power supply circuit can be operated accurately. In this embodiment, since the operation of the power reduction detection circuit 60 is stopped according to the signal change of the P-ON_H1 signal, it is not necessary to adjust the voltages of the negative voltage line 61 and the positive voltage line 62. The function of the present invention can be realized with a simple configuration. The first embodiment has been described above.

(2) Other embodiments:
There are various modifications of the present invention. A specific example of the image output device is not limited to the display device. For example, a media player may be used as an example of the image output device.

  In addition, realization of the operation control circuit using a diode is an example, and any configuration may be used as long as it has a function of stopping the operation of the power reduction detection circuit by shifting to the standby state. Good.

Needless to say, the present invention is not limited to the above embodiments. It goes without saying for those skilled in the art,
・ Applying mutually interchangeable members and configurations disclosed in the above embodiments by appropriately changing the combination thereof.− Although not disclosed in the above embodiments, it is a publicly known technique and the above embodiments. The members and configurations that can be mutually replaced with the members and configurations disclosed in the above are appropriately replaced, and the combination is changed and applied. It is an embodiment of the present invention that a person skilled in the art can appropriately replace the members and configurations that can be assumed as substitutes for the members and configurations disclosed in the above-described embodiments, and change the combinations and apply them. It is disclosed as.

  DESCRIPTION OF SYMBOLS 40 ... Operation control circuit, 50 ... Feedback circuit, 51 ... Photocoupler, 52 ... Conduction switching circuit, 53 ... Supply switching circuit, 60 ... Reduced voltage detection circuit, 61 ... Negative voltage line, 62 ... Positive voltage line, 63 ... Reset Signal output unit, 70 ... secondary side circuit, 71 ... first power supply unit, 72 ... second power supply unit, 73 ... regulator IC, 80 ... primary side circuit, 95 ... power supply circuit, 96 ... main controller, 97 ... Display 98: Back end part 99 ... Front end part 100 ... Display device

Claims (5)

In a power supply device that performs feedback control for controlling oscillation of the primary circuit by the IC according to the output voltage of the secondary circuit,
A voltage reduction detection circuit that monitors the output voltage of the secondary side circuit and resets the oscillation control by the IC when the output voltage of the secondary side circuit is equal to or lower than a predetermined value;
A standby state transition circuit for controlling the IC so that the output voltage of the secondary side circuit is lowered to a predetermined value when transitioning to a standby state;
An operation control circuit for stopping driving of the power reduction detection circuit during the transition to the standby state;   2. The power supply device according to claim 1, wherein when the operation control circuit shifts from a standby state to a normal operation state, the drive of the power reduction detection circuit is delayed after a predetermined period and then restarted. The power reduction detection circuit outputs a reset signal that causes the IC to reset oscillation control by turning on the transistor when the output voltage of the secondary side circuit is equal to or lower than a predetermined value.
3. The operation control circuit according to claim 1, wherein when the operation control circuit shifts to a standby state, the operation control circuit stops the output of the reset signal by maintaining the transistor in an off state. 4. Power supply device. Accepting a power-on operation, outputting a high-level start signal, the power supply device is in a normal start state, and has a main controller that changes the start signal to a low level when transitioning to the standby state,
The operation control circuit includes a diode connected to the base of the transistor on the anode side and connected to the start signal output terminal of the main controller on the cathode side, and when the start signal becomes a low level, the diode is 4. The power supply device according to claim 3, wherein the transistor is maintained in an off state by breakdown. In an image output apparatus including a power supply circuit that performs feedback control for controlling oscillation of the primary circuit by the IC according to the output voltage of the secondary circuit,
The power supply circuit is
The output voltage of the secondary side circuit is monitored, and when the output voltage of the secondary side circuit falls below a predetermined value, a reset signal is output by turning on the transistor, and the oscillation control by the IC is reset. A low voltage detection circuit;
A main controller that accepts a power-on operation, outputs a high-level start signal to place the power supply circuit in a normal start state, and changes to the start signal low level when transitioning to the standby state;
In accordance with a signal output from the main controller, a standby state transition circuit that controls the IC so that the output voltage of the secondary circuit is lowered to a predetermined value;
A diode is connected to the base of the transistor on the anode side and connected to the start signal output terminal of the main controller on the cathode side, and the start signal changes to a low level to cause the diode to break down and An operation control circuit that stops driving of the power reduction detection circuit by maintaining an off state, and restarts the drive of the power reduction detection circuit after delaying the drive of the power reduction detection circuit for a predetermined period when transitioning from a standby state to a normal operation state And an image output device.

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