JP4314491B2 - Power supply circuit and plasma TV - Google Patents

Description

  The present invention relates to a power supply circuit that converts an input voltage on the primary side into a desired voltage via a transformer and outputs the voltage on the secondary side, and a plasma television equipped with the power supply circuit.

  With the recent increase in energy saving, electric and electronic devices are required to reduce energy loss. At the same time, as electrical and electronic equipment becomes more complex, the need to supply highly accurate DC power is increasing.

  Therefore, in order to respond to such demands, such electric and electronic devices have a DC current obtained by rectifying and smoothing commercial AC at high frequency, and are transformed to a desired voltage with high efficiency by a small transformer. Switching power supply circuits configured to do so are widely used.

  FIG. 3 is a block diagram showing an electrical configuration of a typical conventional switching power supply circuit 5 mounted on, for example, a plasma television as an electrical / electronic device.

  In the figure, the power supply circuit 5 includes a transformer 2, a primary winding circuit 1 provided on the primary side of the transformer 2, an auxiliary winding circuit 4, and a secondary provided on the secondary side. For example, a switching power supply circuit 5 for a plasma television provided with a side winding circuit 3.

  The primary winding circuit 1 includes, for example, a diode bridge circuit 1b that full-wave rectifies an AC current from an AC power supply 1a of a commercial power supply 100V, and a pulsating current from the DC current that is full-wave rectified by the diode bridge circuit 1b. A smoothing capacitor 1c, and a primary winding 2a through which an alternating current generated by turning on / off a DC current from which a pulsating current has been removed by the smoothing capacitor 1c is turned on / off by a first switching element 4f included in a switching control IC 4g described later. Have.

  The secondary winding circuit 3 includes a secondary winding 2b that converts the voltage on the primary winding 2a side to a predetermined voltage via the transformer 2, and an alternating current converted to the predetermined voltage by a half wave. A diode 2c for rectification, a smoothing capacitor 2d for removing a pulsating current from a half-wave rectified direct current, a secondary-side feedback circuit 2e for outputting and feeding back the transformed secondary voltage state to the primary side, It has.

  The auxiliary winding circuit 4 inputs an auxiliary winding 2c supplied with power from the transformer 2 during normal times except for startup and an output from the secondary feedback circuit 2e, and converts the converted voltage on the secondary side. Based on the state, a primary-side feedback circuit 4a that appropriately turns on and off the current flowing through the primary winding 2a, and backup power supply to an external circuit when the AC power supply 1a is momentarily interrupted due to a lightning strike or the like. The power supply circuit 4b includes a power interruption circuit 4c provided between the primary side winding circuit 1 for supplying power to the auxiliary winding circuit 4 at the time of startup.

  The secondary-side feedback circuit 2e is divided by two resistors 2f1 and 2f2 connected in series to step down the voltage of the secondary winding 2b at a predetermined ratio between both terminals of the secondary winding 2b. The circuit 2f and the current adjusting resistor 2g, the photodiode 2h, and the E-C of the second switching element 2i connected in series are arranged in parallel, and the two resistors 2f1, 2f1 of the voltage dividing circuit 2f are arranged in parallel. 2f2 and B of the second switching element 2i are connected via a Zener diode 2j, and B is further connected to GND via a resistor. On the other hand, the primary feedback circuit 4a includes a resistor 4d. A phototransistor 4e provided between the constant-current voltage source Vcc and the GND via the photo-transistor and turning on and off between the constant-current voltage source and the GND in response to light reception from the photodiode 2h; A constant current voltage that is turned on / off by the phototransistor 4e is input, and power is supplied from the power supply circuit 4c at the time of start-up and from both terminals of the auxiliary winding 2c at the time of start-up, and is turned on / off by the phototransistor 4e. A switching control IC 4g for turning on and off the built-in first switching element 4f on the basis of the constant current voltage inputted and chopper-controlling the current flowing in the primary winding 2a of the primary winding circuit 1; Comprising.

  When the voltage on the secondary winding 2b side rises above a predetermined voltage, in the secondary feedback circuit 2e, the voltage divided by the voltage dividing circuit 2f is passed through the Zener diode 2j to the second voltage. When applied to B of the switching element 2i, the second switching element 2i is turned on, and the photodiode 2h emits light. In response, the received phototransistor 4e receives a constant current voltage in the primary feedback circuit 4a. The input from the constant current voltage source Vcc to the switching control IC 4g is switched from Hi to Lo by turning on between the sources Vcc and GND, and the switching control IC 4g switches the built-in first switching element 4f on the basis of the input. ON / OFF and chopper control of the current flowing through the primary winding 2a Voltage 2b side is always controlled to within a predetermined value.

  The start-up power supply circuit 4c includes a resistor 4h for stepping down to a voltage suitable for the switching control IC 4g between the AC power supply 1a supplied to the primary winding circuit 1 and one end of the auxiliary winding 2c. And a diode 4i for half-wave rectification are arranged in series.

  That is, during normal times, the auxiliary winding circuit 4 is supplied with power via the auxiliary winding 2c, but at the time of start-up, the primary winding 2a is not yet energized. Can not be fed from. Therefore, only during such start-up, power is supplied from the AC power source 1a in the primary-side winding circuit 1 to the auxiliary winding circuit 4 via the start-up power supply circuit 4c.

  The instantaneous interruption countermeasure circuit 4b includes a diode 4j provided for half-wave rectification so that the anode is on the auxiliary winding 2c side between the one end side of the auxiliary winding 2c and the connection point of the starting power supply circuit 4c. And an electrolytic capacitor 4k provided between the cathode of the diode 4j and the other end of the auxiliary winding 2c in order to store electricity during normal times and to discharge to the external circuit in the event of a momentary interruption. The backup power supply to the external circuit at the time of the instantaneous interruption of the AC power supply 1a caused by the discharge is performed by the discharge from the electrolytic capacitor 4k.

  The plasma television on which the switching power supply circuit 5 according to this conventional example is mounted has, for example, a circuit such as a PFC, a power factor correction circuit, SUS, and ADRESS as the external circuit requiring power supply. The PFC is a circuit for supplying power to the power factor correction circuit, and is an active filter circuit that suppresses generation of high-frequency power from the device. The SUS is an abbreviation for a sustain drive circuit, and supplies 70% of a sustain electrode (sustain electrode) that maintains plasma emission of the PDP, and uses 70% of the entire power source. The ADRESS is a circuit for supplying power to the addressless electrode of the PDP. Functionally, each of these circuits needs to be stably supplied with DC power having higher accuracy than the switching power supply circuit. Therefore, when a momentary interruption occurs in the commercial power supply due to a lightning strike or the like, there is a risk that the operation of these external circuits may be hindered. Therefore, the interruption countermeasure circuit 4b having the electrolytic capacitor 4k as described above is provided. As a result, when an instantaneous interruption occurs in the commercial power supply, the electric power stored in the electrolytic capacitor 4k is immediately discharged, and stable supply of direct current to each external circuit is ensured.

  On the other hand, however, when the switching power supply circuit 5 is started, there is a problem that the start-up time is delayed due to the electrolytic capacitor 4k provided in the instantaneous interruption countermeasure circuit 4b.

  That is, at the time of starting the switching power supply circuit 5, since the primary winding 2a is not yet energized as described above, power cannot be supplied from the auxiliary winding 2c. Power is supplied from the AC power source 1a to the auxiliary winding circuit 4 via the startup power supply circuit 4c. However, the power supplied through the start-up power supply circuit 4c is consumed for storing the electrolytic capacitor 4k of the instantaneous interruption countermeasure circuit 4b. In addition, the electrolytic capacitor 4k has a large capacity because it is intended to supply power to an external circuit at the time of a momentary interruption. Accordingly, it takes time for the electrolytic capacitor 4k to be fully charged, and during that time, the power supply to the switching control IC 4g is not sufficiently performed and the start-up is delayed.

  Further, the delay in starting can be suppressed by increasing the current flowing through the starting power supply circuit 4c, but on the other hand, the current is consumed by the resistor 4h of the starting power supply circuit 4c. There is a problem that power consumption becomes large.

  By the way, for example, the following conventional techniques are known as techniques for restricting charging of a capacitor after startup or reducing power consumption.

  That is, in Japanese Patent Application Laid-Open No. 2000-175449 (Patent Document 1), a capacitor is charged by a series circuit of a starting resistor and a field effect transistor, and the control transistor TR1 is turned on / off based on the charged voltage. When the transistor TR1 is turned on, a voltage is generated in the auxiliary winding to turn on the transistor TR2, turn off the field effect transistor, and prevent charging of the capacitor.

  In Japanese Patent Laid-Open No. 2001-231252 (Patent Document 2), when the power is turned on, the capacitor C2 is charged by the resistor R1 connected to the rectifier circuit and the pulse width control circuit IC starts to operate. The voltage is supplied to the transistor G and turned off after a predetermined time according to the time constant of the resistor R11 and the capacitor C12, and the power consumption by the starting resistor R1 is reduced.

In JP 2002-258920 A (Patent Document 3), a thermistor having a positive characteristic is connected between an output terminal of a rectifier circuit and a power supply terminal of a control IC. When the power is turned on, the capacitor is charged via the thermistor. When the switching operation starts, the temperature of the thermistor rises and the resistance value rises to suppress power consumption by the thermistor.
JP 2000-175449 A JP 2001-231252 A JP 2002-258920 A

  In Patent Document 1, by reducing the starting resistance R, the charging time is shortened even if the capacitor capacity is large. However, in the present invention, the resistance of the start-up power supply circuit is set to step down to a voltage suitable for the switching control IC, and cannot be reduced as in Patent Document 1 to charge the capacitor. If the current is increased, the power consumption is unavoidably increased.

  Further, in Patent Document 1, the transistor TR1 and the field effect transistor are controlled to be turned on / off by the activated control circuit IC, thereby minimizing the current flowing through the activation resistor and suppressing the loss. Before, it can't work. That is, it cannot be applied to the reduction of power consumption while being stored in the electrolytic capacitor immediately before the switching control IC in the present application described above is activated.

  In Patent Document 2, after the pulse width control circuit IC starts operating, voltage is supplied to the transistor G to turn it off, and power consumption by the starting resistor R1 is reduced. It cannot be applied to the reduction of power consumption while being stored in the electrolytic capacitor immediately before the switching control IC is activated.

  In Patent Document 3, since the temperature rise of the thermistor accompanying the start of the switching operation by the control IC is required, as in Patent Documents 1 and 2, it is stored in the electrolytic capacitor immediately before the switching control IC in the present application is activated. It cannot be applied to the reduction of power consumption between the two.

  The present invention has been made in view of the above-described problem, and at the time of starting the switching power supply circuit, the start-up time delay caused by the electrolytic capacitor provided in the instantaneous interruption countermeasure circuit is not caused without increasing the power consumption. It is an object of the present invention to provide a power supply circuit to be avoided and a plasma television equipped with the power supply circuit.

In order to solve the above problems, the present invention relates to a plasma television having a power supply circuit that converts a primary side input voltage to a desired voltage through a transformer and outputs the voltage on the secondary side. Suppressing the generation of high-frequency power from a device that is converted into a predetermined DC voltage and input from the power supply circuit, the PDP to be displayed, a speaker that outputs sound, the power supply circuit to which commercial power is input from the outside, and a predetermined DC voltage A PFC as an external circuit which is an active filter circuit, a power factor correction circuit as an external circuit to which power is input via the PFC, a power factor improved via the power factor correction circuit, and each power input SUS as an external circuit that uses 70% of the entire power source to supply voltage to the sustain electrode that maintains the plasma emission of the PDP, and the addressless power of the PDP Based on the ADRESS as an external circuit for supplying power to the TV, a tuner for extracting and outputting the TV broadcast signal of the channel selected from the TV broadcast signal received by the antenna, and the TV broadcast signal output by the tuner A video processing unit for displaying video on the PDP, an audio processing unit for outputting audio to the speaker, a remote controller for operating a switch on / off, channel switching, volume up / down, and the like, A remote control receiving unit that receives a transmitted operation command, and a controller that controls operations such as switch on / off, channel switching, and volume up / down according to the operation command received by the remote control receiving unit. The power circuit includes a transformer and a primary winding provided on the primary side of the transformer. A switching power supply circuit including a circuit, an auxiliary winding circuit, and a secondary winding circuit provided on the secondary side, wherein the primary winding circuit is configured to receive all alternating current from an AC power supply. A diode bridge circuit for wave rectification, a smoothing capacitor that removes a pulsating current from a direct current that has been full-wave rectified by the diode bridge circuit, and a direct current from which the pulsating current has been removed by the smoothing capacitor are turned on and off by the first switching element. A secondary winding that converts the voltage on the primary winding side to a predetermined voltage via a transformer, and a predetermined winding. A half-wave rectifier diode that converts the alternating current converted to the voltage of the current, a smoothing capacitor that removes the pulsating current from the half-wave rectified direct current, and the transformed secondary voltage state to the primary side. Secondary fee to feed back The auxiliary winding circuit receives the auxiliary winding supplied with power from the transformer during normal times except for startup, and the output from the secondary side feedback circuit, and is converted to the secondary side. The primary side feedback circuit for appropriately turning on and off the current flowing through the primary winding based on the state of the voltage, and the backup power supply to the external circuit at the time of the instantaneous interruption of the AC power source caused by lightning strike A power supply circuit at the time of start-up provided between the power supply circuit at the time of start-up and the primary winding circuit for supplying power to the auxiliary winding circuit at the time of start-up, and the instantaneous power-off from the power supply circuit at the time of start-up A start-up power supply blocking circuit that blocks power supply to the countermeasure circuit and secures power supply to the primary feedback circuit, and the secondary feedback circuit is connected between both terminals of the secondary winding. Next winding voltage A voltage dividing circuit composed of two resistors connected in series for stepping down at a rate and a current adjusting resistor, a photodiode, and a second switching element E-C connected in series are arranged in parallel. In addition, the two resistors of the voltage dividing circuit and B of the second switching element are connected via a Zener diode, and further, the B is GND-connected via a resistor, while the primary feedback The circuit is provided between a constant current voltage source and GND via a resistor, and turns on and off between the constant current voltage source and GND in response to light reception from the photodiode, and a constant current turned on and off by the phototransistor. A voltage source is input, and power is supplied from the power supply circuit at start-up at the time of start-up and from both terminals of the auxiliary winding at times other than start-up. A switching control IC for turning on and off the built-in first switching element based on a constant current voltage that is turned on and off by a transistor and chopper-controlling the current flowing in the primary winding of the primary winding circuit; When the voltage on the secondary winding side rises above a predetermined voltage, the voltage divided by the voltage dividing circuit in the secondary side feedback circuit is supplied to the second voltage via the Zener diode. The second switching element is turned on by being applied to B of the switching element, and the photodiode emits light. In response, the received phototransistor is connected between the constant current voltage source and GND in the primary feedback circuit. To switch the input from the constant current voltage source to the switching control IC from Hi to Lo, Based on the input, the switching control IC turns on and off the built-in first switching element to chopper-control the current flowing through the primary winding, and the start-up power supply circuit supplies the primary winding circuit to the primary side winding circuit. A resistance for stepping down to a voltage suitable for the switching control IC and a diode for half-wave rectification are arranged in series between an AC power source to be operated and one end side of the auxiliary winding, and the measure against instantaneous interruption The circuit stores a first diode provided for half-wave rectification so that the anode is on the auxiliary winding side between the one end side of the auxiliary winding and the start-up power supply circuit connection point, and charges in normal time And a first electrolytic capacitor provided between the cathode of the first diode and the other end side of the auxiliary winding for discharging to the external circuit in the event of a momentary interruption. The electric blocking circuit performs half-wave rectification so that the anode is on the first diode side between the first diode and the start-up power supply circuit connection point, and prevents charging to the first electrolytic capacitor during start-up. A second diode provided to supply power only to the switching control IC, and a cathode of the second diode and the auxiliary winding to eliminate the pulsating current of the supply current to the switching control IC. A second electrolytic capacitor having a small capacity provided between the other end side, and at the time of start-up, the current supplied to the auxiliary winding circuit via the start-up power supply circuit is The second diode of the power feeding blocking circuit prevents the instantaneous interruption countermeasure circuit from flowing into the first electrolytic capacitor side, so that only the small capacity second electrolytic capacitor side is provided. Is, said power storage to the first electrolytic capacitor is not performed, it may be configured to makes it early start to ensure power supply to the switching control IC.

According to inventions constructed as described above, at the time of startup, the current supplied to the auxiliary winding circuit through the startup power supply circuit, a second diode of said startup power supply rejection circuit An inflow to the first electrolytic capacitor side of the instantaneous interruption countermeasure circuit is blocked and flows only to the second electrolytic capacitor side having a small capacity, and no power is stored in the first electrolytic capacitor.

The inventions, in the power supply circuit for outputting an input voltage of the primary side and through the transformer into a desired voltage secondary side, the power supply circuit is provided with a transformer, the primary side of the transformer 1 A switching power supply circuit comprising a secondary side winding circuit, an auxiliary winding circuit, and a secondary side winding circuit provided on the secondary side, wherein the auxiliary winding circuit is in normal time except during startup An auxiliary winding supplied with power from a transformer, a switching control IC for chopper-controlling the primary winding circuit based on a signal fed back from the secondary winding circuit, and the 1 generated due to a lightning strike or the like An instantaneous interruption countermeasure circuit for performing backup power supply to an external circuit when an AC power supply supplied to the secondary winding circuit is instantaneously interrupted, and the primary winding circuit for supplying electric power to the auxiliary winding circuit at the start-up During startup provided between And electric circuit, have a structure comprising and a startup power supply rejection circuit and prevents the supply of power to the instantaneous interruption countermeasure circuit from the startup power supply circuit at startup to ensure power supply to the switching control IC Good .

According to inventions constructed as described above, at the time of startup, the current supplied to the auxiliary winding circuit through the startup power supply circuit, the instantaneous interruption countermeasure circuit by the startup power supply rejection circuit Inflow is prevented.

According to inventions, at the time of startup, the current supplied to the auxiliary winding circuit through the startup power supply circuit, the said instantaneous interruption countermeasure circuit by a second diode of said startup power supply rejection circuit Inflow to the first electrolytic capacitor side is blocked and flows only to the second electrolytic capacitor side having a small capacity, and no electricity is stored in the first electrolytic capacitor.

  Therefore, the power supply to the switching control IC can be secured and the start-up can be performed early without being affected by the power storage of the first electrolytic capacitor.

According to the present invention, during start-up, the current supplied to the auxiliary winding circuit via the start-up power supply circuit is prevented from flowing into the instantaneous interruption countermeasure circuit by the start-up power supply blocking circuit. .

  Therefore, the power supply to the switching control IC is ensured and the operation is promptly started without being affected by the instantaneous interruption countermeasure circuit.

According to the present invention, at the time of startup, the current supplied to the auxiliary winding circuit through the startup power supply circuit, a second diode of said startup power supply rejection circuit of the momentary interruption countermeasure circuit Inflow to the first electrolytic capacitor side is blocked and flows only to the second electrolytic capacitor side having a small capacity, and no power is stored in the first electrolytic capacitor.

  Therefore, the power supply to the switching control IC can be secured and the start-up can be performed early without being affected by the power storage of the first electrolytic capacitor.

According to inventions, at the time of startup, the current supplied to the auxiliary winding circuit through the startup power supply circuit, a second diode of said startup power supply rejection circuit of the momentary interruption countermeasure circuit Inflow to the first electrolytic capacitor side is blocked and flows only to the second electrolytic capacitor side having a small capacity, and no power is stored in the first electrolytic capacitor.

  Therefore, the power supply to the switching control IC can be secured and the start-up can be performed early without being affected by the power storage of the first electrolytic capacitor.

  Hereinafter, examples embodying the present invention will be described.

  In this embodiment, a plasma television will be described as an example of an electric / electronic device provided with a switching power supply circuit.

  FIG. 1 is a block diagram illustrating the configuration of the plasma television 11.

  In the figure, a commercial power supply (for example, AC 100 V) is input to the power supply circuit 12 of the plasma television 11 from the outside. The power supply circuit 12 converts the voltage into a predetermined DC voltage as will be described in detail later, and outputs it to the PFC 12a as an external circuit. The PFC 12a is a circuit for supplying power to the power factor correction circuit 12b, and is an active filter circuit that suppresses generation of high-frequency power from the device.

  The power is input to the power factor correction circuit 12b via the PFC 12a. After the power factor is improved, SUS 12c and ADRESS 12d as external circuits, and further to the controller 11a, the tuner 11b, the remote control reception unit 11h and the like are supplied.

  The SUS 12c is an abbreviation for a sustain drive circuit, and supplies 70% of a sustain electrode (sustain electrode) that maintains plasma emission of the PDP 11c, and uses 70% of the entire power source. The ADRESS 12d is a circuit for supplying power to the addressless electrode of the PDP 11c.

  The tuner 11b extracts and outputs a television broadcast signal of a selected channel from a television broadcast signal received by an antenna (not shown). Based on the TV broadcast signal output from the tuner 11b, the video is displayed on the PDP (plasma display panel) 11c by the video processing unit 11d, and the audio is output from the speaker 11e by the audio processing unit 11f. The remote control receiving unit 11h receives an operation command transmitted from the remote control 11g and outputs it to the controller 11a. The controller 11a controls operations such as switch on / off, channel switching, and volume up / down according to the operation command received by the remote control receiver 11h.

  FIG. 2 shows a circuit diagram of the power supply circuit 12.

  In the figure, the power supply circuit 12 includes a transformer 14, a primary winding circuit 13 provided on the primary side of the transformer 14, an auxiliary winding circuit 16, and a secondary provided on the secondary side. And a side winding circuit 15.

  For example, the primary side winding circuit 13 generates a pulsating current from a diode bridge circuit 13b that full-wave rectifies an AC current from an AC power supply 13a of a commercial power supply 100V, and a DC current that is full-wave rectified by the diode bridge circuit 13b. A smoothing capacitor 13c, and a primary winding 14a through which an alternating current generated by turning on / off a direct current from which a pulsating current has been removed by the smoothing capacitor 13c is turned on and off by a first switching element 16g built in a switching control IC 16f described later. Have.

  The secondary winding circuit 15 includes a secondary winding 14b for converting the voltage on the primary winding 14a side to a predetermined voltage via the transformer 14, and a half wave of the alternating current converted to the predetermined voltage. A diode 15a for rectification, a smoothing capacitor 15b that removes a pulsating current from a half-wave rectified DC current, and a secondary-side feedback circuit 15c that outputs the state of the transformed secondary-side voltage to the primary side for feedback. It has.

  The auxiliary winding circuit 16 receives the auxiliary winding 14c supplied with power from the transformer 14 during normal times except for startup and the output from the secondary feedback circuit 15c, and converts the converted voltage on the secondary side. A primary-side feedback circuit 16a that appropriately turns on and off the current flowing through the primary winding 14a based on the state, and external circuits 12a, 12b, and 12c at the time of a momentary interruption of the AC power supply 13a caused by a lightning strike or the like. , 12d, a power supply circuit 16c at the time of start-up provided between the primary winding circuit 13 for supplying power to the auxiliary winding circuit 16 at the time of start-up, The start-up power supply blocking circuit 1 prevents power supply from the start-up power supply circuit 16c to the instantaneous interruption countermeasure circuit 16b and ensures power supply to the primary feedback circuit 16a. Made with a d.

The secondary-side feedback circuit 15c is divided by two resistors 15d1 and 15d2 connected in series in order to step down the voltage of the secondary winding 14b at a predetermined ratio between both terminals of the secondary winding 14b. The circuit 15e and the current adjusting resistor 15f, the photodiode 15g, and the E-C of the second switching element 15h connected in series are arranged in parallel, and the two resistors 15d1, 15d1 of the voltage dividing circuit 15e are arranged in parallel. 15d2 and B of the second switching element 15h are connected via a Zener diode 15i, and B is further connected to GND via a resistor, while the primary feedback circuit is connected via a resistor 16 Is provided between the constant current voltage source Vcc and GND, and is turned on between the constant current voltage source Vcc and GND in response to light reception from the photodiode 15g. A phototransistor 16e to be turned on and a constant current voltage source Vcc that is turned on / off by the phototransistor 16e are input, from the power supply circuit 16c at the start-up, and from both terminals of the auxiliary winding 14c at the time other than the start-up. The first switching element 16g, which is supplied with power and is turned on / off by the phototransistor 16e and input, is turned on / off, and flows to the primary winding 14a of the primary side winding circuit 13. And a switching control IC 16f for chopper-controlling the current.

  When the voltage on the secondary winding 14b side rises above a predetermined voltage, the voltage divided by the voltage dividing circuit 15e in the secondary side feedback circuit 15c passes through the Zener diode 15i to the second voltage. The second switching element 15h is turned on by being applied to B of the switching element 15h, and the photodiode 15g emits light. In response, the received phototransistor 16e receives a constant current voltage in the primary feedback circuit 16a. The source Vcc and GND are turned on to switch the input from the constant current voltage source Vcc to the switching control IC 16f from Hi to Lo. Based on the input, the switching control IC 16f switches the built-in first switching element 16g. The electricity flowing in the primary winding 14a is turned on and off. Chopper control, voltage of the secondary winding 14b side is always controlled to within a predetermined value.

  The start-up power supply circuit 16c includes a resistor 16h for stepping down to a voltage suitable for the switching control IC 16f between the AC power supplied to the primary winding circuit 13 and one end of the auxiliary winding 14c. A diode 16i for half-wave rectification is arranged in series.

  That is, during normal times, the auxiliary winding circuit 16 is supplied with power through the auxiliary winding 14c, but at the time of start-up, the primary winding 14a is not yet energized. Can not be fed from. Therefore, only during such start-up, power is supplied from the AC power supply 13a in the primary-side winding circuit 13 to the auxiliary winding circuit 16 via the start-up power supply circuit 16c.

  The instantaneous interruption countermeasure circuit 16b is provided for half-wave rectification so that the anode is on the auxiliary winding 14c side between one end side of the auxiliary winding 14c and the connection point of the start-up power supply circuit 16c. Between the cathode of the first diode 16j and the other end side of the auxiliary winding 14c in order to store electricity during normal times and to discharge to the external circuits 12a, 12b, 12c, 12d during a momentary interruption. The first electrolytic capacitor 16k includes a first electrolytic capacitor 16k provided, and backup power feeding to the external circuits 12a, 12b, 12c, and 12d when the AC power supply 13a is momentarily interrupted due to a lightning strike or the like. It is performed by the discharge from.

  The start-up power supply blocking circuit 16d performs half-wave rectification so that the anode is on the first diode 16j side between the connection point of the first diode 16j and the start-up power supply circuit 16c, and the first power supply blocking circuit 16d In order to eliminate the pulsating flow of the current supplied to the switching control IC 16f and the second diode 16l provided to prevent power storage in the electrolytic capacitor 16k and to supply power only to the switching control IC 16f. A small electrolytic second electrolytic capacitor 16m is provided between the cathode of the diode 16l and the other end of the auxiliary winding 14c.

  In the plasma television 11 having the power supply circuit 12 having the above-described circuit configuration, when the power plug is inserted into an outlet, the power is supplied to the auxiliary winding circuit 16 via the power supply circuit 16c at the time of startup. The current is blocked from flowing into the first electrolytic capacitor 16k side of the instantaneous interruption countermeasure circuit 16b by the second diode 16l of the start-up power supply blocking circuit 16d, and the second electrolytic capacitor 16m side with a small capacity is blocked. Only flows into. Therefore, it is not stored in the first electrolytic capacitor 16k, but is stored only in the second electrolytic capacitor 16m.

  Since the second electrolytic capacitor 16m has a small capacity, unlike the case of the first electrolytic capacitor 16k having a large capacity, the power can be stored in a very short time. Therefore, a stable direct current from which the pulsating current is removed by the second diode 16l can be supplied to the switching control IC 16f at an early stage and can be started up at an early stage. Moreover, there is no need to increase the current supplied to the auxiliary winding circuit 16 via the start-up power supply circuit 16c, and power consumption does not increase.

 As described above, according to the power supply circuit provided in the plasma television in the present embodiment, at the time of start-up, the capacity of the instantaneous interruption countermeasure circuit is large due to the small second diode of the start-up power supply blocking circuit. Since the inflow to the first electrolytic capacitor side is blocked, it is possible to provide a power supply circuit that enables early start-up without increasing power consumption, and a plasma television equipped with the power supply circuit.

  In addition, this invention is not limited to the structure of a present Example, It can change suitably about the structure listed below.

1. In the present embodiment, the case where the power supply circuit is mounted on the plasma television has been described. However, the electrical and electronic equipment on which the power supply circuit is mounted is not limited to the plasma television, and other televisions such as a CRT television and a PDP television, Further, it can be widely applied to various electric and electronic devices equipped with a power supply circuit such as various home appliances.

2. The specific circuit configuration of the power supply circuit in the embodiment is merely an example. In the auxiliary winding circuit, the power supply to the switching control IC is prevented by preventing power supply from the power supply circuit at the time of start-up to the instantaneous interruption countermeasure circuit. As long as a start-up power supply blocking circuit for ensuring the above is provided, it can be changed as appropriate.

3. As each switching element, various switching elements such as an FET, a switching transistor, and an IGBT can be applied.

4). Although the switching control IC in the embodiment has an integrated configuration in which a switching element that is turned on / off is built in, the configuration is not limited thereto, and the switching element and the controller portion that controls on / off of the switching element are separately provided. It is also good.

The operation of the present invention will be described below.

According to the present invention, the instantaneous interruption countermeasure circuit is provided for half-wave rectification so that the anode is on the auxiliary winding side between the one end side of the auxiliary winding and the start-up power supply circuit connection point. And a first electrolytic capacitor provided between the cathode of the first diode and the other end of the auxiliary winding in order to store electricity during normal times and to discharge to the external circuit in the event of a momentary interruption. The start-up power supply blocking circuit performs half-wave rectification such that the anode is on the first diode side between the first diode and the start-up power supply circuit connection point, and the first electrolytic capacitor at start-up In order to eliminate the pulsating current of the current supplied to the switching control IC and the second diode provided to prevent the power storage to the power supply and to supply power only to the switching control IC, The cathode of the diode provided between the other end of the auxiliary winding may be configured comprising a second electrolytic capacitor of small capacity.

According to inventions constructed as described above, at the time of startup, the current supplied to the auxiliary winding circuit through the startup power supply circuit, the second diode of the startup power supply rejection circuit As a result, the insufficiency interruption circuit is prevented from flowing into the first electrolytic capacitor side and flows only to the second electrolytic capacitor side having a small capacity, and the first electrolytic capacitor is not charged.

The present invention relates to a power supply circuit that converts a primary input voltage into a desired voltage via a transformer and outputs the voltage on the secondary side. The power supply circuit is provided on the transformer and the primary side of the transformer. A switching power supply circuit for a plasma television comprising a primary side winding circuit and an auxiliary winding circuit, and a secondary side winding circuit provided on the secondary side, wherein the primary side winding circuit is A diode bridge circuit for full-wave rectification of alternating current from an AC power supply, a smoothing capacitor for removing pulsating current from direct-current rectified by the diode bridge circuit, and a direct current from which pulsating current has been removed by the smoothing capacitor And a primary winding through which an alternating current generated by turning on and off the first switching element flows. The secondary winding circuit converts the voltage on the primary winding side to a predetermined voltage via a transformer. Secondary winding to convert, and place A half-wave rectifier diode that converts the alternating current converted to the voltage of the current, a smoothing capacitor that removes the pulsating current from the half-wave rectified direct current, and the transformed secondary voltage state to the primary side. A secondary-side feedback circuit that feeds back, and the auxiliary winding circuit receives an auxiliary winding that is supplied with power from a transformer during normal times except for startup, and inputs an output from the secondary-side feedback circuit. Based on the state of the converted voltage on the secondary side, a primary-side feedback circuit that appropriately turns on and off the current flowing in the primary winding, and an external circuit at the time of an instantaneous interruption of the AC power supply caused by a lightning strike or the like Power supply circuit provided between the primary side winding circuit for supplying power to the auxiliary winding circuit at the time of startup, and the startup power supply circuit at the time of startup from A start-up power supply blocking circuit that blocks power supply to the instantaneous interruption countermeasure circuit and secures power supply to the primary feedback circuit, and the secondary feedback circuit is connected between both terminals of the secondary winding. A voltage dividing circuit composed of two resistors connected in series to step down the voltage of the secondary winding at a predetermined ratio, a current adjusting resistor connected in series, a photodiode, and a second switching element. E-C are respectively arranged in parallel, and between the two resistors of the voltage dividing circuit and B of the second switching element are connected via a Zener diode, and further, the B is connected to GND via a resistor. On the other hand, the primary-side feedback circuit is provided between a constant-current voltage source and GND via a resistor, and turns on and off between the constant-current voltage source and GND in response to light reception from the photodiode. And a constant current voltage source that is turned on / off by the phototransistor are input from the power supply circuit at the time of start-up, and are supplied from both terminals of the auxiliary winding at the time of non-startup. A switching control IC for turning on and off the built-in first switching element based on a constant current voltage that is turned on and off, and chopper-controlling the current flowing in the primary winding of the primary winding circuit. When the voltage on the secondary winding side rises above a predetermined voltage, the voltage divided by the voltage dividing circuit in the secondary side feedback circuit becomes the second switching via the Zener diode. When applied to the element B, the second switching element is turned on, and the photodiode emits light. In the secondary feedback circuit, the received phototransistor turns on between the constant current voltage source and GND, switches the input from the constant current voltage source to the switching control IC from Hi to Lo, and performs switching control based on the input. The IC chopper-controls the current flowing through the primary winding by turning on and off the first switching element incorporated therein, and the start-up power feeding circuit includes an AC power source supplied to the primary winding circuit and the A resistor for stepping down to a voltage suitable for the switching control IC and a diode for half-wave rectification are arranged in series between one end sides of the auxiliary winding, and the instantaneous interruption countermeasure circuit includes the auxiliary winding. The first provided for half-wave rectification so that the anode is on the auxiliary winding side between one end side of the wire and the feeding circuit connection point at the time of starting. A diode and a first electrolytic capacitor provided between the cathode of the first diode and the other end of the auxiliary winding for storing electricity during normal times and discharging to the external circuit in the event of a momentary interruption. The start-up power supply blocking circuit performs half-wave rectification so that the anode is on the first diode side between the first diode and the start-up power supply circuit connection point, and to the first electrolytic capacitor during start-up. A second diode provided to prevent power storage and supply power only to the switching control IC, and to eliminate a pulsating flow of the current supplied to the switching control IC, the cathode of the second diode and the It consists of a second electrolytic capacitor with a small capacity provided between the other end side of the auxiliary winding. The current supplied to the auxiliary winding circuit is prevented from flowing into the first electrolytic capacitor side of the instantaneous interruption countermeasure circuit by the second diode of the start-up power supply blocking circuit, so that the second capacitor having a small capacity is supplied. However, the first electrolytic capacitor may not be charged, and the power supply to the switching control IC may be ensured to start up early.

According to inventions constructed as described above, at the time of startup, the current supplied to the auxiliary winding circuit through the startup power supply circuit, the second diode of the startup power supply rejection circuit As a result, the insufficiency interruption circuit is prevented from flowing into the first electrolytic capacitor side and flows only to the second electrolytic capacitor side having a small capacity, and the first electrolytic capacitor is not charged.

  A power supply circuit that avoids a delay in start-up time caused by the electrolytic capacitor provided in the instantaneous power failure countermeasure circuit without causing an increase in power consumption at the time of starting the switching power supply circuit, and a plasma television equipped with the power supply circuit I will provide a.

It is a block diagram explaining Example 1 of the present invention. It is a circuit diagram explaining Example 1 of the present invention. It is a circuit diagram explaining a prior art.

11 ... Plasma TV 12 ... Power supply circuit 12a ... PFC as an external circuit
12b: Power factor correction circuit as an external circuit 12c: SUS as an external circuit
12d: ADRESS as external circuit
DESCRIPTION OF SYMBOLS 13 ... Primary side winding circuit 13a ... AC power supply 13b ... Diode bridge circuit 13c ... Smoothing capacitor 14 ... Transformer 14a ... Primary winding 14b ... Secondary winding 14c ... Auxiliary winding 15 ... Secondary side winding circuit 15a ... Diode 15b ... Smoothing capacitor 15c ... Secondary feedback circuit 15d1, 15d2 ... Resistor 15e ... Voltage divider 15f ... Current adjustment resistor 15g ... Photodiode 15h ... Second switching element 15i ... Second switching element 16 ... Auxiliary Winding circuit 16a ... primary side feedback circuit 16b ... instantaneous interruption countermeasure circuit 16c ... start-up power supply circuit 16d ... start-up power supply blocking circuit 16e ... phototransistor 16f ... switching control IC
16g ... first switching element 16h ... resistor 16i ... diode 16j ... first diode 16k ... first electrolytic capacitor 16l ... second diode 16m ... second electrolytic capacitors

Claims (2)

Based on a PDP that displays video, a speaker that outputs audio, a tuner that extracts and outputs a TV broadcast signal of a channel selected from a TV broadcast signal received by an antenna, and a TV broadcast signal output by the tuner A video processing unit for displaying video on the PDP, an audio processing unit for outputting audio to the speaker, a remote controller for operating a switch on / off, channel switching, volume up / down, etc., and primary side In a plasma television having a power supply circuit that converts the input voltage of the input signal to a desired voltage via a transformer and outputs it on the secondary side,
The power supply circuit includes a transformer, a primary winding circuit provided on the primary side of the transformer, an auxiliary winding circuit, and a secondary winding circuit provided on the secondary side. A power circuit,
The primary winding circuit includes a diode bridge circuit that full-wave rectifies an alternating current from an alternating current power supply, a smoothing capacitor that removes a pulsating current from a direct current that is full-wave rectified by the diode bridge circuit, and the smoothing capacitor. A primary winding through which an alternating current generated by turning on and off the direct current from which the pulsating current is removed by the first switching element;
The secondary winding circuit includes a secondary winding that converts the voltage on the primary winding side to a predetermined voltage via a transformer, a diode that half-wave rectifies the alternating current converted to the predetermined voltage, and A smoothing capacitor that removes the pulsating current from the half-wave rectified DC current, and a secondary-side feedback circuit that outputs the transformed secondary-side voltage state to the primary side for feedback.
The auxiliary winding circuit receives an auxiliary winding supplied with power from a transformer during normal times except for startup, and an output from the secondary feedback circuit, and is based on the state of the converted voltage on the secondary side. A primary-side feedback circuit that appropriately turns on and off the current flowing through the primary winding, a momentary interruption countermeasure circuit that performs backup power supply to an external circuit in the event of an instantaneous interruption of the AC power supply caused by lightning strikes, and startup Sometimes the power supply circuit at the time of startup provided between the primary side winding circuit to supply power to the auxiliary winding circuit and the power supply circuit from the power supply circuit at the time of start-up to the instantaneous interruption countermeasure circuit are prevented. And a start-up power supply blocking circuit that secures power supply to the primary side feedback circuit,
The secondary side feedback circuit is connected in series with a voltage dividing circuit including two resistors connected in series in order to step down the voltage of the secondary winding at a predetermined ratio between both terminals of the secondary winding. The current adjusting resistor, the photodiode, and the second switching element E-C are arranged in parallel, and between the two resistors of the voltage dividing circuit and the second switching element B are Zeners. The B is connected via a diode, and the B is GND connected via a resistor.
The primary-side feedback circuit is provided between a constant-current voltage source and GND via a resistor, and a phototransistor that turns on and off between the constant-current voltage source and GND according to light reception from the photodiode, and the phototransistor A constant current voltage source that is turned on / off is input, and is supplied from the power supply circuit at start-up at the time of start-up, and is supplied from both terminals of the auxiliary winding except at the time of start-up, and is input by being turned on / off by the phototransistor. A switching control IC for turning on and off the first switching element built in based on the voltage and chopper-controlling the current flowing in the primary winding of the primary winding circuit;
When the voltage on the secondary winding side rises above a predetermined voltage, the voltage divided by the voltage dividing circuit in the secondary side feedback circuit becomes B of the second switching element via the Zener diode. And the second switching element is turned on, the photodiode emits light, and in the primary side feedback circuit, the received phototransistor turns on between the constant current voltage source and GND, and The input from the constant current voltage source to the switching control IC is switched from Hi to Lo, and based on the input, the switching control IC turns on and off the first switching element incorporated therein to generate a current flowing through the primary winding. Chopper control,
The start-up power supply circuit includes a resistor for stepping down to a voltage suitable for the switching control IC, and a half-wave rectification between an AC power source supplied to the primary side winding circuit and one end side of the auxiliary winding. A diode to be connected in series,
The instantaneous interruption countermeasure circuit includes a first diode provided for half-wave rectification so that an anode is on the auxiliary winding side between one end side of the auxiliary winding and the start-up power supply circuit connection point; A first electrolytic capacitor provided between the cathode of the first diode and the other end side of the auxiliary winding in order to store electricity during normal times and to discharge to the external circuit in the event of a momentary interruption;
The start-up power supply blocking circuit performs half-wave rectification so that the anode is on the first diode side between the first diode and the start-up power supply circuit connection point, and supplies the first electrolytic capacitor to the first electrolytic capacitor during start-up. A second diode provided to prevent power storage and supply power only to the switching control IC, and a cathode of the second diode and the auxiliary diode to eliminate a pulsating flow of the power supply current to the switching control IC. A small electrolytic second electrolytic capacitor provided between the other end of the winding,
At the time of start-up, the current supplied to the auxiliary winding circuit via the start-up power supply circuit is caused by the second diode of the start-up power supply blocking circuit to the first electrolytic capacitor side of the instantaneous interruption countermeasure circuit. Is prevented from flowing into the second electrolytic capacitor side with a small capacity, the first electrolytic capacitor is not charged, and the power supply to the switching control IC is ensured to ensure early start-up. Plasma TV characterized by that. In a power supply circuit that converts a primary side input voltage to a desired voltage via a transformer and outputs it on the secondary side.
The power supply circuit includes a transformer, a primary winding circuit provided on the primary side of the transformer, an auxiliary winding circuit, and a secondary winding circuit provided on the secondary side. A power circuit,
The primary winding circuit includes a diode bridge circuit that full-wave rectifies an alternating current from an alternating current power supply, a smoothing capacitor that removes a pulsating current from a direct current that is full-wave rectified by the diode bridge circuit, and the smoothing capacitor. A primary winding through which an alternating current generated by turning on and off the direct current from which the pulsating current is removed by the first switching element;
The secondary winding circuit includes a secondary winding that converts the voltage on the primary winding side to a predetermined voltage via a transformer, a diode that half-wave rectifies the alternating current converted to the predetermined voltage, and A smoothing capacitor that removes the pulsating current from the half-wave rectified DC current, and a secondary-side feedback circuit that outputs the transformed secondary-side voltage state to the primary side for feedback.
The auxiliary winding circuit receives an auxiliary winding supplied with power from a transformer during normal times except for startup, and an output from the secondary feedback circuit, and is based on the state of the converted voltage on the secondary side. A primary-side feedback circuit that appropriately turns on and off the current flowing through the primary winding, a momentary interruption countermeasure circuit that performs backup power supply to an external circuit in the event of an instantaneous interruption of the AC power supply caused by lightning strikes, and startup Sometimes the power supply circuit at the time of startup provided between the primary side winding circuit to supply power to the auxiliary winding circuit and the power supply circuit from the power supply circuit at the time of start-up to the instantaneous interruption countermeasure circuit are prevented. And a start-up power supply blocking circuit that secures power supply to the primary side feedback circuit,
The secondary side feedback circuit is connected in series with a voltage dividing circuit including two resistors connected in series in order to step down the voltage of the secondary winding at a predetermined ratio between both terminals of the secondary winding. The current adjusting resistor, the photodiode, and the second switching element E-C are arranged in parallel, and between the two resistors of the voltage dividing circuit and the second switching element B are Zeners. While B is connected via a diode and B is GND connected via a resistor,
The primary-side feedback circuit is provided between a constant-current voltage source and GND via a resistor, and a phototransistor that turns on and off between the constant-current voltage source and GND according to light reception from the photodiode, and the phototransistor A constant current voltage source that is turned on / off is input, and is supplied from the power supply circuit at start-up at the time of start-up, and is supplied from both terminals of the auxiliary winding at other times than start-up, and is input by being turned on / off by the phototransistor A switching control IC for turning on and off the first switching element built in based on the voltage and chopper-controlling the current flowing in the primary winding of the primary winding circuit;
When the voltage on the secondary winding side rises above a predetermined voltage, the voltage divided by the voltage dividing circuit in the secondary side feedback circuit becomes B of the second switching element via the Zener diode. And the second switching element is turned on, the photodiode emits light, and in the primary side feedback circuit, the received phototransistor turns on between the constant current voltage source and GND, and The input from the constant current voltage source to the switching control IC is switched from Hi to Lo, and based on the input, the switching control IC turns on and off the first switching element incorporated therein to generate a current flowing through the primary winding. Chopper control,
The start-up power supply circuit includes a resistor for stepping down to a voltage suitable for the switching control IC, and a half-wave rectification between an AC power source supplied to the primary side winding circuit and one end side of the auxiliary winding. A diode to be connected in series,
The instantaneous interruption countermeasure circuit includes a first diode provided for half-wave rectification so that an anode is on the auxiliary winding side between one end side of the auxiliary winding and the start-up power supply circuit connection point; A first electrolytic capacitor provided between the cathode of the first diode and the other end side of the auxiliary winding in order to store electricity during normal times and to discharge to the external circuit in the event of a momentary interruption;
The start-up power supply blocking circuit performs half-wave rectification so that the anode is on the first diode side between the first diode and the start-up power supply circuit connection point, and supplies the first electrolytic capacitor to the first electrolytic capacitor during start-up. A second diode provided to prevent power storage and supply power only to the switching control IC, and a cathode of the second diode and the auxiliary diode to eliminate a pulsating flow of the power supply current to the switching control IC. A small electrolytic second electrolytic capacitor provided between the other end of the winding,
At the time of start-up, the current supplied to the auxiliary winding circuit via the start-up power supply circuit is caused by the second diode of the start-up power supply blocking circuit to the first electrolytic capacitor side of the instantaneous interruption countermeasure circuit. Is prevented from flowing into the second electrolytic capacitor side with a small capacity, the first electrolytic capacitor is not charged, and the power supply to the switching control IC is ensured to ensure early start-up. A power supply circuit characterized by that .

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