JP2014100035A - Flyback type switching power supply - Google Patents

Abstract

The present invention makes it possible to greatly contribute to reduction of power consumption by substantially reducing power consumption to zero in an operation stop state by inputting a remote off signal.
When a remote off signal is input to a remote input unit 22, a remote control unit 24 turns on and holds transistors 52 and 54 by charging a capacitor 46, and a starting current I1 and an inverter element of the starting unit 20 The drive current I3 of the drive unit 16 that drives 12 is drawn to fix the inverter element 12 to the OFF state, and the operation is stopped. Further, when the charging of the capacitor 46 is completed, the Zener diode 26 and the transistor 25 of the starting unit 20 are turned off, and the operation of the starting unit 20 is also stopped.
[Selection] Figure 2

Description

The present invention relates to a flyback switching power supply device that controls the output voltage at a constant voltage, and more particularly to a flyback switching power supply device that is operated and stopped by remote control.

  Conventionally, a self-excited flyback switching power supply device performs self-excited oscillation, and therefore has no merit of preparing an oscillation circuit separately, and has a merit that a circuit configuration can be relatively simple, and is widely used. . In addition, since the self-excited flyback type switching power supply device may not stabilize the oscillation frequency, a separately excited flyback type switching power supply device including an oscillation circuit is also used to stabilize the oscillation frequency. .

  In addition, some flyback type switching power supply devices are provided with a remote terminal. Operation is started by supplying a remote-on signal to the remote terminal from the outside, and operation is performed by supplying a remote-off signal. Remote control to stop is possible.

  When an input power supply voltage is applied in a state where a remote-on signal is input, a flyback type switching power supply device turns on an inverter element such as a MOS-FET by supplying a startup current from the startup circuit to the drive circuit. When the primary current flows through the primary winding of the output transformer when it is turned on and energy is stored in the output transformer. When the primary current stops flowing through the primary winding when the inverter element is turned off, the stored energy of the output transformer releases 2 The flyback voltage generated in the next winding is rectified and smoothed to increase the output voltage. When the output voltage reaches a predetermined set voltage, the inverter element is switched to the OFF state in synchronization with the arrival of the primary current to the predetermined upper limit value so that the output voltage is kept constant, and the flyback voltage The inverter element is switched to the on state in synchronization with the end.

  When a remote-off signal is input during operation of such a flyback type switching power supply device, the switch element for remote control is turned on to draw the starting current and the drive current of the inverter element, and the inverter element is fixed off. To stop driving.

Japanese Patent Laid-Open No. 2011-087370 JP 2010-273431 A

  However, in such a conventional flyback type switching power supply with a remote terminal, even when the operation is stopped by the input of a remote off signal, it is activated through the remote control switch element that is turned on. The starting current and the drive current from the inverter element drive circuit continuously flow from the circuit, causing power loss.

  In particular, in facilities and equipment that use a large number of flyback switching power supply units housed in a casing, it is strongly required to reduce power consumption in a standby state or a shutdown state. Conventionally, the power consumption accompanying the stoppage of the switching power supply device has been a factor for raising the overall power consumption, and an improvement in this point is desired.

An object of the present invention is to provide a flyback type switching power supply apparatus that can substantially contribute to reduction of power consumption by substantially reducing power consumption in an operation stop state by inputting a remote off signal.

(Flyback switching power supply)
The present invention
The flyback method is used to obtain a DC output by turning on and off the current of the primary winding of the output transformer by driving the inverter element by the drive unit and rectifying and smoothing the flyback voltage induced in the secondary winding of the output transformer. In switching power supply,
A startup unit that turns on the inverter element by supplying a startup current to the drive unit when a DC input voltage is applied;
When a remote off signal is input to the remote input unit, the drive current of the inverter element is drawn and the start-up current of the start-up part is drawn, and then the start-up part is stopped and the inverter element is fixed in the off state, and the operation is stopped. When a remote on signal is input to the remote input unit in the operation stop state, a remote control unit that releases the start-up current and drive current and operates the start-up unit to resume operation,
It is provided with.

The present invention also provides:
An output transformer comprising a primary winding, a secondary winding and a feedback winding;
An inverter element that periodically turns on and off the primary current flowing through the primary winding;
Energy is stored in the output transformer while the primary current is flowing through the primary winding when the inverter element is turned on, and storage of the output transformer is performed while the primary current is not flowing through the primary winding when the inverter element is turned off. A rectifying / smoothing unit that rectifies and smoothes the flyback voltage generated in the secondary winding due to the release of energy;
Based on the current flowing through the feedback winding, the inverter element is switched to the OFF state in synchronization with the primary current reaching a predetermined upper limit value, and the inverter element is turned on in synchronization with the end of the flyback voltage. A drive to switch to a state;
In a self-excited flyback switching power supply with
A remote input unit for inputting a remote on signal for instructing operation remotely and a remote off signal for instructing operation stop;
A starting unit that supplies a starting current to the drive unit to turn on the inverter element when a DC input voltage is applied;
When a remote off signal is input to the remote input unit, the driving current of the driving unit is drawn and the starting current of the starting unit is drawn, and then the starting unit is stopped and the inverter element is fixed in the off state to stop the operation. When a remote on signal is input to the remote input unit in the operation stop state, a remote control unit that releases the start-up current and drive current and operates the start-up unit to resume operation,
It is provided with.

(Constant current type starter and remote off)
The starter is a constant current circuit that turns on the control element with a constant bias voltage by a Zener diode and supplies a predetermined constant current to the driver as a starter current,
The remote control unit
A charge / discharge circuit in which a capacitor and a resistor are connected in series;
A switch circuit connected to the constant current circuit and the drive unit and controlled by a bias voltage generated in the resistor;
With
Connect the remote input to the charge / discharge circuit in parallel,
When a remote off signal is input, the short circuit at both ends of the charge / discharge circuit is released to start charging the capacitor via the Zener diode, and the switch circuit is turned on with the bias voltage due to the charging current flowing through the resistor and the on state is turned on. The constant current circuit is maintained by drawing the starting current of the constant current circuit and the driving current of the driving unit to stop the operation of the inverter element, and further, the charging voltage of the capacitor is increased and the bias voltage of the Zener diode is decreased. Stop the operation.

(Constant current type starter and remote on)
The charge / discharge circuit further connects a diode in parallel with the resistor. When a remote-on signal is input, both ends of the charge / discharge circuit are shorted to release the stop of the constant current circuit, and at the same time, the capacitor is discharged via the diode. Then, the switch circuit that stops the operation of the inverter element is turned off to start the operation of the inverter element.

(Current mirror type starter and remote off)
The activation unit is a current mirror circuit that connects the control terminals of the control element and the output element to perform common bias, and supplies a predetermined constant current to the drive unit as the activation current.
The remote control unit
A charge / discharge circuit in which a capacitor and a resistor are connected in series;
A switch circuit connected to the current mirror circuit and the drive unit and controlled by a bias voltage generated in the resistor;
With
Connect the remote input to the charge / discharge circuit in parallel,
When a remote-off signal is input, the short circuit at both ends of the charge / discharge circuit is released to start charging the capacitor via the control element of the current mirror circuit, and the switch circuit section is turned on with a bias voltage due to the charging current flowing through the resistor. At the same time, the on-state is maintained and the start-up current of the current mirror circuit and the drive current of the drive unit are drawn to stop the operation of the inverter element. Further, when the capacitor is fully charged, the current mirror circuit is controlled by the charge completion voltage. The operation of the current mirror circuit is stopped by the reverse bias of the element.

(Current mirror type starter and remote on)
The charge / discharge circuit further connects a diode in parallel with the resistor. When a remote-on signal is input, both ends of the charge / discharge circuit are short-circuited and discharged from the capacitor via the diode, stopping the operation of the inverter element. The switch circuit is turned off to start the operation of the inverter element.

  According to the flyback type switching power supply device of the present invention, when a remote off signal is input to the remote input unit, the drive unit draws the drive current and draws the start-up current of the start-up unit, and then stops the start-up unit. Since the inverter element is fixed in the off state and the operation is stopped, in the operation stop state based on the remote off, the start unit stops and the start current does not flow, and the inverter element and its drive unit also stop and drive. Current does not flow, power consumption in the operation stop state is made substantially zero, and power consumption in the standby state accompanied by operation stop of equipment or equipment using a plurality of self-excited flyback type switching power supplies is reduced. Can make a significant contribution to energy conservation. Here, the fact that the power consumption is substantially zero means that the power consumption excluding a negligible power consumption due to a leakage current in each circuit unit becomes zero.

In addition, when a remote-on signal is input to the remote input unit while the operation of the flyback switching power supply is stopped, the remote control unit cancels the start-up current and drive current draw state and operates the start-up unit for operation. Therefore, the operation can be surely resumed from the stop state in which the power consumption is zero.

The circuit diagram which showed 1st Embodiment of the switching power supply of the self-excitation flyback system by this invention which operate | moves by the input of a remote ON signal 1 is a circuit diagram showing the self-excited flyback switching power supply apparatus of FIG. Time chart showing operation and current waveform when shifting to shutdown in FIG. Circuit diagram showing a second embodiment of the present invention in which a current mirror circuit is provided in the starter A circuit diagram showing a third embodiment of the present invention corresponding to the case where the logic of the remote on signal and the remote off signal is inverted with respect to FIG.

[Configuration of switching power supply unit]
FIG. 1 is a circuit diagram showing a first embodiment of a self-excited flyback switching power supply operating according to the present invention operating in a remote-on signal input state.

  As shown in FIG. 1, the switching power supply according to the present embodiment includes an output transformer 10, an inverter element (switching element) 12 using a MOS-FET, a rectifying / smoothing unit 14, a driving unit 16, a control unit 18, and an activation unit 20. The remote input unit 22 and the remote control unit 24 are configured.

  The output transformer 10 includes a primary winding 10a, a secondary winding 10b, and a feedback winding 10c.

  The inverter element 12 is connected in series with the output transformer 10 between the input terminals 1a and 1b, and periodically turns on and off the primary current flowing through the primary winding 10a. When the inverter element 12 is turned on, energy is accumulated in the output transformer 10 while the primary current is flowing in the primary winding 10a of the output transformer 10, and the inverter element 12 is turned off and the primary winding 10a is turned off. While the primary current stops flowing, a flyback voltage is generated in the secondary winding 10b due to the release of energy stored in the output transformer 10. This flyback voltage is also generated in the feedback winding 10c.

  The rectifying / smoothing unit 14 includes a rectifying diode 42 and a smoothing capacitor 44. The rectifying / smoothing unit 14 rectifies and smoothes the flyback voltage generated in the secondary winding of the output transformer 10 when the inverter element 12 is turned off, and outputs the output terminals 2a and 2b. To output a predetermined DC voltage stabilized.

  The drive unit 16 of the inverter element 12 includes an NPN transistor 36, resistors 30, 37, and 38, capacitors 32 and 40, a diode 33, a light receiving unit 34b that receives light from the light emitting unit 34a of the control unit 18, and an overcurrent. A protection operation correction circuit unit 35 is provided.

  A feedback resistor 32 and a feedback resistor 30 are connected in series between one end of the feedback winding 10c and the gate G of the inverter element 12, and a diode 33 and a photocoupler are connected between the feedback winding 10c and the resistor 30. It is connected to the base of the transistor 36 through the light receiving part 34b. Further, an overcurrent protection operation correction unit 35 is connected in parallel with the series circuit of the light receiving unit 34b of the diode 33 and the photocoupler.

  The overcurrent protection operation correction unit 35 functions as a circuit unit that corrects the overcurrent operation value because the overcurrent operation value varies greatly depending on the input voltage and also controls the drooping characteristics.

  The capacitor 32 is charged by the starting current from the starting unit 20 at the time of starting, and turns on the inverter element 12 with a bias due to the charging voltage. The capacitor 32 is charged by the flyback voltage generated in the feedback winding 10c when the inverter element 12 is turned off.

  The source S of the inverter element 12 and the resistor 38 connected to the inverter element 12 are connected to the base of the transistor 36 via the capacitor 40, and the resistor 37 is further connected between the gate G and the source S (or ground) of the switching element 12. Connected. Note that the resistor 38 may have a sufficiently low value or zero ohms.

  The transistor 36 controls the inverter element 12 to be turned off. The transistor 36 receives, via the capacitor 40, a voltage generated in the resistor 38 due to the primary current that flows when the inverter element 12 is turned on at the time of startup accompanying application of a predetermined rated DC input voltage between the input terminals 1a and 1b. When the primary current reaches a predetermined maximum value, it is turned on by increasing the base current, the gate-source voltage Vgs of the inverter element 12 is turned off by pulling it below the threshold voltage Vth, and switching of the inverter element 12 is performed. The output voltage is repeatedly raised toward a predetermined voltage.

  When the output voltage of the rectifying / smoothing unit 14 reaches a predetermined voltage and exceeds the predetermined voltage, the control unit 18 detects that the output voltage exceeds the predetermined reference voltage, and drives the light emitting unit 34a of the photocoupler to emit light. Then, the light receiving unit 34b is turned on. For this reason, an induced voltage generated in the feedback winding 10c causes a base current to flow through the transistor 36 via the light receiving portion 34b, turning it on, and turning the inverter element 12 off. For this reason, the timing at which the inverter element 12 is turned off is earlier than when the light receiving unit 34b is turned off, so that the output voltage is lowered to a predetermined voltage and stabilized.

  The starting unit 20 includes a PNP transistor 25, a Zener diode 26, and resistors 27 and 28. When the predetermined rated DC input voltage is applied between the input terminals 1a and 1b, the starting unit 20 is fixed by turning on the Zener diode 26. The transistor 25 is turned on by the bias voltage, and a predetermined constant current is caused to flow as a starting current to the drive unit 16, the gate-source voltage Vgs of the inverter element 12 is set to be equal to or higher than the threshold voltage Vth, and the inverter element 12 is turned on. The resistor 28 is provided to limit the current after startup.

  The remote input unit 22 inputs a remote on signal for instructing operation output from an external device and a remote off signal for instructing operation stop. The remote on signal is a low level signal that pulls the distance between the remote input terminals 1c and 1b below the threshold. In FIG. 1, the remote on signal 22a is shown in a state where the switch is closed. The remote off signal is a high level signal for pulling up between the remote input terminals 1c and 1b so as to exceed the threshold, and in FIG. ing.

  The remote control unit 24 includes a capacitor 46, resistors 48 and 58, a diode 50, an NPN transistor 52, and a PNP transistor 54. For the capacitor 46, a parallel circuit of a resistor 48 and a diode 50 is connected in series to form a charge / discharge circuit. The capacitor 46 side of the charging / discharging circuit is connected to the resistor 28 of the starting unit 20, and the remote input unit 22 is connected to both ends of the charging / discharging circuit.

  The transistors 52 and 54 constitute a switch circuit, and each collector is connected to the base of the other party in a positive feedback manner. When the transistor 52 is turned on, the transistor 54 is also turned on, and a switch equivalent to a thyristor that maintains the on state. Perform the action.

  When the remote input unit 22 is in the illustrated remote on 22a (low level signal input state), both ends of the charge / discharge circuit are short-circuited, the capacitor 46 is not charged, and the switch circuits of the transistors 52 and 54 are turned off. ing.

  When the remote input unit 22 is opened in a remote off state (high level signal input state), the charging current is supplied to the capacitor 46 through a path that passes through the Zener diode 26, the resistor 28, the capacitor 46, and the resistor 48 of the starting unit 20. The capacitor 46 is started to be charged, and the switch circuits of the transistors 52 and 54 are turned on and held by the bias voltage generated in the resistor 48, and the starting current of the starting unit 20 and the driving current of the driving unit 16 are drawn to be an inverter element. 12 is fixed in the off state. Further, when the charging of the capacitor 46 is completed, the Zener diode 26 of the starting unit 26 is turned off by a reverse bias due to the charging voltage, and the transistor 25 is fixed off.

  Next, the operation of the switching power supply according to the present embodiment will be described separately at the time of startup, at the time of remote off, and at the time of remote on.

[Startup behavior]
As shown in FIG. 1, a predetermined rated DC input voltage is applied between the input terminals 1 a and 1 b in a state in which the remote on 22 a is input by the remote on signal input to the remote input unit 22 (low level signal input state). Then, a starting operation for increasing the voltage toward a predetermined output voltage is performed.

  In this starting operation, by applying a rated DC input voltage between the input terminals 1a and 1b, the zener diode 26 of the starting unit 20 is turned on, a bias voltage is applied between the emitter and base of the transistor 25, and the transistor 25 is turned on. A starting current is passed through the drive unit 16. In this case, the capacitor 46 of the remote control unit 24 is not charged, and the transistors 52 and 54 are off.

  The starting current from the starting unit 20 flows to the feedback winding 10c via the capacitor 32 and the resistor 30 of the driving unit 16, charges the capacitor 32, and the gate-source voltage Vgs of the inverter element 12 by the charging voltage of the capacitor 32. Is raised to the threshold voltage Vth or higher, whereby the inverter element 12 is turned on, and a primary current is supplied to the primary winding 10b of the output transformer 10 to accumulate energy. When the inverter element 12 is turned on, the primary current increases linearly.

  The linearly increasing voltage generated in the resistor 38 by the primary current when the inverter element 12 is turned on is supplied to the transistor 36 via the capacitor 40, and the base current when the primary current reaches a predetermined maximum value is supplied. As the transistor 36 increases, the gate-source voltage Vsg is pulled below the threshold voltage Vth and the inverter element 12 is turned off.

  When the inverter element 12 is turned off, a flyback voltage (reverse induction voltage) is generated in the secondary winding 10b due to the discharge of the accumulated energy, which is rectified by the diode 42 of the rectifying and smoothing unit 14 and smoothed by the capacitor 44. Output. Further, the capacitor 32 is charged by the flyback voltage (reverse induction voltage) generated in the feedback winding 10c.

  When the energy release from the secondary winding 10b is completed and the flyback voltage disappears, the inverter element 12 generates a gate-source voltage Vgs by a voltage obtained by adding the voltage of the feedback winding 10c and the voltage charged in the capacitor 32. The output voltage rises toward a predetermined voltage by repeatedly switching the inverter element 12 in the same manner. The turning on of the inverter element 12 mainly depends on the voltage increase of the feedback winding 10c.

  When the output voltage reaches a predetermined voltage, when the output voltage exceeds the reference voltage by the control unit 18, the light emitting unit 34a of the photocoupler is driven to emit light and the light receiving unit 34b is turned on. For this reason, at an early timing before the primary current reaches a predetermined maximum value, the voltage is obtained by adding the voltage already charged in the capacitor 32 to the voltage of the feedback winding 10c via the diode 33 and the light receiving unit 34b. 36, the base current is supplied to turn on, the gate-source voltage Vgs of the inverter element 12 is pulled below the threshold voltage Vth, the inverter element 12 is turned off, the ON period of the inverter element 12 is shortened, and the output voltage is set to a predetermined voltage. The switching of the inverter element 12 is repeated so that the output voltage is maintained at a predetermined voltage.

[Switching to remote off]
FIG. 2 is a circuit diagram showing the switching power supply device of FIG. 1 shifted to operation stop by the input of a remote off signal, and FIG. 3 is a time chart showing the operation and current waveform when shifting to operation stop of FIG. . 3A is an input state of the remote control input unit 22, FIG. 3B is a current I1 flowing through the capacitor 46, FIG. 3C is a current I2 flowing through the starting unit 20, and FIG. 3D is an inverter. A switching waveform between the gate and the source of the element 12 is shown.

  In the operation state based on the remote-on 22a shown in FIG. 1, when a remote-off signal is input from the outside and the remote-on is switched to the remote-off as shown at time t1 in FIG. Thus, the remote input unit 22 becomes a remote-off 22b with an open contact, and the remote control unit 24 is released from the zener diode 26 and the resistor 28 of the starter circuit 20 by releasing the short-circuit state at both ends with respect to the charge / discharge circuit of the remote control unit 24. The current I4 flows through a path passing through the capacitor 46 and the resistor 48, and charging of the capacitor 46 is started.

  Further, when the transistor 52 is turned on by the bias voltage generated by the current I4 flowing through the resistor 48, and the transistor 52 is turned on, the transistor 54 is turned on by the bias voltage generated by the current flowing through the resistor 58. The transistors 52 and 54 are kept on by the feedback.

  When the transistors 52 and 54 are turned on, the starting current I2 flowing from the transistor 25 of the starting unit 20 flows to the transistors 54 and 52, and the driving current I3 due to the voltage generated in the driving unit 16 flows to the transistors 54 and 52. The gate-source voltage Vgs of the inverter element 12 is forcibly pulled below the threshold voltage Vth, fixing the inverter element 12 to the OFF state and stopping the switching operation as shown in FIG. The driving operation stops.

  As shown in FIG. 3B, the current I1 flowing through the capacitor 46 that starts charging at time t1 decreases according to a predetermined time constant. When charging of the capacitor 46 is completed at time t2, the current I1 flows across the Zener diode 58. The applied voltage is reduced by receiving a reverse bias corresponding to the increase in the charging voltage of the capacitor 46, the Zener diode 26 is turned off at time t2, the bias voltage of the transistor 25 is lost, and the transistor 25 is also turned off. As shown in C), the current I2 flowing from the starter 20 at time t2 is also stopped.

  As a result, in the operation stop state associated with switching to the remote off 22b, the operation of the inverter element 12, the starting unit 20 and the drive unit 16 is completely stopped and no current consumption flows, and the operation is stopped based on the remote off. The power consumption in the state can be made substantially zero. Further, during this operation stop period, the circuit constituted by the transistors 52 and 54 receives the charging voltage of the capacitor 46 and continues to be kept on. However, since the current consumption for this depends on the charging voltage of the capacitor 46, the input terminal Current consumption when viewed from the outside of 1a and 1b is zero.

[Switching to remote on]
In the operation stop state based on the remote off shown in FIG. 2, when a remote on signal is inputted from the outside and the remote off is switched to the remote off, the remote input unit 22 has the remote contact closed as shown in FIG. The switch 22 is turned on, and both ends of the charge / discharge circuit of the remote control unit 24 are short-circuited.

  For this reason, the charged capacitor 46 is rapidly discharged through the diode 50 and the remote on 22a path, and the charging voltage of the capacitor 46 disappears, so that the Zener diode 26 of the starter 20 is turned on and the transistor is turned on by a constant bias voltage. 25 is turned on and a starting current is supplied.

  As the capacitor 46 is discharged, the on states of the transistors 52 and 54 are also released and turned off. For this reason, the starting current from the starting unit 20 effectively flows to the driving unit 16 and is turned on by raising the gate-source voltage Vgs of the inverter element 12 to the threshold voltage Vth or more, and undergoes the starting operation in the same manner as described above. The operation shifts to an operation for maintaining the output voltage at a predetermined voltage.

[Second Embodiment]
FIG. 4 is a circuit diagram showing a second embodiment of the present invention in which a current mirror circuit is provided in the starting unit.

  As shown in FIG. 4, in this embodiment, the output transformer 10, the inverter element 12, the rectifying / smoothing unit 14, the drive unit 16, the control unit 18, the remote input unit 22, and the remote control unit 24 are the same as those in the first embodiment of FIG. Although the configuration is the same, the activation unit 20 is a current mirror circuit, and a constant voltage circuit 64 for overvoltage protection is newly provided.

  The starting unit 20 commonly connects the bases serving as control terminals of the PNP transistor 58 functioning as a control element and the PNP transistor 60 functioning as an output element, and a current limiting resistor is connected to the collector side of the transistor 58. 62 is connected to form a current mirror circuit.

  The current mirror circuit of the starting unit 20 causes a current I2 having the same value as the current I1 flowing through the transistor 58 to flow from the transistor 60 to the driving unit 16 as a starting current.

  Further, a constant voltage circuit unit 64 including a Zener diode 66 and a resistor 68 is provided between the starting unit 20 and the driving unit 16, and when an excessive DC input voltage is applied between the input terminals 1a and 1b, The voltage applied between the gate and the source of the inverter element 12 by the constant voltage circuit section 64 is suppressed to a constant voltage determined by the Zener diode 66 to protect the inverter element 12 and its driving section 16.

  The second embodiment in which a current mirror circuit is used for the starting unit 20 corresponds to the case where the rated DC input voltage applied to the input terminals 1a and 1b is low. That is, in the constant voltage circuit using the Zener diode 26 in the embodiment of FIG. 1, when the rated DC input voltage is low, it may be difficult to secure the Zener voltage and the operation may become impossible. When a current mirror circuit is used for the starting unit 20 of No. 4, this problem is eliminated, and even when the rated DC input voltage is low, it can operate reliably.

[Third Embodiment]
FIG. 5 is a circuit diagram showing a third embodiment of the present invention corresponding to the case where the logic of the remote on signal and the remote off signal is inverted with respect to FIG.

  As shown in FIG. 5, the output transformer 10, the inverter element 12, the rectifying / smoothing unit 14, the driving unit 16, the control unit 18, the starting unit 20, the remote input unit 22, and the remote control unit 24 are the same as those in the first embodiment of FIG. 1. However, a conversion circuit unit 70 that inverts the logic of the remote off signal and the remote on signal is provided between the remote input unit 22 and the remote control unit 24.

  In this embodiment, the remote-on signal for the remote input unit 22 is a high-level signal, which is shown as a remote-on 22a with the switch contact open, and the logic is reversed from that in FIG. Further, the remote off signal for the remote input unit 22 is a Low level signal, which is shown as a remote off 22b indicated by a dotted line with the switch contact closed, and similarly, the logic is reversed from that in FIG.

  The conversion circuit unit 70 includes a conversion element 72 using a MOS-FET, a resistor 74, and a Zener diode 76. The conversion element 72 can obtain the same operation even when other elements such as a transistor and an IGBT (insulated gate bipolar transistor) are used.

  When the remote input unit 22 becomes remote on 22a (high level signal input), the conversion element 72 is turned on by the high level signal input through the resistor 74, and the input to the remote control unit 24 is converted into a low level signal. Both ends of the discharge circuit are short-circuited to prohibit charging of the capacitor 46, and the transistors 52 and 54 are fixed off.

  On the other hand, when the remote input unit 22 becomes remote on 22b (low level signal input), the conversion element 72 is turned off by the input of the low level signal, and the input to the remote control unit 24 is converted into the high level signal, and the charge / discharge circuit The short circuit at both ends is released, charging of the capacitor 46 is started, the transistors 52 and 54 are turned on, and the on state is maintained, whereby the operation is stopped so that the power consumption is substantially zero. The remote-off 22b can be turned off by opening the remote-off 22b without being short-circuited to the ground as shown.

[Modification of the present invention]
(Separate excitation flyback method)
In the above embodiment, the self-excited flyback type switching power supply device was taken as an example, but the separately excited flyback type switching power supply device having an oscillation circuit and having a remote terminal However, similarly to the above-described embodiment, by providing the starter and the remote controller, it is possible to substantially reduce the power consumption during the operation stop by the remote off.

(Inverter element drive)
In the above embodiment, when the output voltage provided on the secondary side exceeds the reference voltage, the drive unit for switching driving the inverter element is transmitted to the primary side by a photocoupler to control the off timing of the inverter element. However, all the off timings of the inverter elements may be controlled by the primary side circuit unit based on the induced voltage generated in the feedback winding.

  Moreover, the drive part of the inverter element of said embodiment is an example, It is not limited to this, The starting part and remote control part of said embodiment are added to the appropriate flyback type switching power supply device provided with the remote terminal. By providing this, the power consumption during operation stop due to remote off can be made substantially zero.

(Transistor circuit part)
The circuit portion of the PNP transistor used in the above embodiment may be an NPN transistor circuit portion, and the NPN transistor circuit portion may be a PNP transistor circuit portion. good.

(Other)
The present invention includes appropriate modifications without impairing the object and advantages thereof, and is not limited by the numerical values shown in the above embodiments.

1a, 1b: Input terminal 1c: Remote terminal 2a, 2b: Output terminal 10: Output transformer 10a: Primary winding 10b: Secondary winding 10c: Feedback winding 12: Inverter element 14: Rectification smoothing unit 16: Drive unit 18: Control unit 20: Start unit 22: Remote input unit 22a: Remote on input 22b: Remote off input 24: Remote control unit 25, 54: PNP transistors 26, 66, 76: Zener diodes 28, 30, 37, 38, 48, 58, 62, 68, 74: resistors 32, 40, 44, 46: capacitor 34a: light emitting unit 34b: light receiving unit 35: overcurrent protection operation correction circuit unit 36, 52, 58, 60: NPN transistors 42, 50 :diode

Claims (7)

A flyback system in which the current of the primary winding of the output transformer is turned on and off by driving the inverter element by the drive unit, and the flyback voltage induced in the secondary winding of the output transformer is rectified and smoothed to obtain a DC output. In the switching power supply of
A starting unit that, when a DC input voltage is applied, supplies a starting current to the driving unit to turn on the inverter element;
When a remote off signal is input to the remote input unit, the drive current of the inverter element is drawn and the starter current of the starter is drawn and then the starter is stopped to fix the inverter element in the off state. A remote control unit that stops operation and releases the start-up current and drive current and operates the start-up unit to resume operation when a remote-on signal is input to the remote input unit in the operation stop state; ,
A switching power supply of a flyback system characterized by comprising:
An output transformer comprising a primary winding, a secondary winding and a feedback winding;
An inverter element that periodically turns on and off the primary current flowing through the primary winding;
While the primary current flows through the primary winding by turning on the inverter element, energy is stored in the output transformer, and when the primary current does not flow through the primary winding by turning off the inverter element. A rectifying / smoothing unit that rectifies and smoothes the flyback voltage generated in the secondary winding by discharging the stored energy of the output transformer;
Based on the current flowing through the feedback winding, the inverter element is switched to the OFF state in synchronization with the primary current reaching a predetermined upper limit value, and the inverter element is synchronized with the end of the flyback voltage. A drive unit for switching
In a flyback type switching power supply with
A remote input unit for inputting a remote on signal for instructing operation remotely and a remote off signal for instructing operation stop;
A starting unit that supplies a starting current to the drive unit to turn on the inverter element when a DC input voltage is applied;
When a remote off signal is input to the remote input unit, the driving current of the driving unit is drawn and the starting current of the starting unit is drawn, and then the starting unit is stopped to fix the inverter element in an off state. A remote control unit that stops operation and releases the start-up current and drive current and operates the start-up unit to resume operation when a remote-on signal is input to the remote input unit in the operation stop state; ,
A switching power supply of a flyback system characterized by comprising:
In the flyback type switching power supply unit according to claim 1 or 2,
The constant current circuit unit is a constant current circuit that is turned on by a constant bias voltage by a Zener diode and supplies a predetermined constant current to the drive circuit unit as a starting current,
The remote control path is
Connected via a Zener diode of the constant current circuit, and short-circuited when the remote-on signal is input, and charged via the Zener diode by releasing the short-circuit when the remote-off signal is input Capacitor to be
A stop driving unit that is turned on by a bias due to a charging current of the capacitor and that self-maintains an on state, draws a starting current of the starting circuit unit, draws a driving current of the driving circuit unit, and stops the operation of the inverter element; ,
With
The flyback switching power supply device, wherein the capacitor turns off the constant current circuit by a reverse bias of the Zener diode according to a charging completion voltage when charging is completed to stop a starting current.
In the flyback type switching power supply unit according to claim 1 or 2,
The starting unit is a constant current circuit that turns on the control element with a constant bias voltage by a Zener diode and supplies a predetermined constant current as a starting current to the driving unit,
The remote control unit is
A charge / discharge circuit in which a capacitor and a resistor are connected in series;
A switch circuit connected to the constant current circuit and the drive unit and controlled by a bias voltage generated in the resistor;
With
The remote input unit is connected in parallel to the charge / discharge circuit,
When a remote-off signal is input, the short circuit at both ends of the charge / discharge circuit is released to start charging the capacitor via the Zener diode, and the switch circuit is turned on with a bias voltage due to a charging current flowing through the resistor. In addition, the on-state is maintained and the start-up current of the constant current circuit and the driving current of the driving unit are drawn to stop the operation of the inverter element. Further, the charging voltage of the capacitor rises to increase the bias of the Zener diode. A flyback type switching power supply device, wherein the operation of the constant current circuit is stopped when the voltage drops.
5. The flyback switching power supply device according to claim 4, wherein the charge / discharge circuit further connects a diode in parallel with the resistor and short-circuits both ends of the charge / discharge circuit when a remote-on signal is input. And simultaneously releasing the stop of the constant current circuit, discharging the capacitor through the diode, turning off the switch circuit that stops the operation of the inverter element, and starting the operation of the inverter element. A flyback switching power supply device characterized by
In the flyback type switching power supply unit according to claim 1 or 2,
The starting unit is a current mirror circuit that connects the control terminals of the control element and the output element to be commonly biased, and supplies a predetermined constant current to the driving unit as a starting current,
The remote control unit is
A charge / discharge circuit in which a capacitor and a resistor are connected in series;
A switch circuit connected to the current mirror circuit and the drive unit and controlled by a bias voltage generated in the resistor;
With
The remote input unit is connected in parallel to the charge / discharge circuit,
When a remote off signal is input, a short circuit between both ends of the charge / discharge circuit is released to start charging the capacitor via the control element of the current mirror circuit, and the bias voltage by the charging current flowing through the resistor is used as the bias voltage. Charging when the switch circuit unit is turned on and the on-state is maintained to draw the starting current of the current mirror circuit and the driving current of the driving unit to stop the operation of the inverter element, and further, the charging of the capacitor is completed A flyback type switching power supply apparatus, wherein the operation of the current mirror circuit is stopped by a reverse bias of a control element of the current mirror circuit by a completion voltage.
  7. The flyback switching power supply device according to claim 6, wherein the charge / discharge circuit further connects a diode in parallel with the resistor and short-circuits both ends of the charge / discharge circuit when a remote-on signal is input. And switching off the switch circuit that stops the operation of the inverter element from the capacitor via the diode, and starts the operation of the inverter element. .

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