JPH0713431Y2 - Power supply circuit - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION [Industrial field of application] The present invention relates to a power supply circuit of an electric device such as an electric razor using an inverter circuit.

[Prior Art] The power supply voltage of commercial AC power supplies currently used in countries around the world is within the range of 100V to 240V.

Therefore, conventionally, when the power supply voltage fluctuates within the above range, a constant voltage circuit 51 is connected to the commercial AC power supply 50 as shown in FIG. Then, after the power supply voltage is reduced to 100V by this constant voltage circuit 51, the inverter circuit is operated by this 100V voltage. The inverter circuit 52 is connected to the constant voltage circuit 51, and the output of this inverter circuit 52 Is
It is connected to a storage battery 55 via a rectifying diode 54 connected to the secondary side of the oscillation transformer 53.
The output end of 55 is connected to a drive circuit 57 of an electric device such as an electric razor via a first switch 56.

The inverter circuit 52 includes an oscillating transistor 58 and an oscillating transformer 53. The primary winding N ₁ of the oscillating transformer 53 is used as the collector winding of the oscillating transistor 58, and the secondary winding N ₂ Is the output winding of the inverter circuit 52, and
The secondary winding N ₃ is connected to the base circuit of the oscillation transistor 58 to form a feedback circuit for oscillation as the base winding.

The base of the oscillation transistor 58 has a base winding and a resistor.
A resistor 66 for base bias, a diode 67 and a resistor 68 are connected via 59, and a first resistor network consisting of resistors 60 and 61 is connected via a second switch 62.

The collector of the oscillation transistor 58 has an oscillation transformer.
A capacitor 64 and a resistor for absorbing spike voltage are connected in series with a diode 63 for preventing reverse current of the primary winding current of 53.
A parallel circuit with 65 is connected.

In such a configuration, when the storage battery 55 is charged, first, the switch 56 is turned off to open the drive circuit 57 from the secondary side of the oscillating transformer 53, and since the charging current may be a small current, the switch 62 is also turned off. To be

In this state, the power supply voltage of the commercial AC power supply 50 is reduced to 100 V by the constant voltage circuit 51 and applied to the inverter circuit 52.

When this voltage is applied, and on the oscillation transistor 58 is time t, the oscillation transformer 531 primary winding N _1, as shown in FIG. 6 (a), the collector current (oscillation transformer The primary current of 53) flows, and this current induces an electromotive force in the secondary winding of the oscillating transformer 53 and also induces a feedback voltage in the base winding N _3, which causes the base circuit to generate a base voltage. An electric current flows. When the base current flows, the collector current further increases. Due to such a positive feedback operation, the oscillation transistor 58 is rapidly saturated.

When the oscillation transistor 58 becomes saturated, the collector current stops flowing, so the secondary winding of the oscillation transformer 53
No electromotive force is induced in N ₂ , the feedback current to the base circuit disappears, and the collector current begins to decrease. When the collector current decreases, the base circuit becomes reverse biased, and the oscillation transistor 58 is turned off at time t ₂ .

In this way, the inverter circuit 52 oscillates, and the secondary winding N ₂ of the oscillating transformer 53 is turned off at the same time as the oscillating transistor 58 is turned off as shown in FIG. 6 (b). Secondary current flows through the secondary winding N ₂ of the transformer 53,
It flows until the next oscillation occurs at t ₃ . This secondary current is rectified by the rectifier diode 54 and charged in the storage battery 55.

At this time, since the switch 62 is off, the base current flows only on the side of the resistor 68, so that the base current is reduced and the oscillation transistor 58 is turned off for a long time. The charging current flowing to the next side is a small current. In this way, the inverter circuit 52 oscillates and the charging current is supplied to the secondary side of the oscillating transformer 53.

During AC operation, the switch 56 is first turned on to set the drive circuit 57 connected to the secondary side circuit of the oscillation transformer 53, and a large current is required.
Turn on 62 as well.

In this state, the drive circuit 57 is
Directly driven by the rectified output of 54, the electrical equipment operates in alternating current.

At this time, since the switch 62 is on, the base current of the oscillating transistor 58 is shunted to the resistor 68 and the resistor 60 so as to flow more, and the time for which the oscillating transistor 58 is turned on is lengthened. There is. That is, in this case, a large current flows through the secondary side of the oscillating transformer 53 of the inverter circuit 52.

[Problems to be solved by the invention] Due to such a configuration, even when the power supply voltage of the commercial AC power supply 50 is largely changed, such as when the power supply is used in a region of 100 V to 240 V, an oscillation transformer is used. In order to make the secondary current flowing through the secondary winding N ₂ of 53 constant, the voltage applied to the inverter circuit 52 must be stepped down to a constant voltage by the constant voltage circuit 51 before use.

Generally, the higher the input voltage of the inverter circuit 52, the shorter the time during which the oscillating transistor 58 is on, and the higher the oscillating frequency.
The secondary current flowing through the secondary winding N ₂ of the oscillating transformer 53 becomes large.

Therefore, when the secondary current of the inverter circuit 52 fluctuates, it causes deterioration of the storage battery 55 during charging, and also causes failure of the drive circuit 57 during AC operation of electric equipment.

Therefore, the constant voltage circuit 51 is indispensable in order to use the electric device even in areas where the power supply voltage of the commercial AC power supply is different. However, the constant voltage circuit 51 has a complicated structure, a large number of parts, a high cost, a large occupied area, and a large electric device.

In addition, in order to switch between charging and alternating current operation, a switch 56 for opening / closing the storage battery 55 and the drive circuit 57 and a switch 62 for switching the secondary current of the oscillation transformer 53 are independent of each other. Since the switch was used, the number of parts was increased, and there was a cost problem.

[Means for Solving Problems] A DC power supply circuit including a commercial AC power supply, a rectifier circuit connected to the commercial AC power supply, and a smoothing circuit connected to an output terminal of the rectifier circuit, and this DC power supply circuit An inverter circuit having an oscillating transistor and an oscillating transformer, which is connected to the output terminal of the control circuit, and a control circuit having a controlling transistor connected between the base and the emitter of the oscillating transistor of the inverter circuit to control the oscillating frequency. In the power supply circuit that reduces the power supply voltage of the commercial AC power supply by the inverter circuit and supplies the drive current to the drive circuit of the electric equipment and the charging current to the storage battery of the electric equipment, the oscillation circuit of the inverter circuit is used. The collector of is connected to one output end of the rectifier circuit via the primary winding of the oscillating transformer and The base of the oscillating transistor is connected to the base winding of the oscillating transformer, the resistor connected to the output terminal of the rectifier circuit through the resistor, the voltage dividing point of the circuit network consisting of the diode and the capacitor, and the emitter of the oscillating transistor is connected. Is connected to the other output terminal of the rectifier circuit via the resistance of the second resistance network, the resistance and the capacitor connected in series to this resistance, and the base of the control transistor is connected via the resistance and the diode. The base of the oscillating transistor is connected to the collector of the controlling transistor through a first resistance network consisting of a resistor and a diode, and a capacitor is connected between the base and the emitter of the controlling transistor, and the second A switch is connected between the voltage dividing point of the resistor network and the drive circuit connected to the secondary winding of the oscillation transformer and the storage battery. H is connected, and the switch switches between the drive circuit and the storage battery, and the parallel circuit of the resistor and the capacitor connected to the voltage dividing point of the second resistance network can be short-circuited by the switch.

[Operation] Since the present invention is configured as described above, the fluctuation of the oscillation frequency of the inverter circuit due to the change of the power supply voltage of the commercial AC power supply is controlled by the control transistor,
When the secondary current of the oscillating transistor of the inverter circuit is kept constant and the power supply voltage of the commercial AC power supply becomes high, the oscillation frequency of the inverter circuit becomes high, the collector current of the oscillating transistor increases, and the second resistance The voltage drop due to the network is large.

When the collector current exceeds the current value set in the second resistance network, the base current flows through the control transistor,
The control transistor is turned on.

When the control transistor is turned on, the base current of the oscillation transistor flows as a collector current of the control transistor, so that the oscillation transistor is turned off.

When the oscillating transistor is turned off, the collector current stops flowing, so that the secondary current flows in the secondary winding of the oscillating transformer and is supplied to the drive circuit.

Next, at the same time as the energy of the primary winding of the oscillating transformer disappears, the base current of the oscillating transistor flows, the oscillating transistor turns on, and the next oscillation starts.

In this way, the fluctuation of the oscillation frequency of the inverter circuit is controlled by the control transistor to keep the secondary current of the oscillation transistor of the inverter circuit constant.

During AC operation, the switch is turned on, and the parallel circuit of the capacitor and the resistor of the second resistance network connected to the emitter circuit of the oscillation transistor is short-circuited.

Here, when the DC output of the rectifier circuit is applied to the inverter circuit, the oscillating transistor is turned on, and a large current is supplied to the drive circuit by the above operation.

At the time of charging, the switch is turned off and the parallel circuit of the capacitor and the resistor of the second resistance network is connected to the emitter circuit of the oscillation transistor. Therefore, as described above, when the oscillating transistor is turned off, at the second voltage dividing point, since the capacitor is charged in the direction in which the emitter side becomes +, this charge operates as a reverse bias, so After the charge is discharged through the resistor, the oscillation transistor turns on.

In this way, the next oscillation of the oscillation transistor is delayed for the time determined by the time constant of the parallel circuit of the capacitor and the resistor, and the oscillation frequency of the inverter circuit becomes low,
The charging current is a small current.

[Embodiment of the Invention] An embodiment of the invention will be described in detail with reference to FIGS. 1 to 4.

Compared to the conventional one shown in FIG. 5, without using the constant voltage circuit 51, the control circuit 8 is connected between the base and emitter of the oscillation transistor 7 of the inverter circuit 6, and at the time of charging and AC operation. The feature of this invention is that the switching between and is performed by one switch.

As shown in FIG. 1, a full-wave rectifier circuit 2 is connected to a commercial AC power source 1 whose power supply voltage changes in the range of 100V to 240V, and a choke coil 3 is connected to the output terminal of this full-wave rectifier circuit 2. And a smoothing capacitor 4 is connected to form a DC power supply circuit 5.

A blocking oscillator type inverter circuit 6 is connected to the output end of the DC power supply circuit 5, that is, both ends of the smoothing capacitor 4, and the oscillation frequency is provided between the base and emitter of the oscillation transistor 7 of the inverter circuit 6. A control circuit 8 for controlling the is connected.

The inverter circuit 6 includes a series circuit of a resistor 9, a resistor 10 and a diode 11, a capacitor 12 connected in parallel to a series circuit of the resistor 10 and the diode 11, an NPN type oscillation transistor 7, an oscillation transformer 13 And an oscillation transistor 7
It is composed of a diode 16 connected to the collector of, a parallel circuit of a resistor 14 and a capacitor 15 connected in series, and a base resistor 17 of the oscillation transistor 7.

The oscillating transformer 13 is magnetically coupled to each other 3
It is composed of individual windings N ₁ , N ₂ , N ₃ , and the first primary winding N ₁ is a collector winding, and the collector of the oscillation transistor 7 and one output of the rectifier circuit 2 The secondary winding N ₂ is connected to the end of the inverter circuit 6
The primary winding N _{3 of the above} is used as a base winding of the oscillation transistor 7 and is used as an oscillation feedback winding of the inverter circuit 6.

The series circuit of the resistor 9, the resistor 10 and the diode 11 is connected in parallel to the smoothing capacitor 4, and the + terminal of the smoothing capacitor 4 is connected in parallel to the parallel circuit of the resistor 14 and the capacitor 15 with the diode 16 connected in series. Connected to the collector of the oscillating transistor 7 via the serial-parallel circuit, and further connected to the collector of the oscillating transistor 7 via the first primary winding N ₁ of the oscillating transformer 13. .

The base of the oscillating transistor 7 is the second primary winding N ₃
(Base winding), resistance 9 and resistance 10 via base resistance 17
It is connected to the partial pressure point of and.

The control circuit 8 includes a control transistor 18, a first resistance network composed of a series circuit of a resistor 19 and a diode 20, and a resistor.
21, a second resistor circuit network including a resistor 22, a resistor 23, and a diode 24.

The collector of the control transistor 18 is connected to the base of the oscillation transistor 7 via the first resistance network, and the base of the control transistor 18 is the diode 24, the resistance 23 (the resistance 21) of the second resistance network. Is connected to the emitter of the oscillation transistor 7 via a first voltage dividing point between the resistor 23 and the resistor 23, and is also connected to the negative terminal of the smoothing capacitor 4 via the resistors 21 and 22. A second voltage dividing point between the resistor 21 and the resistor 22 is connected to one end of a capacitor 25 connected in parallel with the resistor 22, and a movable contact 28a of a switch 28 for switching between charging and AC operation. It is connected.

2 of the oscillating transformer 13 which is the output terminal of the inverter circuit 6
The secondary winding N ₂ is connected to a storage battery 27 incorporated in an electric device via a rectifying diode 26, and
A drive circuit 29 of an electric device is connected to the storage battery 27 via a switch 28 (fixed contact 28b, fixed contact 28c of the switch 28).

The capacitor 30 delays the time when the oscillation transistor 7 is turned off by the control transistor 18, and is a resistor.
The control transistor 18 is turned on with a time constant determined by the values of the capacitor 23 and the capacitor 30.

Next, the operation will be described with reference to FIGS.

A description will be given of an AC operation in which an electric device such as an electric razor is directly activated by the commercial AC power supply 1 and a large current is required, and a charging time in which the storage battery 27 is charged with a small current.

2 and 3 show the AC operation and the charging, respectively, when the power supply voltage is 240 V. (a) shows the oscillation transformer 13
Primary current (collector current of the oscillating transistor 7),
(B) shows the secondary current of the oscillating transformer 13.

First, during AC operation, electrical equipment is directly connected to commercial AC power supply 1
When the switch 28 is turned on at the time t ₁ while being connected to, the parallel circuit of the capacitor 25 and the resistor 22 is short-circuited from the emitter circuit of the oscillation transistor 7.

Then, the AC output of the commercial AC power supply 1 becomes the full-wave rectification circuit 2
Is full-wave rectified by the choke coil 3, smoothed by the smoothing capacitor 4, and at the output end of the smoothing capacitor 4,
DC output is obtained. This DC output is the inverter circuit 6
As shown in FIG. 2 (a), the oscillation transistor 7 is turned on at time t ₁ and the primary side winding N ₁ of the oscillation transformer 13 receives the collector from time t ₁ onward. A current starts to flow, and this collector current is fed back to the negative terminal side of the smoothing capacitor 4 via the resistor 21.

A series-parallel circuit including a diode 16, a capacitor 15, and a resistor 14 connected in parallel to the primary winding N _{1 at} the collector of the oscillating transistor 7 is for preventing the reverse flow of the primary current of the oscillating transformer 13. The collector current is blocked by the diode 16 and flows through the primary winding N ₁ .

When a collector current flows in the primary winding N ₁ , an electromotive force is generated in the direction of arrow A, and in the secondary winding N ₂ , an electromotive force in the opposite direction shown by arrow B is induced. Power is a rectifier diode
Since it has a reverse potential with respect to 26, no current flows in the secondary winding N ₂ .

In addition, since the collector current flows, an electromotive force is also induced in the base winding N ₃ (secondary-side winding N ₃ ) of the oscillation transformer 13 and positive feedback is provided to the base. A base current flows through the transistor for use 7.

When the base current flows through the oscillating transistor 7, the collector current further increases. Thus, the positive feedback operation causes the oscillation transistor 7 to be rapidly saturated with a certain constant base current.

When the oscillation transistor 7 is saturated, the collector current does not flow so much, because the voltage drop of the oscillation transistor 7 becomes large, the current flowing through the primary winding N ₁ is reduced, base winding N ₃ The current flowing in the transistor also becomes small, and as shown in FIG. 2 (a), the oscillation transistor 7 is turned off at time t ₂ .

Here, the collector current value to be saturated is set by the resistor 21 and the resistor 23, and when the collector current exceeds this current value at time t ₂ , the control transistor 18 is passed through the resistor 23 and the diode 24. Base current flows and turns on.

When the control transistor 18 is turned on at time t ₂ , the collector of the control transistor 18 becomes the oscillation transistor 7
Since it is connected to the base of the
Since the base current flowing in the base of the transistor flows as a collector current of the control transistor 18 via the resistor 19 and the diode 20, the oscillation transistor 7 is turned off at time t ₂ .

Oscillating transistor 7 is turned off, the collector current does not flow, 1 to the primary winding N _1, electromotive force is generated in the direction of arrow A and the opposite direction, back electromotive also the secondary winding N ₂ Electricity is generated.

Due to this counter electromotive force, a large secondary current flows in the secondary winding N ₂ , as shown in FIG. 2 (b). Since this secondary current is in the forward direction with respect to the rectifying diode 26, the secondary current is rectified by the rectifying diode 26 and the drive current is supplied to the drive circuit 29.

In this way, when the energy stored in the primary winding N ₁ disappears at time t ₃ , the state returns to the original state, and the inverter circuit 6 starts the next oscillation, but at this time, the switch 28 Is on, the parallel circuit of the capacitor 25 and the resistor 22 is short-circuited.

Therefore, the energy of the primary winding N ₁ of the oscillating transformer 13 is lost, and at the same time, the base current of the oscillating transistor 7 is transferred to the base of the oscillating transistor 7 via the resistors 9, 17 and the base winding N _3. Immediately after that, the oscillation transistor 7 is turned on to start the next oscillation.

In this way, the inverter circuit 6 repeats oscillation, and the drive current is supplied to the drive circuit 29.

If the power supply voltage of the commercial AC power supply 1 changes, for example, if it changes from 240V to 100V, the input voltage of the inverter circuit 6, that is, the voltage across the smoothing capacitor 4 of the DC power supply circuit 5 is low. Therefore, Fig. 4 (a)
As shown in, the oscillation frequency of the inverter circuit 6 becomes low, the collector current of the oscillation transistor 7 decreases, and the voltage drop due to the resistor 21 becomes small, but the collector current becomes
When the current value set by the resistors 21 and 23 of the resistor network is reached, a base current flows through the resistor 23 and the diode 24 to the base of the control transistor 18, and the control transistor 18 turns on at time t ₂ .

When the control transistor 18 is turned on, as described above,
As shown in FIG. 4B, a large secondary current flows through the secondary winding N ₂ of the oscillating transformer 13, and the drive current is supplied to the drive circuit 29.

Next, the case of charging the storage battery 27 will be described.

The charging current may be lower during charging than during AC operation.

Therefore, when the switch 28 is set to the OFF state and connected to the commercial AC power supply 1, the
The secondary current flows through the secondary winding N ₂ , and the charging current is supplied to the storage battery 27. However, when the switch 28 is in the off state, the parallel circuit of the capacitor 25 and the resistor 22 is It is in a state of being connected to the emitter circuit of the oscillation transistor 7.

Therefore, when the oscillation transistor 7 is turned off at time t ₂ ,
At the second voltage dividing point, the capacitor 25 is indicated by a dotted line in Fig. 3 (a).
The potential of the capacitor 25 is
The emitter side is charged in the positive direction.

Therefore, when the oscillating transistor 7 is turned off, the energy stored in the primary winding N ₁ of the oscillating transformer 13 is stored in the secondary winding N ₂ as described above during the AC operation. When delivered, the oscillation transistor 7 turns on and the inverter circuit 6 starts the next oscillation.
Since electric charges are accumulated in the direction in which the emitter of the oscillating transistor 7 becomes + potential, this potential operates as a reverse bias.

Therefore, as shown in FIG. 3A, during the time t ₁ to the time t ₄ , after the electric charge of the capacitor 25 is completely discharged through the resistor 22 along the discharge curve shown by the dotted line, At time t ₄ , the oscillation transistor 7 turns on. Therefore, the next oscillation of the oscillation transistor 7 is delayed by the time determined by the time constant of the capacitor 25 and the resistor 22. Further, since the oscillation frequency of the inverter circuit 6 becomes lower, the secondary current of the oscillation transformer 13 becomes smaller accordingly, and the collector current of the oscillation transistor 7 becomes smaller than that in the case of the AC operation shown in FIG. Since the peak value is lowered due to the resistance 22, the time for turning off the oscillation transistor 7 is shortened accordingly.

Therefore, the control transistor 18 is turned on faster, the peak value of the secondary current of the oscillation transformer 13 is also reduced, and the charging current of the storage battery 27 is reduced.

In this way, the secondary current flowing in the secondary winding N ₂ is proportional to the time when the oscillation transistor 7 is on, so the current value when the control transistor 18 is turned on is
If it is set by the resistance value of the second resistance network consisting of the resistor 23 and the diode 24, and the collector current of the control transistor 18 is set by the resistance value of the first resistance network consisting of the resistor 19 and the diode 20, As shown in FIGS. 4 and 5, even when the power supply voltage changes from 100V to 240V, the secondary current flowing through the secondary winding N ₂ of the oscillation transformer 13 is almost constant.

In addition, switching between AC operation and charging is done with one switch 28
Is switched on and off.

[Advantages of the Invention] The invention is a DC power supply circuit including a commercial AC power supply, a rectifier circuit connected to the commercial AC power supply, and a smoothing circuit connected to an output end of the rectification circuit, and a DC power supply circuit of the DC power supply circuit. An inverter circuit connected to the output terminal and having an oscillating transistor and an oscillating transformer, and connected between the base and emitter of the oscillating transistor of the inverter circuit,
It is composed of a control circuit having a control transistor for controlling the oscillation frequency. The inverter circuit reduces the power supply voltage of the commercial AC power supply to supply the drive current to the drive circuit of the electric equipment and the charging current to the storage battery of the electric equipment. In the power supply circuit that supplies power, the collector of the oscillation transistor of the inverter circuit is connected to one output end of the rectifier circuit via the primary winding of the oscillation transformer, and the base of the oscillation transistor is The base winding of the transformer, the resistor connected to the output of the rectifier circuit through the resistor, the diode connected to the voltage dividing point of the network of capacitors, the emitter of the oscillation transistor, the resistance of the second resistor network And is connected to the other output terminal of the rectifier circuit through a parallel circuit of a resistor and a capacitor that are connected in series with this resistor. At the same time, the base of the control transistor is connected via a resistor and a diode, and the base of the oscillation transistor is
The collector of the control transistor is connected through a first resistance network consisting of a resistor and a diode, a capacitor is connected between the base and emitter of this control transistor, and the voltage dividing point of the second resistance network and oscillation A switch was connected between the drive circuit connected to the secondary winding of the transformer and the storage battery, and the drive circuit and the storage battery were switched by this switch, and the switch was connected to the voltage dividing point of the second resistance network. Since the parallel circuit of the resistor and the capacitor can be short-circuited by the switch, the fluctuation of the oscillation frequency of the inverter circuit due to the change of the power supply voltage of the commercial AC power supply is controlled by the control transistor, and Since the secondary current is constant, it is possible to cope with a wide range of changes in the power supply voltage with a simple circuit configuration, and at the same time, as in the past, There is no need to use a constant voltage circuit, it is possible to miniaturize the entire device.

In addition, during AC operation of electric equipment, the switch is turned on to short-circuit the parallel circuit of the capacitor and the resistor of the second resistance network connected to the emitter circuit of the oscillation transistor to oscillate the oscillation transistor. The frequency is increased to supply a large current to the drive circuit, and when the storage battery is charged, the switch is turned off, the parallel circuit is inserted into the emitter circuit of the oscillation transistor, and the oscillation frequency of the oscillation transistor is lowered to reduce the storage battery. The charging current of is small and
Since switching between charging and AC operation can be performed by the switch that opens and closes the storage battery and the drive circuit, the number of parts is reduced and the cost is reduced accordingly.

[Brief description of drawings]

1 to 4 show an embodiment of the present invention.
The figure shows the circuit diagram, and Fig. 2 shows the current waveform of the oscillating transformer 13 during AC operation when the power supply voltage is 240V.
Is the waveform diagram of the primary current, (b) is the waveform diagram of the secondary current, the third
The figure shows the oscillation transformer 13 during charging when the power supply voltage is 240V.
Shows the current waveform of (a) is a waveform diagram of the primary current,
(B) is a waveform diagram of the secondary current, FIG. 4 is a current waveform of the oscillating transformer 13 during AC operation when the power supply voltage is 100 V, (a) is a waveform diagram of the primary current, b) is a waveform diagram of the secondary current, and FIGS. 5 to 6 show conventional examples.
The figure shows the circuit diagram, and Fig. 6 shows the current waveform of the oscillating transformer 53 when the power supply voltage is 240V. (A) is the waveform diagram of the primary current, (b) is the waveform diagram of the secondary current. is there. 1 ... Commercial AC power supply 2 ... Rectifier circuit 5 ... DC power supply circuit 6 ... Inverter circuit 7 ... Oscillation transistor 8 ... Control circuit 13 ... Oscillation transformer 18 ... Control transistor 19 ... Resistor 20 ...... Diode 21 ...... Resistance 22 ...... Resistance 23 ...... Resistance 25 ...... Capacitor 27 ...... Battery 28 ...... Switch 29 ...... Driving circuit N ₁ ...... Primary winding N ₂ ...... Oscillation transformer 13 ...... Oscillation Side winding of transformer 13 for power supply N ₃ ... Base winding of transformer 13 for oscillation

Claims (1)

[Scope of utility model registration request] 1. A DC power supply circuit comprising a commercial AC power supply, a rectifier circuit connected to this commercial AC power supply, and a smoothing circuit connected to the output end of this rectifier circuit, and connected to the output end of this DC power supply circuit. An inverter circuit having an oscillating transistor and an oscillating transformer, and a control circuit having a controlling transistor connected between the base and the emitter of the oscillating transistor of the inverter circuit and controlling the oscillating frequency. In the power supply circuit for stepping down the power supply voltage of the commercial AC power supply by the inverter circuit to supply the drive current to the drive circuit of the electric device and supplying the charging current to the storage battery of the electric device, The collector of the transistor is connected to one output end of the rectifier circuit via the primary winding of the oscillation transformer. At the same time, the base of the oscillating transistor is connected to the voltage dividing point of the circuit network including the base winding of the oscillating transformer, the resistor connected to the output terminal of the rectifying circuit via the resistor, the diode and the capacitor. The emitter of the oscillating transistor is connected to the other output end of the rectifier circuit through a parallel circuit of the resistor of the second resistor network, the resistor serially connected to the resistor, and the capacitor, and The base of the control transistor is connected through a resistor and a diode, and the collector of the control transistor is connected to the base of the oscillation transistor through a first resistance network consisting of a resistor and a diode. A capacitor is connected between the base and emitter of the transistor for use, and the voltage dividing point of the second resistance network and the A switch is connected between the drive circuit and the storage battery connected to the secondary winding of the vibration transformer, and the drive circuit and the storage battery are switched by this switch, and the switch of the second resistance circuit network is connected. A power supply circuit characterized in that a parallel circuit of the resistor and the capacitor connected to a voltage dividing point can be short-circuited by the switch.