JP2000116124A - Power circuit - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a power circuit which is so structured as to keep the output voltage constant by indirectly detecting the voltage at the secondary side insulated from the primary side and thereby can output constant output voltage. SOLUTION: This power circuit 1 has a surge detection circuit 70. The surge detection circuit 70 detects the voltage including surge voltage induced between terminals (c) and (d) of a voltage detection winding 42 and then outputs the detected voltage to a voltage control section 6. When the voltage control section 6 is input with larger voltage from the surge detection circuit 70, it increases the energy to be transmitted to a secondary winding 43. Therefore, if an energy loss is generated due to surge voltage in a secondary-side rectifier circuit 3, energy transmitted to the secondary winding 43 is increased to compensate for the energy loss and increase the voltage induced between terminals (f) and (g) of the secondary winding 43 to prevent the decline in the output voltage. Thereby, constant output voltage can be obtained.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a power supply circuit, and more particularly to a power supply circuit configured to maintain a constant output voltage by indirectly detecting a voltage on a secondary side insulated from a primary side. About improvement.

[0002]

2. Description of the Related Art A power supply is an indispensable circuit for an electronic device. The power supply is installed independently of the electronic device as a power supply device, is incorporated in the electronic device, or is partially connected to another circuit on a printed circuit board. A variety of installation methods can be selected according to the amount of power to be supplied, such as being provided in a coexistent state.

[0003] Reference numeral 101 in FIG.
A power supply circuit for reducing a DC voltage of about 72 V to generate a DC voltage of 2.5 V;
2, the secondary-side rectifier circuit 103, the transformer 104, and P
It has a WM control circuit 105 and a voltage control unit 106.

The transformer 104 has a primary winding 141, a secondary winding 143, and a gate drive winding 144.
The primary-side current supply circuit 102 includes a smoothing circuit 111, a snubber circuit 112, and a switch transistor 113 including an n-channel MOS transistor.

The drain of the switch transistor 113 is connected to one terminal B of the primary winding 141, the source is connected to one input terminal 162 via the smoothing circuit 111, and the other terminal A of the primary winding 141 is connected. Is connected to the other input terminal 161 via the snubber circuit 112 and the smoothing circuit 111.
It is connected to the. When a DC voltage is applied between the input terminals 161 and 162 and the switch transistor 113 is turned on, a current can be supplied to the primary winding 141.

A PWM control circuit 105 is connected to the gate of the switch transistor 113, and outputs a rectangular wave signal to the gate to switch the switch transistor 1
13 can be controlled, and by adjusting the ratio of the time during which the switch transistor 113 is on (hereinafter referred to as the on-time) to the time during which the switch transistor 113 is off (hereinafter referred to as the off-time). , Switch transistor 11
3 can be adjusted.

[0007] The primary winding 141 and the secondary winding 143 of the transformer 104 are insulated but magnetically coupled.
An electric current flows through the primary winding 141 and the electromotive force is generated in the primary winding 141.
, An induced electromotive force can be induced in the secondary winding 143.

At this time, when an electromotive force is generated in the primary winding 141 and a positive voltage is generated at one terminal A of the primary winding 141 and a negative voltage is generated at the other terminal B, the secondary winding 141 A positive voltage is generated at one terminal G on the ground potential side of the line 143, and a negative voltage is generated at the other terminal F, respectively.

The secondary-side rectifier circuit 103 has an n-channel MO
It has a rectifying transistor 121 composed of an S transistor, a snubber circuit 122, and a smoothing circuit 123. The source of the rectifier transistor 121 is connected to one terminal F of the secondary winding 143, the drain is connected to the output terminal 163 via the smoothing circuit 123, and the other terminal G of the secondary winding 143 is connected to the smoothing circuit. Output terminal 164 via 123
It is connected to the. Then, the terminal F of the secondary winding 143,
When a voltage is generated between G and the rectifying transistor 121 is turned on, a current can be supplied to a load (not shown) via the output terminals 163 and 164.

The operation of the power supply circuit 101 for outputting a constant DC voltage to a load will be described below. A DC voltage of about 36 to 72 V is applied between the input terminals 161 and 162 in advance.
Is charged by a very small current that flows when the power is turned on, and a potential difference is generated between both electrodes of the capacitor 124.

When the switch transistor 113 is turned on after the switch transistor 113 is turned off, a current flows through the primary winding 141, an electromotive force is generated in the primary winding 141, and an induced electromotive force is generated in the secondary winding 143. Induced.

At this time, positive and negative voltages are generated at the terminals A and B of the primary winding 141, respectively. Line 1
A negative voltage is generated at the terminal F of 43, and the source of the rectifying transistor 121 connected to the terminal F is
A voltage lower than that of the terminal G is applied.

On the other hand, the drain of the rectifying transistor 121 is connected to the terminal G via a capacitor 124 in the smoothing circuit 123, and a potential difference is generated between the drain G and the terminal G. Becomes higher than the potential of the terminal G.

Then, since the potential of the drain of the rectification transistor 121 becomes higher than the potential of the source, a forward bias is applied to the rectification transistor 121, but the potential of the terminal E which defines the gate potential of the rectification transistor 121 is obtained. Becomes lower than the potential of the terminal F that defines the source potential of the rectifying transistor 121, and the rectifying transistor 121 is off.

Therefore, no current flows from the secondary winding 143 to the output terminal 163 via the rectifying transistor 121,
Discharge is performed from the capacitor 124 in the smoothing circuit 123, and a discharge voltage is output from the output terminals 163 and 164 to the load.

Thereafter, when the switch transistor 113 which has been in the on state is switched to the off state, the primary winding 141
, An electromotive force having a polarity opposite to that generated when the switch transistor 113 was turned on is generated, and the switch transistor 113 is turned on in each of the secondary winding 143 and the gate drive winding 144. A voltage of the opposite polarity to that when the voltage is generated.

Then, a reverse bias is applied to the rectifier transistor 121 when the switch transistor 113 is on, and the parasitic diode inside the rectifier transistor 121 is forward biased. On the other hand, the potential of the terminal E that defines the potential of the gate of the rectifier transistor 121 is higher than the potential of the terminal F of the gate drive winding 144 that defines the potential of the source of the rectifier transistor 121. Therefore, at this time, a positive voltage is applied to the gate, the rectifier transistor 121 can be turned on in the reverse direction, the rectifier transistor 121 operates in a so-called third quadrant, no current flows through the parasitic diode, and the diode is rectified. A current can flow with a smaller voltage drop than when used as an element.

When the rectifier transistor 121 is turned on in the reverse direction, a current flows from the secondary winding 143 to the smoothing circuit 123 via the rectifying transistor 121,
3 while charging the capacitors in the output terminals 163, 1
Power is supplied from 64 to the load.

As described above, the switch transistor 113
Is repeatedly switched between an on state and an off state, and charging and discharging of the smoothing circuit 123 are repeated, so that the output terminal 16
3, 164 to the load.

In the above-described power supply circuit 101, the output voltage on the secondary side is indirectly detected on the primary side insulated from the secondary side, and the ON state of the switch transistor 113 is set so that the output voltage becomes constant. The primary-side current supply circuit 102 has a voltage detection winding 142 and a voltage detection unit 114, so that the PW
It has a voltage control unit 106 connected to the M control circuit 105.

The voltage detection winding 142 is disposed so as to be magnetically coupled to the primary winding 141 and the secondary winding 143, so that an induced electromotive force is generated in the secondary winding 143, and the voltage detection winding 142 is also provided. An induced electromotive force is generated, and a voltage having a magnitude corresponding to the voltage induced in the secondary winding 143 is applied between terminals C and D of the voltage detection winding 142 magnetically coupled to the secondary winding 143. Has been to happen.

At this time, one terminal G of the secondary winding 143
When a positive voltage is generated at the other terminal F and a negative voltage is generated at the other terminal F, a positive voltage is applied to one terminal D on the ground potential side of the voltage detection winding 142, and a negative voltage is applied to the other terminal C. Are generated in each case.

The voltage detecting section 114 includes resistors 115 and 117
, Capacitors 116 and 118, and a diode 119, resistors 115 and 117, and a capacitor 11
6 and 118 constitute a low-pass filter, respectively. A low-pass filter in the preceding stage including a resistor 115 and a capacitor 116 is connected to terminals C and D of the voltage detection winding 142.

The output of the preceding low-pass filter is connected to the anode of a diode 119, and the cathode thereof is connected to the input of a subsequent low-pass filter consisting of a resistor 117 and a capacitor 118. The output of the low-pass filter at the subsequent stage is connected to the voltage control unit 106, and the voltage between the terminals C and D of the voltage detection winding 142 is removed by a low-pass filter at the previous stage to remove high-band components, and rectified by the diode 119. The voltage between the terminals C and D of the voltage detection winding 142 is rectified and smoothed by removing higher band components by a low-pass filter in the subsequent stage, and can be output to the voltage control unit 106.

The voltage control unit 106 includes an error amplifier 150
And resistors 151 to 154. Resistor 15
Reference numerals 1 and 152 are sequentially connected in series between a predetermined constant voltage Vref supplied from a circuit (not shown) and a ground potential. The connection point of the resistors 151 and 152 is
0 is connected to the inverting input terminal (-). On the other hand, the resistors 153 and 154 are connected in series between the output of the voltage detection unit 114 and the ground potential, and the connection point of the resistors 153 and 154 is connected to the non-inverting input terminal (+) of the error amplifier 150. ing.

A voltage (hereinafter, referred to as a detection voltage) obtained by dividing the DC voltage input from the voltage detection unit 114 by the resistance ratio of the resistors 153 and 154 is applied to a non-inverting input terminal (+ ). On the other hand, the inverting input terminal (-) of the error amplifier 150 has a constant voltage V due to the resistance ratio of the resistors 151 and 152 connected in series.
A voltage obtained by dividing ref (hereinafter referred to as a reference voltage) is input.

The error amplifier 150 controls the PWM control circuit 105 based on the detected voltage and the reference voltage. If the detected voltage is lower than the reference voltage, the error
The PWM control circuit 105 is controlled so that the ON time of the switching transistor 13 is increased and the ON time of the switch transistor 113 is reduced if the detected voltage is higher than the reference voltage.

If the on time is made longer than the off time,
The amount of current flowing through the primary winding 141 increases, and the primary winding 141
Is increased and transmitted to the secondary winding 143 and the voltage detection winding 142. Then, the amount of current flowing through the voltage detection winding 142 increases, the voltage between the terminals C and D of the voltage detection winding 142 increases, and the detection voltage increases.
Conversely, when the on-time is shorter than the off-time, the detection voltage decreases. The detection voltage operates so as to match the reference voltage.

When the detected voltage matches the reference voltage, the voltage between the terminals C and D of the voltage detecting winding 142 becomes constant. The ratio between the voltage between the terminals C and D of the voltage detection winding 142 and the voltage between the terminals F and G of the secondary winding 143 is expressed as follows:
Since the detection ratio is fixed to the reference voltage, the voltage between the terminals F and G of the secondary winding 143 has a constant value because the ratio is determined by the turns ratio between the voltage detection winding 43 and the voltage detection winding 142. In an ideal case, the voltage between the terminals F and G of the secondary winding 43 is equal to the output voltage, so that the output voltage also has a constant value.

Therefore, by setting the reference voltage appropriately in advance, a constant DC voltage can be obtained from the DC voltage input between the input terminals 161 and 162. here,
A DC voltage of 2.5 V can be obtained.

However, when the current flowing through the load is large, when the switch transistor 113 is turned off and the rectifier transistor 121 is turned on accordingly, the state shown in FIG.
As shown in (a), a spike-like surge voltage Δs caused by a parasitic capacitance and a parasitic inductance in the secondary rectifier circuit 103 is added to the voltage V ₁ between C and D of the voltage detection winding 142.
Occurs, and an energy loss occurs in the secondary-side rectifier circuit 103 in accordance with the magnitude of the surge voltage Δs.

On the other hand, the voltage detecting unit 114 is a voltage detecting winding 1
42 C, and smoothing the voltages V ₁ between D, as shown in FIG. 3 (b), to generate a voltage V ₂ surge voltage Δs is removed, the voltage control unit 106, a surge voltage Δs is removed Since the detection voltage is generated from the voltage V ₂ thus obtained and the detected voltage is controlled so as to match the reference voltage, the voltage control unit 10
No. 6 cannot recognize the energy loss corresponding to the surge voltage Δs.

Therefore, from the primary winding 141 to the secondary winding 14
3 is supplied with only necessary energy in an ideal case where no surge voltage Δs is generated.
3 has a problem that the output voltage output from the power supply 3 decreases by an energy loss due to the surge voltage Δs.

[0034]

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned disadvantages of the prior art, and has as its object to indirectly control the voltage on the secondary side which is insulated from the primary side. An object of the present invention is to provide a power supply circuit capable of outputting a constant output voltage in a power supply circuit configured to maintain a constant output voltage by detection.

[0035]

According to a first aspect of the present invention, there is provided an electronic apparatus comprising a transformer, a primary side current supply circuit, a secondary side rectifier circuit, and a control circuit. The transformer has a primary winding, a voltage detection winding, and a secondary winding that are magnetically coupled to each other, and the primary-side current supply circuit has a main switch and a rectifying and smoothing circuit, The main switch is connected in series to the primary winding, and is capable of supplying a current to the primary winding when the main switch is turned on. The conduction / cutoff of the main switch causes energy stored in the primary winding to be supplied. Is divided and transmitted to the secondary winding and the voltage detection winding at a fixed ratio, and a voltage can be induced between the terminals of the secondary winding and the terminals of the voltage detection winding, respectively. Wherein the rectifying and smoothing circuit Rectifying and smoothing the voltage induced between the terminals of the output winding, generating a detection voltage having a magnitude corresponding to the voltage induced between the terminals of the secondary winding, and outputting the detected voltage to the control circuit; The control circuit controls the conduction state of the main switch so as to maintain the detection voltage at a reference voltage,
The voltage induced between the terminals of the secondary winding is maintained at a constant voltage, and the secondary rectifier circuit rectifies and smoothes the voltage induced between the terminals of the secondary winding. In the power supply circuit configured to be able to obtain a DC voltage, the power supply circuit further includes a surge detection circuit, and when the main switch is turned off, a surge voltage is generated in a voltage generated between terminals of the secondary winding. In the case, the surge detection circuit is induced between the terminals of the voltage detection winding, detects a voltage including a surge voltage and outputs the voltage to the control circuit, and the control circuit is input from the surge detection circuit. When the voltage increases, the energy transmitted to the secondary winding is increased to increase the voltage induced between the terminals of the secondary winding.

According to a second aspect of the present invention, in the power supply circuit according to the first aspect, the surge detection circuit has a diode, a resistor, and a capacitor, and an anode of the diode is connected to the voltage detection winding. Connected to one terminal, the cathode of the diode is connected to one end of the resistor, the other end of the resistor is connected to one end of the capacitor, and the other end of the capacitor is the other end of the voltage detection winding. When the main switch is turned on, a positive voltage is generated at one terminal of the voltage detection winding, and a negative voltage is generated at the other terminal of the voltage detection winding, respectively. The current flowing in the voltage detection winding is supplied to the diode, the diode rectifies the current flowing in the voltage detection winding, and the resistor and the capacitor connect the voltage detection winding to the diode. The current flowing through the windings is smoothed,
It is configured to detect a voltage induced in the voltage detection winding.

According to a third aspect of the present invention, in the power supply circuit according to the second aspect, the control circuit has an error amplifier and a switching control circuit, and the error amplifier has a divided detection voltage. When a reference voltage is input, the divided detection voltage is compared with the reference voltage to output an error signal, and the switching control circuit outputs the error signal based on the error signal. , The main switch is configured to control conduction / interruption so that the divided detection voltages match, and the reference voltage is a constant voltage,
A voltage corresponding to the voltage induced between the terminals of the voltage detection winding is superimposed and generated.

In the power supply circuit of the present invention, when the current flowing through the load increases, when the rectifying element in the secondary side rectifier circuit conducts, a surge voltage is generated in the voltage between the terminals of the secondary winding and the voltage increases. A surge voltage also occurs in the voltage between the terminals of the detection winding.

The surge detection circuit detects a voltage including a surge voltage induced between terminals of the voltage detection winding and outputs the voltage to the control circuit. The control circuit detects the voltage input from the surge detection circuit. Increases, the energy transmitted to the secondary winding increases.

For this reason, even if an energy loss caused by a surge voltage occurs in the secondary side rectifier circuit, the energy transmitted to the secondary winding is increased so as to compensate for the loss, By increasing the voltage generated between the terminals of the secondary winding, it is possible to prevent the output voltage from decreasing and to obtain a constant output voltage.

In the present invention, since the surge voltage has a spike-like voltage waveform, has a large voltage peak value, and has a short generation period, it is difficult to reliably detect the voltage peak value and the generation period. Therefore, there was a risk that the loss of energy due to the surge voltage could not be reliably obtained.However, in the present invention, the voltage including the surge voltage was smoothed by the resistor and the capacitor in the surge detection circuit to form a voltage waveform. By smoothing, the surge voltage can be reliably detected.

Further, in the present invention, the control circuit has an error amplifier and a switching control circuit, compares the divided detection voltage with a reference voltage, and compares the divided detection voltage with a reference voltage. When the control circuit operates so as to match the voltage, the output voltage is operated so as to be maintained at a constant voltage. A voltage having a magnitude corresponding to the voltage induced during the period is superimposed.

In a steady state where the reference voltage and the detection voltage match and the output voltage is constant, if a surge voltage occurs when the rectifying element in the secondary side rectifier circuit conducts, the period during which the surge voltage occurs is Since the voltage induced by the voltage induced between the terminals of the secondary winding increases, the reference voltage rises and becomes higher than the divided detection voltage.

Then, the error amplifier controls the switching control circuit so that the divided detection voltage matches the reference voltage, so that the conduction period of the main switch is lengthened and the current flowing through the primary winding increases. In addition, the energy transmitted from the primary winding to the secondary winding increases.

For this reason, in the secondary side rectifier circuit, the energy loss caused by the surge voltage is compensated for,
By increasing the energy transmitted to the secondary winding, the output voltage can be kept constant regardless of the magnitude of the current flowing to the load.

[0046]

Embodiments of the present invention will be described below with reference to the drawings.

Reference numeral 1 in FIG. 1 denotes a power supply circuit according to the embodiment of the present invention. The power supply circuit 1 is a power supply circuit that reduces a DC voltage of about 36 to 72 V to generate a DC voltage of 2.5 V, and includes a primary-side current supply circuit 2, a secondary-side rectifier circuit 3, and a transformer 4. , A PWM control circuit 5 and a voltage control unit 6.

The transformer 4 has a primary winding 41 on the primary side.
And a secondary winding 43 and a gate drive winding 44 on the secondary side, respectively. The primary side current supply circuit 2 includes a smoothing circuit 11, a snubber circuit 12, a switch transistor 13 composed of an n-channel MOS transistor, and a surge detection circuit 70.

The drain of the switch transistor 13 is connected to one terminal b of the primary winding 41. On the other hand, the source of the switch transistor 13 is connected to one input terminal 62 via the smoothing circuit 11. The other terminal a of the primary winding 41 is connected to the snubber circuit 12 and the smoothing circuit 1.
1, a DC voltage is applied between the input terminals 61 and 62, and a current can be supplied to the primary winding 41 when the switch transistor 13 is turned on. I have.

The primary winding 41 and the secondary winding 43 of the transformer 4
Are insulated from each other, but are magnetically coupled, so that when a current flows through the primary winding 41 and an electromotive force is generated in the primary winding 41, an induced electromotive force can be induced in the secondary winding 43. ing.

At this time, when an electromotive force is generated in the primary winding 41 and a positive voltage is generated at one terminal a of the primary winding 41 and a negative voltage is generated at the other terminal b, the secondary winding 41 Line 43
A positive voltage is applied to one terminal g on the ground potential side of
A negative voltage is generated at the other terminal f.

The gate of the switch transistor 13
The PWM control circuit 5 is connected, and by outputting a rectangular wave signal to the gate, the on / off switching of the switch transistor 13 can be controlled.
By adjusting the ratio of the on-time to the off-time, the amount of current flowing through the switch transistor 13 can be adjusted.

The secondary-side rectifier circuit 3 has a rectifier transistor 21 composed of an n-channel MOS transistor, a snubber circuit 22, and a smoothing circuit 23. The source of the rectifier transistor 21 is connected to one terminal f of the secondary winding 43, the drain is connected to the output terminal 63 via the smoothing circuit 23, and the other terminal g of the secondary winding 43 is connected to the smoothing circuit. It is connected to an output terminal 64 via. Then, when a voltage is generated between the terminals f and g of the secondary winding 43 and the rectifying transistor 21 is turned on, a current can be supplied to a load (not shown) via the output terminals 63 and 64.

The operation of applying a constant voltage to a load in the power supply circuit 1 will be described below. First, the case where the current flowing through the load is small will be described. Input terminal 6
A DC voltage of about 36 to 72 V is applied between the terminals 1 and 62. The capacitor 24 in the smoothing circuit 23 is charged by a very small current flowing when the power is turned on, and a potential difference is generated between both electrodes of the capacitor 24. It is assumed that

When the switch transistor 13 is turned on after the switch transistor 13 is turned off, a current flows through the primary winding 41, an electromotive force is generated in the primary winding 41, and an induced electromotive force is generated in the secondary winding 43. appear.

At this time, positive and negative voltages are generated at the terminals a and b of the primary winding 41, respectively. A negative voltage is generated at a terminal f of the rectifying transistor 21 connected to the terminal f, and a terminal g
A lower voltage is applied.

On the other hand, the drain of the rectifying transistor 21 is connected to the terminal g via the capacitor 24 in the smoothing circuit 23. The potential of the drain of the rectifying transistor 21 is changed to the potential of the terminal g by the potential difference between both ends of the capacitor 24. Higher than.

As a result, the potential of the drain of the rectifying transistor 21 becomes higher than the potential of the source, so that a forward bias is applied to the rectifying transistor 21.
Since the potential of the terminal e that defines the gate potential of the rectification transistor 21 is lower than the potential of the terminal f that defines the source potential of the rectification transistor 21, the rectification transistor 21 is off.

Therefore, no current flows from the secondary winding 43 to the output terminal 63 via the rectifying transistor 21, and the capacitor 24 in the smoothing circuit 23 discharges, and the discharge voltage flows from the output terminals 63 and 64 to the load. Is output.

Thereafter, when the switch transistor 13 which has been in the on state is switched to the off state, an electromotive force having a polarity opposite to that generated when the switch transistor 13 was turned on is generated in the primary winding 41. Then, a voltage having a polarity opposite to that when the switch transistor 13 is turned on is generated in the secondary winding 43 and the gate drive winding 44.

Then, the reverse bias is applied to the rectifying transistor 2 when the switch transistor 13 is in the ON state.
1 and the parasitic diode inside the rectifier transistor 21 is forward-biased.

On the other hand, the potential of the terminal e that defines the potential of the gate of the rectifying transistor 21 is higher than the potential of the terminal f of the gate drive winding 44 that defines the potential of the source of the rectifying transistor 21. When a positive voltage is applied, the rectifying transistor 21 can be turned on in the reverse direction, the rectifying transistor 21 performs a so-called third quadrant operation, no current flows through the parasitic diode, and the rectifying transistor 21 is more versatile than when the diode is used as a rectifying element. A current can flow with a small voltage drop.

When the rectifying transistor 21 is turned on in the opposite direction, a current flows from the secondary winding 43 to the smoothing circuit 23 via the rectifying transistor 21, and charges the capacitor 24 in the smoothing circuit 23 while outputting the output terminals 63 and 64. Supply current to the load.

As described above, the on / off state of the switch transistor 13 is repeatedly switched, and the smoothing circuit 2 is switched.
3 is repeated to output terminals 63, 6
4 to the load.

In the power supply circuit 1 described above, the output voltage on the secondary side is indirectly detected on the primary side isolated from the secondary side, and the switch transistor 13 is turned on so that the output voltage becomes constant. The primary-side current supply circuit 2 includes a voltage detection winding 42 and a voltage detection unit 14, and a voltage control unit connected to the PWM control circuit 5. 6.

The voltage detection winding 42 is disposed so as to be magnetically coupled to the primary winding 41 and the secondary winding 43, so that an induced electromotive force is generated in the secondary winding 43 and the voltage detection winding 42 Also, an induced electromotive force is generated in the secondary winding 4.
A voltage having a magnitude corresponding to the voltage induced in the secondary winding 43 is generated between the terminals c and d of the voltage detection winding 42 magnetically coupled to the terminal 3. At this time, the secondary winding 4
3, when a positive voltage is generated at one terminal g and a negative voltage is generated at the other terminal f, the positive voltage is applied to one terminal d on the ground potential side of the voltage detection winding 42, and the other voltage is applied to the other terminal f. A negative voltage is induced at each of the terminals c.

The voltage detector 14 has resistors 15 and 17, capacitors 16 and 18, and a diode 19.
The resistors 15 and 17 and the capacitors 16 and 18 each constitute a low-pass filter. Then, a low-pass filter in the preceding stage including the resistor 15 and the capacitor 16 is connected to the terminals c and d of the voltage detection winding 42.

The output of the previous low-pass filter is connected to the anode of a diode 19, and the cathode is connected to a resistor 1
7, the input of the low-pass filter of the subsequent stage comprising the capacitor 18 is connected.

The output of the low-pass filter at the subsequent stage is connected to the voltage control section 6, and the terminals C and
The voltage between the terminals C and D of the voltage detection winding 42 is removed by removing the high-band component by a low-pass filter in the preceding stage, rectifying the voltage by the diode 19, and further removing the high-band component by the low-pass filter in the subsequent stage. The voltage is rectified and smoothed, and can be output to the voltage control unit 6.

The voltage control section 6 has an error amplifier 50 and resistors 51 to 54. The resistors 51 and 52 are sequentially connected in series between a constant voltage Vref supplied from a circuit (not shown) and the ground potential.
The connection point 2 is connected to the inverting input terminal (-) of the error amplifier 50. On the other hand, the resistors 53 and 54 are connected in series between the source of the switch transistor 13 and the ground potential, and the connection point of the resistors 53 and 54 is connected to the non-inverting input terminal (+) of the error amplifier 50. I have.

A voltage obtained by dividing the DC voltage input from the voltage detector 14 by the resistance ratio of the resistors 53 and 54
(Hereinafter, referred to as a detection voltage) is input to the non-inverting input terminal (+) of the error amplifier 50. On the other hand, a voltage (hereinafter, referred to as a reference voltage) obtained by dividing the constant voltage Vref by the resistance ratio of the resistors 51 and 52 connected in series is input to the inverting input terminal (−) of the error amplifier 50. .

The error amplifier 50 is operated by the auxiliary power supply voltage Vc supplied from a circuit (not shown), compares the detection voltage with a reference voltage, generates an error signal, and outputs the error signal to the PWM control circuit 5. .

The PWM control circuit 5 controls the on / off of the switch transistor 13 based on the error signal. If the detected voltage is lower than the reference voltage, the on-time of the switch transistor 13 is extended, and the detected voltage is set to the reference voltage. If the voltage is higher than the voltage, the on-time of the switch transistor 13 is shortened.

If the on time is made longer than the off time,
The amount of current flowing through the primary winding 41 increases, the energy stored in the primary winding 41 increases, and is transmitted to the secondary winding 43 and the voltage detection winding 42. Then, the amount of current flowing through the voltage detection winding 42 increases, the voltage between the terminals c and d of the voltage detection winding 42 increases, and the detection voltage obtained by dividing this voltage increases. Conversely, when the on-time is shorter than the off-time, the detection voltage decreases. Thus, the detection voltage operates so as to match the reference voltage.

When the detected voltage matches the reference voltage, the voltage between the terminals c and d of the voltage detecting winding 42 becomes constant. Also,
The voltage between the terminals c and d of the voltage detection winding 42 and the secondary winding 4
3 is fixed by the turns ratio between the secondary winding 43 and the voltage detection winding 42. Therefore, when the detection voltage matches the reference voltage, the secondary The voltage between the terminals f and g of the winding 43 becomes constant. In an ideal case, since the voltage between the terminals f and g of the secondary winding 43 and the output voltage are equal, the output voltage is also constant.

Therefore, if the reference voltage is appropriately set in advance, a constant output voltage can be obtained from the DC voltage input between the input terminals 61 and 62. here,
An output voltage of 2.5 V can be obtained.

However, when the current flowing through the load increases, a surge voltage is generated in the voltage between the terminals f and g of the secondary winding 43, so that the energy loss due to the surge voltage causes the secondary rectifier circuit 3 Within. However, since the voltage control unit 6 generates the detection voltage from the voltage from which the surge voltage has been removed and controls the detection voltage to be equal to the reference voltage, the voltage control unit 6 recognizes the energy loss of the surge voltage. Can not.

Therefore, only the necessary energy is supplied from the primary winding 41 to the secondary winding 43 when no surge voltage is generated, and the output voltage output from the secondary rectifier circuit 3 is the surge voltage. However, there is a problem that the energy is reduced by the amount of energy loss.

To cope with this problem, the power supply circuit 1 of the present embodiment is provided with a surge detection circuit 70.
The surge detection circuit 70 includes a diode 71 and a resistor 7.
2 and a capacitor 73.

The anode of the diode 71 is connected to one terminal c of the voltage detection winding 42, the cathode is connected to one end of the resistor 72,
They are connected to each other so that the current flowing through the voltage detection winding 42 can be rectified and supplied to one end of the resistor 72.

The other end of the resistor 72 is connected to one end of a capacitor 73, and the other end of the capacitor 73 is connected to an input terminal 62.
And to the ground potential. Also, resistors 80 and 81 connected in series are arranged between the auxiliary power supply voltage Vc and a connection point of the resistors 51 and 52 connected in series. It is connected to the connection point between 72 and the capacitor 73.

The voltage between the terminals f and g of the voltage detection winding 42, smoothed by the resistor 72 and the capacitor 73, is connected to a resistor 80, which is connected in series so as to match the input level of the error amplifier 50. The voltage is divided by the resistance ratio of 81,
The error amplifier 50 can be input to the inverted input terminal (−) of the error amplifier 50 so as to be superimposed on the connection midpoint of the connection 52.

When a surge voltage is generated between the terminals f and g of the secondary winding 43 in a state where the reference voltage matches the detection voltage and the output voltage is constant, the terminals c and d of the voltage detection winding 42
During this time, a surge voltage is induced and is output via the diode 71 to the connection middle point of the resistors 80 and 81,
And the voltage is superimposed on the middle point between the resistors 51 and 52, so that the voltage at the inverting input terminal (−) of the error amplifier 50, that is, the reference voltage increases.

The error amplifier 50 compares the detection voltage with the reference voltage, generates an error signal and outputs the error signal to the PWM control circuit 5, and the PWM control circuit 5 turns on / off the switch transistor 13 based on the error signal. Controls off operation. Here, a voltage corresponding to the surge voltage is superimposed on the reference voltage,
Since the reference voltage is higher than the detection voltage, the ON time is lengthened.

If the on time is made longer than the off time,
The amount of current flowing through the primary winding 41 increases, and the energy stored in the primary winding 41 increases. When the increased energy is transmitted to the secondary winding 43, the amount of current flowing through the secondary winding 43 and the voltage detection winding 42 increases, and the voltage between the terminals f and g of the secondary winding 43 and the voltage detection Both the voltage between the terminals c and d of the winding 42 rises, and the detection voltage also rises. And
It becomes stable when the detection voltage matches the reference voltage.

As described above, when a surge voltage is generated between the terminals f and g of the secondary winding 43 and the voltage between the terminals f and g rises, the primary winding is kept until the detected voltage matches the reference voltage. 41 to increase the energy stored in the secondary winding 4
3 to increase the energy transmitted. Then, the energy loss due to the surge voltage Δs generated in the secondary side rectifier circuit 3 is compensated, so that even when the current flowing through the load is large, the output voltage does not decrease due to the energy loss due to the surge voltage Δs, Voltage value (2.5
V).

Although the surge voltage has a spike-like waveform, has a high voltage peak value and a short period of occurrence, it is difficult to reliably detect the voltage. However, in this embodiment, the surge detection circuit 70 has a capacitor. The capacitor 73 makes the waveform of the surge voltage blunt, reduces the peak value of the spike-like surge voltage, and prolongs the generation period, so that the surge voltage can be reliably detected. Will be possible. In the present embodiment, the secondary rectifier circuit 3
Although the rectifying transistor 21 is used as the rectifying element, the present invention is not limited thereto, and a diode may be used.

[0088]

By detecting the voltage generated between the terminals of the secondary winding with the voltage detection winding, the current flowing through the load is indirectly detected, and the output voltage is adjusted so as to compensate for the energy loss due to the surge voltage. By increasing the voltage, a desired output voltage can be output correctly.

[Brief description of the drawings]

FIG. 1 is a circuit diagram showing an example of a power supply circuit of the present invention.

FIG. 2 is a circuit diagram showing a conventional power supply circuit.

3A is a voltage waveform diagram of a voltage appearing between terminals of a voltage detection winding. FIG. 3B is a voltage waveform diagram of a voltage obtained by smoothing a voltage appearing between terminals of a voltage detection winding.

[Explanation of symbols]

1. Power supply circuit 2. Primary current supply circuit 3.
Secondary rectifier circuit 4 Transformer 5 PWM control circuit (switching control circuit) 6 Voltage control unit (control circuit) 13 Switch transistor (main switch)
14 voltage detecting section (rectifying and smoothing circuit) 41 primary winding 42 voltage detecting winding 43 secondary winding
44 gate drive winding 50 error amplifier 70
...... Surge detection circuit

 ────────────────────────────────────────────────── ─── Continuing from the front page (72) Inventor Hiroyuki Suzuki 10-13, Minamimachi, Hanno City, Saitama F-term in Shindengen Kogyo Co., Ltd. Hanno Plant (reference) 5H730 AA14 BB43 BB57 DD04 DD41 EE02 EE07 EE14 FD24 FG05

Claims (3)

[Claims] A transformer, a primary-side current supply circuit, a secondary-side rectifier circuit, and a control circuit, wherein the transformer has a primary winding, a voltage detection winding, The primary side current supply circuit has a main switch and a rectifying and smoothing circuit, and the main switch is connected in series to the primary winding, and the primary winding is turned on when conducting. The main switch is turned on / off, so that the energy stored in the primary winding is divided into the secondary winding and the voltage detection winding at a fixed ratio. The voltage is transmitted between the terminals of the secondary winding and between the terminals of the voltage detection winding, and the rectifying and smoothing circuit is induced between the terminals of the voltage detection winding. The rectified and smoothed voltage is applied to the secondary winding. A detection voltage having a magnitude corresponding to a voltage induced between terminals is generated and output to the control circuit, and the control circuit controls a conduction state of the main switch so as to keep the detection voltage at a reference voltage. By doing so, the voltage induced between the terminals of the secondary winding is maintained at a constant voltage, the secondary rectifier circuit rectifies the voltage induced between the terminals of the secondary winding A power supply circuit configured to be able to obtain a DC voltage by smoothing, wherein a surge detection circuit is further provided, and when the main switch is turned off, a surge occurs in a voltage generated between terminals of the secondary winding. When a voltage is generated, the surge detection circuit detects a voltage including a surge voltage induced between terminals of the voltage detection winding and outputs the voltage to the control circuit. Voltage input from That when, by increasing the energy transferred to the secondary winding, a power supply circuit, characterized in that it is configured to increase the voltage induced across the terminals of the secondary winding. 2. The surge detection circuit includes a diode, a resistor, and a capacitor, an anode of the diode is connected to one terminal of the voltage detection winding, and a cathode of the diode is connected to one end of the resistor. The other end of the resistor is connected to one end of the capacitor,
The other end of the capacitor is connected to the other terminal of the voltage detection winding. When the main switch is turned on, a positive voltage is applied to one terminal of the voltage detection winding. A negative voltage is generated at each of the other terminals, and a current flowing through the voltage detection winding is supplied to the diode.The diode rectifies a current flowing through the voltage detection winding, The power supply circuit according to claim 1, wherein the resistor and the capacitor are configured to smooth a current flowing through the voltage detection winding and detect a voltage induced in the voltage detection winding. . 3. The control circuit has an error amplifier and a switching control circuit. The error amplifier compares the divided detection voltage with a reference voltage and outputs an error signal. The switching control circuit is configured to control conduction / interruption of the main switch based on the error signal so that the divided detection voltage matches the reference voltage. 3. The power supply circuit according to claim 2, wherein a voltage corresponding to a voltage induced between the terminals of the voltage detection winding is superimposed on the constant voltage.