JP2000224846A - Power device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To prevent generation of an overshoot (overvoltage) by providing a discharging means (discharging resistor) for performing discharge when an output is cut off, for a feedback capacitor used in a feedback circuit being a power control subject. SOLUTION: The junction between the cathode of a shunt regulator 12 and one end of a feedback capacitor 14 is pulled down to the ground potential, by providing a discharging means (discharging resistor R1) having a large resistance value in the extent of 1 MΩ, so that the feedback capacitor 14 for example being a controlling part of a main power circuit 100 may not be charged, i.e., the potential of the cathode terminal of a shunt regulator 12 may not be a constant value or higher. Restriction to a voltage value or lower free from generation of an overshoot is performed, by preventing the cathode terminal of the shunt regulator 12 from becoming a certain voltage or higher through the use of a discharging means (discharging resistor R1). Consequently, it becomes possible to prevent an overshoot of an output.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

The present invention relates to power supply technology,
In particular, even when an unexpected leak current occurs due to flux moisture absorption or the like in a feedback circuit mainly controlling the power supply, it is possible to prevent a delay in the power supply control and to prevent an overshoot (overvoltage) at startup. Power supply.

[0002]

2. Description of the Related Art As a conventional power supply device, for example, FIG.
There is something like that shown in The conventional power supply device P300 shown in FIG. 3 includes an auxiliary power supply circuit P200 and a main power supply circuit P1.
00 is provided with two power supply circuits. Referring to FIG. 3, P1 is a bridge diode for rectifying an AC voltage (for example, AC 100 V commercial voltage), P2 is a smoothing capacitor, P3 is a main switching element, and P4 is 2
Transformer that converts voltage to the next side and transmits power, P5 is 2
A rectifying unit on the secondary side, P6 is a smoothing unit on the secondary side, P7 is a feedback circuit for transmitting the output voltage to the control circuit P8 on the primary side, and P8 controls a main switching element for maintaining the output voltage at an arbitrary voltage. Control circuit.

In the power supply device P300 of the prior art, if the cathode terminal of the shunt regulator P12 in the feedback circuit P7 becomes higher than a certain voltage for some reason when the AC power supply is turned on, the voltage is controlled by the shunt regulator P12 and the photocoupler P10. Coupler P
Since the light of 10 is delayed, the feedback is delayed. Normally, if the output voltage reaches an arbitrary voltage and the feedback is normally performed, the photocoupler P10 is turned on.
The control circuit P8 adjusts the switching duty so as to lower the output voltage. However, if the feedback is delayed, the control circuit P8 is turned on until the photocoupler P10 is turned on.
8 continuously increases the voltage, so that an overshoot occurs in the output voltage.

For example, while the main power supply circuit P100 is off, the feedback circuit P
When there is a leakage current from the auxiliary power supply circuit P200 to the feedback capacitor P14, the feedback capacitor P14 of the feedback circuit P7 is charged, and when the main power supply circuit P100 is turned on, the output of the feedback circuit P7 is output. The feedback is delayed only during the period in which the current is drawn from the feedback capacitor P14 charged with, and an overvoltage occurs.

The operation when the feedback capacitor P14 is charged by a small leak current from the auxiliary power supply circuit P200 will be specifically described. When the main power supply circuit P100 is turned on, the output voltage rises in the same manner as in the above-described normal state. When the potential of the voltage detection terminal of the shunt regulator P12 becomes equal to or higher than a predetermined voltage, the shunt regulator P12 transitions to the conducting state. However, the feedback capacitor P14 has already been charged by a small leak current from the auxiliary power supply circuit P200. Therefore, during a required period until the potential of the feedback capacitor P14 becomes equal to or lower than the original voltage during normal operation, the photocoupler P1
No current flows through the photodiode within 0. as a result,
No feedback is applied to the control circuit P8 on the primary side, so that the control circuit P8 is in an uncontrolled state, and overshoot and overvoltage occur.

[0006]

However, in the prior art, after being stored for a long period of time in an environment of high humidity or in which dew condensation is likely to occur, if only the auxiliary power supply circuit P200 is left for several hours in an ON state, As a result, the feedback capacitor P14 is charged by the leakage current from the auxiliary power supply circuit P200 as described above, and as a result, there is a case where no feedback is applied to the control circuit P8 on the primary side and the primary side control circuit P8 is in an uncontrolled state, resulting in overshoot or overvoltage. There was a point. The present invention has been made in view of such a problem, and the purpose thereof is, even when an unexpected leak current due to moisture absorption of flux or the like occurs in a feedback circuit which is a power supply control main body, An object of the present invention is to provide a power supply device that avoids a delay in power supply control and prevents occurrence of overshoot (overvoltage) at startup.

[0007]

The gist of the present invention is to avoid a delay in power supply control even if a leak current occurs in a feedback circuit which is a power supply control main body. A power supply device for preventing occurrence of overshoot at start-up, comprising a bridge diode for rectifying an input AC voltage, and two power supply circuits including an auxiliary power supply circuit and a main power supply circuit. The input side of the auxiliary power supply circuit is connected in parallel to the output side of the bridge diode, and the main power supply circuit and the output side of the auxiliary power supply circuit are connected in parallel to the output voltage side,
The main power supply circuit includes a switching element for maintaining an output voltage at an arbitrary voltage, a control circuit for controlling the switching element, and a feedback circuit for transmitting an output voltage to the control circuit. A shunt regulator for generating and outputting a detection signal for notifying the control circuit that the output voltage has reached a predetermined voltage or more when the circuit is ON, and a cathode terminal of the shunt regulator when the main power supply circuit is OFF And a discharge unit for preventing a potential of the power supply from rising above a predetermined potential, wherein the detection signal is fed back to the control circuit to instruct a predetermined voltage control. . The gist of claim 2 of the present invention is to prevent the occurrence of a delay in power supply control and the occurrence of overshoot at startup even when a leakage current occurs in a feedback circuit that is the main power supply control. A power supply device, comprising: a bridge diode for rectifying an input AC voltage; and two power supply circuits including an auxiliary power supply circuit and a main power supply circuit, and the input sides of the main power supply circuit and the auxiliary power supply circuit are bridge diodes. Connected in parallel to the output side of
The output sides of the main power supply circuit and the auxiliary power supply circuit are connected in parallel to an output voltage side, the main power supply circuit includes a switching element for maintaining an output voltage at an arbitrary voltage, a control circuit for controlling the switching element, and an output voltage. And a feedback circuit that transmits the output voltage of the main power supply circuit to the control circuit.The feedback circuit detects that the potential of the feedback capacitor has reached a predetermined voltage or more. A shunt regulator for generating and outputting a detection signal to be notified to a control circuit, and discharging means for preventing a potential of a cathode terminal of the shunt regulator connected to the feedback capacitor from rising above a predetermined potential when the main power supply circuit is turned off. And providing the detection signal to the control circuit. Fed back to resides in the power supply apparatus characterized by being configured to indicate a predetermined voltage control. The gist of claim 3 of the present invention is that the discharging means is a resistance element, and the resistance element is connected between a cathode terminal of the shunt regulator and a ground potential. Or the power supply device according to 2. The gist of claim 4 of the present invention is that the discharging means is a resistance element having a resistance value of about 1 MΩ, and the resistance element is connected between a cathode terminal of the shunt regulator and a ground potential. The power supply device according to claim 1 or 2, wherein
The gist of claim 5 of the present invention is to prevent the occurrence of a delay in power supply control and the occurrence of overshoot at start-up even when a leakage current occurs in a feedback circuit that is the main power supply control. A power supply device, comprising: a bridge diode for rectifying an input AC voltage; and two power supply circuits including an auxiliary power supply circuit and a main power supply circuit, and the input sides of the main power supply circuit and the auxiliary power supply circuit are bridge diodes. The output side of the main power supply circuit and the auxiliary power supply circuit are connected in parallel to the output voltage side, and the main power supply circuit is a switching element for maintaining an output voltage at an arbitrary voltage. A control circuit for controlling a switching element, a feedback circuit for transmitting an output voltage to the control circuit, wherein the feedback circuit A shunt regulator for generating and outputting a detection signal for notifying the control circuit that the output voltage has reached a predetermined voltage or more when the main power supply circuit is ON, and the shunt regulator when the main power supply circuit is OFF A power supply, comprising a clamp means for preventing the potential of the cathode terminal from rising above a predetermined potential, and instructing a predetermined voltage control by feeding back the detection signal to the control circuit. Exists in the device. The gist of claim 6 of the present invention is to prevent the occurrence of a delay in power supply control and the occurrence of overshoot at start-up even when a leakage current occurs in a feedback circuit which is a power supply control main body. A power supply device, comprising: a bridge diode for rectifying an input AC voltage; and two power supply circuits including an auxiliary power supply circuit and a main power supply circuit, and the input sides of the main power supply circuit and the auxiliary power supply circuit are bridge diodes. The output side of the main power supply circuit and the auxiliary power supply circuit are connected in parallel to the output voltage side, and the main power supply circuit is a switching element for maintaining an output voltage at an arbitrary voltage. A control circuit for controlling a switching element, a feedback circuit for transmitting an output voltage to the control circuit, wherein the feedback circuit A feedback capacitor for detecting an output voltage of the main power supply circuit, a shunt regulator for generating and outputting a detection signal for notifying the control circuit that the potential of the feedback capacitor has reached a predetermined voltage or more; and When the power supply circuit is OFF, a clamp means for preventing the potential of the cathode terminal of the shunt regulator connected to the feedback capacitor from rising to a predetermined potential or more is provided, and the detection signal is fed back to the control circuit to generate a predetermined voltage. The power supply device is configured to instruct control. According to another aspect of the present invention, the clamping means is a Zener diode, a cathode terminal of the Zener diode is connected to a cathode terminal of the shunt regulator, and an anode terminal of the Zener diode is connected to the shunt regulator. The power supply device according to claim 5, wherein the power supply device is connected to an anode terminal of the power supply.

[0008]

DESCRIPTION OF THE PREFERRED EMBODIMENTS The features of each embodiment described below are as follows.
In a power supply device, a discharging means (discharging resistor) or a clamping means (clamping zener diode) is provided for a feedback capacitor used in a feedback circuit which is a power supply control main body when an output is turned off, and an unexpected leak due to moisture absorption of a flux or the like is provided. Even when a current is generated, a delay in power supply control is avoided and an overshoot (overvoltage) is prevented from occurring at startup. Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.

(First Embodiment) FIG. 1 is a circuit diagram for explaining a first embodiment of a power supply device according to the present invention.
The power supply device 300 of the present embodiment includes two power supply circuits such as an auxiliary power supply circuit 200 and a main power supply circuit 100, and the input sides of the main power supply circuit 100 and the auxiliary power supply circuit 200 are connected in parallel to the output side of the bridge diode 1. The output sides of the main power supply circuit 100 and the auxiliary power supply circuit 200 are connected to the power supply 30.
0 is connected in parallel to the DC output side. Referring to FIG. 1, 1 is a bridge diode for rectifying an AC voltage (for example, 100 V AC commercial voltage), 2 is a smoothing capacitor,
3 is a main switching element, 4 is a transformer for converting voltage to the secondary side and transmitting power, 5 is a rectifying section on the secondary side, 6
Denotes a secondary-side smoothing unit, 7 denotes an output voltage, and a primary-side control circuit 8
Is a control circuit for controlling a main switching element for maintaining the output voltage at an arbitrary voltage.

In general, in the power supply device 300 in which the feedback circuit 7 to the primary side of the power supply control is composed of the photocoupler 10 and the shunt regulator 12, the line of the cathode terminal of the shunt regulator 12 has a diode backflow prevention circuit or the like. Since it does not exist, it is not considered at all that a circuit-like leakage current normally occurs. However, when the cathode terminal of the shunt regulator 12 is at or above a predetermined potential due to a small leak current generated when flux or PCB absorbs moisture when the power is turned off (the predetermined potential is determined by the size of the feedback capacitor 14 of the feedback circuit 7). (Depends on the cathode terminal potential of the shunt regulator 12 during normal operation), a delay occurs in the current draw of the shunt regulator 12 when the power is turned on, and the light emission of the photocoupler 10 is delayed. As a result, feedback is delayed and overshoot occurs. Comes out.

Therefore, the feedback circuit 7, which is a control part of the main power supply circuit 100 of this embodiment,
When 0 is OFF, the feedback capacitor 14
Is not charged, that is, the potential of the cathode terminal of the shunt regulator 12 does not rise more than a certain level due to a small leak current.
The connection point between the cathode 2 and one end of the feedback capacitor 14 is pulled down to the ground potential by discharging means (discharging resistor R ₁ ) having a large resistance value of about 1 MΩ.

That is, the discharging means (discharging resistor R ₁ ) uses a voltage value that does not cause overshoot (a voltage dependent on the component characteristics and constants of the feedback circuit 7) so that the cathode terminal of the shunt regulator 12 does not exceed a certain voltage. By limiting the value to below, it is possible to easily prevent output overshoot due to this cause. In addition, as a possibility that a voltage is generated at the cathode terminal of the shunt regulator 12 before the power is turned on, a leak current due to moisture absorption of PCB or uncleaned flux is considered. However, the present embodiment is intended to improve moisture resistance. Can be. The voltage value that depends on the component characteristics and constants of the feedback circuit 7 means, for example, a voltage value that depends on the size of the feedback capacitor 14 of the feedback circuit 7 and the cathode terminal potential of the shunt regulator 12 during normal operation. The control circuit 8 is well known to those skilled in the art,
Further, since it is not directly related to the present invention, its detailed configuration is omitted.

The operation of this embodiment will be described below.
First, a normal operation will be described. In the power supply device 300 of the present embodiment, usually, the feedback capacitor 14
Is not charged, the main power supply circuit 100 is turned on.
When the output voltage (shown as DC output in the figure) rises and the potential of the voltage detection terminal of the shunt regulator 12 becomes equal to or higher than a predetermined voltage, the shunt regulator 12 transitions to the conductive state and the photodiode in the photocoupler 10 An ON current flows and the photocoupler 10 is turned on. As a result, the voltage is normally controlled by applying feedback to the primary-side control circuit 8, so that the output voltage of the power supply device 300 is stabilized without overshoot or overvoltage.

That is, even if there is a leakage current from the auxiliary power supply circuit 200 to the feedback capacitor 14, the feedback capacitor 14 is not charged, so that the operation is always normal. In other words, even when an unexpected leak current occurs due to the absorption of flux or the like in the feedback circuit that is the main power supply control, an overshoot (overvoltage) occurs at the start-up by avoiding the delay in the power supply control. This has the effect that it can be prevented.

On the other hand, the above-mentioned conventional power supply device P300
Has two power supply circuits such as an auxiliary power supply circuit P200 and a main power supply circuit P100.
If there is a leakage current from the auxiliary power supply circuit P200 to the feedback capacitor P14 of the feedback circuit P7 of the main power supply circuit P100 during the FF period, there is no discharge means (discharge resistor R ₁ ) of the present invention. Feedback capacitor P14 of feedback circuit P7
Is charged, and at the time of rising when the main power supply circuit P100 is turned on, feedback is delayed only for a period in which the output of the feedback circuit P7 draws current from the charged feedback capacitor P14, and an overvoltage occurs.

The operation when the feedback capacitor P14 is charged by a very small leakage current from the auxiliary power supply circuit P200 will be specifically described. When the main power supply circuit P100 is turned on, the output voltage rises in the same manner as in the normal case described above. When the potential of the voltage detection terminal of the shunt regulator P12 becomes equal to or higher than a predetermined voltage, the shunt regulator P12 transitions to the conducting state. However, the feedback capacitor P14 has already been charged by a small leak current from the auxiliary power supply circuit P200. Therefore, during a required period until the potential of the feedback capacitor P14 becomes equal to or lower than the original voltage during normal operation, the photocoupler P1
No current flows through the photodiode within 0. as a result,
Feedback is not applied to the control circuit P8 on the primary side, and the control circuit P8 is in an uncontrolled state, resulting in overshoot and overvoltage.

On the other hand, the power supply device 300 of the present embodiment
The provision of the discharging means (discharging resistor R ₁ ) prevents the feedback capacitor 14 of the feedback circuit 7 from being charged, so that even if there is a leak current from the auxiliary power supply circuit 200, feedback is provided. This has the effect that overvoltage does not appear late.

As described above, according to the first embodiment, the discharging means (discharging resistor R ₁ ) is provided to form a discharging route to the feedback capacitor 14, so that the feedback capacitor 14 mainly due to the leak current is discharged. As a result of eliminating the charging phenomenon, it is possible to avoid problems such as output overshoot and overvoltage during power supply rise control.

The auxiliary power supply circuit 200 and the main power supply circuit 1
Even when 00 is extremely close, or in a case where a leak current occurs due to a decrease in the flux or the resistance value of the substrate in high humidity or dew condensation, the charging phenomenon of the feedback capacitor 14 mainly caused by the leak current is eliminated. As a result, the mounting distance of the components can be shortened, and in addition, the moisture resistance of the power supply can be improved.

(Second Embodiment) FIG. 2 is a circuit diagram for explaining a second embodiment of the power supply device according to the present invention.
The power supply device 300 of the present embodiment includes two power supply circuits such as an auxiliary power supply circuit 200 and a main power supply circuit 100, and the input sides of the main power supply circuit 100 and the auxiliary power supply circuit 200 are connected in parallel to the output side of the bridge diode 1. The output sides of the main power supply circuit 100 and the auxiliary power supply circuit 200 are connected to the power supply 30.
0 is connected in parallel to the DC output side. Referring to FIG. 2, 1 is a bridge diode for rectifying an AC voltage (for example, 100 V AC commercial voltage), 2 is a smoothing capacitor,
3 is a main switching element, 4 is a transformer for converting voltage to the secondary side and transmitting power, 5 is a rectifying section on the secondary side, 6
Denotes a secondary-side smoothing unit, 7 denotes an output voltage, and a primary-side control circuit 8
Is a control circuit for controlling a main switching element for maintaining the output voltage at an arbitrary voltage.

In general, in the power supply device 300 in which the feedback circuit 7 to the primary side of the power supply control is composed of the photocoupler 10 and the shunt regulator 12, the line of the cathode terminal of the shunt regulator 12 has a diode backflow prevention circuit or the like. Since it does not exist, it is not considered at all that a circuit-like leakage current normally occurs. However, when the cathode terminal of the shunt regulator 12 is at or above a predetermined potential due to a small leak current generated when flux or PCB absorbs moisture when the power is turned off (the predetermined potential is determined by the size of the feedback capacitor 14 of the feedback circuit 7). (Depends on the cathode terminal potential of the shunt regulator 12 during normal operation), a delay occurs in the current draw of the shunt regulator 12 when the power is turned on, and the light emission of the photocoupler 10 is delayed. As a result, feedback is delayed and overshoot occurs. Comes out.

Therefore, the feedback circuit 7, which is a control part of the main power supply circuit 100 of this embodiment,
When 0 is OFF, the feedback capacitor 14
Is not charged, that is, the potential of the cathode terminal of the shunt regulator 12 does not rise more than a certain level due to a small leak current.
Thereby connecting the connection point between one end of the second cathode and the feedback capacitor 14 to the cathode terminal of the clamping means (clamping Zener diode D _z), which pull down the anode terminal of the clamping Zener diode D _z to the ground potential.

That is, a voltage value at which no overshoot occurs in the clamping means (clamping zener diode D _z ) (depending on the component characteristics and constants of the feedback circuit 7) so that the cathode terminal of the shunt regulator 12 does not exceed a certain voltage. By clamping below the voltage value, output overshoot due to this cause can be easily prevented. In addition, there is a possibility that a voltage is generated at the cathode terminal of the shunt regulator 12 before the power is turned on.
Although leakage current due to moisture absorption of CB and uncleaned flux is conceivable, the present embodiment can improve the moisture resistance. Since the control circuit 8 is well known to those skilled in the art and is not directly related to the present invention, its detailed configuration is omitted.

The operation of this embodiment will be described below.
First, a normal operation will be described. In the power supply device 300 of the present embodiment, usually, the feedback capacitor 14
Is not charged, the main power supply circuit 100 is turned on.
At this time, when the output voltage (indicated as DC output in the figure) rises and the potential of the voltage detection terminal of the shunt regulator P12 becomes equal to or higher than a predetermined voltage, the shunt regulator P12 transitions to the conducting state and the photodiode in the photocoupler 10 An ON current flows and the photocoupler 10 is turned on. As a result, the voltage is normally controlled by applying feedback to the primary-side control circuit 8, so that the output voltage of the power supply device 300 is stabilized without overshoot or overvoltage.

That is, even if there is a leakage current from the auxiliary power supply circuit 200 to the feedback capacitor 14, the feedback capacitor 14 is not charged, so that the operation is always normal. In other words, even when an unexpected leak current occurs due to the absorption of flux or the like in the feedback circuit that is the main power supply control, an overshoot (overvoltage) occurs at the start-up by avoiding the delay in the power supply control. This has the effect that it can be prevented.

On the other hand, the above-mentioned conventional power supply device P300
Has two power supply circuits such as an auxiliary power supply circuit P200 and a main power supply circuit P100.
If there is a leakage current from the auxiliary power supply circuit P200 to the feedback capacitor P14 of the feedback circuit P7 of the main power supply circuit P100 during the FF period, the clamping means (clamping Zener diode D
_z ), the feedback capacitor P14 of the feedback circuit P7 is charged, and the output of the feedback circuit P7 draws current from the charged feedback capacitor P14 at the time of rising when the main power supply circuit P100 is turned on. Feedback is delayed and overvoltage occurs.

The operation when the feedback capacitor P14 is charged by a very small leak current from the auxiliary power supply circuit P200 will be specifically described. When the main power supply circuit P100 is turned on, the output voltage rises in the same manner as in the normal state. When the potential of the voltage detection terminal of the shunt regulator P12 becomes equal to or higher than a predetermined voltage, the shunt regulator P12 transitions to the conducting state. However, the feedback capacitor P14 has already been charged by a small leak current from the auxiliary power supply circuit P200. Therefore, during a required period until the potential of the feedback capacitor P14 becomes equal to or lower than the original voltage during normal operation, the photocoupler P1
No current flows through the photodiode within 0. as a result,
Feedback is not applied to the control circuit P8 on the primary side, and the control circuit P8 is in an uncontrolled state, resulting in overshoot and overvoltage.

On the other hand, the power supply device 300 of the present embodiment
Then, the clamping means (Zener diode D for clamping)
_{Since z} ) is provided, it is possible to prevent the feedback capacitor 14 of the feedback circuit 7 from being charged beforehand. Therefore, even if there is a leak current from the auxiliary power supply circuit 200, the feedback is delayed and an overvoltage is not generated. It works.

As described above, according to the second embodiment, by providing the clamping means (clamping Zener diode D _z ), it is possible to avoid problems such as output overshoot and overvoltage during power supply rising control. Become. Further, even when the auxiliary power supply circuit 200 and the main power supply circuit 100 are extremely close to each other, or in a case where a leak current occurs due to a reduction in the flux or the resistance value of the substrate or condensation in high humidity, the leak current is mainly caused by the leak current. As a result, the charging phenomenon of the feedback capacitor 14 can be eliminated. As a result, the mounting distance of the components can be shortened, and in addition, the moisture resistance of the power supply can be improved.

It should be noted that the present invention is not limited to the above embodiments, and each embodiment can be appropriately modified within the scope of the technical idea of the present invention. Further, the number, position, shape, and the like of the constituent members are not limited to the above-described embodiment,
The number, position, shape, and the like suitable for carrying out the present invention can be obtained. In each drawing, the same components are denoted by the same reference numerals.

[0031]

Since the present invention is configured as described above, the following effects can be obtained. First, when a discharge route (discharge resistor) is provided to form a discharge route to the feedback capacitor, the charging phenomenon of the feedback capacitor mainly caused by the leakage current can be eliminated. Problems such as output overshoot and overvoltage can be avoided. Secondly, when the clamp means (clamping zener diode) is provided, it is possible to avoid problems such as output overshoot and overvoltage at the time of power supply rising control. Third, by providing a discharging means (discharging resistor) or a clamping means (clamping Zener diode), when the auxiliary power supply circuit and the main power supply circuit are extremely close to each other, or when the humidity or the resistance value of the substrate in high humidity decreases, Even in cases where condensation occurs and leakage current occurs, the charging phenomenon of the feedback capacitor mainly caused by the leakage current can be eliminated, so that the mounting distance of components can be shortened, and in addition, the power supply This has the effect of increasing the moisture resistance.

[Brief description of the drawings]

FIG. 1 is a circuit diagram illustrating a first embodiment of a power supply device according to the present invention.

FIG. 2 is a circuit diagram illustrating a power supply device according to a second embodiment of the present invention.

FIG. 3 is a circuit diagram for explaining a conventional power supply device.

[Explanation of symbols]

DESCRIPTION OF SYMBOLS 1 ... Bridge diode 2 ... Smoothing capacitor 3 ... Main switching element 4 ... Transformer 5 ... Secondary side rectification part 6 ... Secondary side smoothing part 7 ... Feedback circuit 8 ... Control circuit 10 ... Photocoupler 12 ... Shunt regulator 14 ... feedback capacitor 100 ... main power supply circuit 200 ... auxiliary power supply circuit 300 ... power supply D z _... clamping zener diode (clamping means) R 1 _... discharge resistor (discharge means)

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[Procedure amendment]

[Submission date] February 2, 2000 (200.2.2)

[Procedure amendment 1]

[Document name to be amended] Statement

[Correction target item name] Claims

[Correction method] Change

[Correction contents]

[Claims]

Wherein said discharging means is a resistor element, according to claim 1 which is the resistance element, characterized in that it is connected between ground and the cathode terminal of the shunt regulator
A power supply according to claim 1.

Wherein said discharge means is a resistance element having a resistance value of approximately 1 M.OMEGA, in claim 2 in which the said resistive element, characterized in that it is connected between ground and the cathode terminal of the shunt regulator The power supply as described.

4. A power supply device for preventing a delay in power supply control and an overshoot at start-up even if a leak current occurs in a feedback circuit which is a power supply control main body. A bridge diode for rectifying the AC voltage to be supplied, and two power supply circuits including an auxiliary power supply circuit and a main power supply circuit, and the input sides of the main power supply circuit and the auxiliary power supply circuit are connected in parallel to the output side of the bridge diode. The main power supply circuit and the output side of the auxiliary power supply circuit are connected in parallel to the output voltage side, the main power supply circuit is a switching element for maintaining an output voltage at an arbitrary voltage, a control circuit for controlling the switching element, A feedback circuit for transmitting an output voltage to the control circuit, wherein the feedback circuit includes an O of the main power supply circuit. A shunt regulator for generating and outputting a detection signal informing the control circuit that the output voltage is detected that reaches or exceeds the predetermined voltage at the time, the shunt regulator
Compensation capacitor connected between the cathode and output voltage terminals of
From the output voltage terminal of the shunt regulator
Voltage dividing resistance element for dividing the output voltage of the
When the live part is in the vicinity at F
Unexpected leakage current to the capacitor
Output voltage feed when the sensor is charged
Due to start-up overshoot which causes delay in back
The compensation capacitor is charged mainly due to leakage current
A bypass circuit for preventing the detection signal from being detected.
To the control circuit to perform predetermined voltage control.
And the bypass circuit is turned off when the main power supply circuit is turned off.
Is the potential of the cathode terminal of the shunt regulator.
The potential of the compensation capacitor rises above a predetermined potential.
A power supply device comprising a clamp unit for preventing the power supply from being performed.

Wherein said clamping means is a Zener diode, the cathode terminal of the Zener diode is connected to the cathode terminal of the shunt regulator, an anode terminal of the Zener diode is connected to the anode terminal of the shunt regulator The power supply device according to claim 4 , wherein:

[Procedure amendment 2]

[Document name to be amended] Statement

[Correction target item name] 0007

[Correction method] Change

[Correction contents]

[0007]

The gist of the present invention is to prevent a delay in power supply control from being started even when a leak current occurs in a feedback circuit which is a power supply control main body. A power supply device for preventing the occurrence of overshoot sometimes, comprising a bridge diode for rectifying an input AC voltage, and two power supply circuits including an auxiliary power supply circuit and a main power supply circuit. The input side of the power supply circuit is connected in parallel to the output side of the bridge diode, the output side of the main power supply circuit and the output side of the auxiliary power supply circuit are connected in parallel to the output voltage side, and the main power supply circuit changes the output voltage to an arbitrary voltage. A switching element for maintaining the switching element, a control circuit for controlling the switching element, and a feedback circuit for transmitting an output voltage to the control circuit. Feedback circuit includes a shunt regulator for generating and outputting a detection signal informing the control circuit that the output voltage at the time of ON of the main power supply circuit is detected that reaches or exceeds a predetermined voltage, said Shan
Connected between the cathode of the regulator and the output voltage terminal.
And the output of the shunt regulator
Voltage-dividing resistance element that divides the output voltage from the input voltage terminal
And when the live part is near when the output power is off
Unexpected leakage current occurs in the compensation capacitor.
If the compensation capacitor is charged
Overrun at start-up with delay in feedback of force voltage
The compensation capacitor mainly due to the
A bypass circuit is provided to prevent the capacitor from being charged.
The detection signal is fed back to the control circuit.
Is configured to instruct predetermined voltage control, and
The bypass circuit is activated when the main power supply circuit is turned off.
Before the potential of the cathode terminal of the shunt regulator
The potential of the compensation capacitor rises above a predetermined potential.
Power supply device characterized by having a discharging means for preventing the above . Further, the gist of the invention according to claim 2, wherein the discharging means is a resistor element, according to claim 1 which is the resistance element, characterized in that it is connected between ground and the cathode terminal of the shunt regulator The power supply device according to (1). Further, the gist of the invention according to claim 3, wherein the discharge means is a resistance element having a resistance value of approximately 1 M.OMEGA, that is the resistance element is connected between the ground potential and the cathode terminal of the shunt regulator Characterized by
The power supply device according to claim 2 is provided. In addition, the gist of the invention described in claim 4 is to prevent the occurrence of a delay in power supply control and the occurrence of overshoot at startup even when a leak current occurs in a feedback circuit that is the main power supply control. A power supply device, comprising: a bridge diode for rectifying an input AC voltage; and two power supply circuits including an auxiliary power supply circuit and a main power supply circuit, and the input sides of the main power supply circuit and the auxiliary power supply circuit are bridge diodes. The output side of the main power supply circuit and the auxiliary power supply circuit are connected in parallel to the output voltage side, and the main power supply circuit is a switching element for maintaining an output voltage at an arbitrary voltage. A control circuit for controlling a switching element, a feedback circuit for transmitting an output voltage to the control circuit, wherein the feedback circuit The main and shunt regulator in which the output voltage at the time of ON of the power supply circuit generates and outputs a detection signal informing the control circuit that it has detected that reaches or exceeds the predetermined voltage, the cathode of the shunt regulator - Output voltage terminal
A compensating capacitor connected between the
To divide the output voltage from the output voltage terminal of the regulator.
Voltage resistance element and the live part near output power off
Unexpected leak at one time for the compensating capacitor
When current is generated and the compensation capacitor is charged
Cause a delay in output voltage feedback.
This is mainly due to leakage current due to overshoot during operation.
A bias that prevents the compensation capacitor from being charged
A pass circuit for feeding the detection signal to the control circuit.
And is configured to instruct predetermined voltage control
The bypass circuit turns off the main power supply circuit.
The shunt regulator's cathode terminal
The potential of the compensation capacitor, which is a potential, is equal to or higher than a predetermined potential.
The power supply device further comprises a clamp means for preventing the power device from rising . The gist of the invention according to claim 5 is that the clamping means is a Zener diode, a cathode terminal of the Zener diode is connected to a cathode terminal of the shunt regulator, and an anode terminal of the Zener diode is connected to the shunt regulator. The power supply device according to claim 4 , wherein the power supply device is connected to an anode terminal of the power supply. ────────────────────────────────────────────────── ───

[Procedure amendment]

[Submission Date] May 12, 2000 (2000.5.1)
2)

[Procedure amendment 1]

[Document name to be amended] Statement

[Correction target item name] Claims

[Correction method] Change

[Correction contents]

[Claims]

1. A power supply device for preventing a delay in power supply control and an overshoot at start-up even if a leak current occurs in a feedback circuit which is a power supply control main body. A bridge diode for rectifying the AC voltage to be supplied, and two power supply circuits including an auxiliary power supply circuit and a main power supply circuit, and the input sides of the main power supply circuit and the auxiliary power supply circuit are connected in parallel to the output side of the bridge diode. The main power supply circuit and the output side of the auxiliary power supply circuit are connected in parallel to the output voltage side, the main power supply circuit is a switching element for maintaining an output voltage at an arbitrary voltage, a control circuit for controlling the switching element, A feedback circuit for transmitting an output voltage to the control circuit, wherein the feedback circuit includes an O of the main power supply circuit. A shunt regulator that generates and outputs a detection signal that informs the control circuit that the output voltage has reached a predetermined voltage or more, and a compensation capacitor connected between a cathode and an output voltage terminal of the shunt regulator. A voltage dividing resistor for dividing an output voltage from an output voltage terminal of the shunt regulator, and an output power supply OF
Overshoot at start-up when an unexpected leakage current occurs in the compensation capacitor when the live part is near at the time of F and the compensation capacitor is charged, and the feedback of the output voltage is delayed. A bypass circuit for preventing the compensation capacitor from being charged mainly due to a leakage current caused by the control circuit, and configured to feed back the detection signal to the control circuit to instruct a predetermined voltage control; Comprises a discharging means for preventing the potential of the compensating capacitor, which is the potential of the cathode terminal of the shunt regulator, from rising to a predetermined potential or more when the main power supply circuit is turned off . Cathode
Small leakage current when connected between terminal and ground potential
Prevents charging of the phase compensation capacitor due to
A power supply device comprising a resistance element.

Wherein said discharge means is a resistance element having a resistance value of approximately 1 M.OMEGA, in claim 1 which is the resistance element, characterized in that it is connected between ground and the cathode terminal of the shunt regulator The power supply as described.

3. A power supply device for preventing occurrence of a delay in power supply control and occurrence of overshoot at startup even when a leakage current occurs in a feedback circuit which is a power supply control main body. A bridge diode for rectifying the AC voltage to be supplied, and two power supply circuits including an auxiliary power supply circuit and a main power supply circuit, and the input sides of the main power supply circuit and the auxiliary power supply circuit are connected in parallel to the output side of the bridge diode. The main power supply circuit and the output side of the auxiliary power supply circuit are connected in parallel to the output voltage side, the main power supply circuit is a switching element for maintaining an output voltage at an arbitrary voltage, a control circuit for controlling the switching element, A feedback circuit for transmitting an output voltage to the control circuit, wherein the feedback circuit includes an O of the main power supply circuit. A shunt regulator that generates and outputs a detection signal that informs the control circuit that the output voltage has reached a predetermined voltage or more, and a compensation capacitor connected between a cathode and an output voltage terminal of the shunt regulator. A voltage dividing resistor for dividing an output voltage from an output voltage terminal of the shunt regulator, and an output power supply OF
Overshoot at start-up when an unexpected leakage current occurs in the compensation capacitor when the live part is near at the time of F and the compensation capacitor is charged, and the feedback of the output voltage is delayed. A bypass circuit for preventing the compensation capacitor from being charged mainly due to a leakage current caused by the control circuit, and configured to feed back the detection signal to the control circuit to instruct a predetermined voltage control; is provided with clamping means to prevent the potential of the compensating capacitor is the potential of the cathode terminal of the shunt regulator during OFF of the main power supply circuit rises above a predetermined voltage, said clamping means, cathode terminal wherein Chantregi
Connected to the cathode terminal of the
Connected to the anode terminal of the shunt regulator
And the leakage current of the phase compensating capacitor
A power supply device comprising a Zener diode for preventing charging .

[Procedure amendment 2]

[Document name to be amended] Statement

[Correction target item name] 0007

[Correction method] Change

[Correction contents]

[0007]

The gist of the invention described in claim 1 of the present invention is to avoid a delay in power supply control even if a leak current occurs in a feedback circuit which is a power supply control main body. A power supply device for preventing overshoot from occurring at start-up, comprising: a bridge diode for rectifying an input AC voltage; and two power supply circuits including an auxiliary power supply circuit and a main power supply circuit. And the input side of the auxiliary power supply circuit is connected in parallel to the output side of the bridge diode, and the output side of the main power supply circuit and the auxiliary power supply circuit is connected in parallel to the output voltage side. , A control circuit for controlling the switching element, and a feedback circuit for transmitting an output voltage to the control circuit Wherein the feedback circuit,
A shunt regulator that generates and outputs a detection signal that notifies the control circuit that the output voltage has reached a predetermined voltage or more when the main power supply circuit is ON;
A compensating capacitor connected between the cathode and the output voltage terminal of the shunt regulator, a voltage-dividing resistance element for dividing the output voltage from the output voltage terminal of the shunt regulator, and a live portion near the output power supply when the power supply is off. When unexpected leakage current occurs in the compensating capacitor and the compensating capacitor is charged, the feedback of the output voltage is delayed. A bypass circuit for preventing the capacitor for charging from being charged, and configured to feed back the detection signal to the control circuit to instruct a predetermined voltage control, wherein the bypass circuit is provided when the main power supply circuit is turned off. The compensation shunt regulator, which is the potential of the cathode terminal of the shunt regulator. Comprising a discharge means to prevent the potential of the capacitor rises above a predetermined potential, said discharge means, before
Between the cathode terminal of the shunt regulator and ground potential
The phase compensation by a small leak current in the connected state
Resistance element that prevents charging of the capacitor
A power supply device characterized by the following . Claims of the present invention
The gist of the invention described in Item 2 is that the discharging means is a resistance element having a resistance value of about 1 MΩ, and the resistance element is connected between a cathode terminal of the shunt regulator and a ground potential. The power supply device according to claim 1 . The gist of the invention described in claim 3 of the present invention is that even when a leakage current occurs in a feedback circuit which is a power supply control main body, a delay in power supply control is avoided and an overshoot at startup is prevented. A power supply device for preventing generation, comprising a bridge diode for rectifying an input AC voltage, and two power supply circuits including an auxiliary power supply circuit and a main power supply circuit, and an input of the main power supply circuit and the auxiliary power supply circuit. Side is connected in parallel to the output side of the bridge diode, the output side of the main power supply circuit and the auxiliary power supply circuit is connected in parallel to the output voltage side,
The main power supply circuit includes a switching element for maintaining an output voltage at an arbitrary voltage, a control circuit for controlling the switching element, and a feedback circuit for transmitting an output voltage to the control circuit. A shunt regulator that generates and outputs a detection signal that notifies the control circuit that the output voltage has reached a predetermined voltage or more when the circuit is ON, and a shunt regulator connected between the cathode and the output voltage terminal of the shunt regulator. A compensating capacitor, a voltage-dividing resistor for dividing the output voltage from the output voltage terminal of the shunt regulator, and an unexpected leakage current to the compensating capacitor when the live part is near when the output power is off. Occurs when the compensation capacitor is charged and the output voltage is A bypass circuit for preventing the compensation capacitor from being charged mainly due to a leak current due to an overshoot at the time of start-up which causes a delay in startup, and instructing a predetermined voltage control by feeding back the detection signal to the control circuit. The bypass circuit is provided with a clamp means for preventing the potential of the compensation capacitor, which is the potential of the cathode terminal of the shunt regulator, from rising above a predetermined potential when the main power supply circuit is turned off. The clamping means is provided with
Sword terminal is the cathode terminal of the shunt regulator
And the anode terminal of the shunt regulator
When connected to the anode terminal,
To prevent charging of the phase compensation capacitor.
Power supply device characterized in that the power supply device is a power diode .

Claims (7)

[Claims] 1. A power supply device for preventing a delay in power supply control and an overshoot at start-up even when a leakage current occurs in a feedback circuit which is a power supply control main body. A bridge diode for rectifying the AC voltage to be supplied, and two power supply circuits including an auxiliary power supply circuit and a main power supply circuit, and the input sides of the main power supply circuit and the auxiliary power supply circuit are connected in parallel to the output side of the bridge diode. The main power supply circuit and the output side of the auxiliary power supply circuit are connected in parallel to the output voltage side, the main power supply circuit is a switching element for maintaining an output voltage at an arbitrary voltage, a control circuit for controlling the switching element, A feedback circuit for transmitting an output voltage to the control circuit, wherein the feedback circuit turns on the main power supply circuit; A shunt regulator that generates and outputs a detection signal to notify the control circuit that the output voltage has reached a predetermined voltage or higher, and that the main power supply circuit is turned off.
Discharge means for preventing the potential of the cathode terminal of the shunt regulator from rising to a predetermined potential or more at the time, and configured to feed back the detection signal to the control circuit to instruct predetermined voltage control. A power supply device characterized by the above-mentioned. 2. A power supply device for preventing occurrence of a delay in power supply control and occurrence of overshoot at start-up even if a leak current occurs in a feedback circuit which is a power supply control main body. A bridge diode for rectifying the AC voltage to be supplied, and two power supply circuits including an auxiliary power supply circuit and a main power supply circuit, and the input sides of the main power supply circuit and the auxiliary power supply circuit are connected in parallel to the output side of the bridge diode. The main power supply circuit and the output side of the auxiliary power supply circuit are connected in parallel to the output voltage side, the main power supply circuit is a switching element for maintaining an output voltage at an arbitrary voltage, a control circuit for controlling the switching element, A feedback circuit for transmitting an output voltage to the control circuit, wherein the feedback circuit includes an output of the main power supply circuit. A feedback capacitor that detects a voltage, a shunt regulator that generates and outputs a detection signal that informs the control circuit that the potential of the feedback capacitor has reached a predetermined voltage or more, and that the main power supply circuit is turned off. Discharging means for preventing the potential of the cathode terminal of the shunt regulator connected to the feedback capacitor from rising above a predetermined potential is provided, and the detection signal is fed back to the control circuit to instruct a predetermined voltage control. A power supply characterized by being constituted. 3. The device according to claim 1, wherein the discharging means is a resistance element, and the resistance element is connected between a cathode terminal of the shunt regulator and a ground potential.
Or the power supply device according to 2. 4. The device according to claim 1, wherein the discharging means is a resistance element having a resistance value of about 1 MΩ, and the resistance element is connected between a cathode terminal of the shunt regulator and a ground potential. 3. The power supply device according to 2. 5. A power supply device for preventing a delay in power supply control and an overshoot at start-up even when a leakage current occurs in a feedback circuit which is a power supply control main body. A bridge diode for rectifying the AC voltage to be supplied, and two power supply circuits including an auxiliary power supply circuit and a main power supply circuit, and the input sides of the main power supply circuit and the auxiliary power supply circuit are connected in parallel to the output side of the bridge diode. The main power supply circuit and the output side of the auxiliary power supply circuit are connected in parallel to the output voltage side, the main power supply circuit is a switching element for maintaining an output voltage at an arbitrary voltage, a control circuit for controlling the switching element, A feedback circuit for transmitting an output voltage to the control circuit, wherein the feedback circuit turns on the main power supply circuit; A shunt regulator that generates and outputs a detection signal to notify the control circuit that the output voltage has reached a predetermined voltage or higher, and that the main power supply circuit is turned off.
A clamping means for preventing a potential of a cathode terminal of the shunt regulator from rising to a predetermined potential or more at a time, and configured to feed back the detection signal to the control circuit to instruct a predetermined voltage control. A power supply device characterized by the above-mentioned. 6. A power supply device for preventing occurrence of a delay in power supply control and occurrence of overshoot at startup even when a leakage current occurs in a feedback circuit which is a power supply control main body. A bridge diode for rectifying the AC voltage to be supplied, and two power supply circuits including an auxiliary power supply circuit and a main power supply circuit, and the input sides of the main power supply circuit and the auxiliary power supply circuit are connected in parallel to the output side of the bridge diode. The main power supply circuit and the output side of the auxiliary power supply circuit are connected in parallel to the output voltage side, the main power supply circuit is a switching element for maintaining an output voltage at an arbitrary voltage, a control circuit for controlling the switching element, A feedback circuit for transmitting an output voltage to the control circuit, wherein the feedback circuit includes an output of the main power supply circuit. A feedback capacitor that detects a voltage, a shunt regulator that generates and outputs a detection signal that informs the control circuit that the potential of the feedback capacitor has reached a predetermined voltage or more, and that the main power supply circuit is turned off. A clamp means for preventing the potential of the cathode terminal of the shunt regulator connected to the feedback capacitor from rising above a predetermined potential is provided, and the detection signal is fed back to the control circuit to instruct a predetermined voltage control. A power supply characterized by being constituted. 7. The clamping means is a Zener diode, wherein a cathode terminal of the Zener diode is connected to a cathode terminal of the shunt regulator, and an anode terminal of the Zener diode is connected to an anode terminal of the shunt regulator. The power supply device according to claim 5, wherein: