JPH08251915A - Switching regulator - Google Patents

Abstract

PURPOSE: To protect a load circuit surely against overvoltage regardless of the load conditions by simplifying the circuitry pertaining to the overvoltage protective function. CONSTITUTION: When an overvoltage detection circuit 8 detects an output voltage from a regulator exceeding an overvoltage detection level, oscillation of a pulse width control circuit 6 is interrupted forcibly with a predetermined time lag being set by an overvoltage detection lag circuit 9 and a latch circuit 10. If the duty ratio of switching pulse is suppressed by a pulse width regulation circuit 11 during that interval, abnormal increase of overvoltage is suppressed and the oscillation is interrupted while lowering the output voltage gradually.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a switching regulator provided with an overvoltage protection function, and more particularly to a duty cycle of a switching pulse generated from a pulse width control circuit while an overvoltage is detected by an overvoltage detection circuit. The present invention relates to a switching regulator configured to forcibly stop the generation of a switching pulse after a predetermined time has elapsed from the time of detecting an overvoltage while suppressing the ratio.

[0002]

2. Description of the Related Art Up to now, as a switching regulator having an overvoltage protection function, there has been known one disclosed in, for example, JIII Journal of Technical Disclosure No. 93-12458. FIG. 9 shows a schematic configuration of the switching regulator, and FIG. 10 shows an operation waveform thereof. In this case, from the time when the overvoltage is detected,
If there is a delay before the oscillation circuit stops oscillating, the output voltage transiently exceeds the overvoltage standard upper limit value, but the overvoltage exceeding this overvoltage standard upper limit value is suppressed by the output short circuit. Here, the circuit operation (for details, refer to the above-mentioned public technical report) will be described below.

That is, if some abnormality occurs and the switching regulator falls into an uncontrollable state and an overvoltage occurs due to an abnormal increase in the output voltage, the auxiliary winding voltage of the transformer is linked with the abnormal increase in the output voltage. However, if the auxiliary winding voltage exceeds a certain value and an overvoltage is detected, the operation of the oscillation stop circuit stops the oscillation operation in the oscillation circuit. However, if there is a delay from the detection of overvoltage to the stop of oscillation, the output voltage transiently exceeds the upper limit value of the overvoltage standard. In addition to establishing overvoltage upper limit standards, in order to satisfy these standards, in the output short circuit, the internal transistor is immediately turned on by the overvoltage, and the electrolytic capacitor that constitutes the smoothing circuit passes through a resistor. The transient overvoltage is suppressed by forcibly discharging the electric charge.

On the other hand, the magazine "Electronic Technology Special Increasing Issue" (March 1989, published by Nikkan Kogyo Shimbun, No. 68)
Page) describes a "protection circuit", and FIG. 11 shows the circuit configuration when the overvoltage protection circuit described therein is applied to a switching regulator. In this case, the overvoltage protection circuit 7 is composed of the overvoltage detection circuit 8, the overvoltage detection delay circuit 9 and the latch circuit 10, and when the overvoltage detection circuit 8 detects the overvoltage,
The oscillation operation in the pulse width control circuit 6 is stopped for the first time after a predetermined time. Here, the circuit operation in the case where a failure occurs in the pulse width control circuit 6 or the error amplifier 5 for stabilizing the output voltage will be described below.

That is, when the pulse width control circuit 6 or the error amplifier 5 fails, the switching pulse given from the pulse width control circuit 6 to the switching transistor 13 has its pulse width expanded to the maximum set value, and therefore, is output. Overvoltage is generated. This overvoltage is detected by the overvoltage detection unit 20 in the overvoltage detection circuit 8 and the photocoupler 16 is operated. However, this overvoltage detection output is not immediately transmitted to the pulse width control circuit 6 and the overvoltage detection delay is generated. It is transmitted through the circuit 9 and the latch circuit 10. The overvoltage detection output is delayed by the mask time determined by the resistors 17 and 18 and the capacitor 19 which constitute the overvoltage detection delay circuit 9, and is transmitted to the pulse width control circuit 6 through the latch circuit 10 and its oscillation operation is performed. Is the one that has been stopped. Therefore, as a result of the pulse width of the switching pulse to the switching transistor 13 being maintained at the maximum set value state for the mask time from the time point when the overvoltage detection circuit 8 detects the overvoltage, the overvoltage still increases its voltage value. After continuing the mask time, the switching pulse from the pulse width control circuit 6 to the switching transistor 13 is stopped, and thereafter, the output voltage is gradually decreased from the overvoltage state.

[0006]

[Problems to be Solved by the Invention] However, the above 2
In each of the two conventional techniques, there is a problem that the delay time from the time when the overvoltage is detected to the time when the oscillation operation is actually stopped by the pulse width control circuit is relatively long, which causes the overvoltage standard to be exceeded. Further, particularly in the case of the latter prior art, if the mask time by the overvoltage detection delay circuit is set to be short, the oscillation operation stop easily occurs due to malfunction in the overvoltage detection circuit due to static electricity or external noise. On the contrary, if the mask time is set to be long, the impedance of the load looks large at light load, the rise of the overvoltage becomes sharp, and more time is required until the switching pulse generation in the pulse width control circuit is stopped. Therefore, in some cases, an overvoltage that is several times or more the rated output voltage may be instantaneously generated. On the other hand, as a trend in recent years, in consideration of the fact that the switching regulator is often used from the no-load state along with the reduction in loss of electronic circuits generally connected to the switching regulator as a load, future switching will be considered.・ Regarding demands for regulators, in addition to further downsizing, reliable protection from overvoltage in the load circuit is required regardless of load conditions.

A first object of the present invention is to provide a switching regulator capable of reliably protecting a load circuit from overvoltage regardless of load conditions by simplifying the circuit structure relating to the overvoltage protection function. A second object of the present invention is to provide a switching regulator capable of surely protecting a load circuit from overvoltage regardless of load conditions, with a circuit configuration relating to an overvoltage protection function being simple and more integrated. It is in.

[0008]

SUMMARY OF THE INVENTION The first purpose is basically to provide a circuit between an overvoltage detection circuit and a pulse width control circuit,
This is achieved by providing a pulse width adjustment circuit that acts to suppress the duty ratio of the switching pulse generated from the pulse width control circuit while the overvoltage detection output is being obtained from the overvoltage detection circuit. The second purpose is also
This is achieved by configuring the pulse width adjustment circuit provided between the overvoltage detection circuit and the pulse width control circuit as at least an integrated circuit integrated with the pulse width control circuit.

[0009]

When the overvoltage detection circuit detects that the smoothed output voltage (switching regulator output voltage) is at the overvoltage detection level or higher, the pulse width control circuit stops oscillation after a predetermined time. The pulse width adjustment circuit is newly provided between the overvoltage detection circuit and the pulse width control circuit. While the overvoltage detection output is continuously obtained from the detection circuit), if the duty ratio of the switching pulse generated from the pulse width control circuit is suppressed to be small, not only the abnormal rise of the overvoltage is suppressed, As a result of shifting to the oscillation stop state while the smoothed output voltage is gradually decreased, the circuit configuration related to the overvoltage protection function is simple. To, regardless of the load condition, the load circuit is one that can be reliably protected from an overvoltage.

[0010]

DESCRIPTION OF THE PREFERRED EMBODIMENTS The present invention will be described below with reference to FIGS. First, the general configuration of the switching regulator according to the present invention will be described. FIG. 1 shows the general configuration as a single-stone forward converter type switching regulator. As shown in the figure, the DC input voltage Vin from the input terminal is applied to the primary side of the transformer 2 via the input filter 1 and the switching transistor 3, and the switching transistor 3 controls the pulse width in this state. By performing switching control with a switching pulse of a predetermined cycle from the circuit 6, power conversion of the DC input voltage Vin to the secondary side of the transformer 2 is performed. The converted power to the secondary side is rectified and smoothed by the rectifying / smoothing circuit 4, so that the smoothed output voltage is obtained as the switching regulator output voltage V _o . The output voltage V _o is detected as a state in which the deviation voltage from the specified voltage (rated output voltage) is amplified by the error amplifier 5. Based on this deviation voltage, the pulse width control circuit 6 switches the switching pulse to that pulse. Since the width is variably controlled, the output voltage V _o is controlled to be constantly maintained at the specified voltage.

[0011] Now, as a result of the pulse width of the switching pulse is spread abnormal by some kind of factor, assuming a case where the output voltage V _o falls into over-voltage state, the output voltage V _o is above the overvoltage detection level This is detected by the overvoltage detection circuit 8, but the overvoltage detection output from the overvoltage detection circuit 8 is delayed for a predetermined time by the overvoltage detection delay circuit 9 and then latched (held) by the latch circuit 10 to obtain the pulse width. Although the control circuit 6 is forcibly placed in the oscillation stopped state, the above circuit operation is similar to that of the switching regulator shown in FIG. A different point in the circuit operation is a pulse width adjusting circuit 11 newly provided between the overvoltage detecting circuit 8 and the pulse width controlling circuit 6.
Thus, the duty ratio of the switching pulse generated from the pulse width control circuit 6 is suppressed as small as possible from the time when the overvoltage is detected until the oscillation is stopped (while the overvoltage detection output is continuously obtained from the overvoltage detection circuit 8). It is that. When the duty ratio is controlled to be small, not only the abnormal rise of the overvoltage is suppressed but also the output voltage V _o is gradually lowered to the oscillation stop state. As a result, the circuit configuration is simple. Thus, regardless of load conditions, the load circuit can be reliably protected from overvoltage.

FIG. 2 shows the configuration of the switching regulator in which the essential parts are specifically configured, and FIG. 3 shows the operation of the overvoltage protection circuit when an overvoltage occurs. The operation of the overvoltage protection circuit will be described with reference to FIG. 3. As shown in FIG. 2, in the normal state, the deviation voltage from the error amplifier 5 is controlled by the pulse width control circuit 6.
When the output voltage a (output voltage V _o ) is lower than the specified voltage by being fed back to the input terminal FB of the internal PWM comparator 13 and compared with the triangular wave from the triangular wave oscillator 12, the output is made from the output terminal OUT. The switching pulse b to be generated is PWM-controlled so that its pulse width is wide and, if it is higher than the specified voltage, its pulse width is narrowed, so that the output voltage V _o always matches the specified voltage. It is controlled. By the way, in the PWM control in this normal state,
The maximum pulse width of the switching pulse b (in this example, the pulse width at a duty ratio of 70% is assumed) is set by the voltage d applied to the maximum pulse width setting terminal DTC. As shown in the figure, the reference voltage output from the reference voltage terminal REF is divided by the resistors 14 and 15, but the divided voltage at the resistor 15 (for example, 2.7 V) is the maximum pulse width setting terminal DTC.
Is applied to. As will be described later, when the overvoltage is detected, the diode as the pulse width adjusting circuit 11 is turned on, and the applied voltage d to the maximum pulse width setting terminal DTC is set to be higher than the divided voltage, so that the switching pulse is The pulse width of b is forcibly controlled to be narrower.

Now, assuming that the PWM control is disabled due to some factor and the pulse width of the switching pulse b suddenly expands to the maximum pulse width (corresponding to a duty ratio of 70%), the output voltage V _o is Although the overvoltage state occurs, this overvoltage state is detected by the overvoltage detection circuit 8. The overvoltage detection circuit 8, but the overvoltage state is detected by the overvoltage detector 20 which compares the output voltage V _o and the overvoltage detection level, the photocoupler 16 by overvoltage detection signal c from the voltage detection unit 20 is operating By being in the state, the overvoltage detection signal c is transmitted to the pulse width control circuit 8 via the overvoltage detection delay circuit 9 and the latch circuit 10. More specifically, as shown in the figure, in the resistors 17 and 18 inside the overvoltage detection delay circuit 9 by the overvoltage detection signal c, the reference voltage is divided via the phototransistor in the photocoupler 16, and the resistance 18 is divided. The capacitor 19 is charged by the divided voltage, and after the mask time (set to 1 ms in this example), the latch circuit 10 operates so that the overvoltage protection terminal OVP of the pulse width control circuit 6 becomes The voltage e state is maintained at "H". As a result, the oscillation operation in the pulse width control circuit 6 is stopped and the switching pulse b to the switching transistor 3 is also stopped.

By the way, during the mask time, the pulse width of the switching pulse b from the pulse width control circuit 6 is
Since the duty ratio, which is the maximum pulse width, has expanded to 70%, the output voltage V _o will continue to rise even after the overvoltage is detected until the switching pulse b is stopped, and some measure is taken. Obviously, if not taken, the output voltage V _o will exceed the overvoltage specification.
The pulse width adjusting circuit 11 is provided to prevent this.
Is a diode that also serves as a reverse current prevention. If the photocoupler 16 is activated by the overvoltage detection signal c, a voltage higher than 2.7 V (a voltage slightly lower than the reference voltage) is applied to the resistors 17 and 18, and the diode is turned on. Therefore, the voltage d of the maximum pulse width setting terminal DTC is instantaneously raised to around 4V, so that the pulse width of the switching pulse b is forcibly controlled to be narrower. As a result, within the mask time, the overvoltage rise is suppressed below the overvoltage standard regardless of the overvoltage protection operation speed (mask time) and the load state, and the breakdown of the load circuit due to the overvoltage can be prevented in advance. .

FIG. 4 also shows another switching regulator (one-stone flyback converter system) according to the present invention.
The above configuration is shown as a state in which a main portion thereof is specifically configured as a circuit. As shown in the figure, the main part is configured in the same way as the forward converter method, and the operation of the overvoltage protection circuit at the time of overvoltage occurrence is also the same. Therefore, further description is not required for this. it is obvious.

By the way, in each of the above switching regulators, a diode which also serves as a reverse current prevention is used as the pulse width adjusting circuit 11, but a transistor and a photocoupler can also be used. There is. FIG. 5 shows the configuration of the switching regulator according to the present invention when a transistor is used as the pulse width adjusting circuit. As shown in the figure, what is practically different from the previous ones is that the transistors are used as the pulse width adjusting circuit 11, and the configuration of the peripheral circuits is slightly changed. The overvoltage detection delay circuit 9 is similar to the conventional one. Therefore, the operation of the overvoltage protection circuit will be described below, mainly focusing on only the pulse width adjustment circuit 11.

That is, when an overvoltage is detected by the overvoltage detection unit 20, the phototransistor of the photocoupler 16 which is inserted in series between the resistors 17 and 18 is turned on so that both ends of the resistor 17 (transistor 17 A voltage drop occurs between the base and the emitter of the resistor, which causes the transistor to be turned on, and a current flows between the emitter and the collector, while the voltage across the resistor 14 is equal to the saturation voltage between the collector and the emitter (about 0.5V). Therefore, the voltage applied to the maximum pulse width setting terminal DTC is instantaneously raised to around 4.5 V at the time of detecting the overvoltage, and the same effect as in the case where the diode is used can be obtained.

FIG. 6 also shows the configuration of the switching regulator according to the present invention when a photocoupler is used as the pulse width adjusting circuit. In this case as well, for the same reason, the operation of the overvoltage protection circuit will be described focusing mainly on the pulse width adjustment circuit 11. If the overvoltage detection unit 20 detects an overvoltage, the resistances 17, 1 are detected.
The phototransistor of the photocoupler 16 which is inserted in series with respect to 8 is placed in the ON state. At the same time, since the phototransistor is also turned on in the photocoupler as the pulse width adjusting circuit 11 in which the light emitting diode is connected in series to the light emitting diode of the photocoupler 16, as in the case of the transistor, The voltage applied to the maximum pulse width setting terminal DTC by the phototransistor is instantaneously raised to around 4.5V at the time of detecting the overvoltage, so that the same effect as when the diode is used can be obtained.

Finally, the integration of the circuit configuration relating to the overvoltage protection function will be described. In both FIGS. 7 and 8, at least the pulse width control circuit and the pulse width adjusting circuit (diode, transistor) are integrated as an integrated circuit. 3 shows an internal configuration of the integrated circuit when configured.
I don't really need to explain this, but like this,
When the circuit configuration relating to the overvoltage protection function is configured in a more integrated state, the switching regulator as a whole can be downsized.

[0020]

As described above, according to the first to fourth aspects of the present invention, the switching circuit can simplify the circuit configuration relating to the overvoltage protection function and surely protect the load circuit from the overvoltage regardless of the load condition. In the regulator, according to claim 5, the load circuit can be surely protected from the overvoltage regardless of the load condition with the circuit configuration relating to the overvoltage protection function being simple and more integrated. Each switching regulator is available.

[Brief description of drawings]

FIG. 1 is a diagram showing a schematic configuration of a switching regulator according to the present invention.

FIG. 2 is a diagram showing a configuration of a switching regulator in which a main part is specifically configured in a circuit.

FIG. 3 is a diagram showing an operation of an overvoltage protection circuit when an overvoltage occurs in the switching regulator.

FIG. 4 is a diagram showing a configuration of another switching regulator according to the present invention in a state in which a main part thereof is specifically configured as a circuit.

FIG. 5 is a diagram showing a configuration of a switching regulator according to the present invention when a transistor is used as a pulse width adjusting circuit.

FIG. 6 is a diagram showing a configuration of a switching regulator according to the present invention when a photocoupler is used as a pulse width adjusting circuit.

FIG. 7 is a diagram showing an internal configuration of a pulse width control circuit and a pulse width adjusting circuit (diode) when the integrated circuit is integrally configured as an integrated circuit.

FIG. 8 is a diagram showing an internal configuration of the integrated circuit when the pulse width control circuit and the pulse width adjustment circuit (transistor) are integrally configured as an integrated circuit.

FIG. 9 is a diagram showing a schematic configuration of a switching regulator according to a related art, which is provided with an overvoltage protection function.

FIG. 10 is a diagram showing operation waveforms in the switching regulator.

FIG. 11 is a diagram showing a configuration of another switching regulator according to the related art, which is also provided with an overvoltage protection function.

[Explanation of symbols]

1 ... Input filter, 2 ... Transformer, 3 ... Switching transistor, 4 ... Rectifying / smoothing circuit, 5 ... Error amplifier, 6
... pulse width control circuit, 8 ... overvoltage detection circuit, 9 ... overvoltage detection delay circuit, 10 ... latch circuit, 11 ... pulse width adjustment circuit, 12 ... (triangular wave) oscillator, 13 ... PWM comparator

Front page continued (72) Inventor Masato Onizuka 180 Totsuka-cho, Totsuka-ku, Yokohama, Kanagawa Prefecture

Claims (5)

[Claims] 1. An input filter connected in parallel between input terminals, a switching transistor for switching a DC input voltage passing through the input filter with a switching pulse having a predetermined frequency, and the switching transistor on the primary side. A transformer that is connected and connected in series and that performs power conversion from the primary side to the secondary side, a rectifying / smoothing circuit that rectifies and smoothes the converted power from the secondary side of the transformer, and a rectifying / smoothing circuit from the rectifying / smoothing circuit. An error amplifier that detects and amplifies the deviation voltage between the smoothed output voltage and the specified voltage and an error amplifier that detects that the smoothed output voltage is constantly maintained at the specified voltage based on the deviation voltage from the error amplifier. In contrast, a pulse width control circuit that generates switching pulses with variable pulse width and a smoothed output voltage when an overvoltage occurs An overvoltage detection circuit that detects the above, an overvoltage detection delay circuit that delays the overvoltage detection output from the overvoltage detection circuit for a predetermined time, and a hold output after holding the delayed overvoltage detection output from the overvoltage detection delay circuit. A switching regulator that includes, as at least a component, a latch circuit that forcibly stops the generation of the switching pulse of the pulse width control circuit according to
A pulse width that acts between the overvoltage detection circuit and the pulse width control circuit to suppress the duty ratio of the switching pulse generated from the pulse width control circuit while an overvoltage detection output is obtained from the overvoltage detection circuit. A switching regulator with a regulating circuit. 2. An input filter connected in parallel between input terminals, a switching transistor for switching a DC input voltage passing through the input filter with a switching pulse having a predetermined frequency, and the switching transistor on the primary side. A transformer that is connected and connected in series and that performs power conversion from the primary side to the secondary side, a rectifying / smoothing circuit that rectifies and smoothes the converted power from the secondary side of the transformer, and a rectifying / smoothing circuit from the rectifying / smoothing circuit. An error amplifier that detects and amplifies the deviation voltage between the smoothed output voltage and the specified voltage and an error amplifier that detects that the smoothed output voltage is constantly maintained at the specified voltage based on the deviation voltage from the error amplifier. In contrast, a pulse width control circuit that generates switching pulses with variable pulse width and a smoothed output voltage when an overvoltage occurs An overvoltage detection circuit that detects the above, an overvoltage detection delay circuit that delays the overvoltage detection output from the overvoltage detection circuit for a predetermined time, and a hold output after holding the delayed overvoltage detection output from the overvoltage detection delay circuit. A switching regulator that includes, as at least a component, a latch circuit that forcibly stops the generation of the switching pulse of the pulse width control circuit according to
A pulse that acts between the overvoltage detection circuit and the pulse width control circuit to suppress the duty ratio of the switching pulse generated from the pulse width control circuit while the overvoltage detection output is obtained from the pulse voltage control circuit. A switching regulator with a diode as a width adjustment circuit. 3. An input filter connected in parallel between input terminals, a switching transistor for switching a DC input voltage through the input filter with a switching pulse of a predetermined frequency, and the switching transistor on the primary side. A transformer that is connected and connected in series and that performs power conversion from the primary side to the secondary side, a rectifying / smoothing circuit that rectifies and smoothes the converted power from the secondary side of the transformer, and a rectifying / smoothing circuit from the rectifying / smoothing circuit. An error amplifier that detects and amplifies the deviation voltage between the smoothed output voltage and the specified voltage and an error amplifier that detects that the smoothed output voltage is constantly maintained at the specified voltage based on the deviation voltage from the error amplifier. In contrast, a pulse width control circuit that generates switching pulses with variable pulse width and a smoothed output voltage when an overvoltage occurs An overvoltage detection circuit that detects the above, an overvoltage detection delay circuit that delays the overvoltage detection output from the overvoltage detection circuit for a predetermined time, and a hold output after holding the delayed overvoltage detection output from the overvoltage detection delay circuit. A switching regulator that includes, as at least a component, a latch circuit that forcibly stops the generation of the switching pulse of the pulse width control circuit according to
A pulse that acts between the overvoltage detection circuit and the pulse width control circuit to suppress the duty ratio of the switching pulse generated from the pulse width control circuit while the overvoltage detection output is obtained from the pulse voltage control circuit. A switching regulator with a transistor as a width adjustment circuit. 4. An input filter connected in parallel between input terminals, a switching transistor for switching a DC input voltage through the input filter with a switching pulse of a predetermined frequency, and the switching transistor on the primary side. A transformer that is connected and connected in series and that performs power conversion from the primary side to the secondary side, a rectifying / smoothing circuit that rectifies and smoothes the converted power from the secondary side of the transformer, and a rectifying / smoothing circuit from the rectifying / smoothing circuit. An error amplifier that detects and amplifies the deviation voltage between the smoothed output voltage and the specified voltage and an error amplifier that detects that the smoothed output voltage is constantly maintained at the specified voltage based on the deviation voltage from the error amplifier. In contrast, a pulse width control circuit that generates switching pulses with variable pulse width and a smoothed output voltage when an overvoltage occurs An overvoltage detection circuit that detects the above, an overvoltage detection delay circuit that delays the overvoltage detection output from the overvoltage detection circuit for a predetermined time, and a hold output after holding the delayed overvoltage detection output from the overvoltage detection delay circuit. A switching regulator that includes, as at least a component, a latch circuit that forcibly stops the generation of the switching pulse of the pulse width control circuit according to
A pulse that acts between the overvoltage detection circuit and the pulse width control circuit to suppress the duty ratio of the switching pulse generated from the pulse width control circuit while the overvoltage detection output is obtained from the pulse voltage control circuit. A switching regulator with a photo coupler as a width adjustment circuit. 5. An input filter connected in parallel between input terminals, a switching transistor for switching a DC input voltage passing through the input filter with a switching pulse of a predetermined frequency, and the switching transistor on the primary side. A transformer that is connected and connected in series and that performs power conversion from the primary side to the secondary side, a rectifying / smoothing circuit that rectifies and smoothes the converted power from the secondary side of the transformer, and a rectifying / smoothing circuit from the rectifying / smoothing circuit. An error amplifier that detects and amplifies the deviation voltage between the smoothed output voltage and the specified voltage and an error amplifier that detects that the smoothed output voltage is constantly maintained at the specified voltage based on the deviation voltage from the error amplifier. In contrast, a pulse width control circuit that generates switching pulses with variable pulse width and a smoothed output voltage when an overvoltage occurs An overvoltage detection circuit that detects the above, an overvoltage detection delay circuit that delays the overvoltage detection output from the overvoltage detection circuit for a predetermined time, and a hold output after holding the delayed overvoltage detection output from the overvoltage detection delay circuit. Is provided between the latch circuit for forcibly stopping the generation of the switching pulse of the pulse width control circuit, the overvoltage detection circuit, and the pulse width control circuit, and while the overvoltage detection output is obtained from the overvoltage detection circuit. A switching regulator including at least a pulse width adjusting circuit acting to suppress the duty ratio of a switching pulse generated from the pulse width controlling circuit as a constituent element, wherein at least the pulse width controlling circuit and the pulse width adjusting circuit are A switching regulator configured as an integrated circuit.