JP5761425B2 - Overvoltage protection circuit and power conversion device including the same - Google Patents

Description

  The present invention relates to an overvoltage protection circuit and a power conversion device including the same.

  A device used in an area where the power supply voltage is likely to fluctuate may cause a failure of the device depending on the countermeasure against the voltage rise. Therefore, an overvoltage protection circuit as disclosed in Patent Document 1 (Japanese Patent Laid-Open No. 2009-207329) is provided. This overvoltage protection circuit is configured to shut off the power supply with a relay when the voltage is equal to or higher than a predetermined voltage.

  However, the time required for the power supply voltage to become excessive is extremely short, and the response is slow and it is difficult to reliably protect it by the interruption by the relay. In particular, a semiconductor element such as a semiconductor element that has a short time to withstand overvoltage cannot be protected by being interrupted by a relay. Further, increasing the breakdown voltage of a semiconductor element or the like only for an instantaneous excessive voltage leads to an increase in cost and size.

  Accordingly, an object of the present invention is to provide a small and low-cost overvoltage protection circuit that protects a device from a momentary excessive voltage, and a power conversion device including the same.

An overvoltage protection circuit according to a first aspect of the present invention is an overvoltage protection circuit connected between a power source and a device supplied with power from the power source, and includes an impedance circuit, a voltage detector, a bypass circuit, And a second switch . The impedance circuit is connected in series with the device on a power line connecting the power source and the device. The voltage detector detects the voltage of the power supply. The bypass circuit is a circuit that bypasses the impedance circuit. The second switch opens and closes the power line. The bypass circuit has a switch for opening and closing the bypass circuit. The switch normally closes the bypass circuit, and shuts off the bypass circuit when the value detected by the voltage detector exceeds a predetermined threshold value. The second switch normally turns on the power supply line, and shuts off the power supply line after operation of the switch when the value detected by the voltage detector exceeds a predetermined threshold.

  In this overvoltage protection circuit, since the bypass circuit is normally closed, power is not consumed by the impedance circuit, and it is possible to avoid that the voltage applied to the device is lowered by the voltage drop due to the impedance. it can. On the other hand, at the time of overvoltage, the voltage applied to the device is reduced by the voltage drop of the impedance of the impedance circuit, and the device can be protected from overvoltage.

In this overvoltage protection circuit, since the bypass circuit is normally closed, power is not consumed in the impedance circuit, and the voltage applied to the device is prevented from being lowered by the voltage drop in the impedance circuit. can do.

  When the switch operates during overvoltage, the voltage applied to the device is reduced by the voltage drop in the impedance circuit, and the device can be protected from overvoltage.

  Further, after the switch is operated, the second switch is operated to cut off the power supply line, thereby stopping the power consumption in the impedance circuit. As a result, impedance overheating can be suppressed and the power rating can be reduced.

An overvoltage protection circuit according to a second aspect of the present invention is an overvoltage protection circuit connected between a power source and a device to which power is supplied from the power source, and includes an impedance circuit, a voltage detector, a bypass circuit, And a second switch. The impedance circuit is connected in series with the device on a power line connecting the power source and the device. The voltage detector detects the voltage of the power supply. The bypass circuit is a circuit that bypasses the impedance circuit. The second switch opens and closes the power line. The bypass circuit has a switch for opening and closing the bypass circuit. The switch normally closes the bypass circuit, and shuts off the bypass circuit when the value detected by the voltage detector exceeds a predetermined threshold value. The second switch normally turns on the power supply line, and when the time when the value detected by the voltage detector exceeds a predetermined threshold becomes longer than the predetermined duration determination value, Shut off the line.

  In this overvoltage protection circuit, the voltage applied to the device is reduced by the voltage drop in the impedance circuit, and the device can be protected from overvoltage.

  Further, after the switch is operated, the second switch is operated to cut off the power supply line, thereby stopping the power consumption in the impedance circuit. As a result, impedance overheating can be suppressed and the power rating can be reduced.

An overvoltage protection circuit according to a third aspect of the present invention is an overvoltage protection circuit connected between a power source and a device to which power is supplied from the power source, and includes an impedance circuit, a voltage detector, a bypass circuit, And a second switch and a device voltage detector. The impedance circuit is connected in series with the device on a power line connecting the power source and the device. The voltage detector detects the voltage of the power supply. The bypass circuit is a circuit that bypasses the impedance circuit. The second switch opens and closes the power line. The device voltage detector detects a voltage applied to the device. The bypass circuit has a switch for opening and closing the bypass circuit. The switch normally closes the bypass circuit, and shuts off the bypass circuit when the value detected by the voltage detector exceeds a predetermined threshold value. The second switch normally turns on the power line, and shuts off the power line after the operation of the switch when the value detected by the device voltage detector exceeds a predetermined third threshold.

  In this overvoltage protection circuit, the voltage applied to the device is reduced by the voltage drop in the impedance circuit, and the device can be protected from overvoltage.

  Further, after the switch is operated, the second switch is operated to cut off the power supply line, thereby stopping the power consumption in the impedance circuit. As a result, impedance overheating can be suppressed and the power rating can be reduced.

Overvoltage protection circuit according to a fourth aspect of the present invention is an overvoltage protection circuit connected between the equipment to be supplied with power from a power source and its power supply, and a variable impedance circuit, a voltage detector, a second And a switch . The variable impedance circuit is connected in series with the device on a power line connecting the power source and the device. The voltage detector detects the voltage of the power supply. The second switch opens and closes the power line. Further, the variable impedance circuit makes the impedance value larger than the normal value when the value detected by the voltage detector exceeds a predetermined threshold value. Furthermore, the second switch normally turns on the power line, and when the time when the value detected by the voltage detector exceeds a predetermined threshold becomes longer than the predetermined duration determination value, Cut off.

  In this overvoltage protection circuit, the impedance value is normally set to a small value (including 0), so the power consumption in the variable impedance circuit is suppressed, the voltage drop in the variable impedance circuit is small, and the application to the device It can also be suppressed that the voltage is lowered by the voltage drop in the variable impedance circuit.

  On the other hand, since the impedance value is set to a large value at the time of overvoltage, the voltage applied to the device is reduced by the voltage drop in the variable impedance circuit, and the device can be protected from overvoltage.

  Further, in the overvoltage protection circuit, the power consumption in the impedance circuit is stopped by operating the second switch to cut off the power supply line. As a result, impedance overheating can be suppressed and the power rating can be reduced.

An overvoltage protection circuit according to a fifth aspect of the present invention is the overvoltage protection circuit according to the fourth aspect , in which the variable impedance circuit continuously changes the impedance value according to a change in the detection value by the voltage detector.

  In this overvoltage protection circuit, since the impedance value is set to a large value at the time of overvoltage, the voltage applied to the device is reduced by the voltage drop in the variable impedance circuit, and the device can be protected from the overvoltage.

An overvoltage protection circuit according to a sixth aspect of the present invention is the overvoltage protection circuit according to the fourth aspect , wherein the variable impedance circuit changes the impedance value stepwise in accordance with the change in the detection value by the voltage detector.

  In this overvoltage protection circuit, since the impedance value is set to a large value at the time of overvoltage, the voltage applied to the device is reduced by the voltage drop in the variable impedance circuit, and the device can be protected from the overvoltage.

An overvoltage protection circuit according to a seventh aspect of the present invention is the overvoltage protection circuit according to the fourth aspect , wherein the variable impedance circuit selectively uses a plurality of impedance elements. The plurality of impedance elements includes a first impedance element and a second impedance element. The first impedance element has a first impedance value. The second impedance element has a second impedance value that is greater than the first impedance value. The variable impedance circuit switches the impedance element to be used from the first impedance element to the second impedance element when the value detected by the voltage detector exceeds a predetermined threshold value when the first impedance element is used.

  In this overvoltage protection circuit, since it is normally connected to the first impedance element having the smaller impedance value, the power consumption in the impedance circuit is suppressed, the voltage drop in the impedance circuit is small, and the voltage applied to the device is reduced. It can also be suppressed that the voltage drops by the impedance circuit.

  On the other hand, at the time of overvoltage, since it is connected to the second impedance element having the larger impedance value, the voltage applied to the device is reduced by the voltage drop in the impedance circuit, and the device can be protected from overvoltage.

An overvoltage protection circuit according to an eighth aspect of the present invention is the overvoltage protection circuit according to any one of the fourth to seventh aspects, and further includes a second switch that opens and closes the power supply line. The second switch normally turns on the power supply line, and shuts off the power supply line when the value detected by the voltage detector exceeds a predetermined second threshold.

  In this overvoltage protection circuit, the power consumption in the impedance circuit is stopped by operating the second switch to cut off the power supply line. As a result, impedance overheating can be suppressed and the power rating can be reduced.

An overvoltage protection circuit according to a ninth aspect of the present invention is the overvoltage protection circuit according to any one of the fourth to seventh aspects, the second switch for opening and closing the power supply line, and the voltage applied to the device And a device voltage detector. The second switch normally turns on the power line, and shuts off the power line when the value detected by the device voltage detector exceeds a predetermined third threshold.

  In this overvoltage protection circuit, the power consumption in the impedance circuit is stopped by operating the second switch to cut off the power supply line. As a result, impedance overheating can be suppressed and the power rating can be reduced.

An overvoltage protection circuit according to a tenth aspect of the present invention is the overvoltage protection circuit according to any one of the first to ninth aspects, wherein the power supply is an AC power supply.

  In this overvoltage protection circuit, even if the supply voltage from the AC power supply is an excessive voltage, the voltage applied to the device is reduced by the voltage drop in the impedance circuit. Therefore, it is not necessary to design the rating of the rectification unit of the device high only for protection from an excessive voltage for a short time, and it is reasonable.

An overvoltage protection circuit according to an eleventh aspect of the present invention is the overvoltage protection circuit according to any one of the first to ninth aspects, wherein the power supply is a DC power supply.

  In this overvoltage protection circuit, the switch for turning on and off the alternating current needs bidirectionality, but the switch arranged on the downstream side of the DC power supply may be a one-way switch, so that the cost of the switch can be reduced.

A power converter according to a twelfth aspect of the present invention includes a converter circuit, an inverter circuit, and an overvoltage protection circuit according to a tenth aspect. Converter circuit converts the voltage of the AC power supply into a DC voltage. The inverter circuit converts a DC voltage into an AC voltage.

  In this power converter, the overvoltage protection circuit can protect the converter circuit from excessively applied excessive AC voltage or the inverter circuit from transiently applied excessive DC voltage.

  A power converter according to a thirteenth aspect of the present invention includes an inverter circuit and an overvoltage protection circuit according to an eleventh aspect. The inverter circuit converts the voltage of the DC power source into an AC voltage.

  In this power converter, the overvoltage protection circuit can protect the inverter circuit from an excessive DC voltage applied transiently.

  In the overvoltage protection circuit according to the first aspect of the present invention, since the bypass circuit is normally closed, power is not consumed by the impedance circuit, and the voltage applied to the device is lowered by the voltage drop at the impedance. It can also be avoided. On the other hand, at the time of overvoltage, the voltage applied to the device is reduced by the voltage drop of the impedance of the impedance circuit, and the device can be protected from overvoltage.

In addition , since the bypass circuit is normally closed, power is not consumed in the impedance circuit, and it is possible to prevent the voltage applied to the device from being lowered by the voltage drop in the impedance circuit.

  When the switch operates during overvoltage, the voltage applied to the device is reduced by the voltage drop in the impedance circuit, and the device can be protected from overvoltage.

  Further, after the switch is operated, the second switch is operated to cut off the power supply line, thereby stopping the power consumption in the impedance circuit. As a result, impedance overheating can be suppressed and the power rating can be reduced.

In the overvoltage protection circuit according to the second and third aspects of the present invention, the voltage applied to the device is reduced by the voltage drop in the impedance circuit, and the device can be protected from the overvoltage. Further, after the switch is operated, the second switch is operated to cut off the power supply line, thereby stopping the power consumption in the impedance circuit. As a result, the power rating of the impedance can be reduced.

In the overvoltage protection circuit according to the fourth aspect of the present invention, since the impedance value is normally set to a small value (including 0), the power consumption in the impedance circuit is suppressed, and the voltage drop in the impedance circuit is also small. It is also possible to suppress the voltage applied to the device from being lowered by the voltage drop in the impedance circuit.

  On the other hand, since the impedance value is set to a large value during overvoltage, the voltage applied to the device is reduced by the voltage drop in the impedance circuit, and the device can be protected from overvoltage.

In the overvoltage protection circuit according to the fifth aspect and the sixth aspect of the present invention, since the impedance value is set to a large value at the time of overvoltage, the voltage applied to the device is reduced by the voltage drop in the impedance circuit, Equipment can be protected from overvoltage.

In the overvoltage protection circuit according to the seventh aspect of the present invention, since it is normally connected to the first impedance element having the smaller impedance value, power consumption in the impedance circuit is suppressed, and the voltage drop in the impedance circuit is also small. It is also possible to suppress the voltage applied to the device from being lowered by the voltage drop in the impedance circuit.

  On the other hand, at the time of overvoltage, since it is connected to the second impedance element having the larger impedance value, the voltage applied to the device is reduced by the voltage drop in the impedance circuit, and the device can be protected from overvoltage.

In the overvoltage protection circuit according to the eighth aspect or the ninth aspect of the present invention, the power consumption in the impedance circuit is stopped by operating the second switch to cut off the power supply line. As a result, impedance overheating can be suppressed and the power rating can be reduced.

In the overvoltage protection circuit according to the tenth aspect of the present invention, even if the supply voltage from the AC power supply is an excessive voltage, the voltage applied to the device is reduced by the voltage drop in the impedance circuit. Therefore, it is not necessary to design the equipment with a high voltage rating only for protection from an excessive voltage for a short time, which is reasonable.

In the overvoltage protection circuit according to the eleventh aspect of the present invention, the switch for turning on and off the alternating current needs bidirectionality, but the switch arranged on the downstream side of the DC power supply may be a one-way switch, so the cost of the switch is low. Can be achieved.

In the power conversion device according to the twelfth aspect of the present invention, the overvoltage protection circuit protects the converter circuit from an excessive AC voltage applied transiently or protects the inverter circuit from an excessive DC voltage applied transiently. be able to.

  In the power conversion device according to the thirteenth aspect of the present invention, the overvoltage protection circuit can protect the inverter circuit from an excessive DC voltage applied transiently.

The circuit diagram of the apparatus provided with the overvoltage protection circuit which concerns on 1st Embodiment of this invention. The circuit diagram of a voltage detector. The graph which shows the change of the voltage V when an impedance is only resistance. The graph which shows the change of the voltage V when an impedance contains an inductance component. The circuit diagram of the apparatus provided with the overvoltage protection circuit which concerns on 2nd Embodiment of this invention. The graph which shows the change of the voltage V when an impedance is only resistance. The circuit diagram of the power converter device provided with the overvoltage protection circuit which concerns on 3rd Embodiment of this invention. The circuit diagram of the power converter device provided with the overvoltage protection circuit which concerns on 4th Embodiment of this invention. The graph which shows the change of the voltage V when an impedance is only resistance. The graph which shows the change of the voltage V when an impedance is only resistance. The circuit diagram of the power converter device provided with the overvoltage protection circuit which concerns on another modification. The circuit diagram of the apparatus provided with the overvoltage protection circuit which concerns on 5th Embodiment of this invention. The graph which shows the change of the voltage V when an impedance is only a variable resistance and an impedance increases continuously. The graph which shows the change of the voltage V when an impedance is only a variable resistance and an impedance increases in steps. The circuit diagram of the apparatus provided with the overvoltage protection circuit which concerns on 6th Embodiment of this invention. The graph which shows the change of the voltage V when an impedance is only resistance. The circuit diagram of the apparatus provided with the overvoltage protection circuit which concerns on 7th Embodiment of this invention. The graph which shows the change of the voltage V when an impedance is only resistance. The circuit diagram of the apparatus provided with the overvoltage protection circuit which concerns on 8th Embodiment of this invention. The graph which shows the change of the voltage V when an impedance is only resistance. The circuit diagram of the power converter device provided with the overvoltage protection circuit which concerns on 9th Embodiment of this invention. The circuit diagram of the power converter device provided with the overvoltage protection circuit which concerns on 10th Embodiment of this invention. The circuit diagram of the apparatus provided with the overvoltage protection circuit which concerns on another modification. The graph which shows the change of the voltage V when an impedance is only resistance.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. The following embodiments are specific examples of the present invention and do not limit the technical scope of the present invention.

<First Embodiment>
(1) Configuration of Overvoltage Protection Circuit 50 FIG. 1 is a circuit diagram of a device including an overvoltage protection circuit 50 according to the first embodiment of the present invention. In FIG. 1, the device 30 is supplied with power from a commercial power supply 90 via a pair of power supply lines 901 and 902. The overvoltage protection circuit 50 is connected between the commercial power supply 90 and the device 30.

  The overvoltage protection circuit 50 includes an impedance circuit 20, a voltage detector 33, and a bypass circuit 35.

(2) Detailed configuration of overvoltage protection circuit 50 (2-1) Impedance circuit 20
The impedance circuit 20 is a circuit configured such that an impedance that is a ratio of a voltage and a current in the circuit is Z.

  The impedance circuit 20 is connected between the commercial power supply 90 and the device 30 on the power supply line 902.

(2-2) Voltage detector 33
The voltage detector 33 is configured by an AC voltage detection circuit. There are various AC voltage detection circuits, and they are appropriately adopted depending on use conditions. For example, FIG. 2 is a circuit diagram of a general voltage detector 33. In FIG. 2, the voltage detector 33 includes a transformer circuit 331 and a converter circuit 332.

  The transformer circuit 331 is located on the input side and includes a primary winding 331a and a secondary winding 331b.

  The converter circuit 332 is a circuit in which a rectifying unit 332a formed of a rectifying diode and a smoothing capacitor 332b are connected in parallel.

  In the voltage detector 33, when an AC voltage is applied to the transformer circuit 331, the AC voltage is transformed by the transformer circuit 331. Then, the voltage across the secondary winding 331 b is input to the converter circuit 332.

  The transformed AC voltage input to the converter circuit 332 is converted into a DC voltage by the rectifying unit 332a and smoothed by the smoothing capacitor 332b. This smoothed DC voltage is input to the control unit 40. That is, a DC voltage corresponding to the voltage applied to the primary winding 331a is input to the control unit 40.

(2-3) Bypass circuit 35
The bypass circuit 35 is connected to the impedance circuit 20 in parallel and bypasses the impedance circuit 20. The bypass circuit 35 has a switch 11. The switch 11 opens and closes the bypass circuit 35. Here, opening and closing the bypass circuit 35 means making the bypass circuit 35 conductive or non-conductive to make it non-conductive.

(2-4) Switch 11
The switch 11 normally closes the bypass circuit 35, that is, keeps it conductive. This is because if the bypass circuit 35 is left open (non-conducting state) during normal operation, the impedance circuit 20 is always connected and power is always consumed, and the voltage applied to the device 30 is applied to the impedance circuit 20. This is because the voltage drops by the voltage drop of the impedance Z.

  On the other hand, in order to protect the device 30 at the time of overvoltage, it is necessary to quickly open the bypass circuit 35 and connect the impedance circuit 20 to form a closed circuit of commercial power supply 90-device 30-impedance circuit 20-commercial power supply 90. . Therefore, the switch 11 is required to operate at high speed.

  As the switch 11, a triac, a MOSFET connected so as to conduct in both directions, or the like is employed. In the present embodiment, a phototriac coupler is employed.

  As shown in FIG. 1, the switch 11 includes a light emitting diode 11a on the input side (between A1 and A2), and a phototriac 11b on the output side (between B1 and B2). The equivalent circuit of the phototriac 11b has a configuration in which two photothyristors 111 and 112 are connected in parallel in opposite directions.

  The anode A1 of the light emitting diode 11a is connected to the power source Vc via the resistor R1. The cathode A2 of the light emitting diode 11a is connected to the control unit 40 through a signal line.

  The first anode B1 of the phototriac 11b is connected between the impedance circuit 20 and the device 30 in the power supply line 902. The second anode B2 of the phototriac 11b is connected to the power supply line 902 between the impedance circuit 20 and the commercial power supply 90.

  The light emitting diode 11a emits light when a current flows. When the phototriac 11b receives light from the light emitting diode 11a in a state where the potential of the first anode B1 is higher than the potential of the second anode B2, the photothyristor 111 is turned on. On the other hand, when light from the light emitting diode 11a is received in a state where the potential of the first anode B1 is smaller than the potential of the second anode B2, the photothyristor 112 is turned on.

  As described above, the phototriac 11b is a bidirectional element that operates with respect to a bidirectional applied voltage, and also operates at a high speed, and thus is used as a bidirectional high-speed switch.

  Note that the bidirectional high-speed switch is not limited to the photo triac, but a normal triac or a MOSFET connected so as to conduct in both directions may be employed. When another form of high-speed switch is used, a drive circuit corresponding to the form of the switch is appropriately used.

  Further, the control unit 40 performs operation control of the switch 11, that is, energization control to the light emitting diode 11a.

(3) Operation of Overvoltage Protection Circuit 50 FIG. 3 is a graph showing changes in the voltage V when the impedance of the device 30 is only a resistance component and the impedance Z is only a resistance. In FIG. 1 and FIG. 3, the voltage V = Vac is applied to the device 30 because the bypass circuit 35 is normally in a conductive state with the switch 11 closed.

  When the voltage Vac of the commercial power supply 90 suddenly increases and the control unit 40 determines that the voltage output from the voltage detector 33 has exceeded the threshold, the control unit 40 stops energizing the light emitting diode 11a of the switch 11. Then, the photo triac 11b is turned off. In order to protect the device 30, the switch 11 is required to operate at high speed.

  As a result, a closed circuit of the commercial power source 90-the device 30-the impedance circuit 20-the commercial power source 90 is configured. At this time, only the voltage V = Vac−Vz is applied to the device 30. As a result, the device 30 is protected from overvoltage. If the voltage Vac is increased even after the switch 11 is turned off, the voltage V increases as the voltage Vac increases.

  FIG. 4 is a graph showing changes in the voltage V when the impedance Z includes an inductance component. In FIG. 4, the voltage V = Vac is applied to the device 30 at the normal time. For example, when the voltage Vac of the commercial power supply 90 fluctuates instantaneously to the same value as the maximum overvoltage value in FIG. 3 and the control unit 40 turns off the switch 11, the increase in the voltage V after the switch 11 is turned off is Compared to the case where the impedance Z is only a resistance, it rises more slowly.

  Therefore, it is preferable to employ the impedance Z including an inductance component in an area where the power supply voltage is likely to fluctuate and the overvoltage continues for a long time.

  When the control unit 40 determines that the voltage Vac of the commercial power supply 90 has dropped and the voltage output from the voltage detector 33 has fallen below the threshold for recovery, the control unit 40 energizes the light emitting diode 11a of the switch 11, The photo triac 11b is turned on. As a result, the normal operation is restored.

(4) Features of the first embodiment (4-1)
In the overvoltage protection circuit 50, since the switch 11 is normally turned on and the bypass circuit 35 is closed, no power is consumed in the impedance circuit 20, and the voltage applied to the device 30 is the voltage applied to the impedance circuit 20. It is also possible to avoid lowering by the amount of descent.

(4-2)
Further, when the voltage is overvoltage, the switch 11 is turned off, so that the voltage applied to the device 30 is reduced by the voltage drop of the impedance Z of the impedance circuit 20, and the device 30 can be protected from the overvoltage.

(4-3)
Even if the supply voltage from the commercial power supply 90 is an excessive voltage, the voltage applied to the device 30 is reduced by the voltage drop in the impedance circuit 20. Therefore, it is not necessary to design the equipment with a high voltage rating only for protection from an excessive voltage for a short time, which is reasonable.

Second Embodiment
(1) Configuration of Overvoltage Protection Circuit 50 FIG. 5 is a circuit diagram of a device including an overvoltage protection circuit 50 according to the second embodiment of the present invention. In FIG. 5, the device 30 is supplied with power from a commercial power supply 90 via a pair of power supply lines 901 and 902. The overvoltage protection circuit 50 is connected between the commercial power supply 90 and the device 30.

  The overvoltage protection circuit 50 includes an impedance circuit 20, a voltage detector 33, a bypass circuit 35, and the second switch 12.

(2) Detailed Configuration of Overvoltage Protection Circuit 50 In the second embodiment, the second switch 12 is added to the first embodiment, and the impedance circuit 20, the voltage detector 33, and the bypass circuit 35 are the same. The thing is adopted. Therefore, only the second switch 12 will be described here.

(2-1) Second switch 12
The second switch 12 opens and closes the power line 901. Here, opening and closing the power supply line 901 means that the power supply line 901 is turned on or off to make it non-conductive.

  The second switch 12 normally closes the power supply line 901, that is, keeps it conductive. On the other hand, at the time of overvoltage, the switch 11 is turned off to form a closed circuit of the commercial power supply 90-the device 30-the impedance circuit 20-the commercial power supply 90, and after the protection operation of the device 30 is performed, the second switch 12 is turned off. Then, the power line 901 is shut off.

  The purpose of cutting off the power supply line 901 is to stop the power consumption in the impedance circuit 20, the power rating of the impedance circuit 20 can be reduced, and the cost can be reduced.

  Since the second switch 12 is not required to be as fast as the switch 11, a relay circuit is employed in this embodiment.

  As shown in FIG. 5, the second switch 12 includes a relay contact 12a for opening and closing the power supply line 901, a relay coil 12b for operating the relay contact 12a, and a transistor 12c for energizing and de-energizing the relay coil 12b. Is included. One end of the relay coil 12b is connected to the positive electrode of the power source Vb, and the other end is connected to the collector side of the transistor 12c. The control unit 40 switches the presence / absence of the base current of the transistor 12c, turns on / off the collector and the emitter, and energizes and de-energizes the relay coil 12b.

(3) Operation of Overvoltage Protection Circuit 50 FIG. 6 is a graph showing changes in the voltage V when the impedance Z is only a resistance. 5 and 6, normally, the bypass circuit 35 is in the conductive state with the switch 11 closed, and the second switch 12 has the power supply line 901 in the conductive state, so that the voltage V = Vac is applied to the device 30. Applied.

  When the voltage Vac of the commercial power supply 90 suddenly increases and the control unit 40 determines that the voltage output from the voltage detector 33 has exceeded the threshold, the control unit 40 stops energizing the light emitting diode 11a of the switch 11. Then, the photo triac 11b is turned off.

  As a result, a closed circuit of the commercial power source 90-the device 30-the impedance circuit 20-the commercial power source 90 is configured. At this time, only the voltage V = Vac−Vz is applied to the device 30. As a result, the device 30 is protected from overvoltage.

  Thereafter, when the overvoltage state continues, the voltage V applied to the device 30 increases as the voltage Vac of the commercial power supply 90 increases. However, the second switch 12 shuts off the power supply line 901 when the voltage Vac reaches the second threshold value. As a result, the device 30 is protected and power consumption in the impedance circuit 20 is stopped.

  When the impedance Z includes an inductance component, when the voltage Vac of the commercial power supply 90 increases and the control unit 40 turns off the switch 11, the increase in the voltage V after the switch 11 is turned off is that the impedance Z is only a resistance. Compared to the case, it rises more slowly.

  Therefore, even if the power switch 901 is cut off late by the second switch 12, the damage is small compared to the case where the impedance Z is only a resistance. That is, the device 30 can be protected from a short-time overvoltage even when the power rating of the impedance Z is small.

  When the control unit 40 determines that the voltage Vac of the commercial power supply 90 has dropped and the voltage output from the voltage detector 33 has fallen below the threshold for recovery, the control unit 40 energizes the light emitting diode 11a of the switch 11. Then, the photo triac 11b is turned on. Further, the second switch 12 is turned on and the power supply line 901 is connected to return to the normal operation.

(4) Features of the second embodiment (4-1)
In the overvoltage protection circuit 50, since the switch 11 is normally turned on and the bypass circuit 35 is closed, no power is consumed in the impedance circuit 20, and the voltage applied to the device 30 is the voltage applied to the impedance circuit 20. It is also possible to avoid lowering by the amount of descent.

(4-2)
Further, when the voltage is overvoltage, the switch 11 is turned off, so that the voltage applied to the device 30 is reduced by the voltage drop of the impedance Z of the impedance circuit 20, and the device 30 can be protected from the overvoltage.

(4-3)
Further, the second switch 12 cuts off the power supply line 901 to stop power consumption in the impedance circuit 20. As a result, overheating of the impedance circuit 20 can be suppressed and the power rating can be reduced.

(4-4)
Even if the supply voltage from the commercial power supply 90 is an excessive voltage, the voltage applied to the device 30 is reduced by the voltage drop in the impedance circuit 20. Therefore, it is not necessary to design the device 30 with a high voltage rating only for protection from an excessive voltage for a short time, which is reasonable.

<Third Embodiment>
(1) Configuration of Power Converter 300 FIG. 7 is a circuit diagram of a power converter 300 including an overvoltage protection circuit 100 according to the third embodiment of the present invention. In FIG. 7, the power conversion device 300 includes a DC power supply unit 80, an inverter 95, and an overvoltage protection circuit 100.

  The inverter 95 is supplied with power from the DC power supply unit 80 via a pair of power supply lines 801 and 802. The overvoltage protection circuit 100 is connected between the DC power supply unit 80 and the inverter 95.

(1-1) DC power supply unit 80
The DC power supply unit 80 includes a rectifying unit 81 and a smoothing capacitor 82 connected in parallel with the rectifying unit 81.

  The rectifying unit 81 is configured in a bridge shape by four diodes D1a, D1b, D2a, and D2b. Specifically, the diodes D1a and D1b and D2a and D2b are respectively connected in series. The cathode terminals of the diodes D1a and D2a are both connected to the plus side terminal of the smoothing capacitor 82 and function as the positive side output terminal of the rectifying unit 81. The anode terminals of the diodes D1b and D2b are both connected to the minus terminal of the smoothing capacitor 82 and function as the negative output terminal of the rectifier 81.

  A connection point between the diode D1a and the diode D1b is connected to one pole of the commercial power supply 90. A connection point between the diode D2a and the diode D2b is connected to the other pole of the commercial power supply 90. The rectifying unit 81 rectifies the AC voltage output from the commercial power supply 90 to generate a DC voltage, and supplies this to the smoothing capacitor 82.

  The smoothing capacitor 82 smoothes the voltage rectified by the rectifying unit 81. The smoothed voltage Vdc is applied to the inverter 95 connected to the output side of the smoothing capacitor 82.

  In addition, as a kind of capacitor | condenser, although an electrolytic capacitor, a film capacitor, a tantalum capacitor etc. are mentioned, in this embodiment, an electrolytic capacitor is employ | adopted as the smoothing capacitor 82. FIG.

  The DC power supply unit 80 can be rephrased as a converter circuit that converts an AC voltage into a DC voltage.

(1-2) Inverter 95
The inverter 95 includes a plurality of IGBTs (insulated gate bipolar transistors, hereinafter simply referred to as transistors) and a plurality of free-wheeling diodes. The inverter 95 is applied with the voltage Vdc from the smoothing capacitor 82, and each transistor is turned on and off at the timing instructed by the gate drive circuit 96, thereby generating a drive voltage for driving the motor 500. The motor 500 is, for example, a compressor motor or a fan motor of a heat pump type air conditioner.

  In addition, although the inverter 95 of this embodiment is a voltage source inverter, it is not limited to it, A current source inverter may be sufficient.

(1-3) Gate drive circuit 96
The gate drive circuit 96 changes the on / off state of each transistor of the inverter 95 based on a command from the control unit 40.

(1-4) Overvoltage protection circuit 100
The overvoltage protection circuit 100 includes an impedance circuit 70, a voltage detector 83, a bypass circuit 85, and a second switch 62.

(2) Detailed Configuration of Overvoltage Protection Circuit 100 The third embodiment is different from the first and second embodiments already described in that the overvoltage protection circuit 100 is provided in the direct current section. Therefore, in view of the fact that each component is also replaced from the AC specification to the DC specification, the description will be given again by changing the code even if the names are the same.

(2-1) Impedance circuit 70
The impedance circuit 70 is a circuit configured such that an impedance that is a ratio of a voltage and a current in the circuit is Z. In general, a resistance element is employed.

  The impedance circuit 70 is connected between the DC power supply unit 80 and the inverter 95 on the power supply line 802.

(2-2) Voltage detector 83
The voltage detector 83 is connected to the output side of the smoothing capacitor 82, and detects the voltage across the smoothing capacitor 82, that is, the value of the smoothed voltage Vdc. For example, the voltage detector 83 is configured such that two resistors connected in series with each other are connected in parallel to the smoothing capacitor 82 and the voltage Vdc is divided. The voltage value at the connection point between the two resistors is input to the control unit 40.

(2-3) Bypass circuit 85
The bypass circuit 85 is a circuit that is connected in parallel to the impedance circuit 70 and bypasses the impedance circuit 70. The bypass circuit 85 has a switch 61. The switch 61 opens and closes the bypass circuit 85. Here, opening and closing the bypass circuit 85 means making the bypass circuit 85 conductive or blocked to make it non-conductive.

(2-4) Switch 61
The switch 61 normally closes the bypass circuit 85, that is, keeps it conductive. This is because if the bypass circuit 85 is left open (non-conducting state) during normal operation, power is always consumed by the impedance circuit 70 and the voltage applied to the inverter 95 is lowered by the voltage drop of the impedance Z of the impedance circuit 70. Because it becomes.

  On the other hand, in order to protect the inverter 95 at the time of overvoltage, it is necessary to quickly open the bypass circuit 85 to form a closed circuit of the DC power supply unit 80-inverter 95-impedance circuit 70-DC power supply unit 80. For this reason, the switch 61 is required to operate at high speed. In this embodiment, a transistor is employed, but the form of the switch 61 is not limited to this embodiment.

  As shown in FIG. 7, the switch 61 includes a photocoupler 61a, a drive circuit 61b, and a transistor 61c. The photocoupler 61a includes a light emitting diode 611 and a phototransistor 612.

  The light emitting diode 611 of the photocoupler 61a is connected to the input side (between C1 and C2) of the switch 61. The anode C1 of the light emitting diode 611 is connected to the power source Vc via the resistor R1. The cathode C2 of the light emitting diode 611 is connected to the control unit 40 via a signal line. The phototransistor 612 is connected between the drive circuit 61b and GND.

  A transistor 61c is provided on the output side of the switch 61 (between D1 and D2). The collector D1 of the transistor 61c is connected between the impedance circuit 70 and the inverter 95. The emitter D2 of the transistor 61c is connected between the impedance circuit 70 and the DC power supply unit 80.

  The control signal of the control unit 40 is input to the drive circuit 61b through the photocoupler 61a. A driving power supply (not shown) is connected to the driving circuit 61b. When the control unit 40 turns on the signal line of the light emitting diode 611, the light emitting diode 611 emits light and the phototransistor 612 becomes conductive. While the phototransistor 612 is conducting, a driving signal is output from the driving circuit 61b to the base of the transistor 61c, and the collector D1-emitter D2 of the transistor 61c is conducted.

  Conversely, when the control unit 40 turns off the signal line of the light emitting diode 611, the light emitting diode 611 does not emit light, and the phototransistor 612 does not conduct. While the phototransistor 612 is not conducting, the collector D1 and the emitter D2 of the transistor 61c are not conducting.

(2-5) Second switch 62
The second switch 62 opens and closes the power line 801. Here, opening and closing the power supply line 801 is to turn the power supply line 801 on or off to make it non-conductive.

  The second switch 62 normally closes the power supply line 801, that is, keeps it conductive. On the other hand, when overvoltage occurs, the switch 61 is turned off to form a closed circuit of the DC power supply unit 80-inverter 95-impedance circuit 70-DC power supply unit 80. After the protective operation of the inverter 95 is performed, the second switch 62 Is turned off and the power line 801 is shut off.

  The purpose of cutting off the power supply line 801 is to stop the power consumption in the impedance circuit 70, the power rating of the impedance circuit 70 can be reduced, and the cost can be reduced.

  Since the second switch 62 is not required to be as fast as the switch 61, a relay circuit is employed in this embodiment.

  As shown in FIG. 7, the second switch 62 includes a relay contact 62a for opening and closing the power supply line 801, a relay coil 62b for operating the relay contact 62a, and a transistor 62c for energizing and de-energizing the relay coil 62b. Is included. One end of the relay coil 62b is connected to the positive electrode of the power supply Vb, and the other end is connected to the collector side of the transistor 62c. The controller 40 switches between the presence and absence of the base current of the transistor 62c, turns on and off the collector and the emitter, and performs energization and de-energization of the relay coil 62b.

(3) Operation of Overvoltage Protection Circuit 100 In FIG. 7, normally, the bypass circuit 85 is in the conductive state with the switch 61 closed, and the second switch 62 has the power supply line 801 in the conductive state. The voltage V = Vdc is applied.

  When the voltage Vdc of the DC power supply unit 80 increases rapidly and the control unit 40 determines that the voltage output from the voltage detector 83 exceeds the threshold value, the control unit 40 stops energizing the light emitting diode 611 of the switch 61. Then, the phototransistor 612 is turned off.

  As a result, a closed circuit including the DC power supply unit 80, the inverter 95, the impedance circuit 70, and the DC power supply unit 80 is configured. At this time, only the voltage V = Vdc−Vz is applied to the inverter 95. As a result, the inverter 95 is protected from overvoltage.

  Thereafter, when the overvoltage state continues, the second switch 62 cuts off the power supply line 801 and stops the power consumption in the impedance circuit 70.

  When the control unit 40 determines that the voltage Vac of the commercial power supply 90 has dropped and the voltage output from the voltage detector 83 has fallen below the threshold for recovery, the control unit 40 energizes the light emitting diode 611 of the switch 61, The transistor 61c is turned on. Further, by turning on the second switch 62 and connecting the power supply line 801, the normal operation is restored.

(4) Features of the third embodiment (4-1)
In the overvoltage protection circuit 100, the switch 61 is normally turned on and the bypass circuit 85 is closed, so that no power is consumed in the impedance circuit 70, and the voltage applied to the inverter 95 is the voltage at the impedance circuit 70. It is also possible to avoid lowering by the amount of descent.

(4-2)
Further, when the overvoltage is applied, the switch 61 is turned off, whereby the voltage applied to the inverter 95 is reduced by the voltage drop of the impedance Z of the impedance circuit 70, and the inverter 95 can be protected from the overvoltage.

(4-3)
Further, the second switch 62 cuts off the power supply line 801 to stop the power consumption in the impedance circuit 70. As a result, the power rating of the impedance circuit 70 can be reduced.

(4-4)
Furthermore, since the switch 61 arranged on the downstream side of the DC power supply unit 80 may be a one-way switch, the cost of the switch can be reduced.

<Fourth embodiment>
(1) Configuration of Overvoltage Protection Circuit 100 FIG. 8 is a circuit diagram of a power conversion device 300 including the overvoltage protection circuit 100 according to the fourth embodiment of the present invention. In FIG. 8, the inverter 95 is supplied with power from a DC power supply unit 80 via a pair of power supply lines 801 and 802. A part of the overvoltage protection circuit 100 is connected between the commercial power supply 90 and the DC power supply unit 80, and the other part is connected between the DC power supply unit 80 and the inverter 95.

  The overvoltage protection circuit 100 includes an impedance circuit 70, a voltage detector 33, a bypass circuit 85, and the second switch 12.

  The difference between the fourth embodiment and the already described third embodiment is that a voltage detector and a second switch, which are components of the overvoltage protection circuit 100, are provided between the commercial power supply 90 and the DC power supply unit 80. It is that. That is, the arrangement of the voltage detector and the second switch is the same as the arrangement of the voltage detector 33 and the second switch 12 in the second embodiment. Therefore, in view of the fact that the voltage detector and the second switch are replaced from the DC specification to the AC specification, the voltage detector 33 and the second switch 12 of the second embodiment are employed.

  Therefore, the content of each component is the same as that of the voltage detector 33 and the second switch 12 of the second embodiment, the impedance circuit 70 of the third embodiment, and the bypass circuit 85. Only the operation is explained.

(2) Operation of Overvoltage Protection Circuit 100 In FIG. 8, normally, the bypass circuit 85 is in the conductive state with the switch 61 closed, and the second switch 12 has the power supply line 901 in the conductive state. The voltage V = Vdc is applied.

  When the voltage Vdc of the DC power supply unit 80 suddenly fluctuates and becomes an overvoltage due to the fluctuation of the voltage Vac of the commercial power supply 90, the control unit 40 determines that the voltage output from the voltage detector 33 exceeds the threshold, and the switch The current supply to the light emitting diode 611 of 61 is stopped, and the transistor 61c is turned off.

  As a result, a closed circuit including the DC power supply unit 80, the inverter 95, the impedance circuit 70, and the DC power supply unit 80 is configured. At this time, only the voltage V = Vdc−Vz is applied to the inverter 95. As a result, the inverter 95 is protected from overvoltage.

  Thereafter, the second switch 12 cuts off the power supply line 901 and stops the power consumption in the impedance circuit 70.

(3) Features of the fourth embodiment (3-1)
In the overvoltage protection circuit 100, the switch 61 is normally turned on and the bypass circuit 85 is closed, so that no power is consumed in the impedance circuit 70, and the voltage applied to the inverter 95 is the voltage at the impedance circuit 70. It is also possible to avoid lowering by the amount of descent.

(3-2)
Further, when the overvoltage is applied, the switch 61 is turned off, whereby the voltage applied to the inverter 95 is reduced by the voltage drop of the impedance Z of the impedance circuit 70, and the inverter 95 can be protected from the overvoltage.

(3-3)
Further, the second switch 12 cuts off the power supply line 901 to stop the power consumption in the impedance circuit 70. As a result, overheating of the impedance circuit 70 can be suppressed and the power rating can be reduced.

(3-4)
Furthermore, since the switch 61 arranged on the downstream side of the DC power supply unit 80 may be a one-way switch, the cost of the switch can be reduced.

<Modification>
(A)
The overvoltage protection circuit 50 according to the first embodiment shown in FIG. 1 is an overvoltage protection circuit for an AC voltage, but when the power supply is a DC power supply, or a DC power supply unit that rectifies the AC power supply in the device. In the case of having it, each component may be replaced from the AC specification to the DC specification and provided on the downstream side of the DC power supply unit.

(B)
In the second embodiment, the second switch 12 shuts off the power supply line 901 when the voltage Vac reaches a predetermined second threshold, but it may be cut off when the overvoltage state has passed a predetermined duration. Good.

  FIG. 9 is a graph showing changes in the voltage V when the impedance Z is only a resistance. 5 and 9, normally, the bypass circuit 35 is in the conductive state with the switch 11 closed, and the second switch 12 has the power supply line 901 in the conductive state, so that the voltage V = Vac is applied to the device 30. Applied.

  When the voltage Vac of the commercial power supply 90 suddenly increases and the control unit 40 determines that the voltage output from the voltage detector 33 has exceeded the threshold, the control unit 40 stops energizing the light emitting diode 11a of the switch 11. Then, the photo triac 11b is turned off.

  As a result, a closed circuit of the commercial power source 90-the device 30-the impedance circuit 20-the commercial power source 90 is configured. At this time, only the voltage V = Vac−Vz is applied to the device 30. As a result, the device 30 is protected from overvoltage.

  Thereafter, when the overvoltage state continues, the voltage V applied to the device 30 increases as the voltage Vac of the commercial power supply 90 increases, but the overvoltage state continues for a predetermined duration after the voltage Vac exceeds the threshold value. When the time determination value is reached, the second switch 12 cuts off the power supply line 901. As a result, the device 30 is protected and power consumption in the impedance circuit 20 is stopped.

(C)
In the second embodiment, the second switch 12 shuts off the power supply line 901 when the voltage Vac reaches a predetermined second threshold. However, a device voltage detector 37 for detecting the voltage V applied to the device is further provided. The voltage V may be cut off when it reaches a predetermined third threshold (a circuit diagram at this time is shown in FIG. 11).

  FIG. 10 is a graph showing changes in the voltage V when the impedance Z is only a resistance. 5 and 10, normally, the bypass circuit 35 is in a conductive state with the switch 11 closed, and the second switch 12 has a power supply line 901 in a conductive state, so that the voltage V = Vac is applied to the device 30. Applied.

  When the voltage Vac of the commercial power supply 90 suddenly increases and the control unit 40 determines that the voltage output from the voltage detector 33 has exceeded the threshold, the control unit 40 stops energizing the light emitting diode 11a of the switch 11. Then, the photo triac 11b is turned off.

  As a result, a closed circuit of the commercial power source 90-the device 30-the impedance circuit 20-the commercial power source 90 is configured. At this time, only the voltage V = Vac−Vz is applied to the device 30. As a result, the device 30 is protected from overvoltage.

  Thereafter, when the overvoltage state continues, the voltage V applied to the device 30 increases as the voltage Vac of the commercial power supply 90 increases, but when the voltage V reaches the third threshold value, the second switch 12 cuts off the power line 901. As a result, the device 30 is protected and power consumption in the impedance circuit 20 is stopped.

(D)
The fourth embodiment is different from the third embodiment in that the voltage detector and the second switch are provided between the commercial power supply 90 and the DC power supply unit 80, but only the voltage detector is commercialized. You may make it provide between the power supply 90 and the DC power supply part 80. FIG.

(E)
In 3rd Embodiment and 4th Embodiment, although the example which has an overvoltage protection circuit inside an apparatus was shown, an apparatus is not limited to what has a converter circuit and an inverter circuit.

<Fifth Embodiment>
(1) Configuration of Overvoltage Protection Circuit 150 FIG. 12 is a circuit diagram of a device including an overvoltage protection circuit 150 according to the fifth embodiment of the present invention. In FIG. 12, the device 30 is supplied with power from a commercial power supply 90 via a pair of power supply lines 901 and 902. The overvoltage protection circuit 150 is connected between the commercial power supply 90 and the device 30.

  The overvoltage protection circuit 150 includes a variable impedance circuit 120 and a voltage detector 33.

(2) Detailed configuration of overvoltage protection circuit 150 (2-1) Variable impedance circuit 120
The variable impedance circuit 120 is a circuit configured such that an impedance that is a ratio of a voltage and a current in the circuit is Z. The impedance Z is variable.

  The variable impedance circuit 120 is connected between the commercial power supply 90 and the device 30 on the power supply line 902.

(2-2) Voltage detector 33
The voltage detector 33 is configured by an AC voltage detection circuit. There are various AC voltage detection circuits, and they are appropriately adopted depending on use conditions. Specifically, for example, the voltage detector (see FIG. 2) employed in the first embodiment and the second embodiment is the same as the voltage detector, and the description thereof is omitted here.

(3) Operation of Overvoltage Protection Circuit 150 FIG. 13 is a graph showing changes in the voltage V when the impedance of the device 30 is only the resistance component, the impedance Z is only the variable resistance, and the impedance Z continuously increases. is there. 12 and 13, since the impedance Z is 0 or a value close to 0 at normal time, the voltage V≈Vac is applied to the device 30.

When the voltage Vac of the commercial power supply 90 at normal time is equal to or lower than V ₀ , the voltage Vac of the commercial power supply 90 increases and the control unit 40 determines that the voltage output from the voltage detector 33 exceeds V _0. The control unit 40 continuously increases the impedance Z in accordance with the increase in the detection value of the voltage detector 33.

  As a result, the voltage V = Vac−Vz obtained by subtracting the voltage drop Vz at both ends of the variable impedance circuit 120 is applied to the device 30, and the device 30 is protected from overvoltage.

  When the control unit 40 determines that the voltage Vac of the commercial power supply 90 has dropped and the voltage output from the voltage detector 33 has fallen below the threshold for recovery, the control unit 40 sets the impedance Z of the variable impedance circuit 120 to 0 or Return to a value close to zero. As a result, the normal operation is restored.

(4) Modification Note that the change in the impedance Z is not necessarily a continuous increase as shown in FIG. 13, and may be an intermittent increase.

  For example, FIG. 14 is a graph showing a change in the voltage V when the impedance of the device 30 is only the resistance component, the impedance Z is only the variable resistance, and the impedance Z increases stepwise.

12 and 14, the control unit 40 maintains the impedance Z at 0 or a value close to 0 even when the voltage Vac of the commercial power supply 90 exceeds the normal value V ₀ . Thereafter, further increases the voltage Vac, when the detection value of the voltage detector 33 exceeds V _1, the control unit 40 increases the impedance Z to Z _a. As a result, the voltage drop Vz at both ends of the variable impedance circuit 120 increases, and the voltage V = Vac−Vz is applied to the device 30, and the voltage V applied to the device 30 changes from V ₁ to V ₀ . The device 30 is protected from overvoltage.

Thereafter the voltage Vac increases with the passage of time, the control unit 40 maintains the impedance Z to Z _a. Thereafter, further increases the voltage Vac, when the detection value of the voltage detector 33 exceeds V _2, the control unit 40 increases the impedance Z to Z _b. As a result, the voltage drop Vz at both ends of the variable impedance circuit 120 further increases, and the voltage V = Vac−Vz is applied to the device 30, and the voltage V applied to the device 30 is changed from V ₁ to V _0. The device 30 is protected from overvoltage.

(5) Features of the fifth embodiment (5-1)
In the overvoltage protection circuit 150, since the impedance Z is normally set to a small value (including 0), the power consumption in the variable impedance circuit 120 is suppressed, the voltage drop in the variable impedance circuit 120 is small, and the device 30 It can also be suppressed that the voltage applied to the voltage decreases by the voltage drop in the variable impedance circuit 120.

  On the other hand, since the impedance Z is set to a large value at the time of overvoltage, the voltage applied to the device 30 is reduced by the voltage drop Vz in the variable impedance circuit 120, and the device 30 can be protected from the overvoltage.

(5-2)
Further, the variable impedance circuit 120 can continuously change the impedance Z according to the change in the detection value by the voltage detector 33.

(5-3)
Furthermore, the variable impedance circuit 120 can change the impedance Z in a stepwise manner in accordance with the change in the detection value by the voltage detector 33.

<Sixth Embodiment>
(1) Configuration of Overvoltage Protection Circuit 150 FIG. 15 is a circuit diagram of a device including an overvoltage protection circuit 150 according to the sixth embodiment of the present invention. In FIG. 15, the device 30 is supplied with power from a commercial power supply 90 via a pair of power supply lines 901 and 902. The overvoltage protection circuit 150 is connected between the commercial power supply 90 and the device 30.

  The overvoltage protection circuit 150 includes a variable impedance circuit 120 and a voltage detector 33.

(2) Detailed Configuration of Overvoltage Protection Circuit 150 The sixth embodiment is different from the fifth embodiment in that the variable impedance circuit 120 is configured by a plurality of impedance elements, but other configurations are the fifth embodiment. Is the same. Therefore, only the variable impedance circuit 120 will be described here.

(2-1) Variable impedance circuit 120
The variable impedance circuit 120 includes a low impedance element 121, a high impedance element 122, and a changeover switch 123.

The variable impedance circuit 120 can selectively use the low impedance element 121 and the high impedance element 122 by the changeover switch 123. The low impedance element 121 has an impedance Z ₁ . The high impedance element 122 has an impedance Z ₂ that is greater than the impedance Z ₁ .

  The variable impedance circuit 120 can switch the impedance element to be used from the low impedance element 121 to the high impedance element 122 when the detection value of the voltage detector 33 exceeds a predetermined threshold when the low impedance element 121 is used.

(3) Operation of Overvoltage Protection Circuit 150 FIG. 16 is a graph showing changes in the voltage V when the impedance of the device 30 is only the resistance component and the impedance Z is only the resistance. 15 and 16, the variable impedance circuit 120 is normally connected to the low impedance element 121 at the contact point of the changeover switch 123 in the variable impedance circuit 120. Since the impedance Z ₁ of the low impedance element 121 is 0 or a value close to 0, the voltage V≈Vac is applied to the device 30.

It is assumed that the voltage Vac = V ₀ of the commercial power supply 90 at normal time. The controller 40 uses the low impedance element 121 of the variable impedance circuit 120 to maintain the impedance Z ₁ even when the voltage Vac of the commercial power supply 90 exceeds the normal value V ₀ .

Thereafter, when the voltage Vac further rises and the detection value of the voltage detector 33 exceeds the first threshold value V ₁ , the control unit 40 operates the changeover switch 123 to connect the contact point to the high impedance element 122.

Since the impedance Z ₂ of the high impedance element 122 is larger than the impedance Z ₁ of the low impedance element 121, the voltage drop Vz across the variable impedance circuit 120 increases and the voltage V = Vac−Vz is applied to the device 30. become.

As a result, the voltage V applied to the device 30 decreases from V ₁ to V ₀ , and the device 30 is protected from overvoltage.

When the control unit 40 determines that the voltage Vac of the commercial power supply 90 has dropped and the voltage output from the voltage detector 33 has fallen below the threshold for recovery, the control unit 40 sets the impedance element of the variable impedance circuit 120 to a high impedance Switching from element 122 to low impedance element 121 returns impedance Z ₂ to impedance Z ₁ . As a result, the normal operation is restored.

(4) Features of the sixth embodiment (4-1)
In the overvoltage protection circuit 150, during overvoltage, the voltage applied to the device 30 is reduced by the voltage drop in the variable impedance circuit 120, and the device 30 can be protected from overvoltage.

(4-2)
Even if the supply voltage from the commercial power supply 90 is an excessive voltage, the voltage applied to the device 30 is reduced by the voltage drop in the variable impedance circuit 120, so only for protection from the excessive voltage for a short time. There is no need to design the device 30 with a high voltage rating, which is reasonable.

<Seventh embodiment>
(1) Configuration of Overvoltage Protection Circuit 150 FIG. 17 is a circuit diagram of a device including an overvoltage protection circuit 150 according to the seventh embodiment of the present invention. In FIG. 17, the device 30 is supplied with power from a commercial power supply 90 via a pair of power supply lines 901 and 902. The overvoltage protection circuit 150 is connected between the commercial power supply 90 and the device 30.

  The overvoltage protection circuit 150 includes a variable impedance circuit 120, a voltage detector 33, and the second switch 12.

(2) Detailed Configuration of Overvoltage Protection Circuit 150 In the seventh embodiment, the second switch 12 is added to the fifth embodiment, and the variable impedance circuit 120 and the voltage detector 33 are the same. doing. Therefore, only the second switch 12 will be described here.

(2-1) Second switch 12
The second switch 12 opens and closes the power line 901. Here, opening and closing the power supply line 901 means that the power supply line 901 is turned on or off to make it non-conductive.

  The second switch 12 normally closes the power supply line 901, that is, keeps it conductive. On the other hand, at the time of overvoltage, the second switch 12 is turned off and the power supply line 901 is shut off after the protection operation of the device 30 is performed by changing the impedance Z of the variable impedance circuit 120.

  The purpose of cutting off the power supply line 901 is that the variable impedance circuit 120 is used when the overvoltage of the power supply exceeds the assumed voltage when the variable impedance circuit is designed, or when the duration of the overvoltage state exceeds the assumed time. Therefore, the power rating of the variable impedance circuit 120 can be reduced, and the cost can be reduced. The second switch 12 employs a relay circuit.

  As shown in FIG. 17, the second switch 12 includes a relay contact 12a for opening and closing the power supply line 901, a relay coil 12b for operating the relay contact 12a, and a transistor 12c for energizing and de-energizing the relay coil 12b. Is included. One end of the relay coil 12b is connected to the positive electrode of the power source Vb, and the other end is connected to the collector side of the transistor 12c. The control unit 40 switches the presence / absence of the base current of the transistor 12c, turns on / off the collector and the emitter, and energizes and de-energizes the relay coil 12b.

(3) Operation of Overvoltage Protection Circuit 150 FIG. 18 is a graph showing changes in the voltage V when the impedance of the device 30 is only the resistance component and the impedance Z is only the resistance. In FIG. 17 and FIG. 18, the second switch 12 keeps the power supply line 901 conductive during normal times. Since the impedance Z of the variable impedance circuit 120 is 0 or a value close to 0, the voltage V≈Vac is applied to the device 30.

Assuming that the voltage Vac of the commercial power supply 90 at normal time is equal to or lower than V ₀ , the voltage Vac of the commercial power supply 90 increases and the control unit 40 determines that the voltage output from the voltage detector 33 exceeds V _0. The control unit 40 continuously increases the impedance Z in accordance with the increase in the detection value of the voltage detector 33.

  As a result, the voltage V = Vac−Vz obtained by subtracting the voltage drop Vz at both ends of the variable impedance circuit 120 is applied to the device 30, and the device 30 is protected from overvoltage.

Thereafter, when the overvoltage state continues, the voltage V applied to the device 30 increases as the voltage Vac of the commercial power supply 90 increases. However, the second switch 12 cuts off the power supply line 901 when the voltage Vac reaches the first threshold value V ₁ . As a result, the device 30 is protected and power consumption in the variable impedance circuit 120 is stopped.

  When the control unit 40 determines that the voltage Vac of the commercial power supply 90 has dropped and the voltage output from the voltage detector 33 has fallen below the threshold for recovery, the control unit 40 sets the impedance Z of the variable impedance circuit 120 to 0 or Return to a value close to zero. Further, the second switch 12 is turned on and the power supply line 901 is connected to return to the normal operation.

(4) Features of the seventh embodiment (4-1)
In the overvoltage protection circuit 150, during overvoltage, the voltage applied to the device 30 is reduced by the voltage drop in the variable impedance circuit 120, and the device 30 can be protected from overvoltage.

(4-2)
Further, the second switch 12 cuts off the power supply line 901 to stop power consumption in the variable impedance circuit 120. As a result, overheating of the variable impedance circuit 120 can be suppressed and the power rating can be reduced.

(4-3)
Even if the supply voltage from the commercial power supply 90 is an excessive voltage, the voltage applied to the device 30 is reduced by the voltage drop in the variable impedance circuit 120, so only for protection from the excessive voltage for a short time. There is no need to design the device 30 with a high voltage rating, which is reasonable.

<Eighth Embodiment>
(1) Configuration of Overvoltage Protection Circuit 150 FIG. 19 is a circuit diagram of a device including an overvoltage protection circuit 150 according to the eighth embodiment of the present invention. In FIG. 19, the device 30 is supplied with power from a commercial power supply 90 via a pair of power supply lines 901 and 902. The overvoltage protection circuit 150 is connected between the commercial power supply 90 and the device 30.

  The overvoltage protection circuit 150 includes a variable impedance circuit 120, a voltage detector 33, and the second switch 12.

(2) Detailed Configuration of Overvoltage Protection Circuit 150 The eighth embodiment differs from the seventh embodiment in that the variable impedance circuit 120 is configured by a plurality of impedance elements, but the other configurations are the seventh embodiment. Is the same. Therefore, only the variable impedance circuit 120 will be described here.

(2-1) Variable impedance circuit 120
The variable impedance circuit 120 includes a low impedance element 121, a high impedance element 122, and a changeover switch 123.

The variable impedance circuit 120 can selectively use the low impedance element 121 and the high impedance element 122 by the changeover switch 123. The low impedance element 121 has an impedance Z ₁ . The high impedance element 122 has an impedance Z ₂ that is greater than the impedance Z ₁ .

  The variable impedance circuit 120 can switch the impedance element to be used from the low impedance element 121 to the high impedance element 122 when the detection value of the voltage detector 33 exceeds a predetermined threshold when the low impedance element 121 is used.

(3) Operation of Overvoltage Protection Circuit 150 FIG. 20 is a graph showing a change in voltage V when the impedance of the device 30 is only a resistance component and the impedance Z is only a resistance. In FIG. 19 and FIG. 20, the variable impedance circuit 120 normally has a contact point of the changeover switch 123 connected to the low impedance element 121. Since the impedance Z ₁ of the low impedance element 121 is 0 or a value close to 0, the voltage V≈Vac is applied to the device 30.

The voltage Vac of the commercial power supply 90 at normal time is V ₀ or less. The controller 40 uses the low impedance element 121 of the variable impedance circuit 120 to maintain the impedance Z ₁ even when the voltage Vac of the commercial power supply 90 exceeds the normal value V ₀ .

Thereafter, when the voltage Vac further rises and the detection value of the voltage detector 33 exceeds the first threshold value V ₁ , the control unit 40 operates the changeover switch 123 to connect the contact point to the high impedance element 122.

Since the impedance Z ₂ of the high impedance element 122 is larger than the impedance Z ₁ of the low impedance element 121, the voltage drop Vz across the variable impedance circuit 120 increases and the voltage V = Vac−Vz is applied to the device 30. become.

As a result, the voltage V applied to the device 30 decreases from V ₁ to V ₀ , and the device 30 is protected from overvoltage.

Thereafter, when the overvoltage state continues, the voltage V applied to the device 30 increases as the voltage Vac of the commercial power supply 90 increases. However, the second switch 12 shuts off the power supply line 901 when the voltage Vac reaches the second threshold value V ₂ (V ₂ = V ₁ may be used). As a result, the device 30 is protected and power consumption in the variable impedance circuit 120 is stopped.

When the control unit 40 determines that the voltage Vac of the commercial power supply 90 has dropped and the voltage output from the voltage detector 33 has fallen below the threshold for recovery, the control unit 40 sets the impedance element of the variable impedance circuit 120 to a high impedance Switching from element 122 to low impedance element 121 returns impedance Z ₂ to impedance Z ₁ . Further, the second switch 12 is turned on and the power supply line 901 is connected to return to the normal operation.

(4) Features of the eighth embodiment (4-1)
The overvoltage protection circuit 150 switches the impedance element of the variable impedance circuit 120 from the low impedance element 121 to the high impedance element 122 at the time of overvoltage, so that the voltage applied to the device 30 is reduced by the voltage drop at the impedance Z ₂ . The device 30 can be protected from overvoltage.

(4-2)
Further, the second switch 12 cuts off the power supply line 901 to stop power consumption in the variable impedance circuit 120. As a result, overheating of the variable impedance circuit 120 can be suppressed and the power rating can be reduced.

(4-3)
Even if the supply voltage from the commercial power supply 90 is an excessive voltage, the voltage applied to the device 30 is reduced by the voltage drop in the variable impedance circuit 120, so only for protection from the excessive voltage for a short time. There is no need to design the device 30 with a high voltage rating, which is reasonable.

<Ninth Embodiment>
(1) Configuration of Power Converter 300 FIG. 21 is a circuit diagram of a power converter 300 including an overvoltage protection circuit 200 according to the ninth embodiment of the present invention. In FIG. 21, the power conversion device 300 includes a DC power supply unit 80, an inverter 95, and an overvoltage protection circuit 200.

  The inverter 95 is supplied with power from the DC power supply unit 80 via a pair of power supply lines 801 and 802. The overvoltage protection circuit 200 is connected between the DC power supply unit 80 and the inverter 95.

(1-1) DC power supply unit 80
The DC power supply unit 80 includes a rectifying unit 81 and a smoothing capacitor 82 connected in parallel with the rectifying unit 81.

  The rectifying unit 81 is configured in a bridge shape by four diodes D1a, D1b, D2a, and D2b. Specifically, the diodes D1a and D1b and D2a and D2b are respectively connected in series. The cathode terminals of the diodes D1a and D2a are both connected to the plus side terminal of the smoothing capacitor 82 and function as the positive side output terminal of the rectifying unit 81. The anode terminals of the diodes D1b and D2b are both connected to the minus terminal of the smoothing capacitor 82 and function as the negative output terminal of the rectifier 81.

  A connection point between the diode D1a and the diode D1b is connected to one pole of the commercial power supply 90. A connection point between the diode D2a and the diode D2b is connected to the other pole of the commercial power supply 90. The rectifying unit 81 rectifies the AC voltage output from the commercial power supply 90 to generate a DC voltage, and supplies this to the smoothing capacitor 82.

  The smoothing capacitor 82 smoothes the voltage rectified by the rectifying unit 81. The smoothed voltage Vdc is applied to the inverter 95 connected to the output side of the smoothing capacitor 82.

  In addition, although an electrolytic capacitor, a film capacitor, etc. are mentioned as a kind of capacitor | condenser, in this embodiment, an electrolytic capacitor is employ | adopted as the smoothing capacitor 82. FIG.

  The DC power supply unit 80 can be rephrased as a converter circuit that converts an AC voltage into a DC voltage.

(1-2) Inverter 95
The inverter 95 includes a plurality of IGBTs (insulated gate bipolar transistors, hereinafter simply referred to as transistors) and a plurality of free-wheeling diodes. The inverter 95 is applied with the voltage Vdc from the smoothing capacitor 82, and each transistor is turned on and off at the timing instructed by the gate drive circuit 96, thereby generating a drive voltage for driving the motor 500. The motor 500 is, for example, a compressor motor or a fan motor of a heat pump type air conditioner.

  In addition, although the inverter 95 of this embodiment is a voltage source inverter, it is not limited to it, A current source inverter may be sufficient.

(1-3) Gate drive circuit 96
The gate drive circuit 96 changes the on / off state of each transistor of the inverter 95 based on a command from the control unit 40.

(1-4) Overvoltage protection circuit 200
The overvoltage protection circuit 200 includes a variable impedance circuit 170, a voltage detector 83, and a second switch 62.

(2) Detailed Configuration of Overvoltage Protection Circuit 200 The ninth embodiment is different from the seventh embodiment and the eighth embodiment already described in that the overvoltage protection circuit 200 is provided in the direct current section. Therefore, in view of the fact that each component is also replaced from the AC specification to the DC specification, the description will be given again by changing the code even if the names are the same.

(2-1) Variable impedance circuit 170
The variable impedance circuit 170 is a circuit configured such that an impedance that is a ratio of a voltage and a current in the circuit is Z. In general, a resistance element is employed.

  The variable impedance circuit 170 is connected between the DC power supply unit 80 and the inverter 95 on the power supply line 802.

  The variable impedance circuit 170 includes a low impedance element 171, a high impedance element 172, and a changeover switch 173.

The variable impedance circuit 170 can selectively use the low impedance element 171 and the high impedance element 172 by the changeover switch 173. Low impedance element 171 has an impedance Z _1. The high impedance element 172 has an impedance Z ₂ that is greater than the impedance Z ₁ .

  The variable impedance circuit 170 can switch the impedance element to be used from the low impedance element 171 to the high impedance element 172 when the detection value of the voltage detector 83 exceeds a predetermined threshold when the low impedance element 171 is used.

(2-2) Voltage detector 83
The voltage detector 83 is connected to the output side of the smoothing capacitor 82, and detects the voltage across the smoothing capacitor 82, that is, the value of the smoothed voltage Vdc. For example, the voltage detector 83 is configured such that two resistors connected in series with each other are connected in parallel to the smoothing capacitor 82 and the voltage Vdc is divided. The voltage value at the connection point between the two resistors is input to the control unit 40.

(2-3) Second switch 62
The second switch 62 opens and closes the power line 801. Here, opening and closing the power supply line 801 is to turn the power supply line 801 on or off to make it non-conductive.

  The second switch 62 normally closes the power supply line 801, that is, keeps it conductive. On the other hand, at the time of overvoltage, the second switch 62 is turned off and the power supply line 801 is shut off after the protection operation of the inverter 95 is performed by the impedance Z of the variable impedance circuit 170 changing.

  The purpose of cutting off the power supply line 801 is to stop the power consumption in the variable impedance circuit 170, the power rating of the variable impedance circuit 170 can be reduced, and the cost can be reduced. The second switch 62 employs a relay circuit.

  As shown in FIG. 21, the second switch 62 includes a relay contact 62a for opening and closing the power supply line 801, a relay coil 62b for operating the relay contact 62a, and a transistor 62c for energizing and de-energizing the relay coil 62b. Is included. One end of the relay coil 62b is connected to the positive electrode of the power supply Vb, and the other end is connected to the collector side of the transistor 62c. The controller 40 switches between the presence and absence of the base current of the transistor 62c, turns on and off the collector and the emitter, and performs energization and de-energization of the relay coil 62b.

(3) Operation of Overvoltage Protection Circuit 200 In FIG. 21, the second switch 62 keeps the power supply line 801 conductive during normal operation. In the normal state, the variable impedance circuit 170 has a contact point of the changeover switch 173 connected to the low impedance element 171. Since the impedance Z ₁ of the low impedance element 171 is 0 or a value close to 0, the voltage V≈Vdc is applied to the inverter 95.

  When the voltage Vdc of the DC power supply unit 80 increases and the detection value of the voltage detector 83 exceeds the first threshold value, the control unit 40 operates the changeover switch 173 to connect the contact point to the high impedance element 172.

Since the impedance Z ₂ of the high impedance element 172 is larger than the impedance Z ₁ of the low impedance element 171, the voltage drop Vz at both ends of the variable impedance circuit 170 increases and the voltage V = Vdc−Vz is applied to the inverter 95. become. As a result, the voltage V applied to the inverter 95 decreases, and the inverter 95 is protected from overvoltage.

  Thereafter, when the overvoltage state continues, the voltage V applied to the inverter 95 also increases. However, the second switch 62 cuts off the power supply line 801 when the voltage Vdc of the DC power supply unit 80 reaches the second threshold (or may be the first threshold). As a result, the inverter 95 is protected from overvoltage and the power consumption in the variable impedance circuit 170 is stopped.

When the control unit 40 determines that the voltage Vdc of the DC power supply unit 80 has dropped and the voltage output from the voltage detector 83 has fallen below the threshold for recovery, the control unit 40 increases the impedance element of the variable impedance circuit 170 to a high level. Switching from the impedance element 172 to the low impedance element 171 returns the impedance Z ₂ to the impedance Z ₁ . Further, by turning on the second switch 62 and connecting the power supply line 801, the normal operation is restored.

(4) Features of the ninth embodiment (4-1)
The overvoltage protection circuit 200, during an overvoltage, by switching the impedance components of the variable impedance circuit 170 to a high impedance element 172, the voltage applied to the voltage drop by the inverter 95 in the impedance Z ₂ is reduced, the overvoltage inverters 95 Can be protected from.

(4-2)
Further, the second switch 62 cuts off the power supply line 801 to stop the power consumption in the variable impedance circuit 170. As a result, the power rating of the variable impedance circuit 170 can be reduced.

<Tenth Embodiment>
(1) Configuration of Overvoltage Protection Circuit 200 FIG. 22 is a circuit diagram of a power conversion device 300 including the overvoltage protection circuit 200 according to the tenth embodiment of the present invention. In FIG. 22, the inverter 95 is supplied with power from a DC power supply unit 80 via a pair of power supply lines 801 and 802. A part of the overvoltage protection circuit 200 is connected between the commercial power supply 90 and the DC power supply unit 80, and the other part is connected between the DC power supply unit 80 and the inverter 95.

  The overvoltage protection circuit 200 includes a variable impedance circuit 170, a voltage detector 33, and the second switch 12.

  The difference between the tenth embodiment and the already described ninth embodiment is that a voltage detector, which is a component of the overvoltage protection circuit 200, and a second switch are provided between the commercial power supply 90 and the DC power supply unit 80. It is that. That is, the arrangement of the voltage detector and the second switch is the same as the arrangement of the voltage detector 33 and the second switch 12 in the eighth embodiment. Therefore, in view of the fact that the voltage detector and the second switch are replaced from the DC specification to the AC specification, the voltage detector 33 and the second switch 12 of the eighth embodiment are employed.

  Therefore, the content of each component is the same as that of the voltage detector 33 and the second switch 12 of the eighth embodiment and the variable impedance circuit 170 of the ninth embodiment. .

(2) Operation of Overvoltage Protection Circuit 200 In FIG. 22, the second switch 12 keeps the power supply line 901 conductive during normal operation. In the normal state, the variable impedance circuit 170 has a contact point of the changeover switch 173 connected to the low impedance element 171. Since the impedance Z ₁ of the low impedance element 171 is 0 or a value close to 0, the voltage V≈Vdc is applied to the inverter 95.

  When the voltage Vdc of the DC power supply unit 80 increases due to the fluctuation of the voltage Vac of the commercial power supply 90 and the detected value of the voltage detector 33 exceeds the first threshold value, the control unit 40 operates the changeover switch 173 to change the contact point. Connect to high impedance element 172.

Since the impedance Z ₂ of the high impedance element 172 is larger than the impedance Z ₁ of the low impedance element 171, the voltage drop Vz at both ends of the variable impedance circuit 170 increases and the voltage V = Vdc−Vz is applied to the inverter 95. become. As a result, the voltage V applied to the inverter 95 decreases, and the inverter 95 is protected from overvoltage.

  Thereafter, when the overvoltage state continues, the voltage V applied to the inverter 95 also increases. However, the second switch 12 shuts off the power supply line 901 when the detection value of the voltage detector 33 reaches the second threshold (= may be the first threshold). As a result, the inverter 95 is protected from overvoltage and the power consumption in the variable impedance circuit 170 is stopped.

When the control unit 40 determines that the voltage Vac of the commercial power supply 90 is stable, the voltage Vdc of the DC power supply unit 80 is decreased, and the voltage output from the voltage detector 33 is lower than the threshold for recovery, the control unit 40 Switches the impedance element of the variable impedance circuit 170 from the high impedance element 172 to the low impedance element 171 to return the impedance Z ₂ to the impedance Z ₁ . Further, the second switch 12 is turned on and the power supply line 901 is connected to return to the normal operation.

(3) Features of the tenth embodiment (3-1)
The overvoltage protection circuit 200, during an overvoltage, by switching the impedance components of the variable impedance circuit 170 to a high impedance element 172, the voltage applied to the voltage drop by the inverter 95 in the impedance Z ₂ is reduced, the overvoltage inverters 95 Can be protected from.

(3-2)
Further, the second switch 12 cuts off the power supply line 901 to stop power consumption in the variable impedance circuit 170. As a result, overheating of the variable impedance circuit 170 can be suppressed and the power rating can be reduced.

<Other variations>
(A)
The overvoltage protection circuit 150 according to the fifth embodiment shown in FIG. 1 has an overvoltage protection circuit for an AC voltage as an embodiment. However, when the power supply is a DC power supply, or a DC power supply unit that rectifies the AC power supply in the device. In the case of having it, each component may be replaced from the AC specification to the DC specification and provided on the downstream side of the DC power supply unit.

(B)
In the eighth embodiment, the second switch 12 shuts off the power supply line 901 when the voltage Vac reaches a predetermined second threshold value, but it may be cut off when the overvoltage state has passed a predetermined duration. Good.

(C)
In the eighth embodiment, the second switch 12 shuts off the power supply line 901 when the voltage Vac reaches a predetermined second threshold, but a device voltage detector 37 for detecting the voltage V applied to the device is further provided. The voltage V may be cut off when it reaches a predetermined third threshold value.

FIG. 23 is a circuit diagram of an apparatus including an overvoltage protection circuit 150 according to another modification. FIG. 24 is a graph showing changes in voltage V when the impedance is only resistance. 23 and 24, the variable impedance circuit 120 is normally connected to the low impedance element 121 at the contact point of the changeover switch 123 in the variable impedance circuit 120. Since the impedance Z ₁ of the low impedance element 121 is 0 or a value close to 0, the voltage V≈Vac is applied to the device 30.

The controller 40 uses the low impedance element 121 of the variable impedance circuit 120 to maintain the impedance Z ₁ even when the voltage Vac of the commercial power supply 90 exceeds the normal value V ₀ .

Thereafter, when the voltage Vac further rises and the detection value of the voltage detector 33 exceeds the first threshold value V ₁ , the control unit 40 operates the changeover switch 123 to connect the contact point to the high impedance element 122.

Since the impedance Z ₂ of the high impedance element 122 is larger than the impedance Z ₁ of the low impedance element 121, the voltage drop Vz across the variable impedance circuit 120 increases and the voltage V = Vac−Vz is applied to the device 30. become. As a result, the voltage V applied to the device 30 decreases, and the device 30 is protected from overvoltage.

  Thereafter, the control unit 40 maintains the state in which the contact of the changeover switch 123 is connected to the high impedance element 122. However, if the overvoltage state continues, the control unit 40 increases the voltage Vac of the commercial power supply 90 as shown in FIG. Along with this, the voltage V applied to the device 30 also increases.

When the detection value of the device voltage detector 37 reaches the threshold value V _m , the control unit 40 shuts off the power supply line 901 via the second switch 12. As a result, the device 30 can be protected, and power consumption and temperature rise in the variable impedance circuit 120 can be stopped.

When the control unit 40 determines that the voltage Vac of the commercial power supply 90 has dropped and the voltage output from the voltage detector 33 has fallen below the threshold for recovery, the control unit 40 sets the impedance element of the variable impedance circuit 120 to a high impedance Switching from element 122 to low impedance element 121 returns impedance Z ₂ to impedance Z ₁ . Further, the second switch 12 is turned on and the power supply line 901 is connected to return to the normal operation.

(D)
In the tenth embodiment, the voltage detector and the second switch of the ninth embodiment are changed to be provided between the commercial power supply 90 and the DC power supply unit 80, but only the voltage detector is used as the commercial power supply. 90 and the DC power supply unit 80 may be provided.

(E)
In the ninth embodiment and the tenth embodiment, the example in which the overvoltage protection circuit is provided inside the device has been described, but the device is not limited to the one having the converter circuit and the inverter circuit.

(F)
In the sixth embodiment and the eighth embodiment, instead of the configuration using the changeover switch 123, the switch 11 in the first embodiment is connected in series to the low impedance element 121 and the high impedance element 122, respectively. A switch to be turned on may be switched according to the detection voltage.

(G)
In the ninth and tenth embodiments, instead of the configuration using the changeover switch 173, the switch 71 in the third embodiment is connected in series to the low impedance element 171 and the high impedance element 172, and the voltage detector 83 A switch to be turned on may be switched according to the detection voltage.

  INDUSTRIAL APPLICABILITY The present invention is useful for equipment used in an area where power supply voltage is likely to fluctuate, such as a refrigeration apparatus.

11, 61 Switch 12, 62 Second switch 20, 70 Impedance circuit 33, 83 Voltage detector 35, 85 Bypass circuit 37 Device voltage detector 50, 100 Overvoltage protection circuit 80 DC power supply (DC power supply, converter circuit)
90 Commercial power (AC power)
95 Inverter (Inverter circuit)
120, 170 Variable impedance circuit 121, 171 Low impedance element 122, 172 High impedance element 150, 200 Overvoltage protection circuit 300 Power converter

JP 2009-207329 A

Claims (13)

An overvoltage protection circuit connected between a power source and a device supplied with power from the power source,
An impedance circuit (20, 70) connected in series with the device on a power line connecting the power source and the device;
A voltage detector (33, 83) for detecting the voltage of the power source;
A bypass circuit (35, 85) bypassing the impedance circuit (20, 70);
A second switch (12, 62) for opening and closing the power line;
With
The bypass circuit (35, 85) has a switch (11, 61) for opening and closing the bypass circuit (35, 85),
The switch (11, 61) normally closes the bypass circuit (35, 85), and when the detection value by the voltage detector (33, 83) exceeds a predetermined threshold, the bypass circuit (35, 85). 85) ,
The second switch (12, 62) normally turns on the power line, and when the detection value by the voltage detector (33, 83) exceeds a predetermined second threshold, the switch (11, 62) 61) shut off the power line after the operation of
Overvoltage protection circuit (50, 100). An overvoltage protection circuit connected between a power source and a device supplied with power from the power source,
An impedance circuit (20, 70) connected in series with the device on a power line connecting the power source and the device;
A voltage detector (33, 83) for detecting the voltage of the power source;
A bypass circuit (35, 85) bypassing the impedance circuit (20, 70);
A second switch (12, 62) for opening and closing the power line ;
Equipped with a,
The bypass circuit (35, 85) has a switch (11, 61) for opening and closing the bypass circuit (35, 85),
The switch (11, 61) normally closes the bypass circuit (35, 85), and when the detection value by the voltage detector (33, 83) exceeds a predetermined threshold, the bypass circuit (35, 85). 85),
The second switch (12, 62) normally makes the power line conductive, and the time during which the detected value by the voltage detector (33, 83) exceeds a predetermined threshold is determined as a predetermined duration. When the value becomes longer than the value, the power line is shut off after the operation of the switch (11, 61).
Overvoltage protection circuit (50, 100). An overvoltage protection circuit connected between a power source and a device supplied with power from the power source,
An impedance circuit (20, 70) connected in series with the device on a power line connecting the power source and the device;
A voltage detector (33, 83) for detecting the voltage of the power source;
A bypass circuit (35, 85) bypassing the impedance circuit (20, 70);
A second switch (12, 62) for opening and closing the power line;
A device voltage detector (37) for detecting a voltage applied to the device ;
Equipped with a,
The bypass circuit (35, 85) has a switch (11, 61) for opening and closing the bypass circuit (35, 85),
The switch (11, 61) normally closes the bypass circuit (35, 85), and when the detection value by the voltage detector (33, 83) exceeds a predetermined threshold, the bypass circuit (35, 85). 85),
The second switch (12, 62) normally turns on the power line, and when the value detected by the device voltage detector (37) exceeds a predetermined third threshold, the switch (11, 61). ) Cut off the power line after operation
Overvoltage protection circuit (50, 100). An overvoltage protection circuit connected between a power source and a device supplied with power from the power source,
A variable impedance circuit (120, 170) connected in series with the device on a power line connecting the power source and the device;
A voltage detector (33, 83) for detecting the voltage of the power source;
A second switch (12, 62) for opening and closing the power line;
With
The variable impedance circuit (120, 170) makes the impedance value larger than a normal value when a detection value by the voltage detector (33, 83) exceeds a predetermined threshold value ,
The second switch (12, 62) normally makes the power line conductive, and the time during which the detected value by the voltage detector (33, 83) exceeds a predetermined threshold is determined as a predetermined duration. Shut off the power line when longer than the value,
Overvoltage protection circuit (150, 200). The variable impedance circuit (120, 170) continuously changes the impedance value according to a change in the detection value by the voltage detector (33, 83).
The overvoltage protection circuit (150, 200) according to claim 4 . The variable impedance circuit (120, 170) changes the impedance value stepwise in accordance with a change in the detection value by the voltage detector (33, 83).
The overvoltage protection circuit (150, 200) according to claim 4 . The variable impedance circuit (120, 170) selectively uses a plurality of impedance elements,
The plurality of impedance elements are:
A first impedance element (121, 171) having a first impedance value;
A second impedance element (122, 172) having a second impedance value greater than the first impedance value;
Including
The variable impedance circuit (120, 170) is used when the detected value by the voltage detector (33, 83) exceeds a predetermined threshold value when the first impedance element (121, 171) is used. From the first impedance element (121, 171) to the second impedance element (122, 172),
The overvoltage protection circuit (150, 200) according to claim 4 . The second switch (12, 62) normally turns on the power line, and shuts off the power line when a value detected by the voltage detector (33, 83) exceeds a predetermined second threshold. To
The overvoltage protection circuit (150, 200) according to any one of claims 4 to 7 . A device voltage detector (37) for detecting a voltage applied to the device;
Further comprising
The second switch (12, 62) normally turns on the power line, and shuts off the power line when a value detected by the device voltage detector (37) exceeds a predetermined third threshold. ,
The overvoltage protection circuit (150, 200) according to any one of claims 4 to 7 . The power source is an AC power source;
The overvoltage protection circuit (50, 150) according to any one of claims 1 to 9 . The power source is a DC power source;
The overvoltage protection circuit (100, 200) according to any one of claims 1 to 9 . A converter circuit (80) for converting the voltage of the AC power source into a DC voltage;
An inverter circuit (95) for converting the DC voltage into an AC voltage;
An overvoltage protection circuit according to claim 10;
Comprising
Power conversion device.   An inverter circuit (95) for converting the voltage of the DC power source into an AC voltage;
  An overvoltage protection circuit according to claim 11;
Comprising
Power conversion device.

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