JP6106981B2 - Electronic circuit equipment - Google Patents

Description

  The present invention relates to an electronic circuit device, and more particularly to a technique for protecting a power-supplied supply circuit supplied with power from a DC power supply from overvoltage.

  In general, as electric components and electronic components constituting the electric and electronic circuit device, components having a withstand voltage with respect to the maximum voltage are selected according to the maximum voltage of the connected power source. Therefore, electrical and electronic circuit devices used in areas where the voltage of the power supply (commercial AC power supply) is unstable requires the use of electronic components with a high withstand voltage as the instability increases. Become.

  For this reason, the electrical and electronic circuit device needs to be protected from an overvoltage (a voltage state in which the voltage applied to the electronic component exceeds the component withstand voltage due to an increase in the power supply voltage). As an example of the protection technology from overvoltage, a relay circuit is disposed in the power supply path between the AC power supply and the converter, and the relay circuit detects the overvoltage abnormality of the DC voltage rectified by the rectifier provided in the converter. There is a technique for shutting off (see, for example, Patent Document 1).

JP 2000-92844 A

  However, in the field of air conditioners and the like, there are cases where a plurality of converter circuits (DC power supply) and inverter circuits (powered supply circuit) are provided. If this mechanism is provided, the cost increase and size increase of the entire apparatus become a problem.

  For this, it is also conceivable to detect the power supply voltage of the power supply (commercial AC power supply) and shut off the power supply system when the voltage is abnormal. However, in a combination of a converter circuit, an inverter circuit, and an inductive load (for example, a motor) that do not have a regenerative function, an overvoltage due to the regenerative operation of the inverter cannot be detected only by detecting an abnormality in the power supply system.

  The present invention has been made paying attention to the above-described problem, and an object thereof is to reliably detect an overvoltage while suppressing an increase in cost and size.

In order to solve the above-mentioned problem, the first invention
Electronic circuit device having a plurality of circuit groups (3, 4) including a DC power supply unit (21, 24) and a power supplied circuit (22, 25) supplied with power from the DC power supply unit (21, 24) In
An overvoltage detection unit (28) provided in any one of the circuit groups (3, 4) and detecting an overvoltage of the DC power supply unit (24) of the circuit group (4);
Provided for each circuit group (3) that does not have the overvoltage detection unit (28), from the circuit group (4) side that has the overvoltage detection unit (28), has the overvoltage detection unit (28) In order to prevent the backflow of the current to the circuit group (3) that is not, the DC power supply unit (21) of the circuit group (3) not having the overvoltage detection unit (28) and the overvoltage detection unit (28) A diode (D) for connecting the
Equipped with a,
When the overvoltage detection unit (28) detects an overvoltage, the control unit (27) includes a control unit (27) for cutting off a predetermined power supply path to each of the power supply circuits (22, 25) .

In this configuration, even when the circuit group (4) side having the overvoltage detection unit (28) becomes overvoltage, the overvoltage detection unit (28) detects the overvoltage and has the overvoltage detection unit (28). Even when there is an overvoltage on the side of the circuit group (3) that does not exist, the overvoltage detector (28) detects the overvoltage. That is, the overvoltage of a plurality of circuit groups (3, 4) can be detected by one overvoltage detector (28) .

In this configuration, after the overvoltage detection unit (28) detects the overvoltage, the predetermined power supply path to the power supply circuit (22, 25) is cut off.

In addition, the second invention,
In the electronic circuit device of the first invention,
At least one of the power receiving circuits (22, 25) is an inverter circuit (22),
A control unit (27) is provided that stops the operation of the inverter circuit (22) when the overvoltage detection unit (28) detects an overvoltage.

  In this configuration, since the operation of the inverter circuit (22) is stopped, when an overvoltage occurs due to the regenerative operation by the inverter circuit (22), protection from the overvoltage becomes possible.

In addition, the third invention,
In the electronic circuit device of the first or second aspect of the invention,
A resistor (R5) is provided between the DC power supply (24) of the circuit group (4) having the overvoltage detection unit (28) and the overvoltage detection unit (28).

  In this configuration, even when a sudden voltage rise occurs in the DC power supply unit (21) and a large potential difference occurs with the DC power supply unit (24), an increase in current flowing through the diode (D) is suppressed. be able to.

  According to the first invention, since the overvoltage of a plurality of circuit groups can be detected by one overvoltage detection unit, it is possible to reliably detect the overvoltage while suppressing an increase in cost and size.

According to the first invention, the circuit group can be reliably protected from overvoltage.

In addition, according to the second invention, the electronic circuit device can be more reliably protected from overvoltage.

Further, according to the third aspect of the invention, it is possible to reliably detect overvoltage while suppressing an increase in the cost of components.

FIG. 1 is a diagram illustrating a schematic configuration of a separate type air conditioner according to the first embodiment. FIG. 2 is a diagram illustrating a configuration of the overvoltage detection unit according to the first embodiment. FIG. 3 is a diagram illustrating a schematic configuration of a separate air conditioner according to the second embodiment. FIG. 4 is a diagram illustrating another configuration example of the overvoltage detection unit.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. The following embodiments are essentially preferable examples, and are not intended to limit the scope of the present invention, its application, or its use.

Embodiment 1 of the Invention
Hereinafter, as an electronic circuit device according to the present invention, a separate type air conditioner that performs indoor cooling and heating will be described. FIG. 1 is a diagram showing a schematic configuration of a separate type air conditioner (1) according to Embodiment 1 of the present invention. As shown in the figure, the separate air conditioner (1) includes an indoor unit (10) and an outdoor unit (20). In this example, the indoor unit (10) receives the AC power supply (2). Electric power received by the indoor unit (10) is supplied to the outdoor unit (20) through wiring.

<Configuration of indoor unit>
In this example, the indoor unit (10) includes an indoor unit control power supply circuit (11), an indoor unit control circuit (12), an indoor unit side communication circuit (13), and a switch (SW1). The indoor unit control power supply circuit (11) supplies power to the indoor unit control circuit (12). The indoor unit control circuit (12) controls a fan (not shown) in the indoor unit and processes an instruction from a user (signal from a remote controller). The indoor unit side communication circuit (13) communicates with the outdoor unit (20). In this communication, for example, a signal for changing the operation state of the outdoor unit (20) is sent to the outdoor unit (20), or a signal indicating the state of the outdoor unit (20) is sent from the outdoor unit (20) to the indoor unit. Sent to the side communication circuit (13). The switch (SW1) is a switch that controls power supply to the outdoor unit (20) when starting the outdoor unit (20) (details will be described later).

  The switch (SW1) is a so-called A contact relay. Specifically, the switch (SW1) has one fixed contact and one movable contact, and when the relay coil is energized, these contacts are connected (ON). One end of the switch (SW1) is connected to the AC power source (2). The other end of the switch (SW1) is connected to the indoor unit side communication circuit (13) and is connected to an outdoor unit side communication circuit (26) to be described later via the wiring (L3).

<Configuration of outdoor unit>
The outdoor unit (20) includes a converter circuit (21), an inverter circuit (22), a compressor (23), a rectifier circuit (24), an outdoor unit control power circuit (25), an outdoor unit side communication circuit (26), an outdoor unit A machine control circuit (27), an overvoltage detector (28), a diode (D), and two switches (SW2, SW3).

  The converter circuit (21) is composed of, for example, a diode bridge circuit (not shown), and converts alternating current into direct current. The converter circuit (21) is an example of the DC power supply unit of the present invention. A smoothing capacitor (C22) is provided at an output node (referred to as a DC link unit) of the converter circuit (21). The converter circuit (21) is connected to the indoor unit (10) by wiring (L1, L2). These wirings (L1, L2) are connected to the AC power supply (2) in the indoor unit (10). One of the wirings (L1, L2) and the wiring (L3) are also used for communication between the indoor unit side communication circuit (13) and the outdoor unit side communication circuit (26).

  Further, a switch (SW3) is provided in the middle of the wiring (L1) (in the outdoor unit (20)). The switch (SW3) is a so-called A contact relay.

  The inverter circuit (22) switches the output (direct current) of the converter circuit (21) and converts it into alternating current (for example, three-phase alternating current). The output of the inverter circuit (22) is supplied to the compressor (23). The inverter circuit (22) is an example of the power receiving circuit of the present invention. Here, the converter circuit (21) and the inverter circuit (22) are collectively referred to as a circuit group (3). That is, the converter circuit (21) and the inverter circuit (22) constitute an example of the circuit group of the present invention.

  The compressor (23) is a so-called electric compressor that drives a compression mechanism with a motor (not shown). For example, an IPM motor can be adopted as the motor for the compressor (23). The IPM motor is an inductive load, and when the inverter circuit (22) performs a regenerative operation, power is regenerated in the DC link unit.

  The rectifier circuit (24) receives power from the AC power source (2) and outputs DC. The rectifier circuit (24) is constituted by a diode bridge circuit, for example. The rectifier circuit (24) is an example of the DC power supply unit of the present invention. In this example, in the rectifier circuit (24), one end of the input node is connected to the wiring (L2), and the other end of the input node is connected to the switch (SW2).

  The switch (SW2) is a so-called C contact relay. The C contact relay has two fixed contacts and one movable contact. When the coil of the relay is not energized, one fixed contact (referred to as a normally closed contact in this case) and the movable contact are connected. When the coil is energized, the other fixed contact (referred to as a normally open contact here) and the movable contact are connected. In this example, the switch (SW2) has a movable contact connected to the rectifier circuit (24), a normally open contact connected to the wiring (L1), and a normally closed contact connected via the wiring (L3) to the indoor unit ( 10) Connected to the switch (SW1). As a result, the other end of the input node of the rectifier circuit (24) is connected to the wiring (L1) when the movable contact of the switch (SW2) is at the normally open contact, and to the wiring (L3) when it is on the normally closed contact side. Connected. When the switch (SW1) is turned on when the input node of the rectifier circuit (24) is connected to the wiring (L3), power is supplied to the rectifier circuit (24) from the AC power supply (2).

  The outdoor unit control power supply circuit (25) outputs the rectifier circuit (24) as a direct current having a predetermined voltage. In this example, the outdoor unit control power supply circuit (25) includes a so-called switching power supply. The outdoor unit control power circuit (25) is an example of the power receiving circuit of the present invention. A capacitor (C25) is provided between the input nodes of the outdoor unit control power supply circuit (25) (see FIG. 2). Hereinafter, the rectifier circuit (24) and the outdoor unit control power supply circuit (25) are collectively referred to as a circuit group (4). That is, the rectifier circuit (24) and the outdoor unit control power supply circuit (25) constitute an example of the circuit group of the present invention.

  The outdoor unit side communication circuit (26) communicates with the indoor unit side communication circuit (13) of the indoor unit (10) using one of the wirings (L1, L2) and the wiring (L3). The outdoor unit side communication circuit (26) transmits a predetermined instruction (information) to the control unit (27) according to the result of the communication.

  The outdoor unit control circuit (27) receives an instruction from the outdoor unit side communication circuit (26) and controls switching in the inverter circuit (22) and also controls the switches (SW2 and SW3) (described later). The outdoor unit control circuit (27) includes, for example, a microcomputer and a program for operating the microcomputer. The outdoor unit control circuit (27) is an example of the control unit of the present invention. The switching control function and the switch (SW2, SW3) control function may be realized by a single microcomputer (control unit) or by a separate microcomputer (control unit). Also good.

  FIG. 2 is a diagram illustrating a configuration of the overvoltage detection unit (28) according to the first embodiment. As shown in FIG. 2, the overvoltage detection unit (28) includes a comparator (28a) and four resistors (R1, R2, R3, R4). The resistors (R3, R4) are connected in series between a node having a predetermined reference potential and a node having a ground potential, and a voltage between both nodes is divided and applied to the comparator (28a).

  The resistors (R1, R2) are connected in series between the output nodes of the rectifier circuit (24), and the voltage between both nodes is divided and applied to the comparator (28a). Note that one of the output nodes of the rectifier circuit (24) (in this example, the side connected to the resistor (R2)) is a ground potential.

  Further, both ends of the series resistor (R1, R2) are also connected to the DC link portion of the inverter circuit (22) (the output node of the converter circuit (21)) via the diode (D). With this configuration, the voltage at the output node of the rectifier circuit (24) and the converter circuit (21) and the reference voltage are compared by the comparator (28a), and the comparison result is output. That is, a desired overvoltage can be detected by appropriately determining the reference potential and the values (ratio) of the resistors (R1, R2, R3, R4).

  The diode (D) is provided to prevent the backflow of current from the circuit group (4) side to the circuit group (3) side. In this example, the diode (D) has an anode on the inverter circuit (22) side and a cathode on the overvoltage detection unit (28) side. Of course, the diode (D) may be connected to the ground potential side of the output node of the rectifier circuit (24). In this case, the inverter circuit (22) side is a cathode, and the overvoltage detector (28) side is an anode.

<Overvoltage protection operation>
In the normal operation state, in the indoor unit (10), the switch (SW1) is turned off by the indoor unit control circuit (12). In the outdoor unit (20), the outdoor unit control circuit (27) controls the switch (SW3) to be in an on state and controls the switch (SW2) to be connected to the wiring (L1) side. In this state, power is supplied to the converter circuit (21) and the rectifier circuit (24) via the wirings (L1, L2).

<1> Operation when power supply voltage is abnormal For example, when the AC power supply (2) becomes overvoltage, the output voltages of the converter circuit (21) and the rectifier circuit (24) rise. When the potential at the midpoint of the series resistance (R1, R2) exceeds the reference potential due to the increase in the output voltage, a predetermined signal is output from the comparator (28a) to the outdoor unit control circuit (27).

  The outdoor unit control circuit (27) receives the signal output from the overvoltage detection unit (28) (specifically, the converter circuit (21)), turns off the switch (SW3), and wires the switch (SW2). Switch to the (L3) side. When the switch (SW3) is turned off, the power supply to the converter circuit (21) is cut off. Further, when the switch (SW2) is switched to the wiring (L3) side, the switch (SW1) is turned off, so that the power supply to the rectifier circuit (24) is cut off.

  The order of switching the switches (SW2, SW3) is not particularly limited. The switch (SW2) may be switched first, or the switch (SW3) may be switched first. In this example, since the outdoor unit control power supply circuit (25) is configured by a switching power supply, the outdoor unit control circuit (27) is not connected to the rectifier circuit (24) even if the power supply to the rectifier circuit (24) is cut off. It is possible to operate during a period when the charge stored in the capacitor is sufficient. Therefore, for example, it is conceivable that the outdoor unit control power supply circuit (25) controls the switch (SW3) after switching the switch (SW2) first.

  Even when the switch (SW3) is off and the switch (SW2) is on the wiring (L1) side, if the AC power supply (2) becomes overvoltage, the overvoltage detector (28) detects the overvoltage, The outdoor unit control circuit (27) switches the switch (SW2) to the wiring (L3) side. That is, even when only the circuit group (4) side is operating, the circuit group (4) can be reliably protected from overvoltage.

<2> Operation during regeneration For example, when regeneration from the compressor (23) (motor) occurs, the voltage on the DC link side of the inverter circuit (22) increases. Then, the voltage across the series resistance (R1, R2) in the overvoltage detection unit (28) increases. When the potential at the midpoint of the series resistance (R1, R2) exceeds the reference potential, a predetermined signal is output from the comparator (28a) to the outdoor unit control circuit (27).

  The outdoor unit control circuit (27) receives the signal from the overvoltage detection unit (28), turns off the switch (SW3), and switches the switch (SW2) to the wiring (L3) side. Thereby, the power supply to the converter circuit (21) and the rectifier circuit (24) is cut off.

  In this example, since the capacitor (C25) is provided in the DC link part of the outdoor unit control power circuit (25), the outdoor unit control power circuit (25) is disconnected from the power supply to the rectifier circuit (24). However, there is a possibility of operation during a period when the charge stored in the capacitor (C25) is sufficient. Therefore, in the meantime, the converter circuit (21), the capacitor (C22), and the inverter circuit (22) may be exposed to overvoltage. Therefore, the outdoor unit control circuit (27) also stops switching in the inverter circuit (22).

  In particular, when the capacitance of the smoothing capacitor is as small as several tens of μF as in a so-called electrolytic capacitorless inverter, the capacitor voltage is faster and larger than that of a normal inverter even with the same regenerative power. Therefore, it is desirable to stop switching of the inverter circuit as soon as possible.

  Thereby, the converter circuit (21) and the like can be reliably protected from overvoltage. As described above, the order of switching the switches (SW2, SW3) is not particularly limited.

  Further, when it is not determined whether the cause of the overvoltage is due to power supply voltage abnormality or regeneration, switching of the inverter circuit is stopped when overvoltage is detected even when the power supply voltage is abnormal.

<3> Returning to the normal operation state From the state in which the outdoor unit (20) is stopped for overvoltage protection, for example, it can be returned to the normal operation state by operating as follows.

  For example, when the user instructs the indoor unit (10) (for example, an instruction by operating a remote controller) to restart the separate air conditioner (1), the indoor unit control circuit (12) Turn on the switch (SW1) in the machine (10). Then, the wiring (L3) is connected to one end (wiring (L1) side) of the AC power supply (2) through the switch (SW1). Thereby, power is supplied to the rectifier circuit (24) via the wiring (L3) and the switch (SW2) (switched to the wiring (L3) side when stopped). When the rectifier circuit (24) is supplied with power, predetermined power is supplied from the outdoor unit control power supply circuit (25) to the outdoor unit control circuit (27), and the outdoor unit control circuit (27) becomes operable. That is, the outdoor unit control circuit (27) is activated. When the outdoor unit control circuit (27) is activated, the outdoor unit control circuit (27) turns on the switch (SW3) to operate the converter circuit (21), the inverter circuit (22), and the compressor (23). The outdoor unit control circuit (27) switches the switch (SW2) to the wiring (L1) side. On the indoor unit (10) side, the indoor unit control circuit (12) is operated at a timing at which the outdoor unit control circuit can continue to operate in the process of switching the switch (SW2) of the outdoor unit (20) to the wiring (L1) side. ) Turns off the switch (SW1).

<Effect in this embodiment>
As described above, according to the present embodiment, the overvoltage of the two circuit groups (3, 4) can be detected by the single overvoltage detection unit (28). Further, since the overvoltage is detected on the output side of the converter circuit (21), the overvoltage during regeneration from the compressor (23) side can be detected in addition to the overvoltage on the AC power source (2) side. That is, in this embodiment, it is possible to reliably detect an overvoltage while suppressing an increase in cost and size. After the overvoltage is detected, the circuit group (3, 4) is reliably protected from the overvoltage by cutting off the predetermined power supply path to the power supply circuit (inverter circuit (22) or rectifier circuit (24)). Can be protected. When such reliable protection is possible, the converter circuit (21), inverter circuit (22), compressor (23), rectifier circuit (24), outdoor unit control power circuit (25), outdoor unit control circuit It is not necessary to set an excessive pressure resistance of the parts constituting each part of (27).

<< Embodiment 2 of the Invention >>
FIG. 3 is a diagram showing a schematic configuration of a separate type air conditioner (1) according to Embodiment 2 of the present invention. The separate type air conditioner (1) of the present embodiment is different from the first embodiment in the configuration of the outdoor unit (20).

  Specifically, in the outdoor unit (20) of the present embodiment, the rectifier circuit (24) is configured by one diode (D24). The diode (D24) has an anode connected to the movable contact of the switch (SW2) and a cathode connected to one end of the input node of the outdoor unit control power supply circuit (25). The other end of the input node of the outdoor unit control power circuit (25) is connected to the negative side (ground side) of the DC link of the inverter circuit (22). Also in this example, the converter circuit (21) and the inverter circuit (22) constitute an example of the circuit group (3) of the present invention, and the diode (D24) and the outdoor unit control power supply circuit (25) An example of the circuit group (4) is configured. In this example, a resistor (R6) is provided on the input side of the DC power supply unit (24) in order to prevent inrush during initial charging of the capacitor (C25).

  Even in this configuration, the overvoltage of the two circuit groups (3, 4) can be detected by one overvoltage detector (28). Further, since the overvoltage is detected on the output side of the converter circuit (21), the overvoltage during regeneration from the compressor (23) side can be detected in addition to the overvoltage on the AC power source (2) side. Therefore, it is possible to obtain the same effect as in the first embodiment also in this embodiment.

<< Embodiment 3 of the Invention >>
FIG. 4 is a diagram illustrating another configuration example of the overvoltage detection unit (28). The overvoltage detection unit (28) of the present embodiment can be applied to any of the first and second embodiments.

  In this example, a resistor (R5) is added to the overvoltage detector (28) of the first embodiment. Specifically, a resistor (R5) is further connected to two resistors (R1, R2), and a series resistor (R1, R2, R5) consisting of these three resistors is connected between the output nodes of the rectifier circuit (24). Has been. A potential at a connection point between the resistor (R1) and the resistor (R2) is applied to the comparator (28a). Note that one of the output nodes of the rectifier circuit (24) (in this example, the side connected to the resistor (R2)) is a ground potential. Further, both ends of the resistors (R1, R2) are also connected to the DC link portion of the inverter circuit (22) (the output node of the converter circuit (21)) via the diode (D). This is the same as in the first embodiment.

  Depending on the usage environment and the specifications required for the equipment, the voltage of the DC link may be suddenly higher than the input voltage of the outdoor unit control power supply circuit (25), in which case the diode (D) flows. The current also increases. In particular, when the capacity of the smoothing capacitor is as small as several tens of μF as in a so-called electrolytic capacitorless inverter, a larger diode current flows than in a normal inverter. If the diode (D) or capacitor (C25) is selected according to the increasing current, the cost of the separate air conditioner (1) may be increased. Therefore, in this embodiment, a resistor (R5) is inserted between the diode (D) and the capacitor (C25). By doing so, the current flowing through the diode (D) can be suppressed. As a result, the diode (D) and capacitor (C25) need not be excessively rated, and the total cost of the separate air conditioner (1) can be suppressed.

  Regarding the difference in overvoltage protection level between the DC link unit voltage and the outdoor unit control power circuit (25) generated by inserting a resistor between the diode (D) and the capacitor (C25), the overvoltage detection unit (28 By reducing the ratio of the resistance (R5) to the resistances (R1, R2) in parentheses), it can be suppressed to a level where there is no problem.

  The resistor (R5) may be inserted on the ground side of the output node of the rectifier circuit (24). In this case as well, there is a difference in the overvoltage protection level between the DC link unit voltage and the outdoor unit control power supply circuit (25), but as described above, the resistance to the resistors (R1, R2) in the overvoltage detection unit (28) By reducing the ratio of (R5), it can be suppressed to a level where there is no problem.

<< Other Embodiments >>
The overvoltage protection mechanism described above can also be applied to electronic circuit devices other than a separate air conditioner.

  Further, the use of the inverter circuit (22) is not limited to the compressor. For example, in the field of air conditioners, in addition to the above-described example, a fan motor inverter circuit and other load driving inverter circuits may be provided, and this can also be applied to protection of such inverter circuits. Further, a circuit other than the inverter circuit may be used as the power supply circuit.

  Further, the number of circuit groups (3, 4) may be larger than in the above example. That is, even when there are three or more circuit groups (a combination of the DC power supply unit and the power supply circuit), the overvoltage detection unit (28) is provided in only one of the circuit groups. A circuit group that does not have the overvoltage detection unit (28) inputs a voltage for which an overvoltage is to be detected to the overvoltage detection unit (28) via a diode (D) for preventing current backflow. Thereby, even if an overvoltage occurs in any circuit group, it can be detected by one overvoltage detector (28). Of course, it is not always necessary to reduce the number of overvoltage detection units to one, and the effect of the present technology can be achieved by reducing the number of circuit groups below the number of circuit groups.

  The configuration of the converter circuit (21) is also an example. For example, various AC / DC converters such as an active converter and a PAM can be applied.

  The configuration of each switch (SW1, SW2, SW3) is also an example. A switch other than a relay may be used, and even when a relay is used, the type can be variously selected.

  INDUSTRIAL APPLICABILITY The present invention is useful as a technique for protecting a power supply circuit supplied with power from a DC power supply from overvoltage.

1 Separate air conditioner (electronic circuit device)
3 Circuit group 4 Circuit group 21 Converter circuit (DC power supply)
22 Inverter circuit (powered supply circuit)
24 Rectifier circuit (DC power supply)
25 Power supply circuit for outdoor unit control (power supply circuit)
27 Outdoor unit control circuit (control unit)
28 Overvoltage detector

Claims (3)

Electronic circuit device having a plurality of circuit groups (3, 4) including a DC power supply unit (21, 24) and a power supplied circuit (22, 25) supplied with power from the DC power supply unit (21, 24) In
An overvoltage detection unit (28) provided in any one of the circuit groups (3, 4) and detecting an overvoltage of the DC power supply unit (24) of the circuit group (4);
Provided for each circuit group (3) that does not have the overvoltage detection unit (28), from the circuit group (4) side that has the overvoltage detection unit (28), has the overvoltage detection unit (28) In order to prevent the backflow of the current to the circuit group (3) that is not, the DC power supply unit (21) of the circuit group (3) not having the overvoltage detection unit (28) and the overvoltage detection unit (28) A diode (D) for connecting the
Equipped with a,
An electronic circuit comprising a control unit (27) for cutting off a predetermined power supply path to each of the power supply circuits (22, 25) when the overvoltage detection unit (28) detects an overvoltage apparatus. The electronic circuit device according to claim 1 .
At least one of the power receiving circuits (22, 25) is an inverter circuit (22),
An electronic circuit device comprising a control unit (27) for stopping the operation of the inverter circuit (22) when the overvoltage detection unit (28) detects an overvoltage. The electronic circuit device according to claim 1 or 2 ,
An electronic circuit device comprising a resistor (R5) between a DC power source (24) of a circuit group (4) having the overvoltage detector (28) and the overvoltage detector (28).

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