JP2019176493A - Switching circuit device - Google Patents

Abstract

To provide a switching circuit device capable of suppressing noise caused by high switching speed.SOLUTION: A switching circuit device includes a main circuit switching element having a control electrode, a high potential side electrode, and a low potential side electrode, a high potential side capacitor connected electrically between the control electrode and high potential side electrode, a low potential side capacitor connected electrically between the control electrode and low potential side electrode, and a capacity adjustment switching element connected electrically with the control electrode and adjusting the capacity. The capacity adjustment switching element is connected in series with at least any one of the high potential side electrode and low potential side capacitor.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a switching circuit device.

  Even if the resistance value of the gate resistance RG is lowered by integrating a capacitor between the gate and the emitter of a switching element (T) such as an IGBT or forming a capacitor on the gate substrate, an excessive dI / dt, A semiconductor device that prevents dV / dt from being generated is disclosed (Patent Document 1).

JP 2004-14547 A

  However, the circuit configuration of the semiconductor device has a problem that noise generated with an increase in switching speed cannot be sufficiently suppressed.

  The problem to be solved by the present invention is to provide a switching circuit device capable of suppressing noise generated with an increase in switching speed.

  The present invention electrically connects a high potential side capacitor between the control electrode of the main circuit switching element and the high potential side electrode, and connects the low potential side electrode between the control electrode of the main circuit switching element and the low potential side electrode. A potential adjustment capacitor is electrically connected, and a capacitance adjusting switching element electrically connected to the control electrode is connected in series to at least one of the high potential capacitor and the low potential capacitor. To solve the above problem.

  According to the present invention, since the capacitance when the main circuit switching element is driven can be adjusted by switching control of the capacitance adjusting switching element, there is an effect that the generation of noise can be suppressed by reducing the surge.

It is a circuit diagram of a switching circuit device concerning an embodiment of the present invention. 2 is a graph showing a time chart of the operation of the main circuit switching element and a time chart of the operation of the switching element in the switching circuit device shown in FIG. 1. It is a circuit diagram of a switching circuit device concerning other embodiments of the present invention. 4 is a graph showing a time chart of the operation of the main circuit switching element and a time chart of the operation of the switching element in the switching circuit device shown in FIG. 3. It is a circuit diagram of a switching circuit device concerning other embodiments of the present invention. 6 is a graph showing a time chart of the operation of the main circuit switching element and a time chart of the operation of the switching element in the switching circuit device shown in FIG. 5. It is a circuit diagram of a switching circuit device concerning other embodiments of the present invention. 8 is a graph showing a time chart of the operation of the main circuit switching element and a time chart of the operation of the switching element in the switching circuit device shown in FIG. It is a circuit diagram of a switching circuit device concerning other embodiments of the present invention. FIG. 10 is a graph showing a time chart of the operation of the main circuit switching element and a time chart of the operation of the switching element in the switching circuit device shown in FIG. 9. It is a circuit diagram of a switching circuit device concerning other embodiments of the present invention. 12 is a graph showing a time chart of the operation of the main circuit switching element and a time chart of the operation of the switching element in the switching circuit device shown in FIG. It is a circuit diagram of a switching circuit device concerning other embodiments of the present invention. It is a circuit diagram of a switching circuit device concerning other embodiments of the present invention.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings.

<< First Embodiment >>
FIG. 1 is a circuit diagram of a switching circuit device according to an embodiment of the present invention. The switching circuit device according to the present embodiment is a drive circuit for driving a switching element included in a power conversion circuit or the like, and is applied to a device such as a power conversion device.

  The switching circuit device includes a main circuit switching element 1, a capacitor 2, a capacitor 3, a switching element 4 for switching, a signal generator 10, and a controller 20.

  The main circuit switching element 1 is a circuit element constituting the main circuit. The main circuit is a circuit of a main part of a device applied to the switching element circuit device. For example, when the switching circuit device is applied to a power converter, the main circuit switching element 1 corresponds to a switching element included in the power converter circuit. The main circuit switching element 1 has a control electrode, a high potential side electrode, and a low potential side electrode. The control electrode is connected to the signal generator 10 by wiring for transmitting a control signal. The high potential side electrode and the low potential side electrode are connected to the wiring for the main circuit.

  The main circuit switching element 1 is a semiconductor element such as a MOSFET. In this embodiment, a MOSFET is used for the main circuit switching element 1, the control electrode corresponds to the gate terminal G, the high potential side electrode corresponds to the drain terminal D, and the low potential electrode corresponds to the source terminal S. Equivalent to. The main circuit switching element 1 is a wide band gap semiconductor such as SiC or GaN. As a result, switching loss can be reduced while enabling high-speed switching operation.

  The capacitor 2 is a capacitor for adjusting the capacitance between the gate and the drain of the main circuit switching element 1. The capacitor 2 is electrically connected between the gate terminal G and the drain terminal D.

  The capacitor 3 is a capacitor for adjusting the capacitance between the gate and the source of the main circuit switching element 1. The capacitor 3 is electrically connected between the gate terminal G and the source terminal S. The capacity of the capacitor 3 is larger than the capacity of the capacitor 2.

  The switching element 4 for switching is a switching element for adjusting the gate capacitance of the main circuit switching element 1. The switching element 4 for switching is a switching element for switching conduction and interruption of a bypass line connected between the gate and drain of the main circuit switching element 1. The bypass line includes a capacitor 2 and connects between the gate terminal G and the drain terminal D of the main circuit switching element 1. The switching element 4 for switching is connected in series with the capacitor 2 between the gate terminal G and the drain terminal D of the main circuit switching element 1. The switching element 4 for switching is a semiconductor element such as a MOSFET. In the present embodiment, a MOSFET is used for the switching element 4 for switching. A gate terminal of the switching element 4 for switching is connected to the signal generator 10 by wiring.

  A ground line of the signal generator 10 is connected to the source side of the current path between the drain and source of the main circuit switching element 1.

  The signal generator 10 generates a switching signal based on the control of the controller 20 and transmits the switching signal to the gate terminal of the main circuit switching element 1 and the gate terminal of the switching element 4 for switching.

  The controller 20 is a control circuit that switches the main circuit switching element 1 on and off and the switching switching element 4 on and off.

  Next, the operation of the switching circuit device according to the present embodiment will be described with reference to FIG. FIG. 2 is a graph showing a time chart of the operation of the main circuit switching element 1 and a time chart of the operation of the switching element 4 for switching. The horizontal axis of the graph in FIG. 2 indicates time, and the vertical axis indicates the state of each switching element.

As an initial state, the main circuit switching element 1 is in an on state and the switching element 4 for switching is in an on state. At time t _1, the controller 20, while maintaining the switching switching element 4 in the on state, to turn off the main circuit switching device 1.

  When the switching element 4 for switching is turned on, the drain-gate of the main circuit switching element 1 is brought into conduction through the capacitor 2, so that the capacity between the drain and gate is increased. Therefore, when the main circuit switching element 1 is turned off, the bypass line including the capacitor 2 acts as a differentiation circuit. This differentiation circuit suppresses a decrease in the gate voltage with respect to a voltage change between the drain and the source. When the main circuit switching element 1 is turned off, the voltage change amount between the drain and the source is increased by the high-speed switching operation, but the discharge of the gate charge is suppressed by the action of the differential circuit between the drain and the gate. Thereby, switching speed is suppressed and generation | occurrence | production of a surge is suppressed.

During the time t ₁ to time t _2, the controller 20 switches off the switching switching element 4 from ON.

Immediately before time t ₃ , the controller 20 starts the ON operation of the switching element 4 for switching while maintaining the OFF state of the main circuit switching element 1. At time t _3, switch switching element 4 is a transient state from OFF to ON. The transient state indicates a transient state (transition state) from the start of the ON state of the switching element to the ON state of the switching element. On operation of the switching switching element 4 is terminated between the time t ₃ of the time t _4.

At time t _4, the controller 20, while maintaining the switching switching element 4 in the on state, to turn on the main circuit switching device 1.

  The voltage between the gate and the source of the main circuit switching element 1 is a voltage divided by the capacity ratio between the capacity between the gate and the drain of the main circuit switching element 1 and the capacity between the gate and the source of the main circuit switching element 1. Become. Since the switching switching element 4 is turned on when the main circuit switching element 1 is turned on, the gate-drain capacitance is larger than the capacitance when the switching switching element 4 is turned off. Therefore, the gate-source voltage divided by the drain-source capacitance ratio increases. Thereby, when the main circuit switching element 1 is turned on, the switching speed is increased and the switching loss is reduced.

The controller 20 switches the main circuit switching element 1 and the switching at the times t ₅ , t ₆ , t ₇ , and t ₈ with the same switching control as at the times t ₁ , t ₂ , t ₃ , and t _4. The switching element 4 is controlled. The switching control after the time _{t 8} is the same as the time _{t 1, t 2, t 3} , t 4.

  As described above, in the present embodiment, the capacitor 2 is electrically connected between the control electrode and the high potential side electrode of the main circuit switching element 1, and the control electrode and the low potential side electrode of the main circuit switching element 1 are The switching element 4 is connected in series to the capacitor 2 while the switching element 4 is electrically connected to the control electrode of the main circuit switching element 1 and the switching element 4 is connected in series to the capacitor 2. Yes. Thereby, when the main circuit switching element 1 is driven, the gate capacity of the main circuit switching element 1 can be adjusted by switching control of the switching element 4 for switching, so that surge can be reduced. And by reducing the surge, ringing of current amplitude and voltage amplitude in the current path of the main circuit can be suppressed. As a result, the generation of noise can be suppressed.

  By the way, when the switching speed of the main circuit switching element 1 is increased, resonance noise of the main circuit is likely to occur. In the present embodiment, a surge that becomes a noise generation source can be suppressed by the series circuit of the capacitor 2 connected between the gate and the drain and the switching element 4 for switching. In addition, the switching control device according to the present embodiment can absorb the generated resonance noise. As a result, noise can be suppressed.

  In the present embodiment, the main circuit switching element 1 uses an element (for example, MOSFET) having a gate structure having an insulating film such as an oxide film. In such a structure, the gate voltage tends to be high due to parasitic capacitance or the like, but the gate potential can be suppressed by the above circuit configuration. As a result, the insulating film included in the gate structure can be protected.

  In the present embodiment, the main circuit switching element 1 is turned off with the switching element 4 for switching turned on. As a result, the capacitance between the gate and the source of the main circuit switching element 1 is increased, so that the gate voltage of the main circuit switching element 1 is reduced by the differential circuit with respect to the voltage change between the drain and the source of the main circuit switching element 1. Is suppressed. As a result, it is possible to suppress the occurrence of surge and suppress noise while suppressing switching operation at a certain speed or higher.

  In the present embodiment, the main circuit switching element 1 is turned on while the switching element 4 for switching is turned on. As a result, the gate-drain capacitance of the main circuit switching element 1 is increased, and when the main circuit switching element 1 is turned on, the voltage between the gate and the source is increased, so that the switching speed at turn-on is increased. And loss of the switching element can be reduced.

  In this embodiment, the capacity of the capacitor 2 is larger than the capacity of the capacitor 3. Thereby, the occurrence of surge can be suppressed when the main circuit switching element 1 is turned off.

  The capacitor 2 corresponds to the “high potential side capacitor” of the present invention, the capacitor 3 corresponds to the “low potential side capacitor” of the present invention, and the switching element 4 for switching corresponds to the “capacitance adjusting switching element” of the present invention. Equivalent to.

<< Second Embodiment >>
FIG. 3 is a circuit diagram of a switching circuit device according to another embodiment of the invention. In this example, the connection position of the switching element 4 for switching and the capacities of the capacitors 2 and 3 are different from those of the first embodiment described above. Other configurations are the same as those in the first embodiment described above, and the description thereof is incorporated.

  The connection positions of the capacitors 2 and 3 are the same as those of the switching circuit device according to the first embodiment. The capacity of the capacitor 3 is larger than the capacity of the capacitor 2.

  The switching element 4 for switching is connected in series with the capacitor 3 between the gate terminal G and the source terminal S of the main circuit switching element 1.

  Next, the operation of the switching circuit device according to the present embodiment will be described with reference to FIG. FIG. 3 is a graph showing a time chart of the operation of the main circuit switching element 1 and a time chart of the operation of the switching element 4 for switching. The horizontal axis of the graph in FIG. 3 indicates time, and the vertical axis indicates the state of each switching element.

As an initial state, the main circuit switching element 1 is on and the switching element 4 for switching is off. At time t _1, the controller 20, while maintaining the switching switching element 4 in the OFF state, it turns off the main circuit switching device 1.

  When the switching element 4 for switching is turned off, the capacity between the gate and the source becomes small, and when the main circuit switching element 1 is turned on, the bypass line including the capacitor 2 acts as a differentiating circuit. This differentiation circuit suppresses a decrease in the gate voltage with respect to a voltage change between the drain and the source. When the main circuit switching element 1 is turned off, the voltage change amount between the drain and the source is increased by the high-speed switching operation, but the discharge of the gate charge is suppressed by the action of the differential circuit between the drain and the gate. Thereby, switching speed is suppressed and generation | occurrence | production of a surge is suppressed.

During the time t ₁ to time t _2, controller 20 may turn on the switching switching element 4 from OFF.

Just prior to time t _3, the controller 20, while maintaining the OFF state of the main circuit switching device 1, starts off operation of the switching switching element 4. At time t _3, the switching element 4 for switching is in a transitional state from on to off. The transient state indicates a state (transition state) from the start of the OFF state of the switching element to the OFF state of the switching element. OFF operation of the switching switching element 4 is terminated between the time t ₃ of the time t _4.

At time t _4, the controller 20, while maintaining the switching switching element 4 in the OFF state, to turn on the main circuit switching device 1.

  Since the switching element 4 for switching is turned off when the main circuit switching element 1 is turned on, the capacity between the gate and the source becomes smaller than the capacity when the switching element 4 for switching is turned on. Therefore, the gate-source voltage divided by the drain-source capacitance ratio increases. Thereby, when the main circuit switching element 1 is turned on, the switching speed is increased and the switching loss is reduced.

The controller 20 switches the main circuit switching element 1 and the switching at the times t ₅ , t ₆ , t ₇ , and t ₈ with the same switching control as at the times t ₁ , t ₂ , t ₃ , and t _4. The switching element 4 is controlled. The switching control after the time _{t 8} is the same as the time _{t 1, t 2, t 3} , t 4.

  As described above, in the present embodiment, the switching element 4 is connected in series to the capacitor 3 while the switching element 4 is electrically connected to the control electrode of the main circuit switching element 1. Thereby, when the main circuit switching element 1 is driven, the gate capacity of the main circuit switching element 1 can be adjusted by switching control of the switching element 4 for switching, so that surge can be reduced. And by reducing the surge, ringing of current amplitude and voltage amplitude in the current path of the main circuit can be suppressed. As a result, the generation of noise can be suppressed.

  In the present embodiment, the main circuit switching element 1 is turned off with the switching element 4 for switching turned off. As a result, the capacitance between the gate and the source of the main circuit switching element 1 is reduced, so that the gate voltage of the main circuit switching element 1 is reduced by the differential circuit with respect to the voltage change between the drain and source of the main circuit switching element 1. Is suppressed. As a result, it is possible to suppress the occurrence of surge and suppress noise while suppressing switching operation at a certain speed or higher.

  In the present embodiment, the main circuit switching element 1 is turned on with the switching element 4 for switching turned off. As a result, the gate-source capacitance of the main circuit switching element 1 is reduced, and when the main circuit switching element 1 is turned on, the gate-source voltage is increased, so that the switching speed at turn-off is increased. And loss of the switching element can be reduced.

  In this embodiment, the capacity of the capacitor 3 is larger than the capacity of the capacitor 2. Thereby, the occurrence of surge can be suppressed when the main circuit switching element 1 is turned off.

<< Third Embodiment >>
FIG. 5 is a circuit diagram of a switching circuit device according to another embodiment of the invention. This example is different from the first embodiment described above in that the connection position of the switching element 4 for switching is connected between the gate and the drain of the main circuit switching element 1 and between the gate and the source. Other configurations are the same as those of the first embodiment described above, and the descriptions of the first and second embodiments are incorporated as appropriate.

  The switching element 4A for switching is connected in series with the capacitor 2 between the gate terminal G and the drain terminal D of the main circuit switching element 1. The switching element 4B for switching is connected in series with the capacitor 3 between the gate terminal G and the source terminal S of the main circuit switching element 1. The switching elements for switching 4A and 4B are the same elements as the switching element for switching 4 according to the first embodiment or the second embodiment.

  Next, the operation of the switching circuit device according to the present embodiment will be described with reference to FIG. FIG. 6 is a graph showing a time chart of the operation of the main circuit switching element 1 and a time chart of the operation of the switching elements for switching 4A and 4B. The horizontal axis of the graph in FIG. 6 indicates time, and the vertical axis indicates the state of each switching element.

As an initial state, the main circuit switching element 1 is in an on state, the switching element 4A is in an on state, and the switching element 4B is in an off state. At time t _1, the controller 20, the switch switching element 4A in the on state, while maintaining switch switching element 4B in the off state, turning off the main circuit switching device 1.

  When the switching element 4A is turned on and the switching element 4B is turned off, the gate-drain capacitance is large and the gate-source capacitance is small. Therefore, when the main circuit switching element 1 is turned on, the bypass line including the capacitor 2 acts as a differentiation circuit. This differentiation circuit suppresses a decrease in the gate voltage with respect to a voltage change between the drain and the source. When the main circuit switching element 1 is turned off, the voltage change amount between the drain and the source is increased by the high-speed switching operation, but the discharge of the gate charge is suppressed by the action of the differential circuit between the drain and the gate. Thereby, switching speed is suppressed and generation | occurrence | production of a surge is suppressed.

During the time t ₁ to time t _2, the controller 20 switches off the switching switching elements 4A from ON, switching on the switching switching element 4B from OFF.

Just prior to time t _3, the controller 20, while maintaining the OFF state of the main circuit switching device 1 starts the ON operation and the OFF operation of the switching switching element 4B of switching the switching elements 4A. At time t _3, switch switching element 4A is a transient state from off to on, switching the switching element 4B is a transitional state from ON to OFF. Turned on and off operation of the switching switching element 4B of switching the switching elements 4A is terminated between the time t ₃ of the time t _4.

At time t _4, the controller 20 maintains the switching switching elements 4A in the ON state, and, while maintaining the switching switching element 4B in the OFF state, to turn on the main circuit switching device 1.

  Since the switching element 4A is turned on when the main circuit switching element 1 is turned on, the capacitance between the gate and the drain is larger than the capacitance when the switching element 4 is turned off. Further, since the switching element 4B is turned off when the main circuit switching element 1 is turned on, the capacitance between the gate and the source is smaller than the capacitance when the switching element 4B is turned on. . Therefore, the gate-source voltage divided by the drain-source capacitance ratio increases. Thereby, when the main circuit switching element 1 is turned on, the switching speed is increased and the switching loss is reduced.

The controller 20 switches the main circuit switching element 1 and the switching at the times t ₅ , t ₆ , t ₇ , and t ₈ with the same switching control as at the times t ₁ , t ₂ , t ₃ , and t _4. Switching elements 4A and 4B are controlled. The switching control after the time _{t 8} is the same as the time _{t 1, t 2, t 3} , t 4.

  As described above, in the present embodiment, the switching element 4 </ b> A is connected in series to the capacitor 2 while the switching element 4 is electrically connected to the control electrode of the main circuit switching element 1. Are connected in series with the switching element 4B for switching. Accordingly, when the main circuit switching element 1 is driven, the gate capacity of the main circuit switching element 1 can be adjusted by switching control of the switching elements 4A and 4B for switching, so that surge can be reduced. And by reducing the surge, ringing of current amplitude and voltage amplitude in the current path of the main circuit can be suppressed. As a result, the generation of noise can be suppressed.

  In the present embodiment, the main circuit switching element 1 is turned off with the switching element 4A being turned on and the switching element 4B being turned off. As a result, the capacitance between the gate and the drain of the main circuit switching element 1 is increased and the capacitance between the gate and the source is decreased. A decrease in the gate voltage of the main circuit switching element 1 is suppressed. As a result, it is possible to suppress the occurrence of surge and suppress noise while suppressing switching operation at a certain speed or higher.

  In this embodiment, the main circuit switching element 1 is turned on with the switching element 4A being turned on and the switching element 4B being turned off. As a result, the capacitance between the gate and the drain of the main circuit switching element 1 is increased and the capacitance between the gate and the source of the main circuit switching element 1 is decreased. Therefore, when the main circuit switching element 1 is turned on, the gate− The voltage between the sources is increased, the switching speed at turn-off can be increased, and the loss of the switching element can be reduced.

  The switching element 4A for switching corresponds to the “first capacity adjusting switching element” of the present invention, and the switching element 4B for switching corresponds to the “second capacity adjusting switching element” of the present invention.

<< 4th Embodiment >>
FIG. 7 is a circuit diagram of a switching circuit device according to another embodiment of the invention. This example is different in that the driving circuit for the main circuit switching element according to the first embodiment described above is applied to the upper arm circuit 100 and the lower arm circuit 200, respectively. The other configuration is the same as that of the first embodiment described above, and the description of the first embodiment is incorporated as appropriate.

  The switching circuit device according to the present embodiment is applied to an arm circuit of a power conversion device. The power conversion device is a conversion circuit that converts, for example, power of a DC power source into AC power and outputs the AC power to a load. The conversion circuit is a circuit in which a plurality of switching elements are connected in a bridge shape. The conversion circuit is a circuit in which a plurality of transistors are connected in series in each phase, and a connection point of the transistors connected in series is connected to a load by wiring of each phase. In the following description, an example in which the switching circuit device is applied to an arm circuit for one phase will be described. However, the arm circuits for other phases have the same configuration and switching control.

  The upper arm circuit 100 includes a main circuit switching element 1B, a capacitor 2, a capacitor 3, and a switching element 4C for switching. The lower arm circuit 200 includes a main circuit switching element 1A, a capacitor 2, a capacitor 3, and a switching element 4A for switching. The upper arm circuit 100 and the lower arm circuit 200 are connected in series. The connection form of the circuit elements constituting each arm circuit is the same as the connection form of the switching circuit elements according to the first embodiment.

  Next, the operation of the switching circuit device according to the present embodiment will be described with reference to FIG. FIG. 8 is a graph showing a time chart of operations of the main circuit switching elements 1A and 1B and a time chart of operations of the switching elements 4A and 4C for switching. The horizontal axis of the graph in FIG. 8 indicates time, and the vertical axis indicates the state of each switching element.

  As an initial state, the main circuit switching element 1A is on, the main circuit switching element 1B is off, the switching element 4A is on, and the switching element 4C is off.

Just prior to time t _1, the controller 20, the main circuit switching element 1A on state, the main circuit switching element 1B off state, and, while maintaining the ON state of the switching switching elements 4A, the switch switching element 4C Start on operation. At time t _1, switch switching element 4A is a transitional state from OFF to ON. On operation of the switching switching element 4A is terminated between the time t ₁ of time t _2.

At time t _1, switch switching element 4C is a state of half-on, conduction resistance of the switching switching element 4C is in the ON state of the switching switching element 4C and resistance, the off state of the switching switching element 4C It becomes a value between the resistance values. That is, the controller 20 can set the resistance value of the switching element 4C to an arbitrary resistance value by bringing the switching element 4C into a transient state.

  And the circuit connected from the capacitor 2 to the capacitor 3 via the switching element 4C for switching functions as a CR filter by setting the switching element 4C for transition to a transient state (half-on state). Thereby, noise generated when the main circuit switching element 1A is turned off is suppressed by the CR filter. The controller 20 also suppresses noise generated when the main circuit switching element 1A is turned off by setting the conduction resistance of the switching element 4C for switching so that the cutoff frequency of the CR filter becomes the resonance frequency of the main circuit. it can.

  Further, the main circuit switching element 1A is turned off in a state where the switching element 4A for switching is turned on. Therefore, in the lower arm circuit 200, a differential circuit acts, and a decrease in the gate voltage is suppressed with respect to a voltage change between the drain and source of the main circuit switching element 1A. Thereby, switching speed is suppressed and generation | occurrence | production of a surge is suppressed.

Between time _{t 1} of time _{t 2,} the controller 20 switches off the switching switching elements 4A from ON.

At time t _2, controller 20 turns off the switching switching elements 4A state, while maintaining the switching switching element 4C the on state and the main circuit switching element 1A in the off state, to turn on the main circuit switching device 1B . At this time, since the switching element 4A for switching is in an OFF state, the ratio (C _gs / C _gd ) of the capacitance of the main circuit switching element 1A increases. The ratio of capacitance (C _gs / C _gd ) is the ratio of the gate-source capacitance to the gate-drain capacitance of the main circuit switching element 1A. When the capacitance ratio (C _gs / C _gd ) increases, the main circuit switching element 1A becomes difficult to turn on. This can reduce the possibility of malfunction of the main circuit switching element 1A when the main circuit switching element 1B is turned on.

Just prior to time t _3, the controller 20, the off state of the main circuit switching devices 1A, the main circuit switching element 1B on state, and, while maintaining the ON state of the switching switching element 4C, the switching switching elements 4A Start on operation. At time t _3, switch switching element 4A is a transitional state from OFF to ON. On operation of the switching switching element 4A is terminated between the time t ₃ of the time t _4.

At time t _3, switch switching element 4A is a state of half-on, conduction resistance of the switching switching elements 4A is in the ON state of the switching switching elements 4A and resistance, the off state of the switching switching elements 4A It becomes a value between the resistance values. By setting the switching element 4A for switching to a transient state (half-on state), the circuit connected from the capacitor 2 to the capacitor 3 via the switching element 4A for switching functions as a CR filter. Thereby, noise generated when the main circuit switching element 1B is turned off is suppressed by the CR filter.

  Further, the main circuit switching element 1B is turned off while the switching element 4C for switching is turned on. Therefore, in the upper arm circuit 100, the bypass line including the capacitor 2 acts as a differentiating circuit, and a decrease in the gate voltage is suppressed with respect to a voltage change between the drain and the source of the main circuit switching element 1B. Thereby, switching speed is suppressed and generation | occurrence | production of a surge is suppressed.

Between time _{t 3} of the time _{t 4,} the controller 20 may turn on the switching switching element 4D from OFF.

At time t _4, the controller 20, the switch switching element 4A on state, while maintaining the switching switching element 4C the OFF state and the main circuit switching device 1B in OFF state, to turn on the main circuit switching device 1A . At this time, since the switching element 4C for switching is in an OFF state, the ratio (C _gs / C _gd ) of the capacitance of the main circuit switching element 1B is increased. The capacitance ratio (C _gs / C _gd ) is the ratio of the gate-source capacitance to the gate-drain capacitance of the main circuit switching element 1B. When the capacitance ratio (C _gs / C _gd ) increases, the main circuit switching element 1B becomes difficult to turn on. This can reduce the possibility of malfunction of the main circuit switching element 1B when the main circuit switching element 1A is turned on.

The controller 20 switches the main circuit switching element 1 and the switching at the times t ₅ , t ₆ , t ₇ , and t ₈ with the same switching control as at the times t ₁ , t ₂ , t ₃ , and t _4. The switching element 4 is controlled. The switching control after the time _{t 8} is the same as the time _{t 1, t 2, t 3} , t 4.

  As described above, in the present embodiment, in the upper arm circuit 100, the switching element 4C is electrically connected to the control electrode of the main circuit switching element 1B, and the switching element 4C is connected in series with the capacitor 2. Connected. In the lower arm circuit 200, the switching element 4A is electrically connected to the control electrode of the main circuit switching element 1B, and the switching element 4A is connected in series to the capacitor 2. As a result, when the main circuit switching element 1A or the main circuit switching element 1B is driven, the gate capacity of the main circuit switching elements 1A and 1B can be adjusted by switching control of the switching elements 4A and 4C for switching, thereby reducing surges. it can. And by reducing the surge, ringing of current amplitude and voltage amplitude in the current path of the main circuit can be suppressed. As a result, the generation of noise can be suppressed.

  In the present embodiment, the controller 20 turns off the upper arm circuit 100 and the lower arm circuit 100 when turning off the main circuit switching elements 1A and 1B included in one of the upper arm circuit 100 and the lower arm circuit 200. The switching elements 4A and 4C included in the other arm circuit of the arm circuit 200 are set in a transient state. Thereby, noise generated when the main circuit switching elements 1A and 1B are turned off can be suppressed by the CR filter action.

  In the present embodiment, when the controller 20 turns off the main circuit switching elements 1A and 1B included in either one of the upper arm circuit 100 and the lower arm circuit 200, the controller 20 The included switching elements 4A and 4C are maintained in the ON state. As a result, in the main circuit switching elements 1A and 1B that are turned off, the gate-drain capacitance increases and the gate-source capacitance decreases, so that the drain-source of the main circuit switching element 1 is activated by the action of the differentiation circuit. A decrease in the gate voltage of the main circuit switching element 1 is suppressed with respect to the voltage change between them. As a result, it is possible to suppress the occurrence of surge and suppress noise while suppressing switching operation at a certain speed or higher.

  In the present embodiment, when the controller 20 turns on the main circuit switching elements 1A and 1B included in one of the upper arm circuit 100 and the lower arm circuit 200, the controller 20 The switching elements 4A and 4C included in switching are maintained in an off state, and the switching elements 4A and 4C included in the other arm circuit of the upper arm circuit 100 and the lower arm circuit 200 are maintained in an on state. Thereby, when the main circuit switching elements 1A and 1B included in the one arm circuit are turned on, the possibility of malfunction of the main circuit switching elements 1A and 1B included in the other arm circuit can be reduced.

  The switching elements 4A and 4C for switching correspond to the “capacitance adjusting switching element” of the present invention.

<< 5th Embodiment >>
FIG. 9 is a circuit diagram of a switching circuit device according to another embodiment of the invention. This example is different in that the drive circuit for the main circuit switching element according to the second embodiment described above is applied to the upper arm circuit 100 and the lower arm circuit 200, respectively. Other configurations are the same as those of the second embodiment described above, and the descriptions of the second embodiment and the fourth embodiment are incorporated as appropriate.

  The upper arm circuit 100 includes a main circuit switching element 1B, a capacitor 2, a capacitor 3, and a switching element 4D for switching. The lower arm circuit 200 includes a main circuit switching element 1A, a capacitor 2, a capacitor 3, and a switching element 4B for switching. The upper arm circuit 100 and the lower arm circuit 200 are connected in series. The connection form of the circuit elements constituting each arm circuit is the same as the connection form of the switching circuit elements according to the second embodiment.

  Next, the operation of the switching circuit device according to the present embodiment will be described with reference to FIG. FIG. 10 is a graph showing a time chart of operations of the main circuit switching elements 1A and 1B and a time chart of operations of the switching elements 4B and 4D for switching. The horizontal axis of the graph in FIG. 10 indicates time, and the vertical axis indicates the state of each switching element.

  As an initial state, the main circuit switching element 1A is in the on state, the main circuit switching element 1B is in the off state, the switching switching element 4B is in the off state, and the switching switching element 4D is in the on state.

Just prior to time t _1, the controller 20, the main circuit switching device 1A in the ON state, the OFF state of the main circuit switching element 1B, and, while maintaining the off state of the switching switching element 4B, the changeover switching element 4D Starts off operation. At time t _1, switch switching element 4D is a transitional state from ON to OFF. OFF operation of the switching switching element 4D is terminated between the time t ₁ of time t _2.

At time t _1, switch switching element 4D is a state of half-on, conduction resistance of the switching switching element. 4D, the ON state of the selector switching element 4D and the resistance value, the off state of the switching switching elements 4D It becomes a value between the resistance values. That is, the controller 20 can set the resistance value of the switching element 4D to an arbitrary resistance value by setting the switching element 4D to a transient state.

  By setting the switching element 4D for switching to a transient state (half-on state), the circuit connected from the capacitor 2 to the capacitor 3 via the switching element 4D for switching functions as a CR filter. Thereby, noise generated when the main circuit switching element 1A is turned off is suppressed by the CR filter. The controller 20 also suppresses noise generated when the main circuit switching element 1A is turned off by setting the conduction resistance of the switching element 4D for switching so that the cutoff frequency of the CR filter becomes the resonance frequency of the main circuit. it can.

  Further, the main circuit switching element 1A is turned off with the switching element 4B for switching off. Therefore, in the lower arm circuit 200, a differential circuit acts, and a decrease in the gate voltage is suppressed with respect to a voltage change between the drain and source of the main circuit switching element 1A. Thereby, switching speed is suppressed and generation | occurrence | production of a surge is suppressed.

Between time _{t 1} of time _{t 2,} controller 20 may turn on the switching switching element 4B from OFF.

At time t _2, the controller 20 turns on the switch switching element 4B state, while maintaining the switching switching element 4D the OFF state and the main circuit switching element 1A in the off state, to turn on the main circuit switching device 1B . At this time, since the switching element 4B for switching is in an ON state, the ratio (C _gs / C _gd ) of the electrostatic capacity of the main circuit switching element 1A increases. When the capacitance ratio (C _gs / C _gd ) increases, the main circuit switching element 1A becomes difficult to turn on. This can reduce the possibility of malfunction of the main circuit switching element 1A when the main circuit switching element 1B is turned on.

Just prior to time t _3, the controller 20, the off state of the main circuit switching devices 1A, the main circuit switching element 1B on state, and, while maintaining the off state of the switching switching elements 4D, the switch switching element 4B Start on operation. At time t _3, switch switching element 4B is a transitional state from ON to OFF. OFF operation of the switching switching element 4B is terminated between the time t ₃ of the time t _4.

At time t _3, switch switching element 4B is a state of half-on, conduction resistance of the switching switching element 4B is in the ON state of the switching switching element 4B and the resistance value, the off state of the switching switching element 4B It becomes a value between the resistance values. By setting the switching element 4B for switching to a transient state (half-on state), a circuit connected from the capacitor 2 to the capacitor 3 via the switching element 4B for switching functions as a CR filter. Thereby, noise generated when the main circuit switching element 1B is turned off is suppressed by the CR filter.

  Further, the main circuit switching element 1B is turned off with the switching element 4D for switching off. Therefore, in the upper arm circuit 100, a differentiation circuit acts, and a decrease in the gate voltage is suppressed with respect to a voltage change between the drain and source of the main circuit switching element 1A. Thereby, switching speed is suppressed and generation | occurrence | production of a surge is suppressed.

Between time _{t 3} of the time _{t 4,} the controller 20 may turn on the switching switching element 4D from OFF.

At time t _4, the controller 20 turns off the switch switching element 4B state, while maintaining the switching switching element 4D on state and the main circuit switching device 1B in OFF state, to turn on the main circuit switching device 1A . At this time, since the switching element for switching 4D is in the ON state, the ratio of the capacitance of the main circuit switching element 1B (C _gs / C _gd ) becomes large. When the capacitance ratio (C _gs / C _gd ) increases, the main circuit switching element 1B becomes difficult to turn on. This can reduce the possibility of malfunction of the main circuit switching element 1B when the main circuit switching element 1A is turned on.

The controller 20 controls the main circuit switching elements 1A, 1B at the times t ₅ , t ₆ , t ₇ , t ₈ with the same switching control as at the times t ₁ , t ₂ , t ₃ , t _4. The switching elements 4B and 4D for switching are controlled. The switching control after the time _{t 8} is the same as the time _{t 1, t 2, t 3} , t 4.

  As described above, in the present embodiment, in the upper arm circuit 100, the switching element 4D is electrically connected to the control electrode of the main circuit switching element 1B, and the switching element 4D is connected in series with the capacitor 3. Connected. In the lower arm circuit 200, the switching element 4B is electrically connected to the control electrode of the main circuit switching element 1B, and the switching element 4B is connected in series to the capacitor 3. As a result, when the main circuit switching element 1A or the main circuit switching element 1B is driven, the gate capacity of the main circuit switching elements 1A, 1B can be adjusted by switching control of the switching elements 4B, 4D for switching, thereby reducing surges. it can. And by reducing the surge, ringing of current amplitude and voltage amplitude in the current path of the main circuit can be suppressed. As a result, the generation of noise can be suppressed.

  In the present embodiment, the controller 20 turns off the upper arm circuit 100 and the lower arm circuit 100 when turning off the main circuit switching elements 1A and 1B included in one of the upper arm circuit 100 and the lower arm circuit 200. The switching elements 4B and 4D included in the other arm circuit of the arm circuit 200 are set in a transient state. Thereby, noise generated when the main circuit switching elements 1A and 1B are turned off can be suppressed by the CR filter action.

  In the present embodiment, when the controller 20 turns off the main circuit switching elements 1A and 1B included in either one of the upper arm circuit 100 and the lower arm circuit 200, the controller 20 The included switching elements 4B and 4D are maintained in the off state. As a result, in the main circuit switching elements 1A and 1B that are turned off, a reduction in the gate voltage of the main circuit switching element 1 with respect to a voltage change between the drain and source of the main circuit switching element 1 is suppressed by the action of the differentiation circuit. . As a result, it is possible to suppress the occurrence of surge and suppress noise while suppressing switching operation at a certain speed or higher.

  In the present embodiment, when the controller 20 turns on the main circuit switching elements 1A and 1B included in one of the upper arm circuit 100 and the lower arm circuit 200, the controller 20 Switching switching elements 4B and 4D included are maintained in an off state, and switching switching elements 4B and 4D included in the other arm circuit of upper arm circuit 100 and lower arm circuit 200 are maintained in an on state. Thereby, when the main circuit switching elements 1A and 1B included in the one arm circuit are turned on, the possibility of malfunction of the main circuit switching elements 1A and 1B included in the other arm circuit can be reduced.

  The switching elements 4B and 4D for switching correspond to the “capacitance adjusting switching element” of the present invention.

<< 6th Embodiment >>
FIG. 11 is a circuit diagram of a switching circuit device according to another embodiment of the invention. This example is different in that the driving circuit for the main circuit switching element according to the third embodiment described above is applied to the upper arm circuit 100 and the lower arm circuit 200, respectively. Other configurations are the same as those in the third embodiment described above, and the descriptions of the third to fifth embodiments are incorporated as appropriate.

  The upper arm circuit 100 includes a main circuit switching element 1B, a capacitor 2, a capacitor 3, and switching switching elements 4C and 4D. The lower arm circuit 200 includes a main circuit switching element 1A, a capacitor 2, a capacitor 3, and switching switching elements 4A and 4B. The upper arm circuit 100 and the lower arm circuit 200 are connected in series. The connection form of the circuit elements constituting each arm circuit is the same as the connection form of the switching circuit elements according to the third embodiment.

  Next, the operation of the switching circuit device according to this embodiment will be described with reference to FIG. FIG. 12 is a graph showing a time chart of operations of the main circuit switching elements 1A and 1B and a time chart of operations of the switching elements 4A to 4D for switching. The horizontal axis of the graph in FIG. 12 indicates time, and the vertical axis indicates the state of each switching element.

  As an initial state, the main circuit switching element 1A is on, the main circuit switching element 1B is off, the switching elements 4B and 4C are off, and the switching elements 4A and 4D are on. is there.

Just prior to time t _1, the controller 20 maintains the main circuit switching element 1A on state, the main circuit switching element 1B OFF state, the ON state of the switching switching elements 4A, and the off state of the switching switching element 4B However, the on-operation of the switching element 4C and the off-operation of the switching element 4D are started. At time t _1, switch switching element 4C is a transient state from off to on, switching the switching element 4D is a transitional state from ON to OFF. It turned on and off operation of the switching switching element 4D of switching the switching element 4C is terminated between the time t ₁ of time t _2.

At time _{t 1,} switch switching element 4C, 4D is a state of half-on.

  By making the switching elements 4C and 4D for switching into a transient state (half-on state), the circuit connected from the capacitor 2 to the capacitor 3 via the switching elements 4C and 4D for switching functions as a CR filter. Thereby, noise generated when the main circuit switching element 1A is turned off is suppressed by the CR filter.

  The controller 20 sets the conduction resistance of the switching element 4C for switching and the conduction resistance of the switching element 4D for switching so that the cutoff frequency of the CR filter becomes the resonance frequency of the main circuit. Noise generated at turn-off can be suppressed.

  Further, the main circuit switching element 1A is turned off in a state where the switching element 4A is turned on and a state where the switching element 4B is turned off. Therefore, in the lower arm circuit 200, a differential circuit acts, and a decrease in the gate voltage is suppressed with respect to a voltage change between the drain and source of the main circuit switching element 1A. Thereby, switching speed is suppressed and generation | occurrence | production of a surge is suppressed.

Between time t ₁ of time t _2, the controller 20 switches off the switching switching elements 4A from ON, switching on the switching switching element 4B from OFF.

At time t _2, controller 20, switching the switching elements 4A, 4D and off state, switching the switching element 4B, while maintaining 4C the on state and the main circuit switching element 1A in the off state, the main circuit switching device Turn 1B on. At this time, since the switching element 4A for switching is in the off state and the switching element 4B for switching is in the on state, the capacitance ratio (C _gs / C _gd ) of the main circuit switching element 1A increases. When the capacitance ratio (C _gs / C _gd ) increases, the main circuit switching element 1B becomes difficult to turn on. This can reduce the possibility of malfunction of the main circuit switching element 1A when the main circuit switching element 1B is turned on.

Immediately before time t ₃ , the controller 20 maintains the main circuit switching element 1A in the off state, the main circuit switching element 1B in the on state, the switching switching element 4C in the on state, and the switching switching element 4D in the off state. However, the on operation of the switching element 4A and the off operation of the switching element 4B are started. At time t _3, switch switching element 4A, 4B is a transient state. Turned on and off operation of the switching switching element 4B of switching the switching elements 4A is terminated between the time t ₃ of the time t _4.

At time _{t 3,} switch switching element 4A, 4B is in a state of half-on. By setting the switching elements 4A and 4B for switching to a transient state (half-on state), the circuit connected from the capacitor 2 to the capacitor 3 via the switching elements 4A and 4B for switching functions as a CR filter. Thereby, noise generated when the main circuit switching element 1B is turned off is suppressed by the CR filter.

  The controller 20 sets the conduction resistance of the switching element 4A for switching and the conduction resistance of the switching element 4B for switching so that the cutoff frequency of the CR filter becomes the resonance frequency of the main circuit. Noise generated at turn-off can be suppressed.

  Further, the main circuit switching element 1B is turned off in a state where the switching element 4C is turned on and a state where the switching element 4D is turned off. Therefore, in the upper arm circuit 100, a differentiation circuit acts, and a decrease in the gate voltage is suppressed with respect to a voltage change between the drain and source of the main circuit switching element 1A. Thereby, switching speed is suppressed and generation | occurrence | production of a surge is suppressed.

Between time t ₃ of the time t _4, the controller 20 switches off the switch switching element 4B from ON, switching on the switching switching elements 4A from OFF.

At time t _4, the controller 20, switching the switching elements 4A, 4D on state, switching the switching element 4B, while maintaining 4C the OFF state and the main circuit switching device 1B in OFF state, the main circuit switching device Turn on 1A. At this time, since the switching element 4C for switching is in the off state and the switching element 4D for switching is in the on state, the capacitance ratio (C _gs / C _gd ) of the main circuit switching element 1B increases. The capacitance ratio (C _gs / C _gd ) is the ratio of the gate-source capacitance to the gate-drain capacitance of the main circuit switching element 1B. When the capacitance ratio (C _gs / C _gd ) increases, the main circuit switching element 1A becomes difficult to turn on. This can reduce the possibility of malfunction of the main circuit switching element 1B when the main circuit switching element 1A is turned on.

The controller 20 controls the main circuit switching elements 1A, 1B at the times t ₅ , t ₆ , t ₇ , t ₈ with the same switching control as at the times t ₁ , t ₂ , t ₃ , t _4. And the switching elements 4A to 4D for switching are controlled. The switching control after the time _{t 8} is the same as the time _{t 1, t 2, t 3} , t 4.

  As described above, in the present embodiment, in the upper arm circuit 100, the switching elements 4C and 4D for switching are electrically connected to the control electrode of the main circuit switching element 1B, and the switching element for switching in series with the capacitor 2 is used. 4C is connected, and a switching element 4D for switching is connected in series with the capacitor 3. In the lower arm circuit 200, the switching elements 4A and 4B are electrically connected to the control electrode of the main circuit switching element 1B, the switching element 4A is connected in series to the capacitor 2, and the capacitor 3 On the other hand, the switching element 4B for switching is connected in series. As a result, when the main circuit switching element 1A or the main circuit switching element 1B is driven, the gate capacity of the main circuit switching elements 1A and 1B can be adjusted by switching control of the switching elements 4A to 4D for switching. it can. And by reducing the surge, ringing of current amplitude and voltage amplitude in the current path of the main circuit can be suppressed. As a result, the generation of noise can be suppressed.

<< 7th Embodiment >>
FIG. 13 is a circuit diagram of a switching circuit device according to another embodiment of the invention. This example is different from the third embodiment described above in that a circuit for adjusting the on / off timing of the main circuit switching element 1A and the switching elements 4A, 4B is incorporated. Other configurations are the same as those of the third embodiment described above, and the descriptions of the first to third embodiments are incorporated as appropriate.

  A timing adjustment circuit 50 is connected between a connection point between the switching element 4 </ b> A for switching and the switching element 4 </ b> B for switching and the gate terminal G of the main circuit switching element 1.

  The timing adjustment circuit 50 is a circuit in which a series circuit of a resistor 51 and a diode 52 and a series circuit of a resistor 53 and a diode 54 are connected in parallel. At this time, the respective series circuits are connected in parallel so that the forward direction of the diode 52 and the forward direction of the diode 54 are opposite to each other.

  An NPN transistor is used as the switching element 4A for switching, and a PNP transistor is used as the switching element 4B for switching. The timing adjustment circuit 60 is a circuit that adjusts the ON / OFF timing of the switching elements 4A and 4B for switching. One end of the timing adjustment circuit 60 is connected to a control wiring that connects the signal generator 10 and the gate terminal G of the main circuit switching element 1. The other end of the timing adjustment circuit 60 is connected to the control terminal of the switching element 4A for switching and the control terminal of the switching element 4B for switching.

  The timing adjustment circuit 60 is a circuit in which a series circuit of a resistor 61 and a diode 62 and a series circuit of a resistor 63 and a diode 64 are connected in parallel. At this time, the respective series circuits are connected in parallel so that the forward direction of the diode 62 and the forward direction of the diode 64 are opposite to each other.

  The gate signal generated by the signal generator 10 is input to the gate terminal via the timing adjustment circuit 50 and to the control terminal of the switching element 4A for switching and the control terminal of the switching element 4B for switching via the timing adjustment circuit 60. Is also entered. That is, the controller 20 controls the switching operation of the main circuit switching element 1 and the switching operations of the switching elements 4A and 4B by the same control signal (gate signal).

  Thereby, in this embodiment, switching control in this embodiment is realizable, without adding a complicated control circuit etc. with respect to high-speed switching operation and high-speed switching cycle.

  Note that the timing adjustment circuits 50 and 60 according to the present embodiment may be applied to the switching circuit devices according to the fourth to sixth embodiments.

<< Eighth Embodiment >>
FIG. 14 is a circuit diagram of a switching circuit device according to another embodiment of the invention. In this example, the circuit configuration for connecting the control terminal of the main circuit switching element 1A and the switching elements for switching 4A and 4B and the signal generator 10 is different from the third embodiment described above. Other configurations are the same as those of the third embodiment described above, and the descriptions of the first to third embodiments are incorporated as appropriate.

  As shown in FIG. 14, a push-pull circuit composed of an NPN transistor 81 and a PNP transistor 82 is connected to the gate terminal of the main circuit switching element 1. The control signal line connected to the signal generator 10 is branched and connected to the base of the NPN transistor 81 and the base of the PNP transistor 82. The control signal for the NPN transistor 81 and the control signal for the PNP transistor 82 are common signals.

  A power supply 83 is connected to the collector of the NPN transistor 81. The collector of the PNP transistor 82 is connected to a ground line connected to the power supply 83. The connection point between the emitter of the NPN transistor 81 and the emitter of the PNP transistor 82 is connected to the gate terminal G.

  An NPN transistor is used as the switching element 4A for switching, and a PNP transistor is used as the switching element 4B for switching.

  Thereby, in this embodiment, it becomes possible to control the movement of the two switching elements for switching 4A, 4B with a common electric signal, and the components and control can be simplified.

DESCRIPTION OF SYMBOLS 1, 1A, 1B ... Main circuit switching element 1B Main circuit switching element 2, 3 ... Capacitor 4, 4A-4D ... Switching element 10 ... Signal generator 20 ... Controller 50, 60 ... Timing adjustment circuit 100 ... Upper arm circuit 200 ... Lower arm circuit

According to the present invention, since the capacity when the main circuit switching element is driven can be adjusted, there is an effect that the generation of noise can be suppressed by reducing the surge.

The capacitor 3 is a capacitor for adjusting the capacitance between the gate and the source of the main circuit switching element 1. The capacitor 3 is electrically connected between the gate terminal G and the source terminal S. The capacity of the capacitor 2 is larger than the capacity of the capacitor 3 .

In the present embodiment, the main circuit switching element 1 is turned on with the switching element 4 for switching turned off. Fast since the voltage between the source becomes high, the switching speed of the turn-on - by this, the main circuit the gate of the switching device 1 - the smaller the capacitance between the source, when to turn on the main circuit switching element 1, the gate The loss of the switching element can be reduced.

Between time _{t 3} of the time _{t 4,} the controller 20 may turn on the switching switching elements 4A from OFF.

As described above, in the present embodiment, in the upper arm circuit 100, the switching element 4C is electrically connected to the control electrode of the main circuit switching element 1B, and the switching element 4C is connected in series to the capacitor 2. Connected. In the lower arm circuit 200, the switching element 4A is electrically connected to the control electrode of the main circuit switching element 1A , and the switching element 4A is connected in series to the capacitor 2. As a result, when the main circuit switching element 1A or the main circuit switching element 1B is driven, the gate capacity of the main circuit switching elements 1A and 1B can be adjusted by switching control of the switching elements 4A and 4C for switching, thereby reducing surges. it can. And by reducing the surge, ringing of current amplitude and voltage amplitude in the current path of the main circuit can be suppressed. As a result, the generation of noise can be suppressed.

Claims (20)

A main circuit switching element having a control electrode, a high potential side electrode, and a low potential side electrode;
A high-potential side capacitor electrically connected between the control electrode and the high-potential side electrode;
A low potential side capacitor electrically connected between the control electrode and the low potential side electrode;
A capacitance adjusting switching element that is electrically connected to the control electrode and adjusts the capacitance;
The capacitance adjustment switching element is a switching circuit device connected in series to at least one of the high potential side capacitor and the low potential side capacitor. A controller for controlling on / off of the capacitance adjusting switching element;
The controller sets the conduction resistance of the capacitance adjustment switching element to a resistance value between a resistance value when the capacitance adjustment switching element is in an off state and a resistance value when the capacitance adjustment switching element is in an off state. The switching circuit device according to 1. A controller for controlling on / off of the capacitance adjusting switching element;
The capacitance adjusting switching element is connected in series with the high potential side capacitor between the control electrode and the high potential side electrode,
The controller is
The switching circuit device according to claim 1, wherein the main circuit switching element is turned off in a state where the capacitance adjusting switching element is turned on. A controller for controlling on / off of the capacitance adjusting switching element;
The capacitance adjusting switching element is connected in series with the high potential side capacitor between the control electrode and the high potential side electrode,
The controller is
The switching circuit device according to any one of claims 1 to 3, wherein the main circuit switching element is turned on in a state where the capacitance adjusting switching element is turned on. 5. The switching circuit device according to claim 3, wherein a capacity of the high potential side capacitor is larger than a capacity of the low potential side capacitor. A controller for controlling on / off of the capacitance adjusting switching element;
The capacitance adjustment switching element is connected in series with the low potential side capacitor between the control electrode and the low potential side electrode,
The controller is
The switching circuit device according to any one of claims 1 to 3, wherein the main circuit switching element is turned off in a state where the capacity adjustment switching element is turned off. A controller for controlling on / off of the capacitance adjusting switching element;
The capacitance adjustment switching element is connected in series with the low potential side capacitor between the control electrode and the low potential side electrode,
The controller is
The switching circuit device according to any one of claims 1 to 3, wherein the main circuit switching element is turned on in a state where the capacitance adjusting switching element is turned off. The switching circuit device according to claim 6 or 7, wherein the capacitance of the low potential side capacitor is larger than the capacitance of the high potential side capacitor. The capacity adjustment switching element includes a first capacity adjustment switching element and a second capacity adjustment switching element,
The first capacitance adjustment switching element is connected in series with the high potential side capacitor between the control electrode and the high potential side electrode,
3. The switching circuit device according to claim 1, wherein the second capacitance adjustment switching element is connected in series with the low potential side capacitor between the control electrode and the low potential side electrode. A controller for controlling on / off of the capacitance adjusting switching element;
The controller is
10. The switching circuit device according to claim 9, wherein the main circuit switching element is turned off in a state where the first capacity adjustment switching element is turned on and the second capacity adjustment switching element is turned off. A controller for controlling on / off of the capacitance adjusting switching element;
The controller is
11. The switching circuit device according to claim 9, wherein the main circuit switching element is turned on in a state where the first capacity adjustment switching element is turned on and the second capacity adjustment switching element is turned off. A controller for controlling on / off of the capacitance adjustment switching element and on / off of the main circuit switching element;
The switching circuit device according to claim 1, wherein the controller controls a switching operation of the capacitance adjustment switching element and a switching operation of the main circuit switching element by the same control signal. The switching circuit device according to any one of claims 1 to 12, wherein the main circuit switching element is a wide band gap semiconductor element. An upper arm circuit having the main circuit switching element, the high potential side capacitor, and the low potential side capacitor;
A lower arm circuit having the main circuit switching element, the high potential side capacitor, and the low potential side capacitor and connected in series to the upper arm circuit;
The switching circuit device according to claim 1, further comprising a controller that controls on / off of the capacitance adjusting switching element. The capacitance adjusting switching element is connected in series with the high potential side capacitor between the control electrode and the high potential side electrode in each of the upper arm circuit and the lower arm circuit. ,
The controller is
When turning off the main circuit switching element included in any one of the upper arm circuit and the lower arm circuit,
15. The switching circuit device according to claim 14, wherein the capacitance adjusting switching element included in the other arm circuit of the upper arm circuit and the lower arm circuit is set in a transitional state until switching from an off state to an on state. The capacitance adjusting switching element is connected in series with the high potential side capacitor between the control electrode and the high potential side electrode in each of the upper arm circuit and the lower arm circuit. ,
The controller is
When turning off the main circuit switching element included in any one of the upper arm circuit and the lower arm circuit,
16. The switching circuit device according to claim 14, wherein the capacitance adjusting switching element included in the one arm circuit is maintained in an ON state. The capacitance adjusting switching element is connected in series with the high potential side capacitor between the control electrode and the high potential side electrode in each of the upper arm circuit and the lower arm circuit. ,
The controller is
When turning on the main circuit switching element included in either one of the upper arm circuit and the lower arm circuit,
The capacitance adjustment switching element included in the one arm circuit is maintained in an on state, and the capacitance adjustment switching element included in the other arm circuit of the upper arm circuit and the lower arm circuit is maintained in an off state. The switching circuit device according to any one of claims 14 to 16. The capacitance adjusting switching element is connected in series with the low potential side capacitor between the control electrode and the low potential side electrode in each of the upper arm circuit and the lower arm circuit. ,
The controller is
When turning off the main circuit switching element included in any one of the upper arm circuit and the lower arm circuit,
The switching circuit device according to claim 14, wherein the capacitance adjustment switching element included in the other arm circuit of the upper arm circuit and the lower arm circuit is set in a transient state until switching from an on state to an off state. The capacitance adjusting switching element is connected in series with the low potential side capacitor between the control electrode and the low potential side electrode in each of the upper arm circuit and the lower arm circuit. ,
The controller is
When turning off the main circuit switching element included in any one of the upper arm circuit and the lower arm circuit,
19. The switching circuit device according to claim 14, wherein the capacitance adjusting switching element included in the one arm circuit is maintained in an off state. The capacitance adjusting switching element is connected in series with the low potential side capacitor between the control electrode and the low potential side electrode in each of the upper arm circuit and the lower arm circuit. ,
The controller is
When turning on the main circuit switching element included in either one of the upper arm circuit and the lower arm circuit,
The capacitance adjustment switching element included in the one arm circuit is maintained in an off state, and the capacitance adjustment switching element included in the other arm circuit of the upper arm circuit and the lower arm circuit is turned on. The switching circuit device according to claim 14 or 19, wherein the switching circuit device is maintained at

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