WO2009139503A1 - Dispositif de conversion de courant électrique - Google Patents

Dispositif de conversion de courant électrique Download PDF

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Publication number
WO2009139503A1
WO2009139503A1 PCT/JP2009/059299 JP2009059299W WO2009139503A1 WO 2009139503 A1 WO2009139503 A1 WO 2009139503A1 JP 2009059299 W JP2009059299 W JP 2009059299W WO 2009139503 A1 WO2009139503 A1 WO 2009139503A1
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WO
WIPO (PCT)
Prior art keywords
semiconductor switch
conducting semiconductor
reverse conducting
capacitor
inductive load
Prior art date
Application number
PCT/JP2009/059299
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English (en)
Japanese (ja)
Inventor
嶋田隆一
磯部高範
Original Assignee
国立大学法人東京工業大学
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Priority claimed from PCT/JP2008/059399 external-priority patent/WO2009139079A1/fr
Application filed by 国立大学法人東京工業大学 filed Critical 国立大学法人東京工業大学
Publication of WO2009139503A1 publication Critical patent/WO2009139503A1/fr

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Classifications

    • HELECTRICITY
    • H02GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
    • H02MAPPARATUS FOR CONVERSION BETWEEN AC AND AC, BETWEEN AC AND DC, OR BETWEEN DC AND DC, AND FOR USE WITH MAINS OR SIMILAR POWER SUPPLY SYSTEMS; CONVERSION OF DC OR AC INPUT POWER INTO SURGE OUTPUT POWER; CONTROL OR REGULATION THEREOF
    • H02M7/00Conversion of ac power input into dc power output; Conversion of dc power input into ac power output
    • H02M7/42Conversion of dc power input into ac power output without possibility of reversal
    • H02M7/44Conversion of dc power input into ac power output without possibility of reversal by static converters
    • H02M7/48Conversion of dc power input into ac power output without possibility of reversal by static converters using discharge tubes with control electrode or semiconductor devices with control electrode

Definitions

  • the present invention relates to a power conversion device that converts DC power to AC power, and to a power conversion device that uses a magnetic energy regenerative switch to change the frequency of the output AC power and reduce the conduction loss of semiconductor elements used for switching. Is related to the position. Background art
  • MERS magnetic energy regenerative switch
  • Patent Document 1 a circuit technology called magnetic energy regenerative switch
  • MERS does not have reverse blocking capability, that is, uses a reverse conduction type switching circuit / "semiconductor element.
  • a reverse conduction type switching circuit / semiconductor element for example, a self-extinguishing element and a diode are used.
  • a circuit consisting of a positive element side connected to the negative electrode side of a diode and a negative electrode side of a self-extinguishing element connected to the positive electrode side of a diode, or a semiconductor such as a power MOSFET with a built-in parasitic diode during manufacturing (Hereinafter, these reverse conduction type switching circuit Z semiconductor elements are simply referred to as “reverse conduction type semiconductor switches”).
  • MERS consists of a negative-electrode side of the self-extinguishing element constituting the first reverse-conducting semiconductor switch (hereinafter simply referred to as “the negative-electrode side of the reverse-conducting semiconductor switch”) and a second reverse-conducting semiconductor switch.
  • the first reverse-conducting semiconductor switch leg and the third alternating-current terminal are connected to the positive-electrode side of the self-extinguishing element (hereinafter simply referred to as the “positive-electrode side of the reverse-conducting semiconductor switch”).
  • the second reverse-conducting semiconductor switch leg is connected to the first reverse-conducting semiconductor switch leg with the second AC terminal at the point where the negative-electrode side of the reverse-conducting semiconductor switch and the positive-electrode side of the fourth reverse-conducting semiconductor switch are connected.
  • Full blister configured as a terminal A circuit, and a capacitor connected between the positive terminal and the negative terminal of the full bridge circuit.
  • the first reverse-conducting semiconductor switch and the fourth reverse-conducting semiconductor switch are the first pair
  • the second reverse-conducting semiconductor switch and the third reverse-conducting semiconductor switch are the second pair
  • the first The self-extinguishing element constituting the two reverse conducting semiconductor switches in the pair is in a conducting state (hereinafter simply referred to as “reverse conducting semiconductor”).
  • switch-on state When the switch is in the “on state”, the self-extinguishing element constituting the two reverse conducting semiconductor switches of the second pair is blocked (hereinafter simply referred to as “switch-on state”).
  • the reverse conduction semiconductor switch When the first pair is off, the reverse conduction semiconductor switch is turned on and off so that the second pair is on.
  • MERS allows the capacitor to absorb the “snubber energy” stored in the entire bridge circuit and the controlled circuit when the circuit current is cut off. It functions as a bidirectional current switch circuit that can be regenerated in the circuit. The direction of the current flowing in the control target circuit can be switched between forward and reverse depending on the purpose and range of the control.
  • the capacitance of the capacitor is the capacitance that resonates with the inductance of the inductive load, and the capacitance is selected according to the purpose and range of control.
  • the capacitance of the capacitor so that the resonance frequency determined by the capacitance of the capacitor and the inductance of the inductive load is equal to or higher than the switching frequency of the reverse-conducting semiconductor switch, the reverse-conducting semiconductor
  • the self-extinguishing element constituting the reverse conducting semiconductor switch has substantially zero voltage and zero current.
  • the self-extinguishing element constituting the reverse conducting semiconductor switch can perform a soft switching operation with substantially zero voltage.
  • the ON / OFF state of the reverse conducting semiconductor switch is controlled so that the pair 2 is turned on.
  • the time ratio (duty ratio) between the on time and off time of the reverse conducting semiconductor switch is 0.5, that is, the on time and the off time are equal.
  • the reverse conduction type semiconductor switch ON / OFF state expressed on the time axis is the control signal
  • the phase of the control signal is synchronized with the voltage phase of the AC power supply
  • the phase of the control signal is the voltage phase of the AC power supply. Control is performed so as to proceed from (a state in which the phase of the control signal changes first in time).
  • the AC power supplied to the inductive load can be controlled by changing the phase difference between the voltage phase of the control signal and the AC power supply in accordance with the purpose / range of control.
  • the power converter circuit (hereinafter referred to as the “MERS resonant inverter” circuit) that takes advantage of the features of the AC control device using MERS, such as resonance of inductive load and capacitor, and soft switching operation of reverse conducting semiconductor elements.
  • MERS power converter circuit
  • the M E R S resonant inverter circuit uses a direct current source as a power source and can provide alternating vibration current to an inductive load. That is, it can be used as a direct current / AC power conversion circuit.
  • the MERS resonant inverter circuit includes a first reverse conducting semiconductor switch leg having a first AC terminal at a point connecting the negative side of the first reverse conducting semiconductor switch and the positive side of the second reverse conducting semiconductor switch.
  • a second reverse conducting semiconductor switch leg having a second AC terminal at a point where the negative side of the third reverse conducting semiconductor switch and the positive side of the fourth reverse conducting semiconductor switch are connected,
  • the positive side of the first reverse conduction type semiconductor switch and the positive electrode of the third reverse conduction type semiconductor switch are connected to each other as a positive terminal, and the second reverse conduction type semiconductor switch and the fourth reverse conduction type semiconductor are connected.
  • the capacitance of the capacitor is the capacitance that resonates with the inductance of the inductive load, and the resonance frequency determined by the capacitance of the capacitor and the inductance of the inductive load is the target AC oscillation current.
  • the capacity is selected so as to be equal to or higher than the frequency.
  • the first reverse-conducting semiconductor switch and the fourth reverse-conducting semiconductor switch are the first pair
  • the second reverse-conducting semiconductor switch and the third reverse-conducting semiconductor switch are the second pair, and the first pair When the first pair is on, the second pair is turned off. When the first pair is off, the second pair is turned on. Controls the on / off state of.
  • the switching frequency of the reverse conducting semiconductor switch is equal to or less than the frequency of the target AC oscillating current
  • the self-extinguishing element constituting the reverse conducting semiconductor switch is When the switch is turned off, the self-extinguishing element constituting the reverse conduction type semiconductor switch can perform a soft switching operation with a substantially zero voltage.
  • the DC current source is connected between the positive and negative terminals of the full-bridge circuit (both ends of the capacitor), and the inductive load is between the first AC terminal and the second AC terminal of the full-bridge circuit. It takes the form of connecting to.
  • the ON / OFF time ratio (duty ratio) of the reverse conducting semiconductor switch is 0.5, that is, the ON time and OFF time are equal.
  • the DC current source can be realized by rectifying a commercial AC power supply and then connecting it via a smoothing DC reactor, or by connecting a DC voltage source via a DC reactor.
  • a current in phase with the voltage phase flows.
  • a circuit close to a power factor of 1 is connected from the commercial AC power supply.
  • the capacitor absorbs the magnetic energy stored in the inductive load due to resonance between the capacitor and the inductance component of the inductive load (the capacitor is charged) and regenerates to the inductive load (capacitor Is discharged) and reused.
  • the current capacity of the feeder line from the DC current source to the ME RS resonant inverter circuit can be small. There is also.
  • Patent Document 1 Japanese Patent No. 3 6 3 4 9 8 2
  • Patent Document 2 Japanese Patent No. 3 7 3 5 6 7 3
  • Patent Document 3 International Application Publication Number WO 2 0 0 8 Z 0 4 4 5 1 2 Pan Fretz ⁇ Summary of the Invention
  • the ME RS resonant inverter circuit is highly controllable and can operate stably.
  • the capacitor is charged and discharged by resonating with the inductance component of the inductive load.
  • current flows through at least two reverse conducting semiconductor switches.
  • load current the current equivalent to the apparent power flowing through the inductive load. Amount).
  • Induct the ME RS resonant inverter circuit When applied to a device that requires a large amount of power because the power factor of an inductive load such as a power supply for heating is low, the conduction loss in the reverse conduction type semiconductor switch increases, and the low loss characteristic of soft switching operation May reduce the benefits of low heat generation.
  • the present invention has been made to alleviate the above-described problems, and an object of the present invention is to provide a M E R S resonant inverter circuit having a simple circuit configuration by reducing the number of reverse conducting semiconductor switches to be used. Means for solving the problem
  • the present invention relates to a power conversion device that converts DC power into AC power.
  • An equivalent semiconductor element is a reverse-conducting semiconductor switch (hereinafter simply referred to as “reverse conducting semiconductor switch”), and a first capacitor short-circuit circuit in which a first reverse-conducting semiconductor switch and a first capacitor are connected in parallel.
  • a second capacitor short circuit in which the second reverse conducting semiconductor switch and the second capacitor are connected in parallel, are connected to the negative side of the self-extinguishing element constituting the first reverse conducting semiconductor switch ( (Hereinafter referred to simply as “the negative side of the reverse conducting semiconductor switch”) and the negative terminal of the second reverse conducting semiconductor switch, the two-capacitor horizontal half-type MERS circuit having the negative terminal and the first DC reactor Toru
  • the DC reactor circuit with the positive DC terminal connected to the second DC reactor is connected to the positive side of the self-extinguishing element constituting the first reverse conducting semiconductor switch (hereinafter simply referred to as “reverse conducting type”).
  • a two-capacitor horizontal half-bridge circuit configured as a second AC terminal at the point where the other end of the flow reactor is connected
  • a DC voltage source connected between the positive terminal and the negative terminal of the two-capacitor horizontal half-type bridge circuit
  • An inductive load connected between the first AC terminal and the second AC terminal of the two-capacitor horizontal half bridge circuit
  • a control means and
  • the control means When the self-extinguishing element constituting the first reverse conducting semiconductor switch is in the conducting state (hereinafter simply referred to as “the reverse conducting semiconductor switch is turned on”), the control means When the self-extinguishing element constituting the conductive semiconductor switch is in the blocking state (hereinafter simply referred to as “the reverse conductive semiconductor switch is turned off”), and the first reverse conductive semiconductor switch is in the off state, The second reverse conducting semiconductor switch is turned on so that the first reverse conducting semiconductor switch and the second reverse conducting semiconductor switch are not turned on at the same time. Control the Z-off state,
  • the control means is that the switching frequency (fsw) of on-off of the reverse conducting semiconductor switch is determined by the inductance (L) of the inductive load and the capacitance (C 1) of the first capacitor.
  • a first capacitor short circuit in which the first reverse conduction type semiconductor switch and the first capacitor are connected in parallel, and a second capacitor short circuit in which the second reverse conduction type semiconductor switch and the second capacitor are connected in parallel A two-capacitor horizontal half-type ME RS circuit with the negative terminal connected to the negative side of the first reverse conducting semiconductor switch and the negative side of the second reverse conducting semiconductor switch, and the first inductive
  • the inductive load circuit with the positive terminal as the point where the load and the second inductive load are connected is the point where the positive side of the first reverse conducting semiconductor switch and the other end of the first inductive load are connected.
  • a DC current source connected between the positive terminal and the negative terminal of the two-capacitor horizontal half-type bridge circuit
  • a control means and
  • the control means sets the second reverse conducting semiconductor switch to off, and when the first reverse conducting semiconductor switch is off.
  • the second reverse conducting semiconductor switch is turned on so that the first reverse conducting semiconductor switch and the second reverse conducting semiconductor switch are not turned on at the same time. Control the on / off state of the
  • control means is such that the switching frequency (fsw) of the reverse conduction type semiconductor switch on Z-off is the inductance (L 1) of the first inductive load and the inductance (L 2) of the second inductive load.
  • the first resonant frequency (fresl) determined by the combined inductance (L 1 + L 2) and the capacitance of the first capacitor (C 1), and the combined inductance (L 1 + L 2) Control the ON / OFF state of the reverse conducting semiconductor switch so that it is below the second resonance frequency (fres 2) determined by the capacitance (C 2) of the second capacitor.
  • the self-extinguishing element constituting the reverse conducting semiconductor switch When the reverse conducting semiconductor switch is turned on, the self-extinguishing element constituting the reverse conducting semiconductor switch is at substantially zero voltage and zero current, and when turned off, the reverse conducting semiconductor is The self-extinguishing element constituting the switch is achieved by a power conversion device characterized by performing a soft switching operation of substantially zero voltage.
  • control means When a field-effect transistor or a semiconductor element having an equivalent structure is used as the self-extinguishing element constituting the reverse conducting semiconductor switch, the control means This can also be achieved by a power converter characterized by controlling the arc extinguishing element to be in a conductive state.
  • the first reverse-conducting semiconductor switch and the second reverse-conducting semiconductor switch are connected to the negative terminal of the point where the negative side of the first reverse-conducting semiconductor switch is connected to the negative side of the second reverse-conducting semiconductor switch.
  • the first AC terminal is the point where one end of the capacitor is connected to the positive side of the first reverse-conducting semiconductor switch, and the other end of the capacitor is the second reverse polarity.
  • the point where the point connected to the positive side of the conductive semiconductor switch is used as the second AC terminal, and the point where the 1-capacitor horizontal half-type MERS circuit is connected to the first DC reactor and the second DC reactor. Connect the other end of the first DC reactor to the first AC terminal, and connect the other end of the second DC reactor to the second AC terminal.
  • a control means and
  • control means sets the second reverse conducting semiconductor switch in the off state, and when the first reverse conducting semiconductor switch is in the off state.
  • the second reverse conducting semiconductor switch is turned on so that the first reverse conducting semiconductor switch and the second reverse conducting semiconductor switch are not turned off at the same time. Control the on / off state of the
  • control means is that the switching frequency (fsw) of the reverse conducting semiconductor switch is determined by the resonance frequency (fres) determined by the inductance (L) of the inductive load and the capacitance (C) of the capacitor.
  • the switching frequency (fsw) of the reverse conducting semiconductor switch is determined by the resonance frequency (fres) determined by the inductance (L) of the inductive load and the capacitance (C) of the capacitor.
  • the first reverse-conducting semiconductor switch and the second reverse-conducting semiconductor switch are connected to the negative terminal of the point where the negative side of the first reverse-conducting semiconductor switch is connected to the negative side of the second reverse-conducting semiconductor switch.
  • the first AC terminal is the point where one end of the capacitor is connected to the positive side of the first reverse-conducting semiconductor switch, and the other end of the capacitor is the second reverse polarity.
  • a 1-capacitor horizontal half-type MERS circuit configured as the second AC terminal at the point connected to the positive side of the conductive semiconductor switch, and the first induction Connect the inductive load circuit with the positive terminal at the point where the conductive load and the second inductive load are connected, connect the positive side of the first reverse conducting semiconductor switch and the other end of the first inductive load, And a 1-capacitor side-by-side bridge circuit configured by connecting the positive electrode side of the second reverse conducting semiconductor switch and the other end of the second inductive load;
  • a control means and
  • control means sets the second reverse conducting semiconductor switch in the off state, and when the first reverse conducting semiconductor switch is in the off state.
  • the second reverse conducting semiconductor switch is turned on so that the first reverse conducting semiconductor switch and the second reverse conducting semiconductor switch are not turned off at the same time. Control the on / off state of the
  • control means is such that the switching frequency (: fsw) of the ON-Z OFF of the reverse conducting semiconductor switch is such that the inductance (L 1) of the first inductive load and the inductance (L 2) of the second inductive load
  • the switching frequency (: fsw) of the ON-Z OFF of the reverse conducting semiconductor switch is such that the inductance (L 1) of the first inductive load and the inductance (L 2) of the second inductive load
  • the above object of the present invention is to This is achieved by a power converter characterized by using polar capacitors for the first capacitor and the second capacitor of the power converter described above.
  • connection polarity of the first reverse conducting semiconductor switch and the second reverse conducting semiconductor switch are reversed
  • first capacitor and the second capacitor are polar capacitors
  • this can also be achieved by a power converter characterized by reversing the connection polarity of each.
  • connection polarity of the first reverse conducting semiconductor switch and the second reverse conducting semiconductor switch are reversed
  • first capacitor and the second capacitor are polar capacitors
  • this can also be achieved by a power converter characterized by reversing the connection polarity of each.
  • a DC reactor connected to a DC voltage source
  • a power conversion device characterized by replacing with an AC reactor connected between an AC power source and an AC terminal of a rectifier circuit.
  • a Siris evening AC power adjustment device one end of which is connected to an AC power source
  • a high-impedance transformer whose primary side is connected to the other end of the AC power regulator
  • the power conversion device is characterized in that the control means sends a control signal to the thyris AC power adjustment device and adjusts the amount of AC oscillating current supplied to the inductive load.
  • the above object of the present invention is to In place of the DC voltage source of the above power converter,
  • an induction coil for inductively heating an object to be heated is used.
  • induction heating power supply device characterized in that the frequency of the AC oscillating current supplied to the induction coil is variable according to the object and purpose of the object to be heated.
  • an induction coil for induction heating the object to be heated is provided.
  • an AC oscillating current having a variable frequency can be supplied to an inductive load only by a magnetic energy regenerative switch.
  • the self-extinguishing element constituting the reverse conducting semiconductor switch when turning on the reverse conducting semiconductor switch, is turned off at substantially zero voltage and zero current.
  • the self-extinguishing element that constitutes the reverse conducting semiconductor switch is a soft switching operation with substantially zero voltage, and in a circuit with one capacitor, the reverse conducting semiconductor switch is turned on z off.
  • the self-extinguishing element that constitutes the reverse conducting semiconductor switch is assumed to have a soft switching operation with a substantially zero voltage. It is possible to reduce switching loss in a reverse conducting semiconductor switch.
  • the current flowing through the reverse conducting semiconductor switch is reduced, and conduction loss can be reduced.
  • FIG. 1 is a circuit block diagram showing the configuration of the first embodiment according to the present invention.
  • FIG. 2 is a circuit block diagram showing the configuration of the second embodiment according to the present invention.
  • FIG. 3 is a circuit block diagram showing the configuration of the third embodiment according to the present invention.
  • FIG. 4 is a circuit block diagram showing the configuration of the fourth embodiment according to the present invention.
  • FIG. 5 is a circuit block diagram showing a configuration in which the positive electrode sides of two reverse conducting semiconductor switches are shared in the first embodiment according to the present invention.
  • FIG. 6 is a circuit block diagram showing a configuration in which the positive electrode sides of two reverse conducting semiconductor switches are shared in the second embodiment according to the present invention.
  • FIG. 7 is a circuit block diagram showing a configuration in which the positive electrode sides of two reverse conducting semiconductor switches are shared in the third embodiment according to the present invention.
  • FIG. 8 is a circuit block diagram showing a configuration in which the positive electrode sides of two reverse conducting semiconductor switches are shared in the fourth embodiment according to the present invention.
  • FIG. 9 is a circuit block diagram showing a case where the first inductive load and the second inductive load are replaced with inductive loads having taps in the second embodiment according to the present invention.
  • FIG. 10 is a circuit block diagram showing a case where the DC current source is replaced with a DC voltage source and a DC reactor connected to the DC voltage source in the second embodiment according to the present invention.
  • FIG. 11 is a circuit block diagram showing a case where the direct current source is replaced with a direct current voltage source and a direct current reactor connected to the direct current voltage source in the fourth embodiment according to the present invention.
  • FIG. 12 (A) is a circuit block diagram showing another configuration of the direct current source in each of the power conversion devices of the second and fourth embodiments according to the present invention.
  • FIG. 12 (B) is a circuit block diagram showing still another configuration of the direct current source in each of the power conversion devices of the second and fourth embodiments according to the present invention.
  • FIG. 12 (C) is a circuit block diagram showing a DC voltage source.
  • FIG. 12 (D) is a circuit block diagram showing another configuration of the DC voltage source.
  • FIG. 13 is a diagram showing a computer simulation result (switching frequency is 500 Hz) of the configuration of the first embodiment and the second embodiment according to the present invention.
  • FIGS. 14 (A) to (F) are circuit block diagrams for explaining the operation principle of the first embodiment according to the present invention.
  • FIGS. 15 (A) to (F) are circuit block diagrams for explaining the operation principle of the second embodiment according to the present invention.
  • FIG. 16 is a diagram showing a computer simulation result (switching frequency is 500 Hz) of the configuration of the third embodiment and the fourth embodiment according to the present invention.
  • FIGS. 17 (A) to (F) are circuit block diagrams for explaining the operation principle of the third embodiment according to the present invention.
  • FIGS. 18 (A) to (F) are circuit block diagrams for explaining the operation principle of the fourth embodiment according to the present invention.
  • FIG. 19 is a diagram showing computer simulation results (switching frequency is 200 Hz) of the configuration of the first embodiment and the second embodiment according to the present invention.
  • FIG. 20 is a view showing a computer simulation result (a switching frequency is 200 Hz) of the configuration of the third embodiment and the fourth embodiment according to the present invention.
  • FIG. 21 is a circuit block diagram showing the M E R S resonant inverter circuit.
  • Figure 22 shows the results of computer simulation of the M E R S resonant inverter circuit.
  • Second inductive load 8 Inductive load with tap
  • I 1 oad Inductive load / inductive load circuit Current flowing through an inductive load with Z tap (load current) V c Voltage across capacitor
  • a self-extinguishing element indicates an electronic component capable of controlling the forward conduction state and blocking state of the element by applying a control signal to the gate of the element.
  • FIG. 1 is a circuit block diagram showing a configuration of a power converter according to a first embodiment of the present invention.
  • Fig. 1 shows the connection between the self-extinguishing element and the diode, the positive side of the self-extinguishing element and the negative side of the diode, and the negative side of the self-extinguishing element and the positive side of the diode.
  • the connected circuit or equivalent semiconductor element is formed as a reverse conducting semiconductor switch (hereinafter simply referred to as “reverse conducting semiconductor switch”), and the first reverse conducting semiconductor switch SW 1 and the first capacitor C 1 are connected in parallel.
  • the second capacitor short circuit in which the conductor switch SW2 and the second capacitor C2 are connected in parallel, is connected to the negative side of the self-extinguishing element constituting the first reverse conducting semiconductor switch SW1 (hereinafter simply “ 2 capacitor lateral half type ME RS circuit with the negative terminal DCN as the point connecting the negative side of the second reverse conducting semiconductor switch SW 2 and the first DC
  • a DC reactor circuit with the positive terminal DCP at the point where reactor L dc 1 and second DC reactor L dc 2 are connected is connected to the self-extinguishing element constituting the first reverse conducting semiconductor switch SW 1.
  • the point at which the positive electrode side (hereinafter simply referred to as “the positive electrode side of the reverse conducting semiconductor switch”) and the other end of the first DC reactor L dc 1 are connected is the first AC terminal AC 1
  • Two-capacitor horizontal half-type bridge circuit 1 1 and two-capacitor horizontal half-type bridge circuit 1 1 are configured as the second AC terminal AC 2 at the point where the other end of the coil L dc 2 is connected
  • the control means 4 When the self-extinguishing element constituting the first reverse conducting semiconductor switch SW 1 is in the conducting state (hereinafter simply referred to as “the reverse conducting semiconductor switch is turned on”), the control means 4 The self-extinguishing type semiconductor switch constituting the reverse conducting semiconductor switch SW 2 is blocked (hereinafter simply referred to as “the reverse conducting semiconductor switch is turned off”), and the first reverse conducting semiconductor switch SW 1 is in the off state. In this case, the second reverse conducting semiconductor switch SW2 is turned on, and the first reverse conducting semiconductor switch SW1 and the second reverse conducting semiconductor switch SW2 are not turned on at the same time.
  • control means 4 has an on / off switching frequency (fsw) of the reverse conducting semiconductor switch that is determined by the inductance (L) of the inductive load 5 and the capacitance (C 1) of the first capacitor C 1. Determined first resonance frequency
  • the reverse conduction type semiconductor switch is controlled by controlling the ON Z-off state of the reverse conduction type semiconductor switch so that it is lower than the lower frequency.
  • the self-extinguishing element that constitutes the reverse conducting semiconductor switch is turned on at substantially zero voltage and zero current, and the self-extinguishing element that constitutes the reverse conducting semiconductor switch when turned off. Is characterized by soft switching operation at approximately zero voltage.
  • Figure 13 is the circuit block diagram shown in Figure 1 and shows the computer simulation results when the following circuit constants are used.
  • Capacitance of the first capacitor (C 1) 5 0 0 micro F
  • Capacitance of the second capacitor (C 2) 500 micro F
  • FIG. 13 shows the current flowing through the inductive load (load current) I load, the voltage VI oad applied to the inductive load, the voltage V applied to the first reverse conducting semiconductor switch SW 1 sw 1 (equal to the voltage V c 1 across the first capacitor C 1), the voltage V sw 2 applied to the second reverse conducting semiconductor switch SW 2 (the voltage V c 2 across the second capacitor C 2 Current I sw 1 passing through the first reverse conducting semiconductor switch SW 1, current I sw 2 passing through the second reverse conducting semiconductor switch SW 2, and the first reverse conducting semiconductor switch SW 1
  • the waveforms of the gate control signal G 1 and the gate control signal G 2 of the second reverse conducting semiconductor switch SW 2 are shown.
  • the current flowing through the inductive load (load current) I 1 oad expresses the direction flowing from the first AC terminal AC 1 to the second AC terminal AC 2 as positive.
  • the DC voltage source 1 continuously supplies a DC current to the inductive load 5 through the first DC reactor L dc 1 and the second DC reactor L dc 2 (hereinafter simply referred to as “supply current”). ").
  • supply current a DC current to the inductive load 5 through the first DC reactor L dc 1 and the second DC reactor L dc 2 (hereinafter simply referred to as “supply current”).
  • supply current supplied to the inductive load 5
  • FIGS. 14 (A) to 14 (F) are for explaining the principle of operation, and the control means 4 is not shown.
  • Inductive load 5 shows only an inductance component L and a resistance component R.
  • the arrow indicates the current and its direction, and the thickness of the arrow indicates the magnitude of the current. However, the arrow thickness is relative.
  • the power conversion device can apply the alternating vibration current to the inductive load 5 by repeating the above-described operation in a steady state.
  • the capacitance (C 1) of the first capacitor C 1 and the capacitance (C 2) of the second capacitor C 2 are in resonance with the inductance (L) of the inductive load 5, respectively.
  • An extremely small capacity is sufficient to absorb and release 5 magnetic energy.
  • the first capacitor C 1 and the second capacitor C 2 have a capacity suitable for absorbing and discharging only half the period of the AC oscillation current supplied to the inductive load 5.
  • the capacity and purpose are completely different from the large-capacity smoothing capacitor used to stably supply the DC voltage used in the inverter circuit.
  • the current duty per capacitor is halved compared to the MERS resonant inverter circuit.
  • the first capacitor C 1 and the second capacitor Since the polarity of the capacitor C 2 is always constant when the capacitor is charged and discharged, a polar capacitor can be used.
  • the on / off switching frequency (fsw) of the reverse conducting semiconductor switch is determined by the inductance (L) of the inductive load 5 and the capacitance (C 1) of the first capacitor C 1.
  • Resonance frequency (fresl, 1/2 (L) (CI)) second resonance frequency determined by inductance (L) of inductive load 5 and capacitance of second capacitor C2 (C2)
  • the reverse conducting semiconductor switch is turned on by controlling the on / off state of the reverse conducting semiconductor switch so that it is below the lower frequency of (fres 2, ⁇ / 2 (L) (C 2)).
  • the self-extinguishing element constituting the reverse conducting semiconductor element is substantially zero voltage and substantially zero current, and the self-extinguishing type element constituting the reverse conducting semiconductor element when turned off.
  • the element can be in a soft switching operation at approximately zero voltage. As long as this condition is satisfied, the frequency of the alternating oscillating current supplied to the inductive load 5 can be made variable by controlling the switching frequency of the reverse conducting semiconductor switch.
  • the AC oscillating current supplied to the inductive load 5 consumes energy in the resistance component R of the inductive load 5 and the current is attenuated. Injection of the consumed energy is performed by the DC voltage source 1 that has been made “DC current source” via the first DC reactor L dc 1 and the second DC reactor L dc 2. That is, since the power supplied from the DC voltage source 1 only needs to be consumed by the resistance component R of the inductive load 5, the power converter of the first embodiment according to the present invention from the DC voltage source 1 The current capacity of the power supply line to is small.
  • the power conversion device has as few as two reverse conducting semiconductor switches.
  • the first reverse conducting semiconductor switch SW Since the negative electrode side of 1 and the negative electrode side of the second reverse conducting semiconductor switch SW 2 are connected, there is no need to insulate the circuits that drive the gates of the respective reverse conducting semiconductor switches. You can also share power.
  • the DC voltage source 1 has a feature that half of the voltage of the DC current source 2 of the M E R S resonant inverter circuit is sufficient to obtain the voltage of the AC oscillating current supplied to the inductive load 5.
  • control means is configured such that when the diode becomes conductive in the forward direction. If the self-extinguishing element is controlled to be in a conductive state, a synchronous rectification method can be used to reduce conduction loss.
  • FIG. 2 is a circuit block diagram showing the configuration of the power conversion device according to the second embodiment of the present invention.
  • FIG. 2 shows a first capacitor short-circuit circuit in which a first reverse conducting semiconductor switch SW 1 and a first capacitor C 1 are connected in parallel, a second reverse conducting semiconductor switch SW 2, and Connect the second capacitor short circuit with the second capacitor C 2 connected in parallel to the negative side of the first reverse conducting semiconductor switch SW 1 and the negative side of the second reverse conducting semiconductor switch SW 2.
  • the inductive load circuit with the positive terminal DCP as the point where the two-capacitor horizontal half-type MERS circuit with the negative terminal DCN and the first inductive load 6 and the second inductive load 7 are connected
  • the point where the positive polarity side of the reverse conduction type semiconductor switch SW 1 is connected to the other end of the first inductive load 6 is the first AC terminal AC 1 and the second reverse conduction type semiconductor switch SW 2 Positive side and second invitation
  • the point where the other end of the conductive load 7 is connected is the second AC terminal AC 2
  • the positive terminal of the 2-capacitor horizontal half-bridge circuit 1 2 and 2-capacitor horizontal-half bridge circuit 1 2 DCP A direct current source 2 connected between the negative terminal DCN and a control means 4, and
  • the control means 4 sets the second reverse conducting semiconductor switch SW 2 in the off state, and the first reverse conducting semiconductor switch SW 1 is in the off state.
  • the second reverse conducting semiconductor switch SW2 is turned on, and the first reverse conducting semiconductor switch SW1 and the second reverse conducting semiconductor switch SW2 are turned on simultaneously.
  • the ON / OFF state of the reverse conducting semiconductor switch is controlled so that the
  • control means 4 is configured such that the switching frequency (fsw) of the on-off of the reverse conducting semiconductor switch is such that the inductance (L 1) of the first inductive load 6 and the inductance of the second inductive load 7
  • the reverse conducting semiconductor switch When the reverse conducting semiconductor switch is turned on by controlling the on / off state of the reverse conducting semiconductor switch so that it is lower than the lower frequency, the reverse conducting semiconductor switch
  • the self-extinguishing element that constitutes the power supply is substantially zero voltage and zero current, and when turned off, the self-extinguishing element constituting the reverse conducting semiconductor switch is soft switching that is substantially zero voltage. It is characterized by operation.
  • the operation of the power converter of the second embodiment according to the present invention is the same as that of the power converter of the first embodiment according to the present invention, except that the amount of current differs from the path through which the supply current flows.
  • FIG. 10 is a circuit block diagram in which the DC current source 2 in FIG. 2 is replaced with a DC voltage source 1 and a DC reactor.
  • Fig. 10 the following circuit constants are used, which agrees with the computer simulation results shown in Fig. 13.
  • the DC voltage source 1 continuously supplies a direct current to the first inductive load 6 and the second inductive load 7 through the DC reactor L dc (hereinafter simply referred to as “supply current”). ) Note that the load voltage is measured at both ends of the inductive load circuit.
  • Capacitance of the second capacitor (C 2) 5 0 0 micro F
  • FIG. 15 ( ⁇ ) to FIG. 15 (F) are for explaining the principle of operation, and the control means 4 is not shown.
  • the first inductive load 6 and the second Conductive load 7 shows only the inductance and resistance components.
  • DC current source 2 is composed of DC voltage source 1 and DC reactor L dc, and is the same as FIG.
  • the arrow indicates the current and its direction, and the thickness of the arrow indicates the magnitude of the current. However, the thickness of the arrows is relative.
  • control means 4 turns off the first reverse conducting semiconductor switch SW 1 and simultaneously turns on the reverse conducting semiconductor switch SW 2,
  • the first capacitor C 1 Section (d) in Fig. 3 and state shown in Fig. 15 (D).
  • the first capacitor C 1 is charged by the supply current. Furthermore, the current flowing by the magnetic energy of the first inductive load 6 and the second inductive load 7 is interrupted by the first reverse conducting semiconductor switch SW 2, and as a result, the first capacitor C 1 is turned off. Charge.
  • the power conversion device according to the second embodiment of the present invention can obtain substantially the same AC oscillating current as that of the power conversion device according to the first embodiment of the present invention, based on the operation principle described above.
  • the capacitance (C 1) of the first capacitor C 1 and the capacitance (C 2) of the second capacitor C 2 are respectively the inductance (L 1) of the first inductive load 6 and Synthesis of inductance (L 2) of second inductive load 7 Resonance with inductance (L 1 + L 2) absorbs and releases the magnetic energy of first inductive load 6 and second inductive load 7 An extremely small capacity is sufficient. In other words, a capacity that only absorbs and releases the magnetic energy of the half cycle of the AC oscillating current supplied to the first inductive load 6 and the second inductive load 7 is sufficient.
  • the first capacitor C 1 and the second capacitor C 2 are a large-capacity smoothing capacitor for stably supplying the DC voltage used in the conventional voltage-type PWM chamber circuit, and its capacitance ⁇ The purpose is completely different. Since the first capacitor C 1 and the second capacitor C 2 are alternately charged and discharged, the current duty per capacitor is halved compared to the ME RS resonant inverter circuit. Since the first capacitor C 1 and the second capacitor C 2 always have the same polarity when the capacitor is charged / discharged, polar capacitors can be used. On-off switching frequency of reverse conducting semiconductor switch
  • the self-extinguishing type that constitutes the reverse conducting semiconductor switch
  • the self-extinguishing element constituting the reverse conducting semiconductor switch is a soft switch that is at substantially zero voltage. It can be a bridging operation
  • the AC oscillation current supplied to the first inductive load 6 and the second inductive load 7 is the resistance component R 1 of the first inductive load 6 and the resistance component R of the second inductive load 7. Energy is consumed by the combined resistance component R 1 + R 2 of 2, and the current is attenuated. The consumed energy is injected by the direct current source 2. That is, since the power supplied from the DC current source 2 only needs to be consumed by the combined resistance component of the first inductive load 6 and the second inductive load 7, the current from the DC current source 2 is Another feature is that the current capacity of the power supply line to the power conversion device according to the second embodiment of the invention can be small.
  • the power conversion device of the second embodiment according to the present invention has as few as two reverse conducting semiconductor switches.
  • the first reverse conducting semiconductor switch SW Since the negative electrode side of 1 and the negative electrode side of the second reverse conducting semiconductor switch SW 2 are connected, it is not necessary to insulate the circuits that drive the gates of the respective reverse conducting semiconductor switches from each other. You can also share power.
  • the DC current source 2 is used to obtain the voltage of the AC oscillating current supplied to the first inductive load 6 and the second inductive load 7, and There is also a feature that may be half of the voltage.
  • control means is configured so that the diode becomes conductive in the forward direction. If the self-extinguishing element is controlled to be in a conductive state, a synchronous rectification method can be used to reduce conduction loss.
  • FIG. 3 is a circuit block diagram showing a configuration of a power converter according to a third embodiment of the present invention.
  • FIG. 3 shows that the first reverse conducting semiconductor switch SW 1 and the second reverse conducting semiconductor switch SW 2 are connected to the negative side of the first reverse conducting semiconductor switch SW 1 and the second reverse conducting semiconductor switch SW 1.
  • a reverse-conducting semiconductor switch circuit with the negative terminal DCN as the point where the negative electrode side of the conductive semiconductor switch SW 2 is connected, and a capacitor (1) and one end of the capacitor C are connected to the first reverse-type semiconductor switch SW 1
  • the point connected to the positive side is the first AC terminal AC 1
  • the point where the other end of the capacitor C is connected to the positive side of the second reverse conducting semiconductor switch SW 1 is the second AC terminal AC 2.
  • a DC reactor circuit with a positive terminal DCN at the point where the 1-capacitor horizontal half-type MERS circuit, the first DC reactor L dcl and the second DC reactor L dc 2 are connected is connected to the first DC Connect the other end of the reactor L dc 1 to the first AC terminal AC 1 1 capacitor horizontal half bridge circuit 2 1 and 1 capacitor horizontal half type, which are configured by connecting the other end of the second DC reactor L dc 2 to the second AC terminal AC 2 DC voltage source 1 connected between the positive terminal DCP and the negative terminal DCN of the bridge circuit 2 1 and 1 1 side AC terminal AC 1 and 2nd AC terminal AC 2
  • An inductive load 5 connected between the control means 4 and
  • the control means 4 turns off the second reverse conducting semiconductor switch SW2 and turns off the first reverse conducting semiconductor switch SW1.
  • the second reverse conducting semiconductor switch SW2 is turned on, and the first reverse conducting semiconductor switch SW1 and the second reverse conducting semiconductor switch SW2 are not simultaneously turned off. Control the ON / OFF state of the reverse conducting semiconductor switch
  • control means 4 has a resonance frequency (f r e s, ⁇ / 2) determined by the inductance (L) of the inductive load 5 and the capacitance (C) of the capacitor C.
  • Figure 16 is the circuit block diagram shown in Figure 30 and shows the results of computer simulation when the following circuit constants are used.
  • Switching frequency of reverse conduction type semiconductor switch (f sw): 5 0 0 Hz.
  • Fig. 16 shows the current flowing through the inductive load (load current) I load, the voltage applied to the inductive load V 1 oad (equal to the voltage V c across the capacitor C), the first inverse Voltage V swl applied to conductive semiconductor switch SW 1, voltage V sw 2 applied to second reverse conductive semiconductor switch SW 2, current I swl passing through first reverse conductive semiconductor switch SW 1, The current I sw2 passing through the second reverse conducting semiconductor switch SW2, the gate control signal G1 of the first reverse conducting semiconductor switch SW1, and the gate control signal G2 of the second reverse conducting semiconductor switch SW2 The waveform is shown.
  • the current flowing through the inductive load (load current) I l o a d is expressed as positive in the direction flowing from the first AC terminal A C 1 to the second AC terminal A C 2.
  • the DC voltage source 1 continuously supplies a DC current to the inductive load 5 via the first DC reactor L dcl and the second DC reactor L dc 2 (hereinafter simply referred to as “supply current”). ) From (a) of Fig. 16
  • FIGS. 17 (A) to 17 (F) are for explaining the principle of operation, and the control means 4 is not shown.
  • Inductive load 5 has an inductance component L and a resistance component. Only R is shown.
  • the arrow indicates the current and its direction, and the thickness of the arrow indicates the magnitude of the current. However, the arrow thickness is relative.
  • the power conversion device can apply the alternating vibration current to the inductive load 5 by repeating the above-described operation in a steady state.
  • the capacitance (C) of the capacitor C may be a very small capacitance that only absorbs and releases the magnetic energy of the inductive load 5 by resonance with the inductance (L) of the inductive load 5. In other words, a capacity that is sufficient for absorbing and releasing the half-cycle magnetic energy of the AC oscillation current supplied to the inductive load 5 is sufficient.
  • Capacitor C is completely different from the large-capacity smoothing capacitor for stably supplying the DC voltage used in conventional voltage-type PWM inverter circuits.
  • the switching frequency (fsw) of the reverse conducting semiconductor switch is less than or equal to the resonance frequency (ires) determined by the inductance (L) of the inductive load 5 and the capacitance (C) of the capacitor C.
  • the current flowing through the conductive semiconductor switch is significantly reduced, and the conduction loss of the reverse conductive semiconductor switch is greatly reduced.
  • the reverse conduction type semiconductor switch has a current corresponding to the active power consumed by the resistance component R of the inductive load 5 and is supplied from the DC voltage source 1 to the first DC reactor L dc 1 and the second DC. Only the current supplied to the inductive load 5 through the reactor L dc 2 flows.
  • the AC oscillating current supplied to the inductive load 5 consumes energy in the resistance component R of the inductive load 5 and the current is attenuated.
  • the consumed energy is injected into the first DC reactor L dc 1 and the second DC reactor. This is performed by the DC voltage source 1 which is “direct current source” via L dc 2. That is, since the electric power supplied from the DC voltage source 1 only needs to be consumed by the resistance component R of the inductive load 5, the power converter of the third embodiment according to the present invention from the DC voltage source 1 There is also a feature that the current capacity of the power supply line to can be reduced.
  • the power conversion device of the third embodiment according to the present invention has as few as two reverse conducting semiconductor switches. Also, in order to connect the negative side of the first reverse conducting semiconductor switch SW1 and the negative side of the second reverse conducting semiconductor switch SW2, the circuits that drive the gates of the respective reverse conducting semiconductor switches are insulated from each other. You can share the power supply of the circuit that drives the gate.
  • the DC voltage source 1 has a feature that it can be half the voltage of the DC current source 2 of the M E R S resonant inverter circuit in order to obtain the voltage of the AC oscillating current supplied to the inductive load 5.
  • FIG. 4 is a circuit block diagram showing the configuration of the power conversion device according to the fourth embodiment of the present invention.
  • FIG. 4 shows that the first reverse conducting semiconductor switch SW 1 and the second reverse conducting semiconductor switch SW 2 are connected to the negative side of the first reverse conducting semiconductor switch SW 1 and the second reverse conducting semiconductor switch SW 1.
  • Conductive semiconductor switch SW 2 Reverse-conducting semiconductor switch circuit with the negative terminal DCN connected to the negative side and capacitor C, one end of capacitor C on the positive side of the first reverse-conducting semiconductor switch SW 1 The point connected to the first AC terminal AC 1 and the other end of the capacitor C connected to the positive side of the second reverse conducting semiconductor switch SW 2 are configured as the second AC terminal AC 2.
  • the inductive load circuit with the positive terminal DCP at the point where the RS circuit and the first inductive load 6 and the second inductive load 7 are connected is connected to the positive side of the first reverse conducting semiconductor switch SW 1.
  • 1 capacitor that is configured by connecting the other end of the first inductive load 6 and connecting the positive side of the second reverse conducting semiconductor switch SW 2 and the other end of the second inductive load 7 A horizontal half-type bridge circuit 2 2, and a DC current source 2 connected between a positive terminal DCP and a negative terminal D CN of a 1-capacitor horizontal half-type bridge circuit 2 2, a control means 4, and a control means 4.
  • the first reverse conducting semiconductor switch SW 1 When the first reverse conducting semiconductor switch SW 1 is in the on state, the second reverse conducting semiconductor switch SW 2 is in the off state, and the first reverse conducting semiconductor switch SW 1 is in the off state. In this case, the second reverse conduction type semiconductor switch SW2 is turned on and the first reverse conduction type semiconductor switch SW2 is turned on. Controls the state of the conductor switch SW 1 and the second reverse conducting semiconductor Suitsuchi SW 2 is turned off the reverse conducting semiconductor Suitsuchi so as not to state at the same time on Z off,
  • control means 4 has an on / off switching frequency (fsw) of the reverse conducting semiconductor switch so that the inductance (L 1) of the first inductive load 6 and the inductance of the second inductive load 7 (L 2
  • fsw on / off switching frequency
  • FIG. 11 is a circuit block diagram in which the DC current source 2 in FIG. 4 is replaced with a DC voltage source 1 and a DC reactor L dc.
  • Fig. 11 when the following circuit constants are used, the computer simulation results shown in Fig. 16 agree.
  • the DC voltage source 1 continuously supplies a direct current to the first inductive load 6 and the second inductive load 7 via the DC reactor L dc (hereinafter simply referred to as “supply current”). ) Note that the load voltage is measured at both ends of the inductive load circuit.
  • Switching frequency (i sw) of reverse conducting semiconductor switch 5 0 0 Hz.
  • FIG. 18 (A) to FIG. 18 (F) are for explaining the principle of operation, and the control means 4 is not shown.
  • the first inductive load 6 and the second inductive load 7 show only the inductance component and the resistance component, respectively.
  • the DC current source 2 uses a DC voltage source 1 and a DC reactor L dc, and is the same as Fig. 11. Arrows indicate current and direction The thickness of the arrow indicates the magnitude of the current. However, the thickness of the arrows is relative.
  • the power conversion device can repeat the above-described operation in a steady state, and can provide an AC oscillating current to the first inductive load 6 and the second inductive load 7.
  • the power converter of the fourth embodiment according to the present invention is based on the above operating principle. Almost the same AC oscillating current as that of the power conversion device according to the third embodiment of the present invention can be obtained.
  • the capacitance (C) of the capacitor C is the combined inductance of the inductance (L 1) of the first inductive load 6 and the inductance (L 2) of the second inductive load 7.
  • An extremely small capacity is sufficient to absorb and release the magnetic energy of the first inductive load 6 and the second inductive load 7 by resonance with (L 1 + L 2).
  • the capacity may be sufficient to absorb and release half the magnetic energy of the AC oscillating current supplied to the first inductive load 6 and the second inductive load 7.
  • Capacitor C is completely different in capacity and purpose from the large-capacity smoothing capacitor that stably supplies the DC voltage used in the conventional voltage-type PWM inverter circuit.
  • (fsw) is the resonance frequency determined by the inductance (L 1) of the first inductive load 6, the combined inductance (L 1 + L 2) of the second inductive load 7, and the capacitance (C) of the capacitor C (Ires, 1/2 (L 1 + L
  • the switching frequency (: f SW) of the reverse conducting semiconductor switch is set to the combined inductance of the inductance (L 1) of the first inductive load 6 and the inductance (L 2) of the second inductive load 7 ( L 1 + L 2) and the resonance frequency (ires) determined by the capacitance (C) of the capacitor C, and If it is in the vicinity, the current flowing through the reverse conducting semiconductor switch will be greatly reduced, and the conducting loss of the reverse conducting semiconductor switch will be greatly reduced.
  • the load current does not pass through the reverse conducting semiconductor switch.
  • the reverse-conducting semiconductor switch is effectively consumed by the combined resistance component R 1 + R 2 of the resistance component R 1 of the first inductive load 6 and the resistance component R 2 of the second inductive load 7. Only the current supplied from the DC current source 2 to the first inductive load 6 and the second inductive load 7 flows at a current equivalent to electric power.
  • the voltage across capacitor C is approximately 0 [V]
  • the load current flows through the reverse conducting semiconductor switch.
  • the frequency change range of the AC oscillating current supplied to the first inductive load 6 and the second inductive load 7 is selected according to the purpose and range of control.
  • the AC oscillation current supplied to the first inductive load 6 and the second inductive load 7 is the resistance component R 1 of the first inductive load 6 and the resistance component R of the second inductive load ⁇ .
  • Energy is consumed by the combined resistance component R 1 + R 2 of 2, and the current is attenuated.
  • the consumed energy is injected by the direct current source 2. That is, since the power supplied from the DC current source 2 only needs to be consumed by the combined resistance component of the first inductive load 6 and the second inductive load 7, the current from the DC current source 2 is There is also a feature that the current capacity of the feeder line to the power converter of the fourth embodiment according to the invention can be small.
  • the power converter of the fourth embodiment according to the present invention has as few as two reverse conducting semiconductor switches. Also, since the negative electrode side of the first reverse conducting semiconductor switch SW 1 and the negative electrode side of the second reverse conducting semiconductor switch SW 2 are connected, the circuits that drive the gates of the respective reverse conducting semiconductor switches SW 2 It is possible to share the power supply of the circuit that drives the gate.
  • the DC current source 2 obtains the voltage of the AC oscillating current to be supplied to the first inductive load 6 and the second inductive load 7 by half the voltage of the DC current source 2 of the ME RS resonant inverter circuit. There are also good features.
  • FIG. 19 is a diagram showing computer simulation results of the configurations of the power conversion device of the first embodiment and the power conversion device of the second embodiment according to the present invention.
  • FIG. 20 is a diagram showing a computer simulation result of the configuration of the power conversion device of the third embodiment and the power conversion device of the fourth embodiment according to the present invention.
  • FIG. 19 shows the case where the switching frequency (fsw) of the reverse conducting semiconductor switch is set to 200 Hz in the circuit constants of FIG. 13 and the contents shown in FIG. 1 Same as Figure 3.
  • FIG. 20 shows the case where the switching frequency (fsw) of the reverse conducting semiconductor switch is 2 0 00 Hz in the circuit constants of FIG. 16, and the contents shown in FIG. Same as Figure 6.
  • the power converter of the first embodiment according to the present invention to the power converter of the fourth embodiment according to the present invention supplies alternating frequency alternating current. It is possible to confirm that soft switching operation is performed with approximately zero current when turning on the reverse conducting semiconductor switch and approximately zero voltage when turning off.
  • FIG. 5 and FIG. 6 are circuit block diagrams showing the configurations of the power conversion devices of the fifth and sixth embodiments according to the present invention. More specifically, FIGS. 5 and 6 show that in each of the power converters of the first and second embodiments according to the present invention, the connection polarity of the DC voltage source 1 or the DC current source 2 is reversed, In this configuration, the connection polarity of the first reverse conducting semiconductor switch SW 1 and the second reverse conducting semiconductor switch SW 2 is reversed.
  • the power conversion device of the fifth embodiment according to the present invention includes the power conversion device of the first embodiment according to the present invention and the power conversion device of the sixth embodiment according to the present invention. It has the same functions, actions, and effects as the second power converter.
  • the same configuration can be used when a reverse-conducting semiconductor switch uses a P-channel power MOS FET, or an anti-parallel connection circuit of a transistor and a diode.
  • FIGS. 7 and 8 are circuit block diagrams showing the configurations of the power conversion devices according to the seventh and eighth embodiments of the present invention.
  • FIGS. 7 and 8 show that in each of the power converters of the third and fourth embodiments according to the present invention, the connection polarity of the DC voltage source 1 or the DC current source 2 is reversed, In this configuration, the connection polarity of the first reverse conducting semiconductor switch SW 1 and the second reverse conducting semiconductor switch SW 2 is reversed.
  • the point where the positive electrode side of the first reverse conducting semiconductor switch SW1 and the positive electrode side of the second reverse conducting semiconductor switch SW2 are connected is the positive terminal DC ⁇ ⁇ ⁇ , and the positive electrode side is common.
  • the power conversion device according to the seventh embodiment of the present invention is related to the power conversion device according to the third embodiment of the present invention and the present invention.
  • the power converter of the eighth embodiment has the same functions, operations, and effects as the fourth power converter according to the present invention. .
  • the same configuration can be used when using a reverse channel semiconductor switch with P-channel power M O S F E T, ⁇ ⁇ ⁇ transistor and diode parallel connection circuit.
  • FIG. 9 is a circuit block diagram showing the configuration of the power converter of the ninth embodiment according to the present invention.
  • FIG. 9 shows that the first inductive load 6 and the second inductive load 7 of the power conversion device according to the second embodiment of the present invention are replaced with a tapped inductive load 8.
  • the tap is the positive terminal DC ⁇ and the DC current source 2 is connected. It has the same function, operation, and effect as the second power converter according to the present invention.
  • an inductive load without a tap (not shown)
  • an inductive load without a tap to be supplied with AC vibration current using a tapped coupling transformer (not shown) is used. You may be allowed to match with
  • FIG. 10 and FIG. 11 are circuit block diagrams showing the configurations of the power converters according to the 10th and 11th embodiments of the present invention.
  • FIG. 10 and FIG. 11 show that the DC current source 2 is connected to the DC voltage in each of the power converters of the second and fourth embodiments according to the present invention.
  • the source 1 and the DC reactor L dc connected to the DC voltage source 1 are replaced.
  • FIG. 12 (A) is a circuit block diagram showing another configuration of the DC current source 2 in each of the power conversion devices of the second and fourth embodiments according to the present invention.
  • FIG. 12 (A) shows a direct current source 2, an alternating current power source 3, a rectifier circuit RB, and the like in each of the power converters of the second and fourth embodiments according to the present invention. It is replaced with the AC reactor L ac connected between the AC power supply 3 and the AC terminal of the rectifier circuit RB.
  • the AC power source 3 is converted into a current source by the AC reactor L a c and is converted to DC by the rectifier circuit R B.
  • FIG. 12 (B) is a circuit block diagram showing still another configuration of the DC current source 2 in each of the power conversion devices of the second and fourth embodiments according to the present invention.
  • FIG. 12 (B) shows a DC current source 2, an AC power source 3, and an AC power source device at one end in each of the power converters of the second and fourth embodiments according to the present invention.
  • AC power conditioner T h connected to 3 thyristor AC power conditioner on the primary side ⁇
  • High impedance transformer HIT r connected to the other end of 1 ⁇
  • AC terminal is high impedance transformer HIT It is replaced with a rectifier circuit RB connected to the secondary side of r.
  • the control means 4 can send a control signal to the thyris AC power adjusting device Th to adjust the amount of AC oscillating current supplied to the inductive load.
  • FIG. 12 (D) is a circuit block diagram showing another configuration of the DC voltage source 1 according to the present invention.
  • DC voltage source 1 (Fig. 12 (C)) is replaced with rectifier circuit RB and AC power supply 3 connected between AC terminals of rectifier circuit RB (Fig. 12 (D) ).
  • the DC reactor L dc is connected to the negative terminal of the rectifier circuit RB.
  • the power conversion device according to the present invention described above has only two reverse conducting semiconductor switches. It is also characterized by low switching loss due to soft switching operation. This is advantageous when using a high frequency of several ⁇ ⁇ ⁇ ⁇ ⁇ or higher.
  • an air cooling fan is required due to the radiation of the switching element. Pertaining to If an induction heating power supply using a power converter is used, a fanless design is expected to be possible.

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Abstract

Cette invention se rapporte à un dispositif de conversion de courant électrique qui permet d’alimenter une charge inductive en courant d’oscillation alternatif. Ce dispositif possède une configuration de circuit simple qui n’exige qu’un petit nombre de commutateurs à semi-conducteurs à conduction inverse. De plus, lesdits commutateurs effectuent une opération de commutation souple qui n’entraîne qu’une perte mineure de conduction. Il est en outre possible de modifier la fréquence du courant d’oscillation alternatif qui est fourni à la charge inductive.
PCT/JP2009/059299 2008-05-15 2009-05-14 Dispositif de conversion de courant électrique WO2009139503A1 (fr)

Applications Claiming Priority (4)

Application Number Priority Date Filing Date Title
JPPCT/JP2008/059399 2008-05-15
PCT/JP2008/059399 WO2009139079A1 (fr) 2008-05-15 2008-05-15 Source d’alimentation électrique pour chauffage par induction
US16031509P 2009-03-15 2009-03-15
US61/160,315 2009-03-15

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WO2009139503A1 true WO2009139503A1 (fr) 2009-11-19

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Cited By (2)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN102131323A (zh) * 2010-01-12 2011-07-20 马顺龙 数字集成半桥感应加热控制方案
JP2016039709A (ja) * 2014-08-08 2016-03-22 株式会社島津製作所 高圧電源装置

Citations (3)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
JPH06327265A (ja) * 1993-05-10 1994-11-25 Matsushita Electric Works Ltd インバータ装置
JP2001197756A (ja) * 2000-01-14 2001-07-19 Matsushita Electric Works Ltd 電源装置
JP2008092745A (ja) * 2006-10-05 2008-04-17 Tokyo Institute Of Technology 誘導加熱用電源装置

Patent Citations (3)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
JPH06327265A (ja) * 1993-05-10 1994-11-25 Matsushita Electric Works Ltd インバータ装置
JP2001197756A (ja) * 2000-01-14 2001-07-19 Matsushita Electric Works Ltd 電源装置
JP2008092745A (ja) * 2006-10-05 2008-04-17 Tokyo Institute Of Technology 誘導加熱用電源装置

Cited By (2)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN102131323A (zh) * 2010-01-12 2011-07-20 马顺龙 数字集成半桥感应加热控制方案
JP2016039709A (ja) * 2014-08-08 2016-03-22 株式会社島津製作所 高圧電源装置

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