JP2011041457A - Dc-ac power converter and power conversion circuit thereof - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a DC-AC power converter for converting a DC voltage into an AC voltage, and its power conversion circuit, which are constituted so as to secure a current route for discharging an electromagnetic energy stored in an inductor in a step-up/step-down operation state, and to prevent the generation of a surge voltage in the inductor to improve safety and power conversion efficiency. <P>SOLUTION: The DC-AC power converter performs power conversion of DC voltage of a DC power supply and a single-phase AC voltage of a single-phase AC power supply convertibly. The converter has a switching circuit portion 32, having three DC-side connection ends (U, V, W) in the DC power supply side 15, and having two AC-side connection ends in the single-phase AC power supply side; the inductor 1 arranged between the DC power supply 15 and the switching circuit portion 32; a capacitor 14 arranged between the switch circuit portion 32 and the single-phase AC power supply 17 or a load 16; and a controller 21 for driving the switch circuit portion 32 so as to supply a power of the DC power supply to the single-phase AC power supply or the load, by stepping-up or stepping-down the DC voltage, or supply a power of the single-phase AC power supply to the DC power supply, by stepping-up or stepping-down the single-phase AC voltage. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

The present invention relates to a DC-AC power converter and a power converter circuit thereof.

A conventional power conversion device connects a power supply device having a certain inductance, a matrix converter that converts electric power generated by the power supply device into a desired voltage and frequency and outputs the voltage to an electric load, and connects the electric load to the matrix converter. A capacitor and a switch connected in series between the pair of output lines are provided, and the switch is turned on when the matrix converter performs a step-up operation and turned off when the matrix converter performs a step-down operation. (For example, refer to Patent Document 1).

JP-A-2005-333783 (page 20, FIG. 1, FIG. 6)

However, in the power conversion device of Patent Document 1, the switch side of the reactor L1 connected in series with one end of the battery is open in the step-up operation state, and the path of the current flowing through the reactor L1 cannot be secured. Otherwise, surge voltage may be generated and the switch may be destroyed.
The present invention has a configuration that secures a current path for discharging electromagnetic energy accumulated in an inductor (reactor) in the state of step-up and step-down operation, and prevents the generation of a surge voltage of the inductor, thereby ensuring the safety and power of the power converter. An object of the present invention is to provide a power conversion device and a power conversion circuit that improve conversion efficiency and reversibly convert DC voltage to AC voltage and AC voltage to DC voltage.

In order to solve the above problems, according to one aspect of the present invention, the invention of claim 1 is a DC-AC that reversibly converts power between a DC voltage of a DC power supply and a single-phase AC voltage of a single-phase AC power supply. A power converter,
A switch circuit unit having three DC side connection ends on the DC power source side and two AC side connection ends on the single-phase AC power source side;
An inductor disposed between the DC power supply and the switch circuit unit;
A capacitor disposed between the switch circuit unit and the single-phase AC power supply or load;
The DC voltage is boosted or stepped down to supply the DC power to the single-phase AC power supply or the load, or the single-phase AC voltage is boosted or stepped down to supply the DC power to the DC power supply. A DC-AC power converter is provided that includes a controller that drives the switch circuit unit so as to be supplied.

According to a second aspect of the present invention, in the first aspect, the switch circuit unit connects the other end of the inductor to one end of the first bidirectional switch and one end of the fourth bidirectional switch. One end of the bidirectional switch and one end of the fifth bidirectional switch are connected to one end of the inductor, and one end of the third bidirectional switch and one end of the sixth bidirectional switch are connected to the negative electrode side of the DC power supply. Connecting the other end of the first bidirectional switch, the other end of the second bidirectional switch, and the other end of the third bidirectional switch to one end on the single-phase AC side, The first to sixth bidirectional switches in which the other end of the bidirectional switch, the other end of the fifth bidirectional switch, and the other end of the sixth bidirectional switch are connected to the other end of the single-phase AC side. With a switch,
One end of the inductor is connected to the positive side of the DC power supply,
A DC-AC power converter is applied in which one end of the capacitor is connected to the other end of the first bidirectional switch, and the other end of the capacitor is connected to the other end of the fourth bidirectional switch.

According to a third aspect of the present invention, in the second aspect of the present invention, the DC voltage detector for detecting the voltage of the DC power source, the AC voltage detector for detecting the voltage on the single-phase AC side, and the current of the DC power source are detected. At least one detector of current detectors to
Based on the detection value of the detector, the first to sixth bidirectional switches are turned on and off, and the power of the DC power supply is supplied to the single-phase AC power supply or the power of the single-phase AC power supply is supplied to the DC power supply. A DC-AC power converter provided with a controller for supplying to the power supply is applied.

The invention of claim 4 is the invention of claim 2 or 3, further comprising a DC voltage detector for detecting the voltage of the DC power supply, and an AC voltage detector for detecting the voltage on the single-phase AC side, The first to sixth bidirectional switches are switched so as to enter the step-down operation mode or the step-up operation mode by the interaction with the inductor so as to supply electric power from the DC power source to the single-phase AC power source, and PWM control A DC-AC power conversion device including a controller that supplies power of the DC power source to the single-phase AC power source is applied.

The invention of claim 5 is the invention of claim 4,
When the relationship between the single-phase AC side voltage VRS and the DC power supply voltage VDC is | VRS | <VDC, the step-down operation mode is selected,
When the voltage VRS is VRS> 0, the ON mode for turning on the first bidirectional switch and the sixth bidirectional switch, and the OFF mode for turning on the first bidirectional switch and the fifth bidirectional switch. Alternately control the mode switching state,
When the voltage VRS is VRS <0, an ON mode for turning on the fourth bidirectional switch and the third bidirectional switch, and turning on the fourth bidirectional switch and the second bidirectional switch. By alternately controlling the switching state of the OFF mode,
A DC-AC power converter characterized in that the PWM control is performed by changing the time ratio between the ON mode and the OFF mode is applied.

The invention of claim 6 is the invention of claim 4,
When the relationship between the voltages VRS and VDC on the single-phase AC side is | VRS |> VDC, the step-up operation mode is selected,
When the voltage VRS is VRS> 0, an ON mode for turning on the first bidirectional switch and the third bidirectional switch, and an OFF mode for turning on the first bidirectional switch and the sixth bidirectional switch Alternately control the switching state of
When the voltage VRS is VRS <0, an ON mode for turning on the fourth bidirectional switch and the sixth bidirectional switch, and turning on the fourth bidirectional switch and the third bidirectional switch By alternately controlling the switching state of the OFF mode,
A DC-AC power converter characterized in that the PWM control is performed by changing the time ratio between the ON mode and the OFF mode is applied.

The invention of claim 7 is the invention of claim 4,
A DC voltage detector for detecting the voltage of the DC power supply; an AC voltage detector for detecting the voltage on the single-phase AC side; and a current detector for detecting a current of the DC power supply; The first to sixth bidirectional switches are switched so as to enter the step-down operation mode or the step-up operation mode by interaction with the inductor so as to supply power to the phase AC power source, and the DC power source is controlled by PWM control. A DC-AC power converter characterized by comprising a controller that controls charging of the DC power supply from the single-phase AC power supply or the single-phase AC power supply is applied.

The invention of claim 8 is the invention of claim 7,
In the charging control, when the relationship between the voltages VRS and VDC is | VRS |> VDC, the step-down operation mode is selected.
When the voltage VRS is VRS> 0, an ON mode for turning on the first bidirectional switch and the sixth bidirectional switch, and an OFF mode for turning on the first bidirectional switch and the third bidirectional switch Alternately control the mode switching state,
When the voltage VRS is VRS <0, an ON mode for turning on the fourth bidirectional switch and the third bidirectional switch, and turning on the fourth bidirectional switch and the sixth bidirectional switch. By alternately controlling the switching state of the OFF mode,
A controller that performs the PWM control by changing a time ratio between the ON mode and the OFF mode based on a deviation amount between a current detection value detected by the current detector and a current command. -AC power converter is applied.

The invention of claim 9 is the invention of claim 7,
In the charge control, when the relationship between the voltages VRS and VDC is | VRS | <VDC, the boost operation mode is selected,
When the voltage VRS is VRS> 0, an ON mode that turns on the first bidirectional switch and the fifth bidirectional switch, and an OFF mode that turns on the first bidirectional switch and the sixth bidirectional switch. Alternately control the mode switching state,
When the voltage VRS is VRS <0, an ON mode for turning on the fourth bidirectional switch and the second bidirectional switch, and turning on the fourth bidirectional switch and the third bidirectional switch By alternately controlling the switching state of the OFF mode,
A controller that performs the PWM control by changing a time ratio between the ON mode and the OFF mode based on a deviation amount between a current detection value detected by the current detector and a current command. -AC power converter is applied.

The invention of claim 10 is the invention of any one of claims 4 to 8,
A unidirectional switch that allows current to flow from one end of the single-phase AC side to the positive side of the DC power source through the second bidirectional switch, and a fifth bidirectional switch from the other end of the single-phase AC side A DC-AC power converter characterized by being replaced by a one-way switch that allows current to flow in the direction of the positive electrode side of the DC power supply is applied.

The invention of claim 11 is the invention of claim 3,
A direct current power supply, and a mechanical switch that inverts and outputs the voltage polarity of the direct current power supply,
The inductor connected to one contact of the mechanical switch connected to a positive voltage before reversing the voltage polarity and a negative voltage after reversing, the first bidirectional switch and the fourth bidirectional switch Are replaced with a first one-way switch and a fourth one-way switch in the direction in which a current flows from the storage battery side to the load side,
A second one-way switch in which the second bidirectional switch, the third bidirectional switch, the fifth bidirectional switch, and the sixth bidirectional switch flow in a direction from the load side to the storage battery side. In the power converter replaced with the third unidirectional switch, the fifth unidirectional switch, and the sixth unidirectional switch,
The DC voltage detector for detecting the voltage of the DC power supply, the AC voltage detector for detecting the voltage on the single-phase AC side, and the current detector for detecting the current of the DC power supply;
When supplying power from the DC power source to the single-phase AC side, the connection of the mechanical switch is in a state before the reversal of the voltage polarity, and when charging control of the DC power source from the single-phase AC side, The connection of the mechanical switch is changed so that the voltage polarity is reversed, and the replaced one-way switch is controlled to switch to the step-down operation mode or the step-up operation mode by the interaction with the inductor, and the single phase is controlled by PWM control. A DC-AC power converter is provided, which includes a controller that outputs an AC voltage and supplies power to the single-phase AC side or controls charging of the DC power source.

The invention of claim 12 is the invention of claim 11,
In the generation of the single-phase AC voltage, when the relationship between the voltages VRS and VDC is | VRS | <VDC, the step-down operation mode is selected.
When the voltage VRS is VRS> 0, the first one-way switch and the sixth one-way switch are turned on, and the first one-way switch and the fifth one-way switch are turned on. Alternately control the mode switching state,
When the voltage VRS is VRS <0, the ON mode in which the fourth one-way switch and the third one-way switch are turned on, and the fourth one-way switch and the second one-way switch are turned on. By alternately controlling the switching state of the OFF mode,
A DC-AC power converter characterized by changing the time ratio between the ON mode and the OFF mode and generating the single-phase AC voltage by the PWM control is applied.

The invention of claim 13 is the invention of claim 11,
In the generation of the single-phase AC voltage, when the relationship between the voltages VRS and VDC is | VRS |> VDC, the step-up operation mode is selected.
When the voltage VRS is VRS> 0, the ON mode in which the first unidirectional switch and the third unidirectional switch are turned on, and the first unidirectional switch and the sixth unidirectional switch 6 are turned on. Control the switching state of OFF mode alternately,
When the voltage VRS is VRS <0, the fourth unidirectional switch and the sixth unidirectional switch 6 are turned on, the fourth unidirectional switch and the third unidirectional switch are turned on. By alternately controlling the OFF mode switching state to
A DC-AC power converter characterized by changing the time ratio between the ON mode and the OFF mode and generating the single-phase AC voltage by the PWM control is applied.

The invention of claim 14 is the invention of claim 11,
In the charging control, when the relationship between the voltages VRS and VDC is | VRS |> VDC, the step-down operation mode is selected.
When the voltage VRS is VRS> 0, an ON mode for turning on the fourth unidirectional switch and the third unidirectional switch, and an OFF mode for turning on the fourth unidirectional switch and the sixth unidirectional switch. Alternately control the mode switching state,
When the voltage VRS is VRS <0, the ON mode in which the first one-way switch and the sixth one-way switch are turned on, and the first one-way switch and the third one-way switch are turned on. By alternately controlling the switching state of the OFF mode,
DC-AC power conversion, wherein the PWM control is performed by changing a time ratio between the ON mode and the OFF mode based on a deviation amount between a current detection value detected by the current detector and a current command. The device is applied.

The invention of claim 15 is the invention of claim 11,
In the charge control, when the relationship between the voltages VRS and VDC is | VRS | <VDC, the boost operation mode is selected,
When the voltage VRS is VRS> 0, an ON mode for turning on the fourth unidirectional switch and the second unidirectional switch, and an OFF mode for turning on the fourth unidirectional switch and the third unidirectional switch. Alternately control the mode switching state,
When the voltage VRS is VRS <0, the ON mode in which the first one-way switch and the fifth one-way switch are turned on, and the first one-way switch and the sixth one-way switch are turned on. By alternately controlling the switching state of the OFF mode,
DC-AC power conversion, wherein the PWM control is performed by changing a time ratio between the ON mode and the OFF mode based on a deviation amount between a current detection value detected by the current detector and a current command. The device is applied.

The invention of claim 16 is the invention of any one of claims 1 to 15,
When the operation is stopped by detecting an abnormality, a short circuit is established between the terminals of the inductor to ensure a current path flowing through the inductor, and a protective operation is performed to open a switch that disconnects the storage battery from the power system. The DC-AC power converter characterized by this is applied.

The invention of claim 17 is a DC-AC power conversion circuit that reversibly converts power between a DC voltage of a DC power supply and a single-phase AC voltage of a single-phase AC power supply,
A switch circuit unit having first to third DC side connection ends on the DC power source side, and first and second AC side connection ends on the single-phase AC power source side;
An inductor disposed between the DC power supply and the switch circuit unit;
A DC-AC power conversion circuit including the switch circuit unit and a capacitor disposed between the single-phase AC power supply or a load is applied.

The invention of claim 18 is the switch circuit part according to claim 17, wherein
The first AC side connection end and the first to third DC side connection ends are each connected by a bidirectional switch,
A DC-AC power conversion circuit in which the second AC-side connection end and the first to third DC-side connection ends are each connected by a bidirectional switch is applied.

The invention according to claim 19 provides a bidirectional switch in which the first AC side connection end and the second DC side connection end are connected to the second AC side connection end from the first AC side connection end according to claim 17. Replace with a one-way switch that energizes in the direction of the DC side connection end of
Unidirectional switch for energizing a bidirectional switch connecting the second AC side connection end and the second DC side connection end in the direction from the second AC side connection end to the second DC side connection end A DC-AC power conversion circuit replaced with is applied.

According to a twentieth aspect of the invention, in the nineteenth aspect, a bidirectional switch connecting the first AC side connection end and the third DC side connection end is connected to the third AC side connection end from the first AC side connection end. Replace with a one-way switch that energizes in the direction of the DC side connection end of
Unidirectional switch for energizing a bidirectional switch connecting the second AC side connection end and the third DC side connection end from the second AC side connection end toward the third DC side connection end Is replaced with
Unidirectional switch for energizing a bidirectional switch connecting the first AC side connection end and the first DC side connection end from the first DC side connection end toward the first AC side connection end Is replaced with
Unidirectional switch for energizing a bidirectional switch connecting the second AC side connection end and the first DC side connection end from the first DC side connection end toward the second AC side connection end A DC-AC power conversion circuit replaced with is applied.

ADVANTAGE OF THE INVENTION According to this invention, the surge voltage generation | occurrence | production of an inductor can be prevented and the safety | security and power conversion efficiency of a power converter device can be improved.

The block diagram of the power converter device which shows 1st Embodiment of this invention. The block diagram of the power converter device which shows 2nd Embodiment of this invention. The block diagram of the power converter device which shows 3rd Embodiment of this invention. The figure which shows the electric current path | route in the case of outputting electric power to the system | strain side (single-phase alternating current power supply) by step-down operation from the storage battery in 1st Embodiment of this invention. The figure which shows the electric current path in the case of outputting electric power to the system | strain side (single-phase alternating current power supply) by the pressure | voltage rise operation from the storage battery in 1st Embodiment of this invention. The figure which shows the current pathway in the case of charging a storage battery by step-down operation from the system | strain side (single-phase alternating current power supply) in 1st Embodiment of this invention. The figure which shows the current pathway in the case of charging a storage battery by the pressure | voltage rise operation from the system | strain side (single-phase alternating current power supply) in 1st Embodiment of this invention. The figure which shows the electric current path | route in the case of outputting electric power to the system | strain side (single-phase alternating current power supply) by step-down operation from the storage battery in 2nd Embodiment of this invention. The figure which shows the electric current path | route in the case of outputting electric power to the system | strain side (single-phase alternating current power supply) by the pressure | voltage rise operation from the storage battery in 2nd Embodiment of this invention. The figure which shows the current pathway in the case of charging a storage battery by step-down operation from the system | strain side (single-phase alternating current power supply) in 2nd Embodiment of this invention. The figure which shows that a storage battery cannot be charged by pressure | voltage rise operation from the system | strain side (single-phase alternating current power supply) in 2nd Embodiment of this invention. The figure which shows the current pathway in the case of outputting electric power to the system | strain side (single-phase alternating current power supply) by step-down operation from the storage battery in 3rd Embodiment of this invention. The figure which shows the current pathway in the case of outputting electric power to the system | strain side (single-phase alternating current power supply) by the pressure | voltage rise operation from the storage battery in 3rd Embodiment of this invention. The figure which shows the current pathway in the case of charging a storage battery by step-down operation from the system | strain side (single-phase alternating current power supply) in 3rd Embodiment of this invention. The figure which shows the current pathway in the case of charging a storage battery by the pressure | voltage rise operation from the system side (single-phase alternating current power supply) in 3rd Embodiment of this invention. The figure which shows the electric current path which recirculate | refluxs the inductor current for the protection operation | movement which the controller of this invention performs at the time of abnormality detection of a power converter device. Circuit diagram of step-down converter and diagram showing its operation principle Circuit diagram of boost converter and diagram showing its operation principle The figure which shows the relationship between the storage battery voltage VDC and the single-phase alternating voltage VRS, and step-down / step-up operation region in the present invention. The figure which shows switching of step-down / step-up operation when the storage battery voltage VDC and the single-phase AC voltage VRS are expressed as a function of time in the present invention.

(Operational principle of the present invention)
In the power conversion device of this embodiment, the inductor 1 is used to perform power conversion by stepping down and boosting the power supply voltage. Each configuration of FIG. 17 showing the step-down converter and FIG. 18 showing the step-up converter can be realized by turning on and off each bidirectional switch in FIG. In the circuit of FIG. 1 which is the first embodiment, since the terminals U, V, W and the terminals R, S are connected by the bidirectional switches 24 to 29, the current of the terminal U of the inductor 1 is bidirectional. It can be freely connected to other terminals by on / off control of the switch. Therefore, a positive and negative single-phase AC voltage can be generated between the RS terminals.
Hereinafter, the step-down operation and the step-up operation principle of the present invention will be described first. FIG. 17 is a circuit diagram of the step-down converter and its operation principle. FIG. 18 is a circuit diagram of the step-up converter and its operation principle.

First, the operation of the step-down converter will be described.
In FIG. 17A, the switch SW connected in series with the DC power source Vb is turned on, and current is supplied from the DC power source Vb to the inductor L, the capacitor C, and the load Load as shown by the broken line in FIG. 17B. Shed. Here, C is a capacitor. Next, the switch SW is turned off to disconnect the power source, and current flows through the inductor L, the capacitor C, the load Load, and the diode D as shown by the broken line in FIG. The step-down converter repeatedly switches between the ON mode and the OFF mode, changes the ON / OFF time ratio, performs pulse width modulation, and controls the voltage average value VOUT applied to the load Load.
When the on-time ratio Ton of the step-down converter = ON mode time / (ON mode time + OFF mode time) ≦ 1, VOUT = VDC × Ton. Here, VDC is the voltage of the DC power supply Vb.

Next, the operation of the boost converter will be described.
In FIG. 18A, first, the switch SW is turned on, and a current is allowed to flow only through the inductor L connected in series with the DC power source Vb as shown by the broken line in FIG. 18B. Next, the switch SW is turned off, and current flows through the DC power supply Vb, the inductor L, the diode D, the capacitor C, and the load Load as shown by the broken line in FIG. 18C. The boost converter repeatedly switches between the ON mode and the OFF mode, changes the ON / OFF time ratio, performs pulse width modulation, and controls the average value of the voltage applied to the load Load.
When the on-time ratio Ton of the boost converter = ON mode time / (ON mode time + OFF mode time), VOUT = VDC / (1−Ton).
In the step-down converter of FIG. 17 and the step-up converter of FIG.

Hereinafter, embodiments of the present invention will be described with reference to the drawings. In addition, the same code | symbol is attached | subjected to the same name and duplication description is abbreviate | omitted suitably.
(First embodiment)

FIG. 1 is a configuration diagram of a power conversion device showing a first embodiment of the present invention. In the figure, the power conversion device according to the first embodiment includes an inductor 1, unidirectional switches 2 to 13 in which an IGBT and a diode are connected in series, a filter capacitor 14, a storage battery 15 as a DC power supply, a load 16, and a power system. Side single-phase AC power source 17, DC voltage detector 18 that detects the voltage of the storage battery 15, AC voltage detector 19 that detects the voltage of the single-phase AC power source 17 on the power system side, and current detection that detects the current of the storage battery 15 Device 20 and controller 21. The power conversion circuit 31 includes the inductor 1, first to sixth bidirectional switches 24 to 29, and a capacitor 14, and is a portion indicated by a dotted line. The switch circuit unit 32 includes first to sixth bidirectional switches 24 to 29, and is a portion indicated by a dotted line. Two bidirectional switches 24 to 29 are configured by connecting two one-way switches 2 to 13 in the opposite direction. However, the configuration of the bidirectional switches 24 to 29 shown here is an example, and the present invention is not limited to this.
The controller 21 controls the switching state of the following bidirectional switches (24 to 29) or one-way switches (2 to 13) based on the detection signals of the detectors described above. The controller 21 compares the command value with the detection signal of each detector to perform PI control and the like, and generates a PWM control signal based on the calculation result, and a PWM controller 23 that performs switching control. It is equipped with.

The connection relationship of the power converters in this embodiment is demonstrated. One end of the first bidirectional switch (24) and one end of the fourth bidirectional switch (27) are connected to one end of the inductor 1, and one end of the second bidirectional switch (25) and the fifth bidirectional switch are connected. One end of the switch (28) is connected to the other end of the inductor 1, the other end of the inductor 1 is connected to the positive electrode of the storage battery 15, and one end of the third bidirectional switch (26) and the sixth bidirectional switch ( 29) is connected to the negative electrode of the storage battery 15, the other end of the first bidirectional switch (24), the other end of the second bidirectional switch (25), and the third bidirectional switch (26). The other end is connected to one end of the load side 16, the other end of the fourth bidirectional switch (27), the other end of the fifth bidirectional switch (28), and the other of the sixth bidirectional switch (29). The other end of the first bidirectional switch (24) and the fourth end of the first bidirectional switch (24). A capacitor 14 is connected to the other end of the direction switch (27).

(Three usage patterns of this power converter)
This power converter has three usage patterns for reversibly converting a DC voltage and an AC voltage. When converting from direct current to alternating current, the grid connection pattern (U1) used to connect the power converter to the grid power supply, and the independent operation pattern (U2) used separately from the grid like a portable power supply. There are two usage patterns. There is a charging pattern (U3) for charging a storage battery, which is a DC power supply, when converting from a system power supply (single-phase AC) to DC.
The grid connection pattern (U1) can be used as, for example, a power conditioner such as solar power generation, wind power generation, or a fuel cell, or an uninterruptible power supply (UPS). In this case, an AC voltage detector that detects the power supply voltage of the grid is necessary as the detector for grid connection, but the DC voltage detector that detects the DC voltage of the storage battery is omitted using the rated voltage of the storage battery, etc. You can also
Further, the single operation pattern (U2) can be used as a single-phase AC power supply device in a mountainous area without a system power supply. In this case, the user disconnects the single-phase AC power supply 17 from the power conversion circuit with a switch (not shown). An AC voltage detector for detecting an AC voltage output can be substituted with an output voltage command. The DC voltage detector for detecting the DC voltage of the storage battery can be omitted by using the rated voltage of the storage battery.
Further, as the charging pattern (U3), for example, a charging operation to a storage battery that is a DC power source connected to the power conversion device can be used as a power source device for an electric vehicle or a hybrid vehicle charging station. In this case, a current detector for detecting the current of the storage battery and an AC voltage detector for detecting the power supply voltage of the system are necessary. A DC voltage detector that detects the DC voltage of the storage battery is required when determining whether or not the storage battery needs to be charged or when charging is complete.

In order to perform the step-down operation or the step-up operation in the power conversion device in the present embodiment, the controller 21 uses the magnitude relationship between the storage battery voltage VDC and the absolute value | VRS | of the single-phase AC voltage VRS and the terminal S as a reference. Then, the following control is performed based on the positive / negative polarity of the VRS when the single-phase AC voltage VRS between the terminals RS is measured.
In the following description, the positive / negative polarity of VRS is expressed as VRS> 0 when the voltage at terminal R is higher than the voltage at terminal S, and VRS <0 when the voltage is lower.

A1) When power is output from the storage battery 15 to the system side (single-phase AC power supply 17) A1-1) | VRS | <VDC (step-down operation)
Electric power is output from the storage battery 15 to the system side, and under the condition of | VRS | <VDC, the single-phase AC voltage VRS is output by the step-down operation in the current path shown in FIG. The controller 21 changes the current path in the ON mode and the OFF mode as shown in FIG. 4 depending on whether the VRS is positive or negative. In each state, pulse width modulation is performed by changing the time ratio between the ON mode and the OFF mode, and a voltage having an absolute value lower than the storage battery voltage VDC is output.
That is, when VRS> 0, the switching states of (a) and (b) of FIG. 4 are controlled alternately, and when VRS <0, the switching states of (c) and (d) of FIG. 4 are controlled alternately. And outputs a single-phase AC voltage VRS.
In FIG. 4, in order to avoid complications, the reference numerals in the drawing are omitted as long as the correspondence with FIG. 1 is not impaired (the same applies hereinafter).

A1-2) | VRS |> VDC (step-up operation)
Electric power is output from the storage battery 15 to the system side, and under the condition of | VRS |> VDC, a single-phase AC voltage VRS is output by a boost operation in the current path shown in FIG. The controller 21 changes the current path in the ON mode and the OFF mode as shown in FIG. 5 depending on whether the VRS is positive or negative. In each state, pulse width modulation is performed by changing the time ratio between the ON mode and the OFF mode, and a voltage having a higher absolute value than the storage battery voltage VDC is output.
That is, as in the case of A1-1), the single-phase AC voltage VRS is changed by alternately controlling the switching states of (a) and (b) or (c) and (d) shown in FIG. Output.

A2) When charging the storage battery 15 from the system side (single-phase AC power supply 17) A2-1) | VRS |> VDC (step-down operation)
Electric power is input from the system side to charge the storage battery 15, and under the condition of | VRS |> VDC, a step-down operation is performed in the current path shown in FIG. The controller 21 changes the current path in the ON mode and the OFF mode as shown in FIG. 6 depending on whether the VRS is positive or negative. In each state, the battery 15 is charged from the single-phase AC power supply 17 having a voltage higher in absolute value than the storage battery voltage VDC by changing the time ratio between the ON mode and the OFF mode and performing pulse width modulation.
That is, when VRS> 0, the switching states of (a) and (b) of FIG. 6 are controlled alternately, and when VRS <0, the switching states of (c) and (d) of FIG. 6 are controlled alternately. Then, the storage battery 15 is charged from the single-phase AC power source 17.

A2-2) | VRS | <VDC (step-up operation)
Electric power is input from the system side to charge the storage battery 15, and under the condition of | VRS | <VDC, a boosting operation is performed through the current path shown in FIG. The controller 21 changes the current paths in the ON mode and the OFF mode as shown in FIG. 7 depending on whether the VRS is positive or negative. In each state, the time ratio between the ON mode and the OFF mode is changed to perform pulse width modulation, and charging is performed from the single-phase AC power source 17 having a voltage lower in absolute value than the storage battery voltage VDC.
That is, as in the case of A2-1) described above, the single-phase AC power supply 17 can be controlled by alternately controlling the switching states (a) and (b) or (c) and (d) shown in FIG. The storage battery 15 is charged.

In addition, in the explanatory diagrams of FIGS. 4 to 7, the IGBT is replaced with a mechanical switch so that the on / off state of the IGBT can be easily understood.
When the controller 21 outputs power from the storage battery 15, the detected value of the single-phase AC voltage VRS is compared with the voltage command of the single-phase sine wave, the deviation amount is used as a control signal using a PI controller or the like, and the PWM pulse The AC voltage is output by adjusting the time ratio. When charging the storage battery, the current detection value of the storage battery 15 is compared with the current command, the deviation amount is used as a control signal using a PI controller or the like, and the charging current is flowed by adjusting the time ratio of the PWM pulse. .
As described above, in the first embodiment, the output of the single-phase AC voltage and the storage battery can be charged from the single-phase AC power supply by the on / off state of the bidirectional switch and the pulse width modulation control. In addition, in both the above A1) and A2), the total number of IGBTs and diodes on the current path is always four during operation, so that conduction loss can be reduced. Furthermore, since the path of the current flowing through the inductor 1 is secured, a surge voltage is not generated and safety can be improved.

(Second embodiment)
FIG. 2 is a configuration diagram of a power conversion device according to the second embodiment. In the figure, the difference from FIG. 1 of the first embodiment is that the bidirectional switches 25 and 28 are constituted by unidirectional switches 4 and 10, respectively. With this change, the configuration of the controller 21a and the PWM controller 23a, which is a component thereof, is changed. Other parts are the same as those in FIG.
The output of the power conversion device of the second embodiment assumes an uninterruptible power supply (UPS), and a single-phase AC power supply 17 is connected in parallel with the load 16. The uninterruptible power supply (UPS) charges the storage battery 15 from the single-phase AC power supply 17 and disconnects the single-phase AC power supply 17 and supplies power from the storage battery 15 to the load 16 at the time of a power failure.

In the circuit of FIG. 2 which is the second embodiment, the bidirectional switch 24, 27 connects the terminal U and the terminals R and S, and the bidirectional switch 26, 29 connects the terminal W and the terminals R and S. is doing. Further, the one-way switches 4 and 10 are connected between the terminal V and the terminals R and S in the direction in which current flows from the terminals R and S to the terminal V, respectively. The current at the terminal U of the inductor 1 can be freely connected to the terminals R and S by ON / OFF control of the bidirectional switches 24 and 27. Therefore, a positive and negative single-phase AC voltage can be generated between the RS terminals.

The controller 21a in FIG. 2 performs the following control based on the magnitude relationship between the storage battery voltage VDC and the absolute value | VRS | of the single-phase AC voltage VRS and the positive / negative polarity of the VRS described in the first embodiment. Do.
B1) When power is output from the storage battery 15 to the system side (single-phase AC power supply 17) B1-1) When | VRS | <VDC (step-down operation)
Electric power is output from the storage battery 15 to the system side, and under the condition of | VRS | <VDC, the single-phase AC voltage VRS is output by the step-down operation in the current path shown in FIG. The controller 21a changes the current paths in the ON mode and the OFF mode as shown in FIG. 8 depending on whether the VRS is positive or negative. In each state, pulse width modulation is performed by changing the time ratio between the ON mode and the OFF mode, and a voltage having an absolute value lower than the storage battery voltage VDC is output.
That is, when VRS> 0, the switching states of (a) and (b) in FIG. 8 are alternately controlled, and when VRS <0, the switching states of (c) and (d) in FIG. 8 are alternately controlled. And outputs a single-phase AC voltage VRS.

B1-2) | VRS |> VDC (step-up operation)
Electric power is output from the storage battery 15 to the system side, and under the condition of | VRS |> VDC, a single-phase AC voltage VRS is output by a boost operation in the current path shown in FIG. The controller 21a changes the current path in the ON mode and the OFF mode as shown in FIG. 9 depending on whether the VRS is positive or negative. In each state, pulse width modulation is performed by changing the time ratio between the ON mode and the OFF mode, and a voltage having a higher absolute value than the storage battery voltage VDC is output.
That is, as in the case of B1-1) described above, the single-phase AC voltage VRS is changed by alternately controlling the switching states of (a) and (b) or (c) and (d) shown in FIG. Output.

B2) When charging the storage battery 15 from the system side (single-phase AC power supply 17) B2-1) When | VRS |> VDC (step-down operation)
Electric power is inputted from the system side to charge the storage battery 15, and under the condition of | VRS |> VDC, the step-down operation is performed in the current path shown in FIG. The controller 21a changes the current paths in the ON mode and the OFF mode as shown in FIG. 10 depending on whether the VRS is positive or negative. In each state, the battery 15 is charged from the single-phase AC power supply 17 having a voltage higher in absolute value than the storage battery voltage VDC by changing the time ratio between the ON mode and the OFF mode and performing pulse width modulation.
That is, when VRS> 0, the switching states of (a) and (b) of FIG. 10 are controlled alternately, and when VRS <0, the switching states of (c) and (d) of FIG. Then, the storage battery 15 is charged from the single-phase AC power source 17.

In the explanatory diagrams of FIGS. 8 to 10, the IGBT is replaced with a mechanical switch so that the on / off state of the IGBT can be easily understood.
When the controller 21a outputs power from the storage battery 15, the detected value of the single-phase AC voltage VRS is compared with the voltage command of the single-phase sine wave, and the deviation amount is used as a control signal using a PI controller or the like. The AC voltage is output by adjusting the time ratio. When charging the storage battery, the current detection value of the storage battery 15 is compared with the current command, the deviation amount is used as a control signal using a PI controller or the like, and the charging current is flowed by adjusting the time ratio of the PWM pulse. .
As described above, in the second embodiment, the output of the single-phase AC voltage and the charging from the single-phase AC power source can be performed by the on / off state of the bidirectional switch and the unidirectional switch and the pulse width modulation control. In addition, since the total number of IGBTs and diodes on the current path is always four, conduction loss can be reduced. Furthermore, since the path of the current flowing through the inductor 1 can be secured also in the second embodiment, a surge voltage is not generated, and safety can be improved.

The second embodiment is different from the first embodiment in that the current direction of the terminal V is constant, so that the current of the inductor 1 flows from the terminals U to R and from the terminals U to S when the terminal V is turned on. It can only be controlled. Therefore, as compared with the first embodiment, when power is output from the storage battery 15 to the grid side by the step-down operation, the control characteristics of the inductor 1 near zero current are deteriorated. Further, as is apparent from the current paths shown in FIGS. 11A and 11C, there is a problem that the current for charging the storage battery 15 cannot be supplied from the system side by the boosting operation. However, the circuit configuration of the second embodiment has an advantage that the number of bidirectional switches used can be reduced by two.

(Third embodiment)
FIG. 3 is a configuration diagram of the power conversion device according to the third embodiment. In the figure, the first embodiment is different from FIG. 1 in that the bidirectional switches 24 to 29 are configured by unidirectional switches 3, 4, 6, 9, 10, and 12, respectively. A mechanical switch 30 for switching the state is provided. Along with this change, the configuration of the controller 21b and the PWM controller 23b that is a component thereof are changed. Other parts are the same as those in FIG.
The output of the power conversion device of the third embodiment assumes an uninterruptible power supply (UPS), and a single-phase AC power supply 17 is connected in parallel with the load 16. The uninterruptible power supply (UPS) charges the storage battery 15 from the single-phase AC power supply 17 and disconnects the single-phase AC power supply 17 and supplies power from the storage battery 15 to the load 16 at the time of a power failure.

In the circuit of FIG. 3 which is the third embodiment, the terminals U, V, W and the terminals R, S are connected by the one-way switches 3, 4, 6, 9, 10, 12. When power is sent from the storage battery 15 to the load 16, the positive electrode of the storage battery 15 is connected to the terminal U and the negative electrode of the storage battery 15 is connected to the terminal W. When the storage battery 15 is charged from the system side, the negative electrode of the storage battery 15 is connected to the terminal U and the positive electrode of the storage battery 15 is connected to the terminal W by a mechanical switch such as a relay. The connection of the unidirectional switch between the terminals U, W and the terminals R, S is the same as that of the current source inverter, and the current of the terminal U of the inductor 1 is changed to the terminal R, which is an output terminal by ON / OFF control of the unidirectional switch. S can be freely connected. Therefore, a positive and negative single-phase AC voltage can be generated between the RS terminals.

The controller 21b of FIG. 3 performs the following control based on the magnitude relationship between the storage battery voltage VDC and the absolute value | VRS | of the single-phase AC voltage VRS and the positive / negative polarity of the VRS described in the first embodiment. Do.

C1) When power is output from the storage battery 15 to the system side (single-phase AC power supply 17) C1-1) When | VRS | <VDC (step-down operation)
Electric power is output from the storage battery 15 to the system side, and under the condition of | VRS | <VDC, the single-phase AC voltage VRS is output by the step-down operation in the current path shown in FIG. The controller 21b changes the current paths in the ON mode and the OFF mode as shown in FIG. 12 depending on whether the VRS is positive or negative. In each state, pulse width modulation is performed by changing the time ratio between the ON mode and the OFF mode, and a voltage having an absolute value lower than the storage battery voltage VDC is output.
That is, when VRS> 0, the switching states of (a) and (b) of FIG. 12 are controlled alternately, and when VRS <0, the switching states of (c) and (d) of FIG. And outputs a single-phase AC voltage VRS.

C1-2) | VRS |> VDC (step-up operation)
Electric power is output from the storage battery 15 to the system side, and a single-phase AC voltage VRS is output by a step-up operation in the current path shown in FIG. 13 under the condition of | VRS |> VDC. The controller 21b changes the current paths in the ON mode and the OFF mode as shown in FIG. 13 depending on whether the VRS is positive or negative. In each state, pulse width modulation is performed by changing the time ratio between the ON mode and the OFF mode, and a voltage having a higher absolute value than the storage battery voltage VDC is output.
That is, as in the case of C1-1) described above, the single-phase AC voltage VRS is changed by alternately controlling the switching states of (a) and (b) or (c) and (d) shown in FIG. Output.

C2) When charging the storage battery 15 from the system side (single-phase AC power supply 17) In the third embodiment, when charging the storage battery 15 from the system side, first, the mechanical switch 30 is used to set the positive and negative polarity of the storage battery 15. As described above, it is necessary to change the connection. In the following description, it is assumed that this connection change has already been completed.
C2-1) | VRS |> VDC (step-down operation)
Electric power is input from the system side to charge the storage battery 15, and under the condition of | VRS |> VDC, a step-down operation is performed in the current path shown in FIG. The controller 21b changes the current paths in the ON mode and the OFF mode as shown in FIG. 14 depending on whether the VRS is positive or negative. In each state, the battery 15 is charged from the single-phase AC power supply 17 having a voltage higher in absolute value than the storage battery voltage VDC by changing the time ratio between the ON mode and the OFF mode and performing pulse width modulation.
That is, when VRS> 0, the switching states of (a) and (b) of FIG. 14 are controlled alternately, and when VRS <0, the switching states of (c) and (d) of FIG. 14 are controlled alternately. Then, the storage battery 15 is charged from the single-phase AC power source 17.

C2-2) | VRS | <VDC (step-up operation)
Electric power is input from the system side to charge the storage battery 15, and under the condition of | VRS | <VDC, a boosting operation is performed through the current path shown in FIG. The controller 21b changes the current paths in the ON mode and the OFF mode as shown in FIG. 15 depending on whether the VRS is positive or negative. In each state, the time ratio between the ON mode and the OFF mode is changed to perform pulse width modulation, and charging is performed from the single-phase AC power source 17 having a voltage lower in absolute value than the storage battery voltage VDC.
That is, as in the case of C2-1) described above, the single-phase AC power supply 17 can be controlled by alternately controlling the switching states of (a) and (b) or (c) and (d) shown in FIG. The storage battery 15 is charged.

In addition, in the explanatory diagrams of FIGS. 12 to 15, the IGBT is replaced with a mechanical switch so that the on / off state of the IGBT can be easily understood.
When the controller 21b outputs power from the storage battery 15, the detected value of the single-phase AC voltage VRS is compared with the voltage command of the single-phase sine wave, the deviation amount is used as a control signal using a PI controller or the like, and the PWM pulse The AC voltage is output by adjusting the time ratio. Further, at the time of charging, the current detection value of the storage battery 15 is compared with the current command, the deviation amount is used as a control signal using a PI controller or the like, and the charging current is flowed by adjusting the time ratio of the PWM pulse.
As described above, in the third embodiment, the output of the single-phase AC voltage and the charging from the single-phase AC power source can be performed by the polarity switching of the storage battery, the ON / OFF state of the one-way switch, and the pulse width modulation control. . In addition, since the total number of IGBTs and diodes on the current path is always four, conduction loss can be reduced. Compared with the first embodiment and the second embodiment, a mechanical switch is added. However, the number of bidirectional switches can be greatly reduced, so that the apparatus can be made inexpensive. In addition, since a current path through the inductor 1 can be secured, a surge voltage is not generated, and safety can be improved.

FIG. 19 shows the correspondence between the level of the storage battery voltage VDC and the single-phase AC voltage VRS and the voltage region in which the step-up / step-down operation is performed in each embodiment. The controller performs the step-down operation and the step-up operation based on the state switching between taking out (discharging) or charging power from the externally input storage battery, the detected values of VDC and VRS, and the correspondence shown in FIG. Switch. The hatched lines near zero in FIG. 19 indicate that the control is impossible because VDC and | VRS | approach a value that is as low as the switch ON voltage (several volts).

FIG. 20 shows a switching correspondence diagram between the time change of the single-phase AC voltage VRS and the step-down operation / step-up operation performed by the controller. During charging, if | VRS | becomes as low as a voltage drop (several volts) when the switch is turned on, the boosting operation cannot be performed, and in this state, control becomes impossible. However, if the system is operated so that the power factor of the system becomes 1 (the phase difference between the voltage and current is zero) during charging, the current in this uncontrollable part is also almost zero, and the current distortion becomes slight.

In each embodiment, the case where a configuration in which an IGBT and a diode are connected in series is used as a one-way switch has been described. However, if a reverse blocking IGBT (RB-IGBT) is used, a diode is not necessary, and a current path element is provided. The number can be reduced and the conduction loss can also be reduced.

In each embodiment, when the VRS overvoltage is detected when power is output from the storage battery to the grid side, or when the VDC overvoltage is detected when charging the storage battery from the grid side, the output current and the storage battery When an abnormality occurs such as when an overcurrent is detected, the operation of the power converter must be stopped. However, in this protection operation, when the operation is stopped by turning off all the switches, the electromagnetic energy accumulated in the inductor 1 is discharged all at once, and a surge voltage is generated. The switch may be destroyed. In order to solve this problem, the controller of the present embodiment shifts to a mode for returning the inductor current as shown in FIG. 16 when such an abnormality is detected. This suppresses the generation of a surge voltage and opens a contact of a switch (not shown) that disconnects the input terminal and the output terminal to perform a protective operation. Since a current path through the inductor is secured, surge voltage is not generated, and safety can be improved.

In FIG. 16, (a) and (b) correspond to the circuit configuration of the first embodiment, (a) is when the bidirectional switches 27 and 28 are turned on, and (b) is the bidirectional switch 24. And 25 are turned on. Also, (c) and (d) in the figure correspond to the circuit configuration of the second embodiment, (c) is when the bidirectional switch 27 and the unidirectional switch 10 are turned on, (d) is A case where the bidirectional switch 24 and the one-way switch 4 are turned on is shown. Further, (e) and (f) in the figure correspond to the circuit configuration of the third embodiment, (e) is when the one-way switches 9 and 10 are turned on, and (f) is the one-way switch 3. And 4 are turned on.
By turning on each of the switches described above, the current of the inductor 1 can be recirculated, and the generation of a surge voltage when an abnormality is detected in the power converter can be suppressed.

1 Inductor 2-13 One-way switch 14 Capacitor 15 Storage battery (DC power supply)
16 Load 17 Single-phase AC power supply 18 DC voltage detector 19 AC voltage detector 20 Current detectors 21, 21a, 21b Controller 22 Operators 23, 23a, 23b PWM controllers 24-29 Bidirectional switch 30 Mechanical switch 31 Power conversion Circuit 32 Switch circuit Vb DC power supply SW Switch L Inductor (reactor)
C capacitor
D Diode Load Load

Claims (20)

A DC-AC power conversion device that reversibly converts power between a DC voltage of a DC power supply and a single-phase AC voltage of a single-phase AC power supply,
A switch circuit unit having three DC side connection ends on the DC power source side and two AC side connection ends on the single-phase AC power source side;
An inductor disposed between the DC power supply and the switch circuit unit;
A capacitor disposed between the switch circuit unit and the single-phase AC power supply or load;
The DC voltage is boosted or stepped down to supply the DC power to the single-phase AC power supply or the load, or the single-phase AC voltage is boosted or stepped down to supply the DC power to the DC power supply. And a controller for driving the switch circuit unit so as to supply the DC-AC power converter. The switch circuit unit connects the other end of the inductor to one end of the first bidirectional switch and one end of the fourth bidirectional switch, and connects one end of the second bidirectional switch and the fifth bidirectional switch. One end is connected to one end of the inductor, one end of the third bidirectional switch and one end of the sixth bidirectional switch are connected to the negative side of the DC power supply, and the other end of the first bidirectional switch And the other end of the second bidirectional switch and the other end of the third bidirectional switch are connected to one end of the single-phase AC side, and both the other end of the fourth bidirectional switch and the fifth The first to sixth bidirectional switches connected to the other end of the direction switch and the other end of the sixth bidirectional switch to the other end of the single-phase AC side,
One end of the inductor is connected to the positive side of the DC power supply,
2. The DC-AC power according to claim 1, wherein one end of the capacitor is connected to the other end of the first bidirectional switch, and the other end of the capacitor is connected to the other end of the fourth bidirectional switch. Conversion device. A DC voltage detector for detecting the voltage of the DC power supply, an AC voltage detector for detecting the voltage on the single-phase AC side, and at least one detector of a current detector for detecting the current of the DC power supply;
Based on the detection value of the detector, the first to sixth bidirectional switches are turned on and off, and the power of the DC power supply is supplied to the single-phase AC power supply or the power of the single-phase AC power supply is supplied to the DC power supply. A DC-AC power converter according to claim 2, further comprising a controller that supplies the controller.   A DC voltage detector for detecting a voltage of the DC power supply; and an AC voltage detector for detecting a voltage on the single-phase AC side, and supplying the power from the DC power source to the single-phase AC power source. A controller for switching the first to sixth bidirectional switches so as to be in a step-down operation mode or a step-up operation mode by interaction with the inductor, and supplying power of the DC power source to the single-phase AC power source by PWM control; The DC-AC power converter according to claim 2 or 3, characterized by comprising: When the relationship between the single-phase AC side voltage VRS and the DC power supply voltage VDC is | VRS | <VDC, the step-down operation mode is selected,
When the voltage VRS is VRS> 0, the ON mode for turning on the first bidirectional switch and the sixth bidirectional switch, and the OFF mode for turning on the first bidirectional switch and the fifth bidirectional switch. Alternately control the mode switching state,
When the voltage VRS is VRS <0, an ON mode for turning on the fourth bidirectional switch and the third bidirectional switch, and turning on the fourth bidirectional switch and the second bidirectional switch. By alternately controlling the switching state of the OFF mode,
5. The DC-AC power converter according to claim 4, wherein the PWM control is performed by changing a time ratio between the ON mode and the OFF mode. When the relationship between the voltages VRS and VDC on the single-phase AC side is | VRS |> VDC, the step-up operation mode is selected,
When the voltage VRS is VRS> 0, an ON mode for turning on the first bidirectional switch and the third bidirectional switch, and an OFF mode for turning on the first bidirectional switch and the sixth bidirectional switch Alternately control the switching state of
When the voltage VRS is VRS <0, an ON mode for turning on the fourth bidirectional switch and the sixth bidirectional switch, and turning on the fourth bidirectional switch and the third bidirectional switch By alternately controlling the switching state of the OFF mode,
5. The DC-AC power converter according to claim 4, wherein the PWM control is performed by changing a time ratio between the ON mode and the OFF mode. A DC voltage detector for detecting the voltage of the DC power supply; an AC voltage detector for detecting the voltage on the single-phase AC side; and a current detector for detecting a current of the DC power supply; The first to sixth bidirectional switches are switched so as to enter the step-down operation mode or the step-up operation mode by interaction with the inductor so as to supply power to the phase AC power source, and the DC power source is controlled by PWM control. 5. The DC-AC power converter according to claim 4, further comprising a controller that controls charging of the DC power source from the single-phase AC power source or the single-phase AC power source. In the charging control, when the relationship between the voltages VRS and VDC is | VRS |> VDC, the step-down operation mode is selected.
When the voltage VRS is VRS> 0, an ON mode for turning on the first bidirectional switch and the sixth bidirectional switch, and an OFF mode for turning on the first bidirectional switch and the third bidirectional switch Alternately control the mode switching state,
When the voltage VRS is VRS <0, an ON mode for turning on the fourth bidirectional switch and the third bidirectional switch, and turning on the fourth bidirectional switch and the sixth bidirectional switch. By alternately controlling the switching state of the OFF mode,
A controller for performing the PWM control by changing a time ratio between the ON mode and the OFF mode based on a deviation amount between a current detection value detected by the current detector and a current command. Item 8. The DC-AC power converter according to Item 7. In the charge control, when the relationship between the voltages VRS and VDC is | VRS | <VDC, the boost operation mode is selected,
When the voltage VRS is VRS> 0, an ON mode that turns on the first bidirectional switch and the fifth bidirectional switch, and an OFF mode that turns on the first bidirectional switch and the sixth bidirectional switch. Alternately control the mode switching state,
When the voltage VRS is VRS <0, an ON mode for turning on the fourth bidirectional switch and the second bidirectional switch, and turning on the fourth bidirectional switch and the third bidirectional switch By alternately controlling the switching state of the OFF mode,
A controller for performing the PWM control by changing a time ratio between the ON mode and the OFF mode based on a deviation amount between a current detection value detected by the current detector and a current command. Item 8. The DC-AC power converter according to Item 7.   A unidirectional switch that allows current to flow from one end of the single-phase AC side to the positive side of the DC power source through the second bidirectional switch, and a fifth bidirectional switch from the other end of the single-phase AC side The DC-AC power converter according to any one of claims 4 to 8, wherein the DC-AC power converter is replaced with a one-way switch that allows a current to flow in the direction of the positive electrode side of the DC power supply. A direct current power supply, and a mechanical switch that inverts and outputs the voltage polarity of the direct current power supply,
The inductor connected to one contact of the mechanical switch connected to a positive voltage before reversing the voltage polarity and a negative voltage after reversing, the first bidirectional switch and the fourth bidirectional switch Are replaced with a first one-way switch and a fourth one-way switch in the direction in which a current flows from the storage battery side to the load side,
A second one-way switch for flowing current from the load side to the storage battery side through the second bidirectional switch, the third bidirectional switch, the fifth bidirectional switch, and the sixth bidirectional switch; In the power converter replaced with the third unidirectional switch, the fifth unidirectional switch, and the sixth unidirectional switch,
The DC voltage detector for detecting the voltage of the DC power supply, the AC voltage detector for detecting the voltage on the single-phase AC side, and the current detector for detecting the current of the DC power supply;
When supplying power from the DC power source to the single-phase AC side, the connection of the mechanical switch is in a state before inversion of the voltage polarity, and when charging control of the DC power source from the single-phase AC side, The connection of the mechanical switch is changed so that the voltage polarity is reversed, and the replaced one-way switch is switched to enter the step-down operation mode or the step-up operation mode by the interaction with the inductor, and the single phase is controlled by PWM control. 4. The DC-AC power converter according to claim 3, further comprising a controller that outputs an AC voltage and supplies electric power to the single-phase AC side or controls charging of the DC power source. In the generation of the single-phase AC voltage, when the relationship between the voltages VRS and VDC is | VRS | <VDC, the step-down operation mode is selected.
When the voltage VRS is VRS> 0, the first one-way switch and the sixth one-way switch are turned on, and the first one-way switch and the fifth one-way switch are turned on. Alternately control the mode switching state,
When the voltage VRS is VRS <0, the ON mode in which the fourth one-way switch and the third one-way switch are turned on, and the fourth one-way switch and the second one-way switch are turned on. By alternately controlling the switching state of the OFF mode,
12. The DC-AC power converter according to claim 11, wherein the single-phase AC voltage is generated by the PWM control while changing a time ratio between the ON mode and the OFF mode. In the generation of the single-phase AC voltage, when the relationship between the voltages VRS and VDC is | VRS |> VDC, the step-up operation mode is selected.
When the voltage VRS is VRS> 0, the ON mode in which the first unidirectional switch and the third unidirectional switch are turned on, and the first unidirectional switch and the sixth unidirectional switch 6 are turned on. Control the switching state of OFF mode alternately,
When the voltage VRS is VRS <0, the fourth unidirectional switch and the sixth unidirectional switch 6 are turned on, the fourth unidirectional switch and the third unidirectional switch are turned on. By alternately controlling the OFF mode switching state to
12. The DC-AC power converter according to claim 11, wherein the single-phase AC voltage is generated by the PWM control while changing a time ratio between the ON mode and the OFF mode. In the charging control, when the relationship between the voltages VRS and VDC is | VRS |> VDC, the step-down operation mode is selected.
When the voltage VRS is VRS> 0, an ON mode for turning on the fourth unidirectional switch and the third unidirectional switch, and an OFF mode for turning on the fourth unidirectional switch and the sixth unidirectional switch. Alternately control the mode switching state,
When the voltage VRS is VRS <0, the ON mode in which the first one-way switch and the sixth one-way switch are turned on, and the first one-way switch and the third one-way switch are turned on. By alternately controlling the switching state of the OFF mode,
The PWM control is performed by changing a time ratio between the ON mode and the OFF mode based on a deviation amount between a current detection value detected by the current detector and a current command. DC-AC power converter. In the charge control, when the relationship between the voltages VRS and VDC is | VRS | <VDC, the boost operation mode is selected,
When the voltage VRS is VRS> 0, an ON mode for turning on the fourth unidirectional switch and the second unidirectional switch, and an OFF mode for turning on the fourth unidirectional switch and the third unidirectional switch. Alternately control the mode switching state,
When the voltage VRS is VRS <0, the ON mode in which the first one-way switch and the fifth one-way switch are turned on, and the first one-way switch and the sixth one-way switch are turned on. By alternately controlling the switching state of the OFF mode,
The PWM control is performed by changing a time ratio between the ON mode and the OFF mode based on a deviation amount between a current detection value detected by the current detector and a current command. DC-AC power converter.   When the operation is stopped by detecting an abnormality, a short circuit is established between the terminals of the inductor to ensure a current path flowing through the inductor, and a protective operation is performed to open a switch that disconnects the storage battery from the power system. The DC-AC power converter according to any one of claims 1 to 15 characterized by things. A DC-AC power conversion circuit that reversibly converts power between a DC voltage of a DC power supply and a single-phase AC voltage of a single-phase AC power supply,
A switch circuit unit having first to third DC side connection ends on the DC power source side, and first and second AC side connection ends on the single-phase AC power source side;
An inductor disposed between the DC power supply and the switch circuit unit;
A DC-AC power conversion circuit comprising: a capacitor disposed between the switch circuit unit and the single-phase AC power supply or load. The switch circuit unit is
The first AC side connection end and the first to third DC side connection ends are each connected by a bidirectional switch,
18. The DC-AC power converter circuit according to claim 17, wherein the second AC side connection end and the first to third DC side connection ends are each connected by a bidirectional switch. Unidirectional switch for energizing a bidirectional switch connecting the first AC side connection end and the second DC side connection end from the first AC side connection end to the second DC side connection end Is replaced with
Unidirectional switch for energizing a bidirectional switch connecting the second AC side connection end and the second DC side connection end in the direction from the second AC side connection end to the second DC side connection end 18. The DC-AC power conversion circuit according to claim 17, wherein Unidirectional switch for energizing a bidirectional switch connecting the first AC side connection end and the third DC side connection end from the first AC side connection end to the third DC side connection end Is replaced with
Unidirectional switch for energizing a bidirectional switch connecting the second AC side connection end and the third DC side connection end from the second AC side connection end toward the third DC side connection end Is replaced with
Unidirectional switch for energizing a bidirectional switch connecting the first AC side connection end and the first DC side connection end from the first DC side connection end toward the first AC side connection end Is replaced with
Unidirectional switch for energizing a bidirectional switch connecting the second AC side connection end and the first DC side connection end from the first DC side connection end toward the second AC side connection end 20. The DC-AC power conversion circuit according to claim 19, wherein the DC-AC power conversion circuit is replaced with.

Images