WO2016125373A1 - Dc/dcコンバータ - Google Patents
Dc/dcコンバータ Download PDFInfo
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- WO2016125373A1 WO2016125373A1 PCT/JP2015/083609 JP2015083609W WO2016125373A1 WO 2016125373 A1 WO2016125373 A1 WO 2016125373A1 JP 2015083609 W JP2015083609 W JP 2015083609W WO 2016125373 A1 WO2016125373 A1 WO 2016125373A1
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- phase shift
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- shift amount
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- H—ELECTRICITY
- H02—GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
- H02M—APPARATUS 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
- H02M3/00—Conversion of dc power input into dc power output
- H02M3/02—Conversion of dc power input into dc power output without intermediate conversion into ac
- H02M3/04—Conversion of dc power input into dc power output without intermediate conversion into ac by static converters
- H02M3/06—Conversion of dc power input into dc power output without intermediate conversion into ac by static converters using resistors or capacitors, e.g. potential divider
- H02M3/07—Conversion of dc power input into dc power output without intermediate conversion into ac by static converters using resistors or capacitors, e.g. potential divider using capacitors charged and discharged alternately by semiconductor devices with control electrode, e.g. charge pumps
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- G—PHYSICS
- G05—CONTROLLING; REGULATING
- G05F—SYSTEMS FOR REGULATING ELECTRIC OR MAGNETIC VARIABLES
- G05F1/00—Automatic systems in which deviations of an electric quantity from one or more predetermined values are detected at the output of the system and fed back to a device within the system to restore the detected quantity to its predetermined value or values, i.e. retroactive systems
- G05F1/10—Regulating voltage or current
- G05F1/12—Regulating voltage or current wherein the variable actually regulated by the final control device is ac
- G05F1/32—Regulating voltage or current wherein the variable actually regulated by the final control device is ac using magnetic devices having a controllable degree of saturation as final control devices
- G05F1/34—Regulating voltage or current wherein the variable actually regulated by the final control device is ac using magnetic devices having a controllable degree of saturation as final control devices combined with discharge tubes or semiconductor devices
- G05F1/38—Regulating voltage or current wherein the variable actually regulated by the final control device is ac using magnetic devices having a controllable degree of saturation as final control devices combined with discharge tubes or semiconductor devices semiconductor devices only
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- H—ELECTRICITY
- H02—GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
- H02M—APPARATUS 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
- H02M1/00—Details of apparatus for conversion
- H02M1/38—Means for preventing simultaneous conduction of switches
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- H—ELECTRICITY
- H02—GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
- H02M—APPARATUS 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
- H02M3/00—Conversion of dc power input into dc power output
- H02M3/02—Conversion of dc power input into dc power output without intermediate conversion into ac
- H02M3/04—Conversion of dc power input into dc power output without intermediate conversion into ac by static converters
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- H—ELECTRICITY
- H02—GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
- H02M—APPARATUS 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
- H02M3/00—Conversion of dc power input into dc power output
- H02M3/02—Conversion of dc power input into dc power output without intermediate conversion into ac
- H02M3/04—Conversion of dc power input into dc power output without intermediate conversion into ac by static converters
- H02M3/10—Conversion of dc power input into dc power output without intermediate conversion into ac by static converters using discharge tubes with control electrode or semiconductor devices with control electrode
- H02M3/125—Conversion of dc power input into dc power output without intermediate conversion into ac by static converters using discharge tubes with control electrode or semiconductor devices with control electrode using devices of a thyratron or thyristor type requiring extinguishing means
- H02M3/135—Conversion of dc power input into dc power output without intermediate conversion into ac by static converters using discharge tubes with control electrode or semiconductor devices with control electrode using devices of a thyratron or thyristor type requiring extinguishing means using semiconductor devices only
- H02M3/137—Conversion of dc power input into dc power output without intermediate conversion into ac by static converters using discharge tubes with control electrode or semiconductor devices with control electrode using devices of a thyratron or thyristor type requiring extinguishing means using semiconductor devices only with automatic control of output voltage or current, e.g. switching regulators
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- H—ELECTRICITY
- H02—GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
- H02M—APPARATUS 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
- H02M3/00—Conversion of dc power input into dc power output
- H02M3/02—Conversion of dc power input into dc power output without intermediate conversion into ac
- H02M3/16—Conversion of dc power input into dc power output without intermediate conversion into ac by dynamic converters
- H02M3/18—Conversion of dc power input into dc power output without intermediate conversion into ac by dynamic converters using capacitors or batteries which are alternately charged and discharged, e.g. charged in parallel and discharged in series
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- H—ELECTRICITY
- H02—GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
- H02M—APPARATUS 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
- H02M3/00—Conversion of dc power input into dc power output
- H02M3/22—Conversion of dc power input into dc power output with intermediate conversion into ac
- H02M3/24—Conversion of dc power input into dc power output with intermediate conversion into ac by static converters
- H02M3/28—Conversion of dc power input into dc power output with intermediate conversion into ac by static converters using discharge tubes with control electrode or semiconductor devices with control electrode to produce the intermediate ac
- H02M3/325—Conversion of dc power input into dc power output with intermediate conversion into ac by static converters using discharge tubes with control electrode or semiconductor devices with control electrode to produce the intermediate ac using devices of a triode or a transistor type requiring continuous application of a control signal
- H02M3/335—Conversion of dc power input into dc power output with intermediate conversion into ac by static converters using discharge tubes with control electrode or semiconductor devices with control electrode to produce the intermediate ac using devices of a triode or a transistor type requiring continuous application of a control signal using semiconductor devices only
- H02M3/33538—Conversion of dc power input into dc power output with intermediate conversion into ac by static converters using discharge tubes with control electrode or semiconductor devices with control electrode to produce the intermediate ac using devices of a triode or a transistor type requiring continuous application of a control signal using semiconductor devices only of the forward type
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- H—ELECTRICITY
- H02—GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
- H02M—APPARATUS 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
- H02M3/00—Conversion of dc power input into dc power output
- H02M3/22—Conversion of dc power input into dc power output with intermediate conversion into ac
- H02M3/24—Conversion of dc power input into dc power output with intermediate conversion into ac by static converters
- H02M3/28—Conversion of dc power input into dc power output with intermediate conversion into ac by static converters using discharge tubes with control electrode or semiconductor devices with control electrode to produce the intermediate ac
- H02M3/325—Conversion of dc power input into dc power output with intermediate conversion into ac by static converters using discharge tubes with control electrode or semiconductor devices with control electrode to produce the intermediate ac using devices of a triode or a transistor type requiring continuous application of a control signal
- H02M3/335—Conversion of dc power input into dc power output with intermediate conversion into ac by static converters using discharge tubes with control electrode or semiconductor devices with control electrode to produce the intermediate ac using devices of a triode or a transistor type requiring continuous application of a control signal using semiconductor devices only
- H02M3/33569—Conversion of dc power input into dc power output with intermediate conversion into ac by static converters using discharge tubes with control electrode or semiconductor devices with control electrode to produce the intermediate ac using devices of a triode or a transistor type requiring continuous application of a control signal using semiconductor devices only having several active switching elements
- H02M3/33576—Conversion of dc power input into dc power output with intermediate conversion into ac by static converters using discharge tubes with control electrode or semiconductor devices with control electrode to produce the intermediate ac using devices of a triode or a transistor type requiring continuous application of a control signal using semiconductor devices only having several active switching elements having at least one active switching element at the secondary side of an isolation transformer
- H02M3/33584—Bidirectional converters
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- H—ELECTRICITY
- H02—GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
- H02J—CIRCUIT ARRANGEMENTS OR SYSTEMS FOR SUPPLYING OR DISTRIBUTING ELECTRIC POWER; SYSTEMS FOR STORING ELECTRIC ENERGY
- H02J2207/00—Indexing scheme relating to details of circuit arrangements for charging or depolarising batteries or for supplying loads from batteries
- H02J2207/20—Charging or discharging characterised by the power electronics converter
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- H—ELECTRICITY
- H02—GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
- H02J—CIRCUIT ARRANGEMENTS OR SYSTEMS FOR SUPPLYING OR DISTRIBUTING ELECTRIC POWER; SYSTEMS FOR STORING ELECTRIC ENERGY
- H02J7/00—Circuit arrangements for charging or depolarising batteries or for supplying loads from batteries
-
- H—ELECTRICITY
- H02—GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
- H02M—APPARATUS 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
- H02M1/00—Details of apparatus for conversion
- H02M1/0048—Circuits or arrangements for reducing losses
- H02M1/0054—Transistor switching losses
- H02M1/0058—Transistor switching losses by employing soft switching techniques, i.e. commutation of transistors when applied voltage is zero or when current flow is zero
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- Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y02—TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
- Y02B—CLIMATE CHANGE MITIGATION TECHNOLOGIES RELATED TO BUILDINGS, e.g. HOUSING, HOUSE APPLIANCES OR RELATED END-USER APPLICATIONS
- Y02B70/00—Technologies for an efficient end-user side electric power management and consumption
- Y02B70/10—Technologies improving the efficiency by using switched-mode power supplies [SMPS], i.e. efficient power electronics conversion e.g. power factor correction or reduction of losses in power supplies or efficient standby modes
Definitions
- the present invention relates to a DC / DC converter in which a primary side and a secondary side are insulated by a transformer, and more particularly to a DC / DC converter that performs power transmission between two DC power sources.
- the conventional bidirectional DC / DC converter performs bidirectional power transmission between a first DC power source and a second DC power source, and includes a transformer and a plurality of semiconductor switching elements.
- the first DC power source having a plurality of semiconductor switching elements and a first converter unit connected between the DC power source and the first winding of the transformer and converting power between DC / AC Connected to the second winding of the transformer, and controls the second converter unit for converting power between direct current and alternating current, and the semiconductor switching elements in the first and second converter units.
- the first and second converter sections include capacitors connected in parallel to the semiconductor switching elements, and first and second reactors connected to AC input / output lines.
- the control circuit uses the first reactor to transfer each semiconductor switching element in the first converter unit to a zero voltage during power transmission from the first DC power source to the second DC power source.
- the second converter unit is boosted using the second reactor. Control to do.
- control is performed so that each semiconductor switching element in the second converter unit performs zero voltage switching using the second reactor.
- the first converter unit is controlled to perform a boost operation using the first reactor.
- the bi-directional DC / DC converter as described in Patent Document 1 has a simple circuit configuration that is symmetrical with respect to the transformer, enables zero voltage switching regardless of the power transmission direction, and is bidirectional with simple control. Power transmission can be realized. However, the polarity of the transformer current is switched during power transmission and a reverse current may be generated, which may increase reactive power that does not contribute to power transmission. In addition, response delays may occur due to the effects of short-circuit prevention time, etc., and the response to the command value of the transmission power may be extremely deteriorated. It was difficult to change and follow the command value.
- the present invention has been made to solve the above-described problems, and with a simple circuit configuration, it is possible to transmit power while preventing a reverse current of the transformer current in a wide voltage range, thereby realizing low loss.
- An object of the present invention is to provide a DC / DC converter that can be used.
- Another object of the present invention is to obtain a highly responsive and reliable output control that can change the transmission power quickly even when the power transmission direction changes even in response to a steep load change.
- a DC / DC converter performs power transmission between a first DC power source and a second DC power source, and includes a transformer and a plurality of semiconductor switching elements each connected with an antiparallel diode.
- a plurality of semiconductor switching elements each comprising a first converter unit connected between the first DC power source and the first winding of the transformer, and anti-parallel diodes, each of which is composed of a full bridge circuit including two bridge circuits
- a second converter unit connected between the second DC power source and the second winding of the transformer, and an AC input / output of the second converter unit.
- the control circuit includes a first circuit that performs feedback control so as to reduce the differential current value, and a second circuit that corrects one of control inputs and outputs of the first circuit based on the current detection value and the current command value.
- the control circuit is one of a positive side and a negative side of a first bridge circuit that is one bridge circuit of the first converter unit.
- the semiconductor switching element is used as the first reference element, and one of the semiconductor switching elements on the positive side / negative side of the second bridge circuit that is one bridge circuit in the second converter section is used as the second reference element. 1. Of the four bridge circuits in the second converter unit, all the semiconductor switching elements constituting the second bridge circuit are turned off, and the other three bridge circuits are connected to the positive side semiconductor switching element and the negative side.
- the semiconductor switching elements of the first reference element and the first reference element and the first diagonal element that are diagonally related to each other have the same on-time ratio.
- the second phase shift amount which is the phase shift amount of the drive signal with the switching element, is controlled.
- the second circuit adjusts the first and second phase shift amounts by the correction to cause the current detection value to follow the current command value.
- the DC / DC converter according to the present invention with a simple circuit configuration, power can be transmitted while preventing a reverse current of the transformer current in a wide voltage range, and a reduction in loss can be realized. Further, even when the power transmission direction changes even in response to a steep load change, the transmission power can be changed quickly, and output control with high responsiveness and high reliability can be obtained.
- FIG. 6 is a current path diagram illustrating a charging operation of the battery charge / discharge device according to embodiment 1 of the present invention.
- FIG. 6 is a current path diagram illustrating a charging operation of the battery charge / discharge device according to embodiment 1 of the present invention.
- FIG. 6 is a current path diagram illustrating a charging operation of the battery charge / discharge device according to embodiment 1 of the present invention.
- FIG. 6 is a current path diagram illustrating a charging operation of the battery charge / discharge device according to embodiment 1 of the present invention.
- FIG. 6 is a current path diagram illustrating a charging operation of the battery charge / discharge device according to embodiment 1 of the present invention.
- FIG. 6 is a current path diagram illustrating a charging operation of the battery charge / discharge device according to embodiment 1 of the present invention.
- FIG. 6 is a current path diagram illustrating a charging operation of the battery charge / discharge device according to embodiment 1 of the present invention. It is a figure explaining the charging operation of the battery charging / discharging apparatus by Embodiment 1 of this invention.
- FIG. 6 is a current path diagram illustrating a charging operation of the battery charge / discharge device according to embodiment 1 of the present invention.
- FIG. 6 is a current path diagram illustrating a charging operation of the battery charge / discharge device according to embodiment 1 of the present invention.
- FIG. 6 is a current path diagram illustrating a charging operation of the battery charge / discharge device according to embodiment 1 of the present invention.
- FIG. 6 is a current path diagram illustrating a charging operation of the battery charge / discharge device according to embodiment 1 of the present invention.
- FIG. 6 is a current path diagram illustrating a charging operation of the battery charge /
- FIG. 6 is a current path diagram illustrating a charging operation of the battery charge / discharge device according to embodiment 1 of the present invention. It is a drive signal waveform diagram of the battery charge / discharge device according to embodiment 1 of the present invention.
- FIG. 6 is a current path diagram illustrating a charging operation of the battery charge / discharge device according to embodiment 1 of the present invention.
- FIG. 6 is a current path diagram illustrating a charging operation of the battery charge / discharge device according to embodiment 1 of the present invention.
- FIG. 6 is a current path diagram illustrating a charging operation of the battery charge / discharge device according to embodiment 1 of the present invention.
- FIG. 6 is a current path diagram illustrating a charging operation of the battery charge / discharge device according to embodiment 1 of the present invention.
- FIG. 6 is a current path diagram illustrating a charging operation of the battery charge / discharge device according to embodiment 1 of the present invention.
- FIG. 6 is a current path diagram illustrating a charging operation of the battery charge / discharge device according to embodiment 1 of the present invention.
- FIG. 6 is a current path diagram illustrating a charging operation of the battery charge / discharge device according to embodiment 1 of the present invention.
- FIG. 6 is a current path diagram illustrating a charging operation of the battery charge / discharge device according to embodiment 1 of the present invention.
- FIG. 6 is a current path diagram illustrating a charging operation of the battery charge / discharge device according to embodiment 1 of the present invention.
- FIG. 6 is a current path diagram illustrating a charging operation of the battery charge / discharge device according to embodiment 1 of the present invention.
- FIG. 6 is a current path diagram illustrating a charging operation of the battery charge / discharge device according to embodiment 1 of the present invention.
- Embodiment 1 of this invention It is a control block diagram of the battery charging / discharging device by Embodiment 1 of this invention. It is a flowchart which shows the correction
- FIG. 1 is a diagram showing a circuit configuration of a battery charge / discharge device 100 as a DC / DC converter according to Embodiment 1 of the present invention.
- the battery charging / discharging device 100 performs charging / discharging of the battery 2 by bidirectional power conversion between a DC power source 1 as a first DC power source and a battery 2 as a second DC power source. is there.
- the battery charging / discharging device 100 includes a high-frequency transformer 3 (hereinafter simply referred to as a transformer 3) as an insulated transformer, a first smoothing capacitor 4 connected in parallel to the DC power source 1, and a first converter unit.
- the battery charge / discharge device 100 includes a control circuit 20 that controls the first switching circuit 5 and the second switching circuit 8.
- the first switching circuit 5 includes a plurality of semiconductor switching elements Q4A, Q4B, Q3A, Q3B (hereinafter simply referred to as Q4A, Q4B, Q3A, Q3B, or semiconductor switching elements) each composed of an IGBT, a MOSFET, or the like with diodes 12 connected in antiparallel.
- the DC side is connected to the first smoothing capacitor 4 and the AC side is connected to the first winding 3a of the transformer 3 to perform bidirectional power conversion between DC / AC.
- the first switching circuit 5 is a zero voltage switching circuit in which the voltage across the elements at the time of switching of each semiconductor switching element Q can be made substantially zero voltage, and a capacitor 13 is connected in parallel to each semiconductor switching element Q.
- the A first reactor 9 is connected to an AC input / output line between the semiconductor switching element Q and the transformer 3, and the first reactor 9 and the first winding 3 a are connected in series.
- the second switching circuit 8 includes a plurality of semiconductor switching elements Q2A, Q2B, Q1A, Q1B (hereinafter simply referred to as Q2A, Q2B, Q1A, Q1B, or semiconductor switching element Q) each composed of an IGBT or MOSFET with diodes 12 connected in antiparallel.
- the DC side is connected to the second smoothing capacitor 7 and the AC side is connected to the second winding 3b of the transformer 3 to perform bidirectional power conversion between DC and AC.
- the second switching circuit 8 is a zero voltage switching circuit in which the voltage across the elements at the time of switching of each semiconductor switching element Q can be made almost zero voltage, and a capacitor 13 is connected in parallel to each semiconductor switching element Q.
- the A second reactor 10 is connected to an AC input / output line between the semiconductor switching element Q and the transformer 3, and the second reactor 10 and the second winding 3b are connected in series. Further, a reactor 11 is connected to the DC side of the second switching circuit 8.
- a current sensor (not shown) is installed between the second smoothing capacitor 7 and the battery 2 to detect the current flowing through the reactor 11 as the charging current i of the battery 2 (current with the arrow direction being positive). The sensed output is input to the control circuit 20. Further, a voltage sensor (not shown) for detecting the voltage v of the first smoothing capacitor 4 is installed, and the sensed output is input to the control circuit 20. The control circuit 20 generates drive signals 21a and 21b for switching control of the semiconductor switching elements Q of the first switching circuit 5 and the second switching circuit 8 based on the input current i and voltage v values. The first switching circuit 5 and the second switching circuit 8 are driven and controlled. A current sensor for detecting the charging current i of the battery 2 may be provided at a position closer to the second switching circuit 8 than the second smoothing capacitor 7.
- FIG. 2 is a control block diagram when power is transmitted from the DC power source 1 to the battery 2, that is, when the battery 2 is charged.
- a charging current i that is an output current of the battery charging / discharging device 100 is detected and input to the control circuit 20.
- the current detection value of charging current i is simply referred to as charging current i for convenience.
- the subtractor 30 subtracts the input charging current i from the charging current command value i * to calculate the differential current value 30a, and the PI controller 31 as the first circuit
- the output DUTY ratio D (hereinafter simply referred to as DUTY ratio D) of the first switching circuit 5 and the second switching circuit 8 is determined, and each semiconductor switching Drive signals 21a and 21b for the element Q are generated.
- the voltage of the first smoothing capacitor 4 connected in parallel to the DC power supply 1 is the same DC voltage as the voltage of the DC power supply 1.
- FIG. 3 is a diagram illustrating waveforms of the drive signals 21a and 21b of the semiconductor switching elements Q of the first switching circuit 5 and the second switching circuit 8 during the step-up charging of the battery charge / discharge device 100.
- periods A + to J + are provided for each of a plurality of gate patterns which are drive signal combination patterns.
- the reference numerals of the driving signals of Q4A, Q4B, Q3A, Q3B, Q2A, Q2B, Q1A, and Q1B are indicated by the reference numerals of the elements.
- the entire drive signal is generated with reference to the first bridge circuit (Q4A, Q4B) which is one of the bridge circuits in the first switching circuit 5.
- Q1A and Q1B of the second bridge circuit (Q1A, Q1B) which is one of the bridge circuits in the second switching circuit 8 are held in the off state.
- the three bridge circuits other than the second bridge circuit are Q4A, Q3A, Q2A on the positive side (high voltage side) and Q4B, Q3B on the negative side (low voltage side) constituting each bridge circuit.
- Q2B are controlled at an on-time ratio of 50%, excluding the short-circuit prevention time td.
- the short-circuit prevention time td is a time set to prevent the positive-side semiconductor switching element and the negative-side semiconductor switching element from being simultaneously turned on, and after one of them is turned off, the set short-circuit prevention time td After the elapse of time, the other is turned on.
- Q4A in the first bridge circuit is a first reference element
- Q1A in the second bridge circuit is a second reference element
- Q3B is a first diagonal element
- Q2B that is diagonally related to the second reference element Q1A is a second diagonal element.
- phase shift amount ⁇ 1 first phase shift amount
- phase shift amount ⁇ 2 second phase shift amount of the driving signal of the corner element Q2B is determined according to the DUTY ratio D that is a control command. That is, the phase shift amounts ⁇ 1 and ⁇ 2 are controlled according to the DUTY ratio D.
- the phase shift amount ⁇ 1 is kept to a minimum, and the phase shift amount ⁇ 2 changes according to the DUTY ratio D.
- the diagonal on time t1 is determined by the phase shift amount ⁇ 1.
- the diagonal on time t1a in which Q4B and Q3A are simultaneously turned on is also equal to the diagonal on time t1.
- a drive signal equal to that of the first bridge circuit (Q4A, Q4B) is assumed as a virtual drive signal, and Q1A is virtually turned on by the virtual drive signal of the second reference element Q1A.
- a period in which the second diagonal element Q2B is turned on is defined as a virtual diagonal on time t2.
- This virtual diagonal on time t2 is determined by the phase shift amount ⁇ 2 of the drive signal of the second diagonal element Q2B with respect to the phase of the drive signal of the first reference element Q4A.
- a virtual diagonal on time t2a in which Q1B virtual on and Q2A on based on the Q1B virtual driving signal overlap is also equal to the virtual diagonal on time t2.
- FIGS. 4 to 13 Current paths corresponding to the gate patterns shown in FIG. 3 are shown in FIGS. 4 to 13 correspond to periods B + to J + and period A + in FIG. 3 in order.
- the operation of the battery charge / discharge device 100 within one cycle will be described based on FIG. 3 and FIGS.
- the voltage of the battery 2 is higher than the voltage generated in the second winding 3 b, and power is transmitted from the DC power supply 1 to the battery 2.
- the description starts from the period B +.
- the period B + in the first switching circuit 5, since Q4A and Q3B are turned on and the two diagonal elements are conducted, energy is transmitted from the DC power supply 1 side via Q4A and Q3B.
- the polarity of the current is reversed with respect to a period J + and a period A + described later. Since Q2A is turned on in the second switching circuit 8, the current flows back through the diode of Q1A and Q2A. Therefore, the period B + is a period in which the first reactor 9 and the second reactor 10 are excited (FIG. 4).
- the period C + energy is transmitted from the DC power supply 1 side in the first switching circuit 5 because Q4A and Q3B are on and the two diagonal elements are conducted.
- Q2A is turned off, current flows from the Q1A diode through the Q2B diode, and power is transmitted to the battery 2 side. Therefore, the period C + is a period in which the excitation energy of the first reactor 9 and the second reactor 10 is transmitted to the battery 2 side (FIG. 5).
- the period D + energy is transmitted from the DC power source 1 side in the first switching circuit 5 because Q4A and Q3B are on and the two diagonal elements are conducted.
- Q2B is turned on, current flows from the Q1A diode via the Q2B or Q2B diode, and power is transmitted to the battery 2 side. Therefore, the period D + is a period in which the excitation energy of the first reactor 9 and the second reactor 10 is transmitted to the battery 2 side (FIG. 6).
- the period E + in the first switching circuit 5, Q4A is turned off, and the current circulates through the Q4B diode and Q3B.
- the second switching circuit 8 since the Q1A diode and the Q2B or Q2B diode are turned on, the return current gradually decreases depending on the voltage of the battery 2.
- the reflux current becomes 0 [A]
- the diode of Q1A is turned off and maintains 0 [A]. Therefore, the period E + is a period during which the reflux current decreases (FIG. 7).
- the period F + in the first switching circuit 5, Q3B is turned off and Q4B is turned on. Since Q4B is turned on from the diode conduction state, ZVS (zero voltage switching) is established.
- the return current is 0 [A] or more in the period E +, that is, when the current remains, the current is regenerated to the DC power supply 1 side via the Q4B or Q4B diode and the Q3A diode.
- the second switching circuit 8 since the diode of Q1A and the diode of Q2B or Q2B are on, the return current gradually decreases due to (voltage of DC power supply 1 ⁇ voltage of battery 2).
- the reflux current becomes 0 [A]
- the diode of Q1A is turned off and maintains 0 [A]. Therefore, the period F is a period during which the return current decreases (FIG. 8).
- the period G + in the first switching circuit 5, Q3A is turned on, Q3A and Q4B are on, and the two diagonal elements are conducted, so that energy is transmitted from the DC power supply 1 side via Q3A and Q4B. At this time, the polarity of the current is reversed from the period F +. In the second switching circuit 8, since Q2B is on, the current flows back through the Q1B diode and Q2B. Therefore, the period G + is a period for exciting the first reactor 9 and the second reactor 10 (FIG. 9).
- the period H + in the first switching circuit 5, since Q3A and Q4B are on and the two diagonal elements are conducted, energy is transmitted from the DC power supply 1 side via Q3A and Q4B.
- Q2B On the second switching circuit 8 side, Q2B is turned off, current flows through the Q2A diode and the Q1B diode, and power is transmitted to the battery 2 side. Therefore, the period H + is a period during which the excitation energy of the first reactor 9 and the second reactor 10 is transmitted to the battery 2 side (FIG. 10).
- the period I + is a period in which the excitation energy of the first reactor 9 and the second reactor 10 is transmitted to the battery 2 side (FIG. 11).
- the period J + in the first switching circuit 5, Q4B is turned off, and the current circulates through the Q4A diode and Q3A.
- the second switching circuit 8 since the Q2A or Q2A diode and the Q1B diode are on, the return current gradually decreases with the voltage of the battery 2.
- the reflux current becomes 0 [A]
- the diode of Q1B is turned off and maintains 0 [A]. Therefore, the period J + is a period during which the reflux current decreases (FIG. 12).
- the period A + in the first switching circuit 5, Q3A is turned off and Q4A is turned on. Since Q4A is turned on from the diode conduction state, ZVS (zero voltage switching) is established.
- the period J + when the return current is 0 [A] or more, that is, when the current remains, the current is regenerated to the DC power supply 1 side via the Q4A or Q4A diode and the Q3B diode.
- the second switching circuit 8 since the diode of Q2A or Q2A and the diode of Q1B are on, the return current gradually decreases depending on (voltage of DC power supply 1 ⁇ voltage of battery 2).
- the reflux current becomes 0 [A]
- the diode of Q1B is turned off and maintains 0 [A]. Therefore, the period A + is a period during which the reflux current decreases (FIG. 13).
- the battery charge / discharge device 100 boosts the voltage generated in the second winding 3b of the transformer 3 and supplies power to the battery 2.
- the first switching circuit 5 When the voltage of the DC power supply 1 is VL, the first switching circuit 5 generates a positive pulse of the voltage VL at the diagonal on time t1 when Q4A and Q3B are simultaneously turned on, and the diagonal on time t1a when Q4B and Q3A are simultaneously turned on.
- a negative pulse of voltage ( ⁇ VL) is output to and applied to the first winding 3 a of the transformer 3.
- the voltage of ( ⁇ VL) ⁇ NB / NL is applied to the second winding 3b of the transformer 3 at this time. Is applied.
- periods (B +, G +) for exciting the second reactor 10 are provided within the diagonal on-time (t1, t1a) in which the voltage is applied to the transformer 3, that is, the second reactor.
- the step-up operation is performed using 10 as a step-up reactor.
- the switching of each semiconductor switching element Q in the first switching circuit 5 on the primary side of the transformer 3 is all zero voltage switching by the action of the capacitor 13 and the first reactor 9. Note that a part of the switching of the secondary side second switching circuit 8 is zero voltage switching.
- FIG. 14 is a diagram illustrating waveforms of the drive signals 21a and 21b of the semiconductor switching elements Q of the first switching circuit 5 and the second switching circuit 8 during the step-down charging of the battery charge / discharge device 100. Also in this case, periods A- to J- are provided for each of a plurality of gate patterns, which are combination patterns of drive signals, and the codes of the drive signals of Q4A, Q4B, Q3A, Q3B, Q2A, Q2B, Q1A, Q1B are shown. Is indicated by the symbol of each element for convenience. Similar to the step-up charging shown in FIG.
- the entire drive signal is generated with reference to the first bridge circuit (Q4A, Q4B) in the first switching circuit 5, and the second bridge in the second switching circuit 8 is generated.
- Q1A and Q1B of the circuits (Q1A and Q1B) are held in the off state.
- the three bridge circuits other than the second bridge circuit (Q1A, Q1B) are Q4A, Q3A, Q2A on the positive side (high voltage side) and Q4B, Q3B on the negative side (low voltage side) constituting each bridge circuit.
- Q2B are controlled at an on-time ratio of 50%, excluding the short-circuit prevention time td.
- phase shift amount ⁇ 1 first phase shift amount
- phase shift amount ⁇ 2 second phase shift amount of the driving signal of the corner element Q2B is determined according to the DUTY ratio D that is a control command.
- the phase shift amount ⁇ 1 and the phase shift amount ⁇ 2 are equal, and both phase shift amounts ⁇ 1 and ⁇ 2 change according to the DUTY ratio D.
- the diagonal on times t1 and t1a are determined by the phase shift amount ⁇ 1.
- the second bridge circuit (Q1A, Q1B) is assumed to have a drive signal equal to that of the first bridge circuit (Q4A, Q4B) as a virtual drive signal
- the above-described virtual diagonal on times t2, t2a are phase-shifted. It is determined by the quantity ⁇ 2.
- the diagonal on times t1 and t1a are equal to the virtual diagonal on times t2 and t2a.
- FIGS. 15 to 24 Current paths corresponding to the gate patterns shown in FIG. 14 are shown in FIGS. 15 to 24 correspond to periods D- to J- and periods A to C in FIG. 14, respectively.
- the operation of the battery charge / discharge device 100 within one cycle will be described. Note that the voltage of the battery 2 is lower than the voltage generated in the second winding 3 b, and power is transmitted from the DC power supply 1 to the battery 2. For convenience, the description starts from the period D-.
- the period D- in the first switching circuit 5, Q3B is turned on, Q4A and Q3B are turned on, and the two diagonal elements are conducted, so that energy is transmitted from the DC power supply 1 side.
- Q2B is turned on, current flows from the Q1A diode via the Q2B or Q2B diode, and power is transmitted to the battery 2 side. Therefore, the period D ⁇ is a period during which power is transmitted to the battery 2 (FIG. 15).
- the period E- in the first switching circuit 5, Q4A is turned off, and the current circulates through the Q4B diode and Q3B.
- the second switching circuit 8 since the Q1A diode and the Q2B or Q2B diode are turned on, the return current gradually decreases depending on the voltage of the battery 2.
- the reflux current becomes 0 [A]
- the diode of Q1A is turned off and maintains 0 [A]. Therefore, the period E ⁇ is a period during which the reflux current decreases (FIG. 16).
- the periods F ⁇ and G ⁇ are periods in which the reflux current decreases (FIGS. 17 and 18).
- the period H- in the first switching circuit 5, when Q3B is turned off and the return current is 0 [A] or more, that is, when the current remains, the DC power supply 1 is connected via the Q4B or Q4B diode and the Q3A diode. Current is regenerated to the side.
- Q2B In the second switching circuit 8, Q2B is turned off, but since the diode of Q1A and the diode of Q2B are turned on, the return current gradually decreases depending on (voltage of DC power supply 1 ⁇ voltage of battery 2).
- the reflux current becomes 0 [A]
- the diode of Q1A is turned off and maintains 0 [A]. Therefore, the period H ⁇ is a period during which the reflux current decreases (FIG. 19).
- the period I- in the first switching circuit 5, Q3A is turned on, Q3A and Q4B are turned on, and the two diagonal elements are turned on, so that energy is transmitted from the DC power supply 1 side through Q3A and Q4B. .
- the polarity of the current is reversed from the period H ⁇ .
- Q2A is turned on, current flows through the Q2A or Q2A diode and the Q1B diode, and power is transmitted to the battery 2 side. Therefore, the period I ⁇ is a period during which power is transmitted to the battery 2 side (FIG. 20).
- the period J- in the first switching circuit 5, Q4B is turned off, and the current circulates through the Q4A diode and Q3A.
- the second switching circuit 8 since the Q1B diode and the Q2A or Q2A diode are on, the return current gradually decreases with the voltage of the battery 2.
- the reflux current becomes 0 [A]
- the diode of Q1B is turned off and maintains 0 [A]. Therefore, the period J ⁇ is a period during which the reflux current decreases (FIG. 21).
- the period J- is a period during which the return current decreases (FIGS. 22 and 23).
- the period C- in the first switching circuit 5, Q3A is turned off, and when the return current is 0 [A] or more, that is, when the current remains, the DC power source 1 is connected via the Q4A or Q4A diode and the Q3B diode. Current is regenerated to the side.
- Q2A is turned off, but since the diode of Q2A and the diode of Q1B are turned on, the return current gradually decreases depending on (voltage of DC power supply 1 ⁇ voltage of battery 2).
- the reflux current becomes 0 [A]
- the diode of Q1B is turned off and maintains 0 [A]. Therefore, the period C- is a period during which the reflux current decreases (FIG. 24).
- the battery charge / discharge device 100 steps down the voltage generated in the second winding 3b of the transformer 3 and supplies power to the battery 2.
- the switching of each semiconductor switching element Q in the first switching circuit 5 on the primary side of the transformer 3 is all zero voltage switching by the action of the capacitor 13 and the first reactor 9. Note that a part of the switching of the secondary side second switching circuit 8 is zero voltage switching.
- FIG. 25 is a control block diagram when the battery charging / discharging device 100 transmits power from the battery 2 to the DC power source 1, that is, when the battery 2 is discharged.
- the battery charging / discharging device 100 outputs to the DC power source 1, and the voltage v of the first smoothing capacitor 4 is detected as an output voltage and input to the control circuit 20.
- the subtractor 32 subtracts the input output voltage v from the output voltage command value v * to calculate a differential voltage
- the PI controller 33 calculates the calculated differential voltage.
- the charging current command value i * is calculated so as to approach 0.
- the subtractor 30 calculates the differential current value 30a by subtracting the input charging current i from the charging current command value i *, and the PI controller 31 performs feedback control so that the differential current value 30a approaches 0.
- the DUTY ratio D of the first switching circuit 5 and the second switching circuit 8 is determined, and the drive signals 21a and 21b of the respective semiconductor switching elements Q are generated.
- the charging current i and the charging current command value i * are negative in polarity because the reverse operation is performed when power is supplied from the DC power supply 1.
- the second smoothing capacitor 7 connected in parallel to the battery 2 has the same DC voltage as the voltage of the battery 2.
- FIG. 26 is a diagram illustrating waveforms of the drive signals 21a and 21b of the semiconductor switching elements Q of the first switching circuit 5 and the second switching circuit 8 during the step-down discharge of the battery charge / discharge device 100.
- FIG. 27 is a diagram showing waveforms of drive signals 21 a and 21 b of the semiconductor switching elements Q of the first switching circuit 5 and the second switching circuit 8 during the boosting discharge of the battery charge / discharge device 100.
- the reverse operation at the time of step-down charging is performed, and the driving signal of the first switching circuit 5 and the driving signal of the second switching circuit 8 at the time of step-down charging are switched. It is a thing.
- the operations in the periods AA- to JJ- are the same as those obtained by reversing the first switching circuit 5 and the second switching circuit 8 in the periods A- to J- during the step-down charging.
- the boosting discharge of the battery charging / discharging device 100 as shown in FIG. 27, the reverse operation at the time of boosting charging is performed, and the driving signal of the first switching circuit 5 and the driving signal of the second switching circuit 8 at the time of boosting charging are switched. It is a thing.
- the operation in each period AA + to JJ + is the same as that in which the first switching circuit 5 and the second switching circuit 8 in each period A + to J + during boost charge are reversed.
- the second switching circuit 8 When the voltage of the battery 2 is VB, the second switching circuit 8 generates a positive pulse of the voltage VB at the diagonal on time t3 when Q1A (second reference element) and Q2B (second diagonal element) are simultaneously turned on. A negative pulse of voltage ( ⁇ VB) is output at the diagonal on time t3a when Q1B and Q2A are simultaneously turned on, and is applied to the second winding 3b of the transformer 3. Assuming that the winding ratio between the first winding 3a and the second winding 3b of the transformer 3 is NL: NB, the voltage of ( ⁇ VB) ⁇ NL / NB is applied to the first winding 3a of the transformer 3 at this time. Is applied. In the step-down discharge shown in FIG.
- the voltage of the DC power source 1 is lower than the voltage generated in the first winding 3a. In the step-up discharge shown in FIG. 27, the voltage of the DC power source 1 is generated in the first winding 3a. Power is transmitted from the battery 2 to the DC power source 1 in both cases.
- the first switching circuit 5 and the second switching circuit 8 are controlled as follows.
- the entire drive signal is generated with reference to the second bridge circuit (Q1A, Q1B) in the second switching circuit 8.
- Q4A and Q4B of the first bridge circuits (Q4A and Q4B) in the first switching circuit 5 are held in the off state.
- the three bridge circuits other than the first bridge circuit (Q4A, Q4B) are Q1A, Q2A, Q3A on the positive side (high voltage side) and Q1B, Q2B on the negative side (low voltage side) constituting each bridge circuit.
- the Q3B is controlled at an on-time ratio of 50%, excluding the short-circuit prevention time td.
- the control circuit 20 switches each semiconductor switching element Q of the second switching circuit 8 on the power transmission side, the voltage of the capacitor 13 connected in parallel to each semiconductor switching element Q during the short-circuit prevention time td. Increases to the voltage of the second smoothing capacitor 7 or decreases to near zero voltage to perform zero voltage switching.
- phase shift amount ⁇ 3 (third phase shift amount) of the drive signal of the second diagonal element Q2B with respect to the phase of the drive signal of the second reference element Q1A and the first pair with respect to the phase of the drive signal of the second reference element Q1A
- the phase shift amount ⁇ 4 (fourth phase shift amount) of the drive signal of the corner element Q3B is determined according to the DUTY ratio D that is a control command. That is, the phase shift amounts ⁇ 3 and ⁇ 4 are controlled according to the DUTY ratio D.
- the phase shift amount ⁇ 3 and the phase shift amount ⁇ 4 are equal, and both phase shift amounts ⁇ 3 and ⁇ 4 change according to the DUTY ratio D.
- boost discharge shown in FIG. 27 the phase shift amount ⁇ 3 is kept to a minimum, and the phase shift amount ⁇ 4 changes according to the DUTY ratio.
- the diagonal on time t3 when Q1A and Q2B are simultaneously turned on is determined by the phase shift amount ⁇ 3, and the diagonal on time t3a when Q1B and Q2A are simultaneously turned on is also diagonally on.
- the control circuit 20 assumes a driving signal equal to the second bridge circuit (Q1A, Q1B) as a virtual driving signal for the first bridge circuit (Q4A, Q4B), and the virtual driving signal of Q4A by the virtual driving signal of Q4A.
- a period in which ON and Q3B are overlapped is defined as a virtual diagonal ON time t4.
- This virtual diagonal on time t4 is determined by the phase shift amount ⁇ 4.
- a virtual diagonal on time t4a in which Q4B virtual on and Q3A on based on the Q4B virtual driving signal overlap is also equal to the virtual diagonal on time t4.
- the battery charging / discharging device 100 performs bidirectional power transmission with four control modes of step-up charging, step-down charging, step-down discharging, and step-up discharging.
- charging which is power transmission from the DC power source 1 to the battery 2
- the phase shift amount ⁇ 2 of the drive signal of the diagonal element Q2B is controlled according to the DUTY ratio D.
- phase shift amount ⁇ 3 of the drive signal of the second diagonal element Q2B with respect to the phase of the drive signal of the second reference element Q1A and the first diagonal element Q3B is controlled according to the DUTY ratio D.
- FIG. 28 shows phase shift amounts ⁇ 1 to ⁇ 4 according to the DUTY ratio D, diagonal on times t1 and t3, and virtual diagonal on times t2 and t4.
- the DUTY ratio D is determined according to the transmission power. In this case, the power in the charging direction is positive.
- the phase shift amount ⁇ 1 during charging and the phase shift amount ⁇ 4 during discharging are both the phase shift amount of the first diagonal element Q3B, and are therefore described with the same solid line.
- the phase shift amount ⁇ 2 at the time of charging and the phase shift amount ⁇ 3 at the time of discharging are both the phase shift amount of the second diagonal element Q2B, and are therefore described with the same dotted line.
- the diagonal on-time t1 and the virtual diagonal on-time t4 are continuously described with the same solid line
- the virtual diagonal on-time t2 and the diagonal on-time t3 are continuously described with the same dotted line.
- tmax the maximum on-time tmax is set based on the short-circuit prevention time td required for each semiconductor switching element Q of the first switching circuit 5 to perform zero voltage switching.
- the phase shift amount ⁇ 1 of the drive signal of Q3B with respect to the phase of the drive signal of Q4A is the minimum and equal to the short-circuit prevention time td.
- the phase shift amount ⁇ 2 of the drive signal of the second diagonal element Q2B with respect to the phase of the drive signal of Q4A is a value not less than the phase shift amount ⁇ 1, and both the phase shift amounts ⁇ 1 and ⁇ 2 are minimum (short-circuit prevention time td).
- the first reference point 22 is the starting point. Then, when the DUTY ratio D increases, the control circuit 20 keeps the phase shift amount ⁇ 1 to the minimum and increases the phase shift amount ⁇ 2.
- the diagonal on time t1 and the virtual diagonal on time t2 are both points 22a at which the maximum on time tmax is reached. . Then, when the DUTY ratio D increases from the point 22a as a starting point, the control circuit 20 maintains the diagonal on time t1 at the maximum on time tmax and reduces the virtual diagonal on time t2.
- the phase shift amount ⁇ 1 and the phase shift amount ⁇ 2 are equal, and both phase shift amounts ⁇ 1 and ⁇ 2 change according to the DUTY ratio D.
- the control circuit 20 maximizes the phase shift amounts ⁇ 1 and ⁇ 2 when the DUTY ratio D is 0, and decreases both the phase shift amounts ⁇ 1 and ⁇ 2 as the DUTY ratio D increases.
- the diagonal on time t1 and the virtual diagonal on time t2 increase.
- control circuit 20 controls the first switching circuit 5 from the control in which the second bridge (Q1A, Q1B) in the second switching circuit 8 is held in the off state when the phase shift amounts ⁇ 1, ⁇ 2 are both maximum.
- the power transmission direction is switched by switching to the control for holding one bridge (Q4A, Q4B) in the off state.
- the diagonal on-time t1 and the virtual diagonal on-time t2 are both minimum, that is, when there is no power transmission, so that smooth switching is possible without causing the influence of switching.
- the control circuit 20 is diagonally turned on so that the period during which the voltage is applied to the second winding 3 b of the transformer 3 is maximized.
- the phase shift amount ⁇ 3 of the drive signal of Q2B with respect to the phase of the drive signal of Q1A is the minimum (short circuit prevention time td).
- the phase shift amount ⁇ 4 of the Q3B drive signal with respect to the phase of the Q1A drive signal is equal to or greater than the phase shift amount ⁇ 3.
- the control circuit 20 starts from the second reference point 23 where the phase shift amounts ⁇ 3 and ⁇ 4 are both minimum (short-circuit prevention time td), and the phase shift occurs when the discharge power increases and the DUTY ratio D increases in the negative direction.
- the amount ⁇ 3 is kept to a minimum and the phase shift amount ⁇ 4 is increased.
- the diagonal on-time t3 and the virtual diagonal on-time t4 are both points 23a where the maximum on-time tmax is reached. . Then, when the DUTY ratio D increases in the negative direction starting from the point 23a, the control circuit 20 maintains the diagonal on-time t3 at the maximum on-time tmax and reduces the virtual diagonal on-time t4.
- phase shift amount ⁇ 3 and the phase shift amount ⁇ 4 are equal, and both phase shift amounts ⁇ 3 and ⁇ 4 change according to the DUTY ratio D.
- phase shift amounts ⁇ 3 and ⁇ 4 are maximum, both the diagonal on time t3 and the virtual diagonal on time t4 are minimum, and there is no power transmission.
- the phase shift amounts ⁇ 3 and ⁇ 4 are maximum when the DUTY ratio is 0, and the control circuit 20 reduces both the phase shift amounts ⁇ 3 and ⁇ 4 when the DUTY ratio D increases in the negative direction.
- the diagonal on time t3 and the virtual diagonal on time t4 increase.
- control circuit 20 controls the first bridge (Q4A, Q4B) of the first switching circuit 5 to be in the off state when both the phase shift amounts ⁇ 3, ⁇ 4 are the maximum, so that the second switching circuit 8 in the second switching circuit 8
- the power transmission direction is switched by switching to the control in which the two bridges (Q1A, Q1B) are held in the off state. Since this switching is in a state where there is no power transmission, smooth switching is possible without causing the influence of switching.
- the minimum value of t1 to t4 is larger than 0 is shown in FIG. 28, it may be 0.
- the battery charging / discharging device 100 has a simple circuit configuration that is symmetrical with respect to the transformer 3, and the control circuit 20 controls the phase shift amounts ⁇ 1 to ⁇ 4 according to the DUTY ratio D, so that the power Bidirectional power conversion can be performed regardless of the transmission direction and regardless of the voltage of the DC power source 1 and the battery 2. Thereby, the battery charging / discharging device 100 can realize bidirectional power conversion operation with simple control.
- the battery charging / discharging device 100 can transmit power bidirectionally while preventing a reverse current of the transformer current in a wide voltage range with a simple circuit configuration, and can realize a low loss. Further, the peak value and effective value of the transformer current can be reduced, and the size reduction of the transformer 3 can be promoted.
- the control circuit 20 performs feedback control so that the differential current value 30a between the charging current i and the charging current command value i * approaches 0, whereby the first switching circuit 5
- the DUTY ratio D of the second switching circuit 8 is calculated to determine the phase shift amounts ⁇ 1 to ⁇ 4.
- FIG. 28 shows that the transmission power and the DUTY ratio D are in an ideal proportional relationship, and the change in the transmission power is caused by the changes in the diagonal on times t1 and t3 and the virtual diagonal on times t2 and t4. It corresponds.
- FIG. 29 is an example of a transition diagram of the charging current i when the diagonal on times t1 and t3 and the virtual diagonal on times t2 and t4 are changed, and is adjusted by correcting phase shift amounts ⁇ 1 to ⁇ 4, which will be described later.
- FIG. In this case, the voltage of the DC power source 1 and the voltage of the battery 2 are equal, the winding ratio of the first winding 3a and the second winding 3b of the transformer 3 is 1: 1, and the short-circuit prevention time td is 4 in the switching cycle. %.
- the short-circuit prevention time td is appropriately set based on the switching speed of the semiconductor switching element Q so as to prevent the semiconductor switching element Q from being short-circuited and perform zero voltage switching.
- the switching speed is generally described in a data sheet disclosed by a semiconductor manufacturer.
- the switching period of the semiconductor switching element Q is 1
- the diagonal on-times t1 and t3 and the virtual diagonal on-times t2 and t4 are normalized.
- the maximum value (maximum on time tmax) of the diagonal on times t1 and t3 and the virtual diagonal on times t2 and t4 is 0.42 except for the short-circuit prevention time td that is twice the half cycle.
- the charging current i does not change although the diagonal on-times t1 and t3 and the virtual diagonal on-times t2 and t4 are changed.
- the period of step-down charging in which the diagonal on-time t1 and the virtual diagonal on-time t2 are controlled to the same amount, and the diagonal on-time t3 and the virtual diagonal on-time t4 are controlled to the same amount.
- the period of step-down discharge When performing step-down charging from the DC power source 1 to the battery 2, the voltage generated in the second winding 3 b needs to be higher than the voltage of the battery 2.
- the voltage generated in the first winding 3 a needs to be higher than the voltage of the DC power supply 1.
- the voltage generated in the second winding 3b and the battery in step-down charging are the same.
- the voltage generated in the first winding 3a and the voltage of the DC power supply 1 are equal, so that a period in which the charging current i does not change occurs.
- FIG. 30 is a partially enlarged view in which the boosting charge period in FIG. 29 is enlarged.
- step-up charging the virtual diagonal on time t2 is changed while the diagonal on time t1 is kept at the maximum, but there is a period during which the charging current i does not change.
- FIG. 31 is a partially enlarged view in which the boosting discharge period in FIG. 29 is enlarged.
- step-up discharge the virtual diagonal on time t4 is changed while the diagonal on time t3 is kept at the maximum. In this case, there is also a period during which the charging current i does not change.
- FIG. 32 is a control block diagram of the control circuit 20.
- the control circuit 20 includes a subtractor 30, a PI controller 31, a drive signal generation unit 34, and a correction unit 35 as a second circuit that corrects the output of the PI controller 31 that is the first circuit.
- the subtractor 30 calculates the differential current value 30a between the charging current i and the charging current command value i *, and the PI controller 31 sets the differential current value 30a to 0. Feedback control is performed so as to approach each other, and the DUTY ratio D of the first switching circuit 5 and the second switching circuit 8 is calculated.
- the correction unit 35 determines the correction amount 35a based on the charging current i and the charging current command value i *.
- the drive signal generation unit 34 corrects the phase shift amounts ⁇ 1 to ⁇ 4 with the correction amount 35a, and generates the drive signals 21a and 21b for the respective semiconductor switching elements Q.
- the correction amount 35a calculated by the correction unit 35 may be the one that corrects the phase shift amounts ⁇ 1 to ⁇ 4 or the one that corrects the DUTY ratio D. As a result, the control result that is the output of the PI controller 31 is corrected.
- the phase shift amounts ⁇ 1 to ⁇ 4 are adjusted.
- the adjustment of the phase shift amounts ⁇ 1 to ⁇ 4 that is, the adjustment of the diagonal on times t1 and t3 and the virtual diagonal on times t2 and t4, depends on the four control modes of step-up charging, step-down charging, step-down discharging, and step-up discharging.
- the symmetry to be adjusted and the adjustment direction are determined, which will be described below based on the flowchart shown in FIG.
- the magnitude of the differential current value 30a increases beyond a predetermined value, or the magnitude of the differential current value 30a is When it is not reduced beyond the predetermined period, that is, when a response delay of the charging current i to the charging current command value i * is detected, it is determined that there is a difference (step S1), and the process proceeds to correction control.
- step S2 When the control mode is boost charging (step S2), if the differential current value 30a is positive, that is, if the charging current i is lower than the charging current command value i * (step S3), the virtual diagonal on time t2 is reduced. Adjust (step S4). In step S3, when the differential current value 30a is negative, that is, when the charging current i is higher than the charging current command value i *, the virtual diagonal on time t2 is adjusted to increase (step S5).
- step S6 When the control mode is step-down charging (step S6), when the differential current value 30a is positive, that is, when the charging current i is lower than the charging current command value i * (step S7), the diagonal on time t1 and the virtual diagonal on The time t2 is adjusted to increase by the same amount (step S8).
- step S7 when the differential current value 30a is negative, that is, when the charging current i is higher than the charging current command value i *, the diagonal on-time t1 and the virtual diagonal on-time t2 are adjusted to be reduced by the same amount. (Step S9).
- step S10 When the control mode is step-down discharge (step S10), when the differential current value 30a is positive, that is, when the charging current i is lower than the charging current command value i * (step S11), the diagonal on time t3 and the virtual diagonal on The time t4 is adjusted so as to be reduced by the same amount (step S12).
- step S11 when the differential current value 30a is negative, that is, when the charging current i is higher than the charging current command value i *, the diagonal on-time t3 and the virtual diagonal on-time t4 are adjusted to increase by the same amount. (Step S13).
- step S14 When the control mode is step-up discharge (step S14), when the differential current value 30a is positive, that is, when the charging current i is lower than the charging current command value i * (step S15), the virtual diagonal on time t4 is increased. Adjust (step S16). In step S15, when the differential current value 30a is negative, that is, when the charging current i is higher than the charging current command value i *, the virtual diagonal on-time t4 is adjusted to decrease (step S17).
- the control circuit 20 includes the correction unit 35, and performs correction control by detecting a response delay in control for causing the charging current i to follow the charging current command value i *. Therefore, in the control of the battery charging / discharging device 100, even if the charging current i does not change even if the phase shift amounts ⁇ 1 to ⁇ 4 are changed, the charging current command value i is quickly shifted to the outside of the region. * Can be followed. Further, the correction unit 35 operates not only in the region where the charging current i does not change, and improves the responsiveness in any case such as a sudden load change or a change in the charging current command value i *, and the charging current i is changed to the charging current.
- the first circuit that performs feedback control so that the differential current value 30a approaches 0 may use a control configuration other than the PI controller 31.
- the battery 2 is used as one DC power supply (second DC power supply), but the present invention is not limited to this. Furthermore, you may comprise both a 1st, 2nd DC power supply with a battery.
- FIG. 34 is a control block diagram of the control circuit 20 according to the second embodiment.
- the control circuit 20 includes a subtracter 30, a PI controller 31, a drive signal generation unit 34, and a correction circuit 41 as a second circuit that corrects the output of the PI controller 31 that is the first circuit.
- the apparatus and the control configuration other than the correction control using the correction circuit 41 are the same as those in the first embodiment.
- the correction circuit 41 includes subtractors 36 and 39, a PI controller 37, a target mathematical model 38, and a correction calculation unit 40, and determines a correction amount 40a based on the charging current i and the charging current command value i *.
- the target mathematical model 38 is a mathematical model of the ideal operation in which the battery charging / discharging device 100 monotonously increases the current (charging current i) with respect to the DUTY ratio, that is, the operational targets of the first and second switching circuits 5 and 8. It is a model.
- the target mathematical model 38 calculates an estimated current value ia obtained by estimating the target charging current i using the DUTY ratio Da as an input.
- the subtractor 36 subtracts the estimated current value ia calculated by the target mathematical model 38 from the charging current command value i * to calculate a difference, and the PI controller 37 causes the difference to approach zero.
- the DUTY ratio Da is calculated by performing feedback control.
- the calculated DUTY ratio Da is input to the target mathematical model 38, and the target mathematical model 38 calculates the estimated current value ia.
- the estimated current value ia is input to the two subtractors 36 and 39, and the subtractor 39 subtracts the charging current i from the estimated current value ia to calculate an estimated deviation 39a that is a difference.
- the correction calculation unit 40 determines the correction amount 40a based on the estimated deviation 39a.
- the difference current value 30a between the charging current i and the charging current command value i * is calculated by the subtractor 30, and the PI controller 31 performs feedback control so that the difference current value 30a approaches 0, thereby performing the first switching.
- the DUTY ratio D of the circuit 5 and the second switching circuit 8 is calculated.
- the drive signal generation unit 34 adjusts the phase shift amounts ⁇ 1 to ⁇ 4 by correcting the phase shift amounts ⁇ 1 to ⁇ 4, and drives the drive signal 21a of each semiconductor switching element Q. , 21b is generated.
- the correction circuit 41 calculates an estimated current value ia based on the charging current command value i * using the target mathematical model 38, and calculates a difference (estimated deviation) between the charging current i and the estimated current value ia.
- the phase shift amounts ⁇ 1 to ⁇ 4 are adjusted by the correction amount 40a determined from 39a). For this reason, in the control of the battery charge / discharge device 100, the charging current i can be quickly shifted from the region where the charging current i does not change even if the phase shift amounts ⁇ 1 to ⁇ 4 are changed to follow the charging current command value i *. it can.
- the correction control is performed based on the differential current value 30a. Therefore, if the differential current value 30a is the same, the control is the same for any change in the charging current i and the charging current command value i *. However, in this embodiment, since the estimated current value ia changes only in accordance with the charging current command value i *, the control is suitable for each.
- FIG. 35 is a control block diagram of the control circuit 20 according to the third embodiment.
- the control circuit 20 includes an adder / subtractor 30b, a PI controller 31, a drive signal generator 34, and a correction circuit 41a as a second circuit for correcting the input of the PI controller 31.
- the apparatus and the control configuration other than the correction control using the correction circuit 41a are the same as those in the first embodiment.
- the correction circuit 41a includes subtractors 36 and 39, a PI controller 37, and a target mathematical model 38, and based on the charging current command value i * using the target mathematical model 38 as in the second embodiment.
- An estimated current value ia is calculated, and an estimated deviation 39a that is a difference between the charging current i and the estimated current value ia is determined.
- the adder / subtractor 30b adds the charging current command value i * and the estimated deviation 39a and subtracts the charging current i to calculate the differential current value 30c, and the PI controller 31 provides feedback so that the differential current value 30c approaches zero.
- the DUTY ratio D of the first switching circuit 5 and the second switching circuit 8 is calculated.
- the drive signal generator 34 determines the phase shift amounts ⁇ 1 to ⁇ 4 based on the DUTY ratio D, and generates the drive signals 21a and 21b for the respective semiconductor switching elements Q.
- the correction circuit 41a calculates an estimated current value ia based on the charging current command value i * using the target mathematical model 38, and estimates the difference between the charging current i and the estimated current value ia.
- the difference current value that is the input of the PI controller 31 is corrected using the deviation 39a as a correction amount. That is, the difference current value 30a between the charging current i and the charging current command value i * is added with the estimated deviation 39a to derive a corrected difference current value 30c.
- the phase shift amounts ⁇ 1 to ⁇ 4 are determined by feedback control of the corrected differential current value 30c. Therefore, the phase shift amounts ⁇ 1 to ⁇ 4 are adjusted by the correction control.
- the charging current i can be quickly shifted from the region where the charging current i does not change even if the phase shift amounts ⁇ 1 to ⁇ 4 are changed to follow the charging current command value i *. it can. Further, in any case such as a sudden load change or a change in the charging current command value i *, the responsiveness is improved, and the charging current i is made to quickly follow the charging current command value i *. An effect is obtained. Further, since the estimated deviation 39a is a current value, the differential current value 30c can be calculated by a simple correction calculation, and the phase shift amounts ⁇ 1 to ⁇ 4 can be adjusted.
- the estimated deviation 39a may be input to the adder / subtractor 30b via the equalizer 42.
- the gain characteristic of the equalizer 42 is set to be larger than one, and when there is no margin in the stability of the feedback system, the phase characteristic of the equalizer 42 is advanced and the phase is advanced. Set to. Thereby, the controllability of the correction control can be improved.
- FIG. 37 is a diagram showing a circuit configuration of a battery charger 100A as a DC / DC converter according to Embodiment 4 of the present invention.
- the battery charging device 100A charges the battery 2 from the DC power source 1 by power conversion with step-up and step-down.
- the battery charging device 100A includes a high-frequency transformer 3 (hereinafter simply referred to as a transformer 3) as an insulated transformer, a first smoothing capacitor 4 connected in parallel to the DC power source 1, and a first converter unit.
- the battery charging device 100A includes a control circuit 20A that controls the first switching circuit 5A and the second switching circuit 8A.
- the first switching circuit 5A includes a plurality of semiconductor switching elements Q4A, Q4B, Q3A, Q3B (hereinafter simply referred to as Q4A, Q4B, Q3A, Q3B, or semiconductor switching elements) each composed of an IGBT, a MOSFET, or the like with diodes 12 connected in antiparallel.
- the DC side is connected to the first smoothing capacitor 4 and the AC side is connected to the first winding 3a of the transformer 3 to perform power conversion between DC / AC.
- the second switching circuit 8A includes a plurality of semiconductor switching elements Q2A, Q2B, Q1A, Q1B (hereinafter simply referred to as Q2A, Q2B, Q1A, Q1B, or semiconductor switching element Q) each composed of an IGBT, a MOSFET, or the like with diodes 12 connected in antiparallel.
- the DC side is connected to the second smoothing capacitor 7 and the AC side is connected to the second winding 3b of the transformer 3 to perform DC / AC power conversion.
- the second reactor 10 is connected to an AC input / output line between the semiconductor switching element Q and the transformer 3, and the second reactor 10 and the second winding 3b are connected in series. Further, the reactor 11 is connected to the DC side of the second switching circuit 8A.
- a current sensor (not shown) is installed between the second smoothing capacitor 7 and the battery 2 to detect the current flowing through the reactor 11 as the charging current i of the battery 2 (current with the arrow direction being positive). The sensed output is input to the control circuit 20A. Further, a voltage sensor (not shown) for detecting the voltage v of the first smoothing capacitor 4 is installed, and the sensed output is input to the control circuit 20A. The control circuit 20A generates drive signals 21a and 21b for switching control of the semiconductor switching elements Q of the first switching circuit 5A and the second switching circuit 8A based on the values of the input charging current i and voltage v. The first switching circuit 5A and the second switching circuit 8A are driven and controlled. A current sensor that detects the charging current i of the battery 2 may be provided at a position closer to the second switching circuit 8A than the second smoothing capacitor 7.
- Control and operation at the time of step-up charging and step-down charging of the battery charging device 100A are the control operations in the same phase shift method as in the first embodiment.
- the control block diagram of the control circuit 20A is the same as that shown in FIG. 32 used in the first embodiment.
- the fourth embodiment performs one-way power transmission only for charging.
- capacitors are not arranged in parallel in each semiconductor switching element Q, and the first reactor is not connected to the AC input / output line of the first switching circuit 5A. For this reason, the switching of the first and second switching circuits 5A and 8A is not zero voltage switching.
- the battery charging device 100A performs power transmission from the DC power source 1 to the battery 2 with two control modes of step-up charging and step-down charging.
- the control circuit 20A controls the phase shift amount ⁇ 1 of the drive signal of the first diagonal element Q3B relative to the phase of the drive signal of the first reference element Q4A and the drive signal of the second diagonal element Q2B.
- the phase shift amount ⁇ 2 is controlled according to the DUTY ratio ( ⁇ 0).
- the control circuit 20A includes a correction unit 35 so that when the phase shift amounts ⁇ 1 and ⁇ 2 are determined from the calculated DUTY ratio D, the responsiveness of the charging current i to the charging current command value i * is improved.
- the phase shift amounts ⁇ 1 and ⁇ 2 are adjusted by correction. In this case, the transition of the charging current i during the charge control is the same as that during the charge control in the first embodiment.
- the correction unit 35 operates not only in the region where the charging current i does not change, and improves the responsiveness in any case such as a sudden load change or a change in the charging current command value i *, and the charging current i is changed to the charging current. Immediately follow the command value i *.
- the bus voltage of the first and second switching circuits 5 and 8 can be stabilized, and the battery charger 100A can be stably operated with high reliability.
- the bidirectional control shown in the first embodiment is applied in one direction, but the second and third embodiments can be similarly applied.
- FIG. 38 shows a circuit configuration of a battery charger 100B as a DC / DC converter according to Embodiment 5 of the present invention.
- a capacitor 13 is connected in parallel to each semiconductor switching element Q of the first switching circuit 5, and a first reactor 9 is connected to the AC input / output line of the first switching circuit 5.
- the control circuit 20B uses the capacitor 13 and the first reactor 9 in the first switching circuit 5 by controlling the first and second phase shift amounts ⁇ 1 and ⁇ 2 according to the DUTY ratio ( ⁇ 0).
- the semiconductor switching elements Q in the first switching circuit 5 are controlled so as to perform zero voltage switching.
- Other configurations and controls are the same as those in the fourth embodiment.
- the same effect as in the fourth embodiment can be obtained, and switching loss can be reduced by switching the first switching circuit 5 to zero voltage.
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Abstract
Description
上記制御回路は、上記差分電流値を小さくするようにフィードバック制御する第1回路と、上記電流検出値および上記電流指令値に基づいて上記第1回路の制御入出力の一方を補正する第2回路とを備える。
上記制御回路は、上記第1直流電源から上記第2直流電源への第1電力伝送において、上記第1コンバータ部の一方のブリッジ回路である第1ブリッジ回路の正側/負側のいずれか一方の半導体スイッチング素子を第1基準素子とし、上記第2コンバータ部内の1つのブリッジ回路である第2ブリッジ回路の正側/負側のいずれか一方の半導体スイッチング素子を第2基準素子として、上記第1、第2コンバータ部内の4つの上記ブリッジ回路の内、上記第2ブリッジ回路を構成する各半導体スイッチング素子を全てオフ状態にし、他の3つのブリッジ回路について、正側の半導体スイッチング素子と負側の半導体スイッチング素子とを同じオン時間比率とし、上記第1基準素子と該第1基準素子と対角の関係にある第1対角素子としての半導体スイッチング素子との間の駆動信号の位相シフト量である第1位相シフト量、および、上記第1基準素子と、上記第2基準素子と対角の関係にある第2対角素子としての半導体スイッチング素子との間の駆動信号の位相シフト量である第2位相シフト量を制御する。そして、上記第2回路は、上記補正により上記第1、第2位相シフト量を調整して上記電流検出値を上記電流指令値に追従させるものである。
以下、この発明の実施の形態1について説明する。
図1は、この発明の実施の形態1によるDC/DCコンバータとしてのバッテリ充放電装置100の回路構成を示した図である。図に示すように、バッテリ充放電装置100は、第1直流電源としての直流電源1と第2直流電源としてのバッテリ2との間で双方向の電力変換によるバッテリ2の充放電を行うものである。
バッテリ充放電装置100は、絶縁されたトランスとしての高周波トランス3(以下、単にトランス3と称す)と、直流電源1に並列に接続された第1平滑コンデンサ4と、第1コンバータ部としての第1スイッチング回路5と、バッテリ2に並列に接続された第2平滑コンデンサ7と、第2コンバータ部としての第2スイッチング回路8と、第1スイッチング回路5、第2スイッチング回路8の各交流入出力線に接続された第1リアクトル9、第2リアクトル10とを備える。またバッテリ充放電装置100は、第1スイッチング回路5および第2スイッチング回路8を制御する制御回路20を備える。
なお、バッテリ2の充電電流iを検出する電流センサは、第2平滑コンデンサ7より第2スイッチング回路8側の位置に設けても良い。
なお、充電制御による電力伝送を第1電力伝送、放電制御による電力伝送を第2電力伝送とする。
図2は、直流電源1からバッテリ2への電力伝送、即ちバッテリ2を充電する場合の制御ブロック図である。バッテリ充放電装置100の出力電流である充電電流iは検出されて制御回路20に入力される。なお、充電電流iの電流検出値を、便宜上、単に充電電流iと称す。図に示すように制御回路20では、減算器30が、入力された充電電流iを充電電流指令値i*から減算して差分電流値30aを演算し、第1回路としてのPI制御器31は、差分電流値30aを0に近づけるようにフィードバック制御することにより、第1スイッチング回路5および第2スイッチング回路8の出力DUTY比D(以下、単にDUTY比Dと称す)を決定し、各半導体スイッチング素子Qの駆動信号21a、21bを生成する。
また、直流電源1に並列接続された第1平滑コンデンサ4の電圧は、直流電源1の電圧と同じ直流電圧となる。
この場合、第1スイッチング回路5内の一方のブリッジ回路である第1ブリッジ回路(Q4A,Q4B)を基準として、全体の駆動信号が生成される。第2スイッチング回路8内の一方のブリッジ回路である第2ブリッジ回路(Q1A,Q1B)のQ1A、Q1Bはオフ状態に保持される。
そして、第1基準素子Q4Aの駆動信号の位相に対する第1対角素子Q3Bの駆動信号の位相シフト量θ1(第1位相シフト量)と、第1基準素子Q4Aの駆動信号の位相に対する第2対角素子Q2Bの駆動信号の位相シフト量θ2(第2位相シフト量)とが、制御指令であるDUTY比Dに応じて決定される。即ち、位相シフト量θ1、θ2がDUTY比Dに応じて制御される。この位相シフト量θ1、θ2の制御についての詳細は後述するが、この場合、位相シフト量θ1が最小に保持され、位相シフト量θ2がDUTY比Dに応じて変化する。
以下、図3および図4~図13に基づいて、一周期内のバッテリ充放電装置100の動作を示す。なお、バッテリ2の電圧は、第2巻線3bに発生する電圧より高いものとし、直流電源1からバッテリ2へ電力伝送される。
便宜上、期間B+から説明していく。
直流電源1の電圧をVLとすると、第1スイッチング回路5は、Q4A、Q3Bが同時オンする対角オン時間t1に電圧VLの正のパルスを、Q4B、Q3Aが同時オンする対角オン時間t1aに電圧(-VL)の負のパルスを出力して、トランス3の第1巻線3aに印加する。トランス3の第1巻線3aと第2巻線3bとの巻線比をNL:NBとすると、この時、トランス3の第2巻線3bには、(±VL)×NB/NLの電圧が印加される。
また、トランス3の一次側の第1スイッチング回路5における各半導体スイッチング素子Qのスイッチングは、コンデンサ13および第1リアクトル9の作用で、全てゼロ電圧スイッチングとなる。なお、二次側の第2スイッチング回路8のスイッチングは、一部がゼロ電圧スイッチングとなる。
図3で示した昇圧充電時と同様に、第1スイッチング回路5内の第1ブリッジ回路(Q4A,Q4B)を基準として、全体の駆動信号が生成され、第2スイッチング回路8内の第2ブリッジ回路(Q1A,Q1B)のQ1A、Q1Bはオフ状態に保持される。また、第2ブリッジ回路(Q1A,Q1B)以外の3つのブリッジ回路は、各ブリッジ回路を構成する正側(高電圧側)のQ4A、Q3A、Q2Aおよび負側(低電圧側)のQ4B、Q3B、Q2Bは、短絡防止時間tdを除くと、それぞれ50%のオン時間比率で制御される。
以下、図14および図15~図24に基づいて、一周期内のバッテリ充放電装置100の動作を示す。なお、バッテリ2の電圧は、第2巻線3bに発生する電圧より低いものとし、直流電源1からバッテリ2へ電力伝送される。
便宜上、期間D-から説明していく。
また、トランス3の一次側の第1スイッチング回路5における各半導体スイッチング素子Qのスイッチングは、コンデンサ13および第1リアクトル9の作用で、全てゼロ電圧スイッチングとなる。なお、二次側の第2スイッチング回路8のスイッチングは、一部がゼロ電圧スイッチングとなる。
図25は、バッテリ充放電装置100がバッテリ2から直流電源1へ電力伝送する、即ちバッテリ2を放電する場合の制御ブロック図である。この場合、バッテリ充放電装置100は、直流電源1に出力しており、第1平滑コンデンサ4の電圧vが出力電圧として検出されて制御回路20に入力される。図に示すように、制御回路20では、減算器32が、入力された出力電圧vを出力電圧指令値v*から減算して差分電圧を演算し、PI制御器33は、演算された差分電圧を0に近づけるように充電電流指令値i*を演算する。
そして、減算器30が、入力された充電電流iを充電電流指令値i*から減算して差分電流値30aを演算し、PI制御器31は、差分電流値30aを0に近づけるようにフィードバック制御することにより、第1スイッチング回路5および第2スイッチング回路8のDUTY比Dを決定し、各半導体スイッチング素子Qの駆動信号21a、21bを生成する。
バッテリ充放電装置100の昇圧放電において、図27に示すように、昇圧充電時の逆方向動作となり、昇圧充電時における第1スイッチング回路5の駆動信号と、第2スイッチング回路8の駆動信号を入れ替えたものである。そして、各期間AA+~JJ+における動作についても、昇圧充電時の各期間A+~J+におけるにおける第1スイッチング回路5と第2スイッチング回路8とを逆にしたものと同様である。
図26に示す降圧放電では、直流電源1の電圧は第1巻線3aに発生する電圧より低いものとし、図27に示す昇圧放電では、直流電源1の電圧は第1巻線3aに発生する電圧より高いものとし、双方においてバッテリ2から直流電源1へ電力伝送される。
第2スイッチング回路8内の第2ブリッジ回路(Q1A,Q1B)を基準として、全体の駆動信号が生成される。第1スイッチング回路5内の第1ブリッジ回路(Q4A,Q4B)のQ4A、Q4Bはオフ状態に保持される。
また、第1ブリッジ回路(Q4A,Q4B)以外の3つのブリッジ回路は、各ブリッジ回路を構成する正側(高電圧側)のQ1A、Q2A、Q3Aおよび負側(低電圧側)のQ1B、Q2B、Q3Bは、短絡防止時間tdを除くと、それぞれ50%のオン時間比率で制御される。この場合、制御回路20は、電力を送る側の第2スイッチング回路8の各半導体スイッチング素子Qをスイッチングする際、短絡防止時間tdの間に各半導体スイッチング素子Qに並列接続されたコンデンサ13の電圧が第2平滑コンデンサ7の電圧まで増加する、あるいはゼロ電圧近辺まで低下するようにしてゼロ電圧スイッチングする。
図26に示す降圧放電では、位相シフト量θ3と位相シフト量θ4とは等しく、双方の位相シフト量θ3、θ4がDUTY比Dに応じて変化する。また、図27に示す昇圧放電では、位相シフト量θ3が最小に保持され、位相シフト量θ4がDUTY比に応じて変化する。
また、制御回路20は、第1ブリッジ回路(Q4A,Q4B)に対して、第2ブリッジ回路(Q1A,Q1B)と等しい駆動信号を仮想駆動信号として想定し、Q4Aの仮想駆動信号によるQ4Aの仮想オンとQ3Bのオンとが重なる期間を仮想対角オン時間t4とする。この仮想対角オン時間t4は、位相シフト量θ4により決まる。なお、Q4Bの仮想駆動信号によるQ4Bの仮想オンとQ3Aのオンとが重なる仮想対角オン時間t4aも、仮想対角オン時間t4と等しい。
なお、充電時の位相シフト量θ1と放電時の位相シフト量θ4とは、共に第1対角素子Q3Bの位相シフト量であるため、同様の実線で続けて記載した。また、充電時の位相シフト量θ2と放電時の位相シフト量θ3とは、共に第2対角素子Q2Bの位相シフト量であるため、同様の点線で続けて記載した。同様に、対角オン時間t1と仮想対角オン時間t4を同様の実線で続けて記載し、仮想対角オン時間t2と対角オン時間t3とを同様の点線で続けて記載した。
トランス3の第1巻線3aから第2巻線3bに電力伝送されて第2巻線3bに電圧が発生している期間は、Q4A、Q3Bの同時オンする対角オン時間t1、およびQ4B、Q3Aの同時オンする対角オン時間t1aである。
昇圧時には、この期間を出来る限り長くすることで、第1スイッチング回路5および第2スイッチング回路8の還流期間に関わる損失を低減することが可能となる。
この昇圧充電時には、トランス3に電圧印加されている対角オン時間(t1、t1a)内に、第2スイッチング回路8で第2リアクトル10を励磁する期間がある。即ち、Q4Aの駆動信号の位相に対する第2対角素子Q2Bの駆動信号の位相シフト量θ2は位相シフト量θ1以上の値で、位相シフト量θ1、θ2が共に最小(短絡防止時間td)となる第1基準点22を起点とする。そして、制御回路20は、DUTY比Dが増大すると位相シフト量θ1を最小に保持すると共に位相シフト量θ2を増大させる。
位相シフト量θ1、θ2が最大の時、対角オン時間t1および仮想対角オン時間t2は共に最小(例えば0)で、電力伝送がない状態である。降圧充電時では、制御回路20は、DUTY比Dが0のとき、位相シフト量θ1、θ2が最大で、DUTY比Dが増大すると位相シフト量θ1、θ2を共に低減させる。この時、対角オン時間t1および仮想対角オン時間t2は増大する。
位相シフト量θ3、θ4が最大の時、対角オン時間t3および仮想対角オン時間t4は共に最小となり、電力伝送がない状態である。降圧放電時では、DUTY比が0のとき位相シフト量θ3、θ4が最大で、制御回路20は、DUTY比Dが負方向に増大すると位相シフト量θ3、θ4を共に低減させる。この時、対角オン時間t3および仮想対角オン時間t4は増大する。
なお、t1~t4の最小値が0より大きい場合を図28に示しているが、0でも良い。
これによりトランス3に逆電流が流れることはなく、無効電力が抑制でき損失が低減できる。このため、バッテリ充放電装置100は、簡易な回路構成で、広い電圧範囲でトランス電流の逆流を防止しつつ双方向に電力伝送でき、低損失化を実現できる。また、トランス電流のピーク値および実効値を低減でき、トランス3の小型化を促進できる。
図29では、半導体スイッチング素子Qのスイッチング周期を1として、対角オン時間t1、t3、仮想対角オン時間t2、t4を正規化して図示した。対角オン時間t1、t3、仮想対角オン時間t2、t4の最大値(最大オン時間tmax)は、半周期から2倍の短絡防止時間tdを除き、0.42となる。
図30は、図29における昇圧充電の期間を拡大した部分拡大図である。昇圧充電においては、対角オン時間t1を最大に保持したまま仮想対角オン時間t2を変化させているが、充電電流iが変化しない期間が存在する。また、図31は、図29における昇圧放電の期間を拡大した部分拡大図である。昇圧放電においては、対角オン時間t3を最大に保持したまま仮想対角オン時間t4を変化させているが、この場合も充電電流iが変化しない期間が存在する。昇圧充電および昇圧放電においては、対角オン時間t1、t3と仮想対角オン時間t2、t4との差が小さい領域で、短絡防止時間tdに起因して充電電流iが変化しない期間が発生する。
図32は、制御回路20の制御ブロック図である。制御回路20は、減算器30、PI制御器31および駆動信号生成部34と、第1回路であるPI制御器31の出力を補正する第2回路としての補正部35とを備える。図2および図25を用いて説明したように、充電電流iと充電電流指令値i*との差分電流値30aを減算器30で演算し、PI制御器31が、差分電流値30aを0に近づけるようにフィードバック制御して、第1スイッチング回路5および第2スイッチング回路8のDUTY比Dを演算する。補正部35は、充電電流iと充電電流指令値i*とに基づいて補正量35aを決定する。駆動信号生成部34は、DUTY比Dに基づいて位相シフト量θ1~θ4を決定する際、補正量35aにより補正し、各半導体スイッチング素子Qの駆動信号21a、21bを生成する。
補正部35が演算する補正量35aは、位相シフト量θ1~θ4を補正するものでも、DUTY比Dを補正するものでも良く、結果的にPI制御器31の出力である制御結果が補正され、位相シフト量θ1~θ4は調整される。
まず、充電電流iが充電電流指令値i*に等しくなるように追従制御されている状態から、差分電流値30aの大きさが所定値を超えて増加する、あるいは差分電流値30aの大きさが所定期間を超えて低減されないとき、即ち、充電電流iの充電電流指令値i*への応答遅れを検出すると、差分ありと判定して(ステップS1)、補正制御に移行する。
制御モードが降圧充電の場合(ステップS6)、差分電流値30aが正、即ち、充電電流iが充電電流指令値i*より低いときは(ステップS7)、対角オン時間t1と仮想対角オン時間t2とを同量で増やすように調整する(ステップS8)。ステップS7において、差分電流値30aが負、即ち、充電電流iが充電電流指令値i*より高いときは、対角オン時間t1と仮想対角オン時間t2とを同量で減らすように調整する(ステップS9)。
制御モードが昇圧放電の場合(ステップS14)、差分電流値30aが正、即ち、充電電流iが充電電流指令値i*より低いときは(ステップS15)、仮想対角オン時間t4を増やすように調整する(ステップS16)。ステップS15において、差分電流値30aが負、即ち、充電電流iが充電電流指令値i*より高いときは、仮想対角オン時間t4を減らすように調整する(ステップS17)。
これにより、負荷急変時など充電動作と放電動作の切り替えが発生した場合に、速やかに充放電を切り替えることができ、第1、第2スイッチング回路5、8の母線電圧を安定化できる。このためバッテリ充放電装置100を高い信頼性で安定して運転させることができる。
なお、差分電流値30aを0に近づけるようにフィードバック制御する第1回路は、PI制御器31以外の制御構成を用いても良い。
次に、この発明の実施の形態2について説明する。
上記実施の形態1では、制御回路20は、充電電流iと充電電流指令値i*との差分電流値30aから応答遅れを検出して補正制御を行ったが、この実施の形態2では、バッテリ充放電装置100のモデルとしての目標数式モデル38を用いて補正制御を行う。
図34は、この実施の形態2による制御回路20の制御ブロック図である。制御回路20は、減算器30、PI制御器31および駆動信号生成部34と、第1回路であるPI制御器31の出力を補正する第2回路としての補正回路41とを備える。
なお、補正回路41を用いた補正制御以外の装置および制御の構成は、上記実施の形態1と同様である。
補正回路41では、減算器36が、目標数式モデル38が演算する推定電流値iaを充電電流指令値i*から減算して差分を算出し、該差分をPI制御器37にて0に近づけるようにフィードバック制御することによりDUTY比Daを演算する。演算されたDUTY比Daは目標数式モデル38に入力され、目標数式モデル38は推定電流値iaを演算する。推定電流値iaは2つの減算器36、39に入力され、減算器39は、充電電流iを推定電流値iaから減算して差分である推定偏差39aを算出する。そして補正演算部40は推定偏差39aに基づいて補正量40aを決定する。
また、上記実施の形態1では差分電流値30aに基づいて補正制御するため、差分電流値30aが同じであれば、充電電流i、充電電流指令値i*のいずれの変化でも同じ制御であったが、この実施の形態では、充電電流指令値i*に応じてのみ推定電流値iaが変化する為、それぞれに適した制御となる。
次に、この発明の実施の形態3について説明する。
上記実施の形態1、2では、第2回路(補正部35、補正回路41)は第1回路(PI制御器31)の制御結果を補正するものであったが、この実施の形態3では、PI制御器31の入力を補正する。
図35は、この実施の形態3による制御回路20の制御ブロック図である。制御回路20は、加減算器30b、PI制御器31および駆動信号生成部34と、PI制御器31の入力を補正する第2回路としての補正回路41aとを備える。
なお、補正回路41aを用いた補正制御以外の装置および制御の構成は、上記実施の形態1と同様である。
加減算器30bは、充電電流指令値i*と推定偏差39aを加算し充電電流iを減算して差分電流値30cを演算し、PI制御器31は、差分電流値30cを0に近づけるようにフィードバック制御することにより、第1スイッチング回路5および第2スイッチング回路8のDUTY比Dを演算する。駆動信号生成部34は、DUTY比Dに基づいて位相シフト量θ1~θ4を決定して各半導体スイッチング素子Qの駆動信号21a、21bを生成する。
このため、バッテリ充放電装置100の制御において、位相シフト量θ1~θ4を変化させても充電電流iが変化しない領域内から外側に速やかに移行させて充電電流指令値i*へ追従することができる。また、負荷急変や充電電流指令値i*の変更など、いずれの場合にも即応性を向上させ、充電電流iを充電電流指令値i*に速やかに追従させ、上記実施の形態2と同様の効果が得られる。
また、推定偏差39aは電流値であるため、容易な補正演算により差分電流値30cを演算でき、位相シフト量θ1~θ4が調整できる。
次に、この発明の実施の形態4について説明する。
図37は、この発明の実施の形態4によるDC/DCコンバータとしてのバッテリ充電装置100Aの回路構成を示す図である。図に示すように、バッテリ充電装置100Aは、昇圧および降圧を伴う電力変換により、直流電源1からバッテリ2へ充電を行うものである。
バッテリ充電装置100Aは、絶縁されたトランスとしての高周波トランス3(以下、単にトランス3と称す)と、直流電源1に並列に接続された第1平滑コンデンサ4と、第1コンバータ部としての第1スイッチング回路5Aと、バッテリ2に並列に接続された第2平滑コンデンサ7と、第2コンバータ部としての第2スイッチング回路8Aと、第2スイッチング回路8Aの交流入出力線に接続された第2リアクトル10とを備える。またバッテリ充電装置100Aは、第1スイッチング回路5Aおよび第2スイッチング回路8Aを制御する制御回路20Aを備える。
第2スイッチング回路8Aは、それぞれダイオード12が逆並列接続されたIGBTあるいはMOSFET等から成る複数の半導体スイッチング素子Q2A、Q2B、Q1A、Q1B(以下、単にQ2A、Q2B、Q1A、Q1Bあるいは半導体スイッチング素子Qと称す)を有するフルブリッジ回路で、直流側が第2平滑コンデンサ7に、交流側がトランス3の第2巻線3bに接続されて、直流/交流間の電力変換を行う。
また、第2スイッチング回路8Aは、半導体スイッチング素子Qとトランス3との間の交流入出力線に第2リアクトル10が接続され、第2リアクトル10と第2巻線3bとが直列接続される。さらに、第2スイッチング回路8Aの直流側にはリアクトル11が接続される。
なお、バッテリ2の充電電流iを検出する電流センサは、第2平滑コンデンサ7より第2スイッチング回路8A側の位置に設けても良い。
また、この実施の形態4では、各半導体スイッチング素子Qにはコンデンサを並列配置せず、第1スイッチング回路5Aの交流入出力線に第1リアクトルを接続させない。このため、第1、第2スイッチング回路5A、8Aのスイッチングは、ゼロ電圧スイッチングとはならない。
上記実施の形態4では、第1、第2スイッチング回路5A、8Aは、ゼロ電圧スイッチングに対応しないものを示したが、電力供給側の第1スイッチング回路のみゼロ電圧スイッチングさせても良い。
図38は、この発明の実施の形態5によるDC/DCコンバータとしてのバッテリ充電装置100Bの回路構成を示す図である。
その他の構成および制御は、上記実施の形態4と同様である。
この実施の形態5では、上記実施の形態4と同様の効果を得るとともに、第1スイッチング回路5をゼロ電圧スイッチングすることにより、スイッチング損失の低減が図れる。
Claims (11)
- 第1直流電源と第2直流電源との間の電力伝送を行うDC/DCコンバータにおいて、
トランスと、
それぞれ逆並列ダイオードが接続された複数の半導体スイッチング素子を備えた2つのブリッジ回路によるフルブリッジ回路で構成され、上記第1直流電源と上記トランスの第1巻線との間に接続される第1コンバータ部と、
それぞれ逆並列ダイオードが接続された複数の半導体スイッチング素子を備えた2つのブリッジ回路によるフルブリッジ回路で構成され、上記第2直流電源と上記トランスの第2巻線との間に接続される第2コンバータ部と、
上記第2コンバータ部の交流入出力線に接続された第2リアクトルと、
上記第2直流電源に入出力される電流の電流検出値と電流指令値との差分電流値に基づいて出力DUTY比を演算して、上記第1コンバータ部、第2コンバータ部内の上記各半導体スイッチング素子を駆動制御する制御回路とを備え、
上記制御回路は、
上記差分電流値を小さくするようにフィードバック制御する第1回路と、上記電流検出値および上記電流指令値に基づいて上記第1回路の制御入出力の一方を補正する第2回路とを備え、
上記第1直流電源から上記第2直流電源への第1電力伝送において、
上記第1コンバータ部の一方のブリッジ回路である第1ブリッジ回路の正側/負側のいずれか一方の半導体スイッチング素子を第1基準素子とし、上記第2コンバータ部内の1つのブリッジ回路である第2ブリッジ回路の正側/負側のいずれか一方の半導体スイッチング素子を第2基準素子として、上記第1、第2コンバータ部内の4つの上記ブリッジ回路の内、上記第2ブリッジ回路を構成する各半導体スイッチング素子を全てオフ状態にし、他の3つのブリッジ回路について、正側の半導体スイッチング素子と負側の半導体スイッチング素子とを同じオン時間比率とし、
上記第1基準素子と該第1基準素子と対角の関係にある第1対角素子としての半導体スイッチング素子との間の駆動信号の位相シフト量である第1位相シフト量、および、上記第1基準素子と、上記第2基準素子と対角の関係にある第2対角素子としての半導体スイッチング素子との間の駆動信号の位相シフト量である第2位相シフト量を制御し、
上記第2回路は、上記補正により上記第1、第2位相シフト量を調整して上記電流検出値を上記電流指令値に追従させる、
DC/DCコンバータ。 - 上記第1コンバータ部の交流入出力線に接続された第1リアクトルをさらに備え、
上記制御回路は、
上記第2直流電源から上記第1直流電源への第2電力伝送において、
上記第1、第2コンバータ部内の4つの上記ブリッジ回路の内、上記第1ブリッジ回路を構成する各半導体スイッチング素子を全てオフ状態にし、他の3つのブリッジ回路について、正側の半導体スイッチング素子と負側の半導体スイッチング素子とを同じオン時間比率とし、
上記第2基準素子と上記第2対角素子との間の駆動信号の位相シフト量である第3位相シフト量、および、上記第2基準素子と上記第1対角素子との間の駆動信号の位相シフト量である第4位相シフト量を制御し、
上記第2回路は、上記補正により上記第3、第4位相シフト量を調整して上記電流検出値を上記電流指令値に追従させる、
請求項1に記載のDC/DCコンバータ。 - 上記第1コンバータ部の交流入出力線に接続された第1リアクトルをさらに備え、
上記第1コンバータ部の上記複数の半導体スイッチング素子は、それぞれ並列コンデンサが接続されており、
上記制御回路は、
上記第1電力伝送において、上記第1、第2位相シフト量を制御することにより、上記並列コンデンサおよび上記第1リアクトルを利用して上記第1コンバータ部内の上記各半導体スイッチング素子がゼロ電圧スイッチングするように制御する、
請求項1に記載のDC/DCコンバータ。 - 上記第1コンバータ部および第2コンバータ部の上記複数の上記半導体スイッチング素子は、それぞれ並列コンデンサが接続されており、
上記制御回路は、
上記第1電力伝送において、上記第1、第2位相シフト量を制御することにより、上記第1コンバータ部内の上記並列コンデンサおよび上記第1リアクトルを利用して上記第1コンバータ部内の上記各半導体スイッチング素子がゼロ電圧スイッチングするように制御し、
上記第2電力伝送において、上記第3、第4位相シフト量を制御することにより、上記第2コンバータ部内の上記並列コンデンサおよび上記第2リアクトルを利用して上記第2コンバータ部内の上記各半導体スイッチング素子がゼロ電圧スイッチングするように制御する、
請求項2に記載のDC/DCコンバータ。 - 上記制御回路は、
上記第1電力伝送において、上記第1位相シフト量と上記第2位相シフト量とが共に最小になる点を第1基準点とし、上記第1直流電源から上記第2直流電源への第1伝送電力が上記第1基準点以下の第1期間では、上記第1、第2位相シフト量を同量に制御して、上記第1伝送電力が増大すると上記第1、第2位相シフト量を低減させ、上記第1伝送電力が上記第1基準点より大きい第2期間では、上記第1伝送電力が増大すると上記第1位相シフト量を最小に保持すると共に上記第2位相シフト量を増大させ、
上記第2電力伝送において、上記第3位相シフト量と上記第4位相シフト量とが共に最小になる点を第2基準点とし、上記第2直流電源から上記第1直流電源への第2伝送電力が上記第2基準点以下の第3期間では、上記第3、第4位相シフト量を同量に制御して、上記第2伝送電力が増大すると上記第3、第4位相シフト量を低減させ、上記第2伝送電力が上記第2基準点より大きい第4期間では、上記第2伝送電力が増大すると上記第3位相シフト量を最小に保持すると共に上記第4位相シフト量を増大させ、
上記第1電力伝送において上記第1期間で上記第1、第2位相シフト量が最大の時、および上記第2電力伝送において上記第3期間で上記第3、第4位相シフト量が最大の時に、上記第1電力伝送と上記第2電力伝送とを切り換える、
請求項4に記載のDC/DCコンバータ。 - 上記制御回路では、
上記第1回路は、上記差分電流値を小さくするように上記出力DUTY比を演算し、該出力DUTY比に基づいて上記第1~第4位相シフト量を演算し、
上記第2回路の補正により、上記第1電力伝送では上記第1期間に上記第1、第2位相シフト量を共に調整し、上記第2期間に上記第2位相シフト量のみを調整し、上記第2電力伝送では上記第3期間に上記第3、第4位相シフト量を共に調整し、上記第4期間に上記第4位相シフト量のみを調整する、
請求項5に記載のDC/DCコンバータ。 - 上記第2回路は、DUTY比に対して電流が単調増加して上記第1、第2コンバータ部の動作目標となるモデルを用い、上記電流指令値に基づいて上記電流の推定値である推定電流値を演算し、該推定電流値と上記電流検出値との差分である推定偏差を用いて補正する、
請求項2、請求項4から請求項6のいずれか1項に記載のDC/DCコンバータ。 - 上記第2回路は、上記推定電流値が上記電流指令値に追従するように上記DUTY比を演算して上記モデルを動作させる、
請求項7に記載のDC/DCコンバータ。 - 上記第2回路は、上記第1回路の制御出力である上記出力DUTY比を補正して上記第1~第4位相シフト量を調整する、
請求項2、請求項4から請求項8のいずれか1項に記載のDC/DCコンバータ。 - 上記第2回路は、上記第1回路の制御入力である上記差分電流値に上記推定偏差を加算して該差分電流値を補正することで上記第1~第4位相シフト量を調整する、
請求項7または請求項8に記載のDC/DCコンバータ。 - 上記制御回路は、
上記第1電力伝送において、上記第1基準素子の駆動信号と等しい仮想駆動信号を上記第2基準素子に対して想定し、上記第2位相シフト量を制御することで、上記第2基準素子の仮想オンと上記第2対角素子のオンとが重なる仮想対角オン時間を制御し、上記第1位相シフト量を制御することで、上記第1基準素子と上記第1対角素子とが共にオンする対角オン時間を制御し、
上記第2電力伝送において、上記第2基準素子の駆動信号と等しい仮想駆動信号を上記第1基準素子に対して想定し、上記第4位相シフト量を制御することで、上記第1基準素子の仮想オンと上記第1対角素子のオンとが重なる仮想対角オン時間を制御し、上記第3位相シフト量を制御することで、上記第2基準素子と上記第2対角素子とが共にオンする対角オン時間を制御する、
請求項2、請求項4から請求項10のいずれか1項に記載のDC/DCコンバータ。
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