WO2016111156A1 - Dc/dcコンバータ - Google Patents
Dc/dcコンバータ Download PDFInfo
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- WO2016111156A1 WO2016111156A1 PCT/JP2015/085676 JP2015085676W WO2016111156A1 WO 2016111156 A1 WO2016111156 A1 WO 2016111156A1 JP 2015085676 W JP2015085676 W JP 2015085676W WO 2016111156 A1 WO2016111156 A1 WO 2016111156A1
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- switching element
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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
- H02M3/145—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 triode or transistor type requiring continuous application of a control signal
- H02M3/155—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 triode or transistor type requiring continuous application of a control signal using semiconductor devices only
- H02M3/156—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 triode or transistor type requiring continuous application of a control signal using semiconductor devices only with automatic control of output voltage or current, e.g. switching regulators
- H02M3/158—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 triode or transistor type requiring continuous application of a control signal using semiconductor devices only with automatic control of output voltage or current, e.g. switching regulators including plural semiconductor devices as final control devices for a single load
- H02M3/1582—Buck-boost 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
- H02M7/00—Conversion of ac power input into dc power output; Conversion of dc power input into ac power output
- H02M7/42—Conversion of dc power input into ac power output without possibility of reversal
- H02M7/44—Conversion of dc power input into ac power output without possibility of reversal by static converters
- H02M7/48—Conversion of dc power input into ac power output without possibility of reversal by static converters using discharge tubes with control electrode or semiconductor devices with control electrode
- H02M7/483—Converters with outputs that each can have more than two voltages levels
- H02M7/4837—Flying capacitor 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
- H02M1/00—Details of apparatus for conversion
- H02M1/08—Circuits specially adapted for the generation of control voltages for semiconductor devices incorporated in 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
- H02M3/145—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 triode or transistor type requiring continuous application of a control signal
- H02M3/155—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 triode or transistor type requiring continuous application of a control signal using semiconductor devices only
-
- 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
- H02M1/0003—Details of control, feedback or regulation circuits
- H02M1/0009—Devices or circuits for detecting current in a converter
Definitions
- This invention relates to a DC / DC converter.
- the first controller (25) calculates the first calculation value
- the second controller (26) calculates the second calculation value
- the control blocks (27) and (28) first and second Add or subtract the operation value of 2
- the gate signal G1, at G2 (S1) ⁇ (S4) the conduction rate control to the controlling the output voltage and the charge and discharge capacitor voltage to prevent overvoltage breakdown of (S1) ⁇ (S4).
- the output voltage Vout changes to the output voltage target value Vout * due to the difference in calculation speed between the first controller 25 and the second controller 26.
- the follow-up time of the charge / discharge capacitor voltage Vcf to the target charge / discharge capacitor voltage Vcf * may be delayed, and a relatively high voltage may be applied to the switching element. For this reason, when designing a conventional DC / DC converter, it is necessary to select a switching element in consideration of the case where a relatively high voltage is applied to such a switching element, which is a factor of an increase in cost.
- the present invention has been made to solve the above-described problems.
- the follow-up time of the charge / discharge capacitor voltage Vcf to the target charge / discharge capacitor voltage Vcf * is configured not to be delayed.
- the DC / DC converter according to the present invention includes a low-voltage side smoothing capacitor that holds a low-voltage side voltage, a negative-side terminal connected to a negative-side terminal of the low-voltage side smoothing capacitor, and a high-voltage side smoothing capacitor that holds a high-voltage side voltage.
- a first semiconductor circuit connected to the negative terminal of the low-voltage side smoothing capacitor, one end connected to the other end of the first semiconductor circuit, and the other end connected to the positive terminal of the low-voltage side smoothing capacitor via a reactor Second semiconductor circuit, one end connected to the other end of the second semiconductor circuit, one end connected to the other end of the third semiconductor circuit, the other end connected to the high-voltage side smoother
- a fourth semiconductor circuit connected to the positive terminal of the capacitor, one end connected to an intermediate connection point between the first semiconductor circuit and the second semiconductor circuit, and the other end connected to the third semiconductor circuit and the third semiconductor circuit;
- Four Discharge capacitor connected to an intermediate connection point between the conductor circuit, and a control device for controlling the respective semiconductor circuit,
- Each of the first and second semiconductor circuits has a function of a switching element
- Each of the third and fourth semiconductor circuits has a function of a diode element,
- a step-up operation for converting the input voltage of the low-voltage side smoothing capacitor into a boosted voltage and outputting
- the target charge / discharge capacitor voltage Vcf * of the charge / discharge capacitor voltage Vcf is compared with the follow-up time of the output voltage Vout to the output voltage target value Vout *. Since the follow-up time is not delayed, a switching element having a lower withstand voltage than that of the prior art can be selected, and the manufacturing cost of the DC / DC converter can be reduced.
- FIG. 2 is a circuit diagram illustrating a configuration of a control device according to the first embodiment.
- FIG. 3 is an explanatory diagram illustrating an operation mode of the DC / DC converter according to the first embodiment.
- FIG. 3 is an operation explanatory diagram of the DC / DC converter according to the first embodiment.
- FIG. 3 is an operation explanatory diagram of the DC / DC converter according to the first embodiment.
- FIG. 3 is an operation explanatory diagram of the DC / DC converter according to the first embodiment.
- FIG. 3 is an operation explanatory diagram of the DC / DC converter according to the first embodiment.
- FIG. 3 is an operation explanatory diagram of the DC / DC converter according to the first embodiment.
- FIG. 6 is a circuit diagram illustrating a configuration of a control device according to a second embodiment.
- FIG. 10 is an operation flowchart of the limiter 30 of the control device according to the second embodiment. It is a figure explaining the time change of the output voltage Vout of Embodiment 2, and the charging / discharging capacitor
- FIG. 1 to 8 show a first embodiment for carrying out the present invention.
- FIG. 1 is a block diagram showing the configuration of a DC / DC converter
- FIG. 2 is a block diagram showing the configuration of the control device of FIG.
- FIG. 3 is an explanatory diagram showing an operation mode of the DC / DC converter of FIG. 4 to 7 are operation explanatory diagrams of the DC / DC converter of FIG.
- FIG. 8 is a diagram for explaining the time change between the output voltage Vout and the charge / discharge capacitor voltage Vcf.
- FIG. 9 is a figure explaining the time change of the output voltage Vout and charging / discharging capacitor
- a DC / DC converter 100 is a bidirectional type capable of bidirectional power conversion between a low voltage side and a high voltage side, and includes a terminal group and first, second, third, and second terminals, respectively.
- the first terminal 100a, the second terminal 100b, the third terminal 100c, and the fourth terminal 100d as the four terminals, and between the first terminal 100a (Vcom) and the second terminal 100b (VL) that are the low-voltage side terminals
- the DC input voltage Vin input to the terminal is boosted to a voltage equal to or higher than the input voltage Vin, and the boosted output voltage Vout is between the third terminal 100c (Vcom) and the fourth terminal 100d (VH), which are terminals on the high voltage side. Is output.
- the DC / DC converter 100 includes a low-voltage side smoothing capacitor 11 (Ci) and a high-voltage side smoothing capacitor 108 (Co) as a capacitor device, a reactor 12 (L), a DC voltage converter 101, a voltage sensor 103, a voltage A sensor 104, a current sensor 105, and a control device 109 are included.
- the low-voltage side smoothing capacitor 11 has one terminal connected to the first terminal 100a and the other terminal connected to the second terminal 100b to smooth the input voltage Vin.
- the first terminal 100a and the third terminal 100c are connected in common. Note that the first terminal 100a and the third terminal 100c may be combined.
- Reactor 12 (L) is for energy storage, and is connected to second terminal 100b and second connection portion 101c (described later) that is a connection portion between switching element S2 and switching element S3.
- the DC voltage conversion unit 101 includes a switching element series circuit 101a as a semiconductor series circuit and a charge / discharge capacitor 101f (Cf), and boosts the input voltage Vin to the output voltage Vout.
- switching element series circuit 101a four switching elements S1, S2, S3, and S4 as first to fourth semiconductor circuits are respectively connected via a first connection portion 101b, a second connection portion 101c, and a third connection portion 101d. They are connected in series in this order.
- Each of the switching elements S1 to S4 uses, for example, a combination of an IGBT (Insulated Gate Bipolar Transistor) and an antiparallel diode. In this embodiment, the switching elements S1 to S4 are turned on when the gate signal is high.
- a charge / discharge capacitor 101f is connected to the first connection portion 101b and the third connection portion 101d.
- the switching element S1 is connected to the first terminal 100a on the side opposite to the first connection part 101b, and the second connection part 101c is connected to the second terminal 100b via the reactor 12. Both ends of the switching element series circuit 101a are connected to the third terminal 100c and the fourth terminal 100d, and the first terminal 100a and the third terminal 100c are connected in common, and the first terminal 100a and the second terminal 100b are on the low voltage side.
- the third terminal 100c and the fourth terminal 100d are on the high voltage side. More specifically, the emitter terminal of the switching element S1 is connected to the first terminal 100a, and the collector terminal of the switching element S4 is connected to the fourth terminal 100d.
- a second connection portion 101c which is a connection portion between the collector terminal of the switching element S2 and the emitter terminal of the switching element S3, is connected to the second terminal 100b via the reactor 12.
- the charge / discharge capacitor 101f has one terminal connected to the first connection portion 101b, which is a connection portion between the collector terminal of the switching element S1 and the emitter terminal of the switching element S2, and the other terminal connected to the collector terminal of the switching element S3.
- the switching element S4 is connected to a third connecting part 101d that is a connecting part to the emitter terminal.
- the voltage sensor 103 detects the inter-terminal voltage as the high voltage side output voltage of the high voltage side smoothing capacitor 108 on the output side as the capacitor device and the high voltage side capacitor.
- the voltage sensor 104 detects the voltage (hereinafter referred to as charge / discharge capacitor voltage) Vcf of the charge / discharge capacitor 101f included in the DC voltage conversion unit 101.
- Current sensor 105 detects a reactor current IL flowing through reactor 12.
- the high-voltage smoothing capacitor 108 on the output side smoothes the output voltage Vout that has been boosted by the DC voltage converter 101.
- the control device 109 generates gate signals (G1 to G4) of the four switching elements S1 to S4 according to the detection values of the voltage sensors 103 and 104 and the current sensor 105, and each switching element S1 to S4 of the DC voltage conversion unit 101 is generated. S4 is turned ON / OFF.
- FIG. 2 is a circuit diagram showing a detailed configuration of the control device 109.
- the control device 109 includes a subtractor 21, a multiplier 22, a subtracter 23, a first control block 24, a first controller 25, a second controller 26, a second control block 27, and a third control block 28.
- the first control block 24 includes a multiplier 24a, a comparator 24b, an open / close contact 24c, an inverter 24e, and an open / close contact 24f.
- the second control block 27 has an adder 27a and a subtractor 27b.
- the third control block 28 includes a comparator 28a, a comparator 28b, an inverter 28c, and an inverter 28d.
- the subtractor 21, the multiplier 22, and the first controller 25 are the first arithmetic unit in the present invention, and the multiplier 29, the subtracter 23, the first control block 24, and the second controller 26 are in the present invention. It is a 2nd calculating part, and the 2nd control block 27 and the 3rd control block 28 are the opening / closing control part in this invention.
- the comparator 24b is a reactor current direction detection unit in the present invention.
- the voltage detection value of the charge / discharge capacitor detected by the voltage sensor 104 is input to the multiplier 22 as the charge / discharge capacitor voltage Vcf.
- the charge / discharge capacitor voltage Vcf is doubled by the multiplier 22 whose multiplication constant is set to 2, and the output voltage provisional target value Vout ** is calculated.
- the output voltage provisional target value Vout ** and the output voltage Vout as the detected value of the high-voltage side voltage detected by the voltage sensor 103 are input to the subtractor 21, and the difference voltage ⁇ Vout which is the difference between them is input to the first controller 25. Is input.
- the output voltage target value Vout * as the command value for the high-voltage side is multiplied by 0.5 by the multiplier 29 in which the multiplication constant is set to 0.5, and charging / discharging as the voltage command value for the charge / discharge capacitor is performed.
- a capacitor voltage target value Vcf * is calculated.
- the charge / discharge capacitor voltage target value Vcf * and the charge / discharge capacitor voltage Vcf are input to the subtractor 23, and a difference voltage ⁇ Vcf which is the difference between them is calculated and output to the first control block 24.
- the second controller 26 amplifies the voltage difference ⁇ Vcf between the charge / discharge capacitor voltage target value Vcf * and the charge / discharge capacitor voltage Vcf.
- the charge / discharge capacitor voltage target value Vcf * is half the output voltage target value Vout * (0.5 times) as described above. It is said.
- the reactor current IL detected by the current sensor 105 is input to the comparator 24b, and the switching contacts 24c and 24f are opened / closed according to the polarity of the reactor current IL, thereby charging / discharging capacitor voltage target.
- the polarity of the difference voltage ⁇ Vcf between the value Vcf * and the charge / discharge capacitor voltage Vcf is switched, and when the reactor current IL is positive, the difference voltage ⁇ Vcf is output as it is, and when the reactor current IL is negative, the multiplier 24a
- the polarity is inverted by multiplying by -1, and then the switching contact 24f is closed via the inverter 24e to output to the second controller 26.
- the output is input to the second control block 27 as the first calculation value of the first controller 25 and the output as the second calculation value of the second controller 26, and both are added by the adder 27a to be the switching element. It is output to the third control block 28 as the ON duty D1 as the energization rate of S1. Further, the difference between the output of the first controller 25 and the output of the second controller 26 is calculated by the subtractor 27b and output to the third control block 28 as the ON duty D2 as the energization rate of the switching element S2. .
- the third control block 28 is a block for generating a PWM (Pulse Width Modulation) signal.
- the gate signal G1 of the switching element S1 inputs the ON duty D1 and the first triangular wave SW1 to the comparator 28a. Is generated by comparing.
- the gate signal G2 of the switching element S2 is generated by inputting the ON duty D2 and the second triangular wave SW2 to the comparator 28b and comparing the two.
- An inverted signal of G2 inverted by the inverter 28d is output as the gate signal G3 of the switching element S3, and an inverted signal of G1 inverted by the inverter 28c is output as the gate signal G4 of the switching element S4.
- a signal obtained by inverting the phases of the first triangular wave SW1 and the second triangular wave SW2 by 180 degrees is used.
- the steady state refers to a state when the switching elements S1 to S4 are on / off controlled and the output voltage is stably obtained.
- an operation state of the DC / DC converter 100 a state in which the electric motor 3 is driven (powering operation) by supplying electric power from the battery 2 to the electric motor 3, and electric power generated by the electric motor 3 in the electric power generation state is supplied to the battery 2.
- mode 1 to mode 4 there are four operation modes of mode 1 to mode 4 as the operation mode of the DC / DC converter in the steady state.
- S1 and S3 are on, S2 and S4 are off, energy is stored in the charge / discharge capacitor 101f during power running, and energy of the charge / discharge capacitor 101f is during regeneration. Will be released.
- S1 and S3 are turned off, S2 and S4 are turned on, energy is discharged from the charge / discharge capacitor 101f during power running, and energy is charged to the charge / discharge capacitor 101f during regeneration. It will be in the state which accumulates.
- FIG. 3A in mode 1, S1 and S3 are on, S2 and S4 are off, energy is stored in the charge / discharge capacitor 101f during power running, and energy of the charge / discharge capacitor 101f is during regeneration. Will be released.
- S1 and S3 are turned off, S2 and S4 are turned on, energy is discharged from the charge / discharge capacitor 101f during power running, and energy is charged to the charge /
- mode 3 is a state in which S1 and S2 are off, S3 and S4 are on, the reactor 12 energy is released during power running, and the reactor 12 energy is accumulated during regeneration. It becomes.
- S1 and S2 are on, S3 and S4 are off, energy is stored in the reactor 12 during power running, and the energy of the reactor 12 is released during regeneration. It becomes.
- the input voltage Vin which is the low-voltage side voltage input between the first terminal 100a and the second terminal 100b, is boosted to an arbitrary voltage, and the third terminal 100c- An output voltage Vout can be output between the fourth terminals 100d.
- the DC / DC converter 100 operates differently in a steady state when the step-up ratio N of the output voltage Vout with respect to the input voltage Vin is less than twice or more than twice.
- FIG. 4 shows the gate signal voltage waveform of each of the switching elements S1 to S4, the waveform of the reactor current IL, the waveform of the current Icf of the charge / discharge capacitor 101f, and the charge / discharge capacitor voltage Vcf when the step-up ratio N is less than twice.
- the waveform is shown.
- the charge / discharge capacitor voltage Vcf is controlled to be about a half of the output voltage Vout.
- the magnitude relationship among the input voltage Vin, the output voltage Vout, and the charge / discharge capacitor voltage Vcf is: It is as follows.
- the input voltage Vin input between the first terminal 100a and the second terminal 100b is an arbitrary voltage less than 1 to 2 times.
- the voltage of the battery 2 is supplied to the electric motor 3 while being output as the output voltage Vout between the third terminal 100c and the fourth terminal 100d.
- FIG. 5 shows the waveform of the gate signal voltage of each of the switching elements S1 to S4, the waveform of the reactor current IL, and the waveform of the current (charge / discharge capacitor current) Icf of the charge / discharge capacitor 101f when the step-up ratio N is twice or more.
- the waveform of the charge / discharge capacitor voltage Vcf is shown.
- the charging / discharging capacitor voltage Vcf is controlled to be about a half of the output voltage Vout.
- the magnitude relationship among the input voltage Vin, the output voltage Vout, and the charging / discharging capacitor voltage Vcf is as follows. It is like that. Vout>Vcf> Vin
- the input voltage Vin input between the first terminal 100a and the second terminal 100b is boosted to an arbitrary voltage more than twice.
- the energy of the battery 2 is supplied to the electric motor 3 while outputting the output voltage Vout between the third terminal 100c and the fourth terminal 100d.
- FIG. 6 shows the gate signal voltage waveform of the switching elements S1 to S4, the waveform of the reactor current IL, the waveform of the charge / discharge capacitor current Icf, and the waveform of the charge / discharge capacitor voltage Vcf when the step-up ratio N is less than twice. ing.
- the charge / discharge capacitor voltage Vcf is controlled to be about a half of the output voltage Vout.
- the magnitude relationship among the input voltage Vin, the output voltage Vout, and the charge / discharge capacitor voltage Vcf is: It is as follows. Vout>Vin> Vcf
- the input voltage Vin input between the first terminal 100a and the second terminal 100b is an arbitrary voltage less than 1 to 2 times.
- the power generation energy of the motor 3 is stored in the battery 2 while being output as the output voltage Vout between the third terminal 100c and the fourth terminal 100d.
- FIG. 7 shows the gate signal voltage waveform of the switching element S1 and the switching element S2, the waveform of the reactor current IL, the waveform of the charge / discharge capacitor current Icf, and the charge / discharge capacitor during the regenerative operation when the boost ratio N is twice or more.
- the waveform of the voltage Vcf is shown.
- the charging / discharging capacitor voltage Vcf is controlled to be about a half of the output voltage Vout.
- the magnitude relationship among the input voltage Vin, the output voltage Vout, and the charging / discharging capacitor voltage Vcf is as follows. It is like that. Vout>Vcf> Vin
- the input voltage Vin input between the first terminal 100a and the second terminal 100b is boosted to an arbitrary voltage more than twice.
- the power generation energy of the motor 3 is stored in the battery 2 while being output as the output voltage Vout between the third terminal 100c and the fourth terminal 100d.
- the ON duty of the switching element S1 is D1
- the ON duty of the switching element S2 is D2
- the ON duty of the switching element S3 is (1-D2)
- the ON duty of the switching element S4 is (1-D1).
- the capacitance of the low-voltage side smoothing capacitor 11 is Ci
- the capacitance of the high-voltage side smoothing capacitor 108 on the output side is Co
- the capacitance of the charge / discharge capacitor 101f is Cf
- the inductance value of the reactor 12 for storing energy is L
- the state average equation of the DC / DC converter 100 can be expressed by equation (1).
- the actual DC / DC converter has a deviation from an ideal state such as a loss due to a resistance component of the circuit and an ON duty error due to variations in the signal delay of the gate signal.
- the difference between the ON duty D1 of the switching element S1 and the ON duty D2 of the switching element S2 has a great influence on the charge / discharge capacitor voltage Vcf.
- the ON duty D1 is larger than the ON duty D2 during power running, the expression (1)
- the charge / discharge capacitor voltage Vcf gradually increases and finally becomes the same value as the output voltage Vout.
- the ON duty D1 is smaller than the ON duty D2, the charging / discharging capacitor voltage Vcf gradually decreases during powering from the equation (1), and finally becomes zero volts.
- a value obtained by multiplying the charge / discharge capacitor voltage Vcf by a constant 2 is used as an output voltage provisional target value Vout **, and feedback control is performed based on the difference between the output voltage provisional target value Vout ** and the output voltage Vout.
- a value obtained by multiplying the first controller 25 to be performed and the output voltage target value Vout * by a constant 0.5 is a target charge / discharge capacitor voltage Vcf *, and a difference between the target charge / discharge capacitor voltage Vcf * and the charge / discharge capacitor voltage Vcf.
- a second controller 26 for performing feedback control based on the above, and adding and subtracting the output values of the first and second controllers 25 and 26 to obtain an added value and a subtracted value, and an ON duty command for the switching elements S1 to S4 Therefore, the output voltage Vout and the charge / discharge capacitor voltage Vcf can be controlled to desired values.
- the output voltage provisional target value Vout ** and the constant 2 are a first calculated value and a first constant, respectively, which are characteristics of the present invention.
- the target charge / discharge capacitor voltage Vcf * and the constant 0.5 are a second calculated value and a second constant, respectively, which are characteristics of the present invention.
- the control device 109 When the output voltage Vout is larger than the output voltage target value Vout *, the charge / discharge capacitor voltage Vcf is first reduced by the second controller 26 for the purpose of reducing the output voltage Vout.
- the second calculation value is output so that the ON duty D1 becomes larger than the ON duty D2 during regeneration so that D1 becomes smaller than the ON duty D2.
- the output temporary target value Vout ** decreases, and the first controller 25 outputs a first calculation value that decreases both the ON duty of the switching element S1 and the switching element S2. .
- the second controller 26 first increases the charge / discharge capacitor voltage Vcf for the purpose of increasing the output voltage Vout. Outputs a second calculated value so that the ON duty D1 is larger than the ON duty D2, and during regeneration, the ON duty D1 is smaller than the ON duty D2. As the charge / discharge capacitor Vcf increases, the output temporary target value Vout ** increases, and the first controller 25 outputs a first calculation value that increases both the ON duty of the switching element S1 and the switching element S2. .
- the power running operation (reactor current IL is positive) and the regenerative operation (reactor current IL is The convergence condition is different in the case of (negative).
- the second controller 26 controls the switching element to reduce the charge / discharge capacitor voltage Vcf *.
- a second calculated value that decreases the ON duty D1 of S1 and increases the ON duty D2 of the switching element S2 is output.
- the second controller 26 controls the switching element to increase the charge / discharge capacitor voltage Vcf.
- a second calculation value for increasing the ON duty D1 of S1 and decreasing the ON duty D2 of the switching element S2 is output.
- the second controller 26 causes the switching element to reduce the charge / discharge capacitor voltage Vcf.
- a second calculation value for increasing the ON duty D1 of S1 and decreasing the ON duty D2 of the switching element S2 is output.
- the second controller 26 controls the switching element to raise the charge / discharge capacitor voltage Vcf.
- a second calculated value that decreases the ON duty D1 of S1 and increases the ON duty D2 of the switching element S2 is output.
- the output voltage Vout can be controlled to the output voltage target value Vout * and the charge / discharge capacitor voltage Vcf can be controlled to the target charge / discharge capacitor voltage Vcf * regardless of the power running operation and the regenerative operation. It becomes possible.
- the current sensor 105 since the current sensor 105 only needs to have a function of determining the polarity of the current flowing through the reactor 12, an inexpensive device can be used, and a DC / DC converter control device can be configured at low cost. It becomes possible.
- a first controller 25 that performs feedback control based on the difference between the output voltage target value Vout * and the output voltage Vout to set the output voltage Vout to the output voltage target value Vout *, and the charge / discharge capacitor voltage Vcf as the charge / discharge capacitor 101f
- the target charge / discharge capacitor voltage Vcf * is set to a half value of the output voltage Vout in order to obtain the target voltage (target charge / discharge capacitor voltage) Vcf *, and the target charge / discharge capacitor voltage Vcf * and the charge / discharge capacitor voltage
- a second controller 26 that performs feedback control based on the difference from Vcf is provided, and the output voltage Vout and the charge / discharge capacitor voltage Vcf are controlled to desired values.
- the output voltage target value Vout * changes abruptly, compared to the follow-up time of the output voltage Vout to the output voltage target value Vout * due to the difference in calculation speed between the first controller 25 and the second controller 26, The follow-up time of the charge / discharge capacitor voltage Vcf to the target charge / discharge capacitor voltage Vcf * becomes long.
- the first calculation value output from the first controller 25 is an absolute value of 1 or 1 to the second calculation value.
- the target of the charge / discharge capacitor voltage Vcf is compared with the follow-up time of the output voltage Vout to the output voltage target value Vout *.
- the follow-up time to the charge / discharge capacitor voltage Vcf * becomes long.
- the switching element S4 when the switching element S1 is in the ON state and the switching element S4 is in the OFF state, the switching element S4 has a relatively high voltage (maximum difference described later) during the follow-up time of the charge / discharge capacitor voltage Vcf to the target charge / discharge capacitor voltage Vcf *.
- the voltage ⁇ Vmax1) may be applied.
- a relatively high voltage (maximum difference) is applied to the switching element S1 during the follow-up time of the charge / discharge capacitor voltage Vcf to the target charge / discharge capacitor voltage Vcf *.
- Voltage ⁇ Vmax1) may be applied, and the withstand voltage of the switching element needs to be higher than such a relatively high voltage (maximum differential voltage ⁇ Vmax1).
- FIG. 8 shows a time change of the output voltage Vout and the charge / discharge capacitor voltage Vcf when the output voltage target value Vout * in the present embodiment changes rapidly
- FIG. 9 shows a conventional DC / DC converter.
- condenser voltage Vcf in the conventional DC / DC converter is demonstrated.
- the horizontal axis indicates time change
- the vertical axis indicates the voltage value.
- one thick line in the figure indicates a change in the charge / discharge capacitor voltage Vcf
- the other thick line indicates a change in the output voltage Vout.
- one thin line indicates a change in the target charge / discharge capacitor voltage Vcf *
- the other thin line indicates a change in the output voltage target value Vout *.
- the voltage applied to the switching element S4 is a difference between the output voltage Vout and the charge / discharge capacitor voltage Vcf.
- the voltage applied to the switching element S1 is the difference between the output voltage Vout and the charge / discharge capacitor voltage Vcf.
- the output voltage target value Vout * is assumed to be Vout1 *, which is substantially equal to the output voltage Vout.
- the output voltage Vout reaches Vout2 *, and the charge / discharge capacitor voltage Vcf is also Vcf2 *. It is assumed that the operation due to the command value variation is completed.
- the first controller 25 When there is a sudden change in the command value at which the output voltage target value Vout * changes from Vout1 * to Vout2 * at time T1, the first controller 25 responds to the difference ( ⁇ Vout) between Vout2 * and Vout1 *. The first calculation value for increasing both the ON duty of the switching element S1 and the switching element S2 is output.
- the calculation process of the second controller 26 is delayed compared to the first controller 25, or the first
- the calculation result of the controller 25 is 1 or 0 or a value close to them, and the second calculation value is not reflected in the ON duty
- the output voltage Vout ⁇ 0.5 in the transition period from time T1 to time T2.
- Charge / discharge capacitor voltage Vcf, and the maximum differential voltage ⁇ Vmax1 between the output voltage Vout and the charge / discharge capacitor voltage Vcf is generated. Therefore, when designing a conventional DC / DC converter, it is necessary to select a switching element having a withstand voltage equal to or higher than ⁇ Vmax1 in consideration of the maximum differential voltage ⁇ Vmax1.
- FIG. 8 a time change between the output voltage Vout and the charge / discharge capacitor voltage Vcf in the first embodiment will be described.
- the horizontal axis in FIG. 8 indicates the time change, and the vertical axis indicates the voltage value.
- one thick line in the figure indicates a change in the charge / discharge capacitor voltage Vcf
- the other thick line indicates a change in the output voltage Vout.
- one thin line indicates a change in the target charge / discharge capacitor voltage Vcf *
- the other thin line indicates a change in the output voltage target value Vout *.
- a dotted line indicates a change in the output voltage provisional target value Vout **.
- the switching element S1 when the switching element S1 is in the ON state and the switching element S4 is in the OFF state, the voltage applied to the switching element S4, the switching element S1 is in the OFF state, and the switching element S4 is in the ON state.
- the voltage applied to the switching element S1 is the difference between the output voltage Vout and the charge / discharge capacitor voltage Vcf.
- the time T1 and the time T2 are similar to those of the conventional DC / DC converter.
- the first controller 25 determines that the output voltage temporary target value Vout ** and the output voltage Vout In accordance with the difference ( ⁇ Vout) between the switching elements S1 and S2, a first calculation value for increasing both ON duties is output. Since the output voltage provisional target value Vout ** is the charge / discharge capacitor voltage Vcf ⁇ 2, the first calculated value does not output a value far from the charge / discharge capacitor voltage Vcf as compared with the conventional method.
- the maximum differential voltage ⁇ Vmax2 between the output voltage Vout and the charge / discharge capacitor voltage Vcf is a value smaller than the maximum differential voltage ⁇ Vmax1 in the conventional DC / DC converter.
- constant 2 is selected as the first constant and constant 0.5 is set as the second constant.
- the first constant is appropriately set according to the breakdown voltage and performance of the switching element.
- a constant larger than 1 can be selected, and a constant larger than 0 and smaller than 1 can be selected as the second constant.
- the first constant is set to 1.9 and 2.1 and the second constant is set to constant 0.4 and 0.6. May be preferable.
- the superiority of the case where the output voltage target value Vout * changes suddenly has been described.
- the output voltage target value Vout is determined. Even when the difference between * and the output voltage Vout increases, the difference between the output voltage Vout and the charge / discharge capacitor voltage Vcf does not spread more than expected (Vout * (max) ⁇ 0.5). can get.
- the switching of the switching elements S3 and S4 is always turned on and the operation method for transferring power between the battery 2 and the motor 3 without switching is adopted. Even when transitioning to the step-up operation, the difference between the output voltage Vout and the charge / discharge capacitor voltage Vcf does not spread more than expected (Vout * (max) ⁇ 0.5), so the same effect can be obtained.
- the charge / discharge capacitor voltage Vcf during the mode 1 period increases when the powering operation is performed, and decreases when the regenerative operation is performed.
- the charging / discharging capacitor voltage Vcf during the mode 2 period decreases when the power running operation is performed, and increases when the regenerative operation is performed.
- FIG. 1 A DC / DC converter according to Embodiment 2 of the present invention will be described.
- the configuration of the DC / DC converter is the same as that of the first embodiment
- FIG. 10 is a circuit diagram showing the configuration of the control device
- FIG. 11 shows the limiter 30 of the control device.
- FIG. 12 is an operation flow diagram
- FIG. 12 is a diagram for explaining temporal changes in the output voltage Vout and the charge / discharge capacitor voltage Vcf. 1 and 2 are the same as or equivalent to the components shown in the first embodiment, and detailed description thereof is omitted.
- FIG. 10 is a circuit diagram showing a detailed configuration of the control device 139.
- the control device 139 includes a subtractor 21, a subtractor 23, a first control block 24, a first controller 25, a second controller 26, a second control block 27, a third control block 28, and a limiter 30. And a multiplier 31.
- the first control block 24 includes a multiplier 24a, a comparator 24b, an open / close contact 24c, an inverter 24e, and an open / close contact 24f.
- the second control block 27 has an adder 27a and a subtractor 27b.
- the third control block 28 includes a comparator 28a, a comparator 28b, an inverter 28c, and an inverter 28d.
- the limiter 30, the subtractor 21, and the first controller 25 are the first arithmetic unit in the present invention, and the multiplier 31, the subtractor 23, the first control block 24, and the second controller 26 are in the present invention. It is a 2nd calculating part, and the 2nd control block 27 and the 3rd control block 28 are the opening / closing control part in this invention.
- the comparator 24b is a reactor current direction detection unit in the present invention.
- FIG. 11 is an operation flowchart of the limiter 30.
- the output voltage target value Vout * and the charge / discharge capacitor voltage Vcf are input to the limiter 30.
- the charge / discharge capacitor voltage Vcf is preset as the output voltage provisional target value Vout **.
- the sum with the voltage value V2 is output from the limiter 30.
- the output voltage target value Vout * is set as the limiter 30 as the output voltage provisional target value Vout **.
- the voltage value V1 is set to a voltage value equal to or lower than the withstand voltage of the switching element
- the voltage value V2 is set to a value equal to or lower than the voltage value V1, whereby the output voltage provisional target value Vout **
- the voltage applied to the switching element is not significantly different from Vout, and the voltage applied to the switching element can be lower than the withstand voltage of the switching element.
- the voltage value V1 indicates the first voltage value in the present invention
- the voltage value V2 indicates the second voltage value in the present invention.
- the voltage detection value of the charge / discharge capacitor detected by the voltage sensor 104 is input to the limiter 30 as the charge / discharge capacitor voltage Vcf.
- the output voltage target value Vout * is also input to the limiter 30.
- the limiter 30 calculates the output voltage provisional target value Vout **.
- the output voltage provisional target value Vout ** and the output voltage Vout as the detected value of the high-voltage side voltage detected by the voltage sensor 103 are input to the subtractor 21, and the difference voltage ⁇ Vout which is the difference between them is input to the first controller 25. Is input.
- the output voltage Vout is multiplied by 0.5 by a multiplier 31 having a multiplication constant set to 0.5, and a charge / discharge capacitor voltage target value Vcf * as a voltage command value of the charge / discharge capacitor is calculated.
- the charge / discharge capacitor voltage target value Vcf * and the charge / discharge capacitor voltage Vcf are input to the subtractor 23, and a difference voltage ⁇ Vcf which is the difference between them is calculated and output to the first control block 24.
- the output voltage provisional target value Vout ** and the multiplication constant of 0.5 are the first calculated value and the fourth constant, respectively, which characterize the present invention.
- the target charge / discharge capacitor voltage Vcf * is a fourth calculated value indicating the feature of the present invention.
- the reactor current IL detected by the current sensor 105 is input to the comparator 24b, and the switching contacts 24c and 24f are opened / closed according to the polarity of the reactor current IL, thereby charging / discharging capacitor voltage target.
- the polarity of the difference voltage ⁇ Vcf between the value Vcf * and the charge / discharge capacitor voltage Vcf is switched, and when the reactor current IL is positive, the difference voltage ⁇ Vcf is output as it is, and when the reactor current IL is negative, the multiplier 24a
- the polarity is inverted by multiplying by -1, and then the switching contact 24f is closed via the inverter 24e to output to the second controller 26.
- the output is input to the second control block 27 as the first calculation value of the first controller 25 and the output as the second calculation value of the second controller 26, and both are added by the adder 27a to be the switching element. It is output to the third control block 28 as the ON duty D1 as the energization rate of S1. Further, the difference between the output of the first controller 25 and the output of the second controller 26 is calculated by the subtractor 27b and output to the third control block 28 as the ON duty D2 as the energization rate of the switching element S2. .
- the output voltage Vout is controlled to the output voltage target value Vout * regardless of the power running operation and the regenerative operation, and the charge / discharge capacitor voltage Vcf. Can be controlled to the target charge / discharge capacitor voltage Vcf *.
- the current sensor 105 since the current sensor 105 only needs to have a function of determining the polarity of the current flowing through the reactor 12, an inexpensive device can be used, and a DC / DC converter control device can be configured at low cost. It becomes possible.
- FIG. 12 a time change between the output voltage Vout and the charge / discharge capacitor voltage Vcf in the first embodiment will be described.
- the horizontal axis in FIG. 12 indicates the time change, and the vertical axis indicates the voltage value.
- one thick line in the figure indicates a change in the charge / discharge capacitor voltage Vcf
- the other thick line indicates a change in the output voltage Vout.
- one thin line indicates a change in the target charge / discharge capacitor voltage Vcf *
- the other thin line indicates a change in the output voltage target value Vout *.
- a dotted line indicates a change in the output voltage provisional target value Vout **.
- the switching element S1 when the switching element S1 is in the ON state and the switching element S4 is in the OFF state, the voltage applied to the switching element S4, the switching element S1 is in the OFF state, and the switching element S4 is in the ON state.
- the voltage applied to the switching element S1 is the difference between the output voltage Vout and the charge / discharge capacitor voltage Vcf.
- the time T1 and the time T2 are similar to those of the conventional DC / DC converter.
- the first controller 25 determines that the output voltage temporary target value Vout ** and the output voltage Vout In accordance with the difference ( ⁇ Vout) between the switching elements S1 and S2, a first calculation value for increasing both ON duties is output. Since the output voltage provisional target value Vout ** is calculated by the limiter 30 and limited by the charge / discharge capacitor voltage Vcf, the first calculation value does not vary greatly compared to the conventional DC / DC converter.
- the maximum differential voltage ⁇ Vmax3 between the output voltage Vout and the charge / discharge capacitor voltage Vcf is a value smaller than the maximum differential voltage ⁇ Vmax1 in the conventional DC / DC converter. That is, when designing the DC / DC converter in the present embodiment, a switching element having a withstand voltage equal to or higher than the voltage value V1 may be selected in consideration of the voltage value V1 or lower. Therefore, since a cheap switching element compared with the conventional method can be selected, the cost of the DC / DC converter can be suppressed.
- the superiority in the case where the output voltage target value Vout * changes suddenly has been described.
- the DC / DC converter of the second embodiment when the DC / DC converter of the second embodiment is started, the output voltage target value Vout Even when the difference between * and the output voltage Vout becomes large, the difference between the output voltage Vout and the charge / discharge capacitor voltage Vcf does not spread to V1 or more, so the same effect can be obtained.
- the switching of the switching elements S3 and S4 is always turned on, and the operation method for transferring power between the battery 2 and the motor 3 without switching is adopted. Even during the transition to the step-up operation, the difference between the output voltage Vout and the charge / discharge capacitor voltage Vcf does not spread beyond the voltage value V1, so that the same effect can be obtained.
- the switching elements S1 to S4 have been described as IGBTs.
- the switching elements may be MOSFETs, JFETs, or the like.
- the switching element and the diode element may be formed of a wide band gap semiconductor having a larger band gap than silicon.
- the wide band gap semiconductor include silicon carbide (SiC), a gallium nitride material, and diamond.
- Switching elements and diode elements (diodes) formed of such wide bandgap semiconductors have high voltage resistance and high allowable current density, so switching elements and diode elements can be miniaturized. By using the switching elements and diode elements thus made, it is possible to reduce the size of a semiconductor module incorporating these elements.
- the heat resistance is high, the heat radiation fins of the heat sink can be downsized and the water cooling part can be air cooled, so that the semiconductor module can be further downsized. Furthermore, since the power loss is low, it is possible to increase the efficiency of the switching element and the diode element, and further increase the efficiency of the semiconductor module. Moreover, although both the switching element and the diode element may be configured by a wide band gap semiconductor, either one of the elements may be configured by a wide band gap semiconductor, as described in this embodiment. An effect can be obtained.
- the embodiments can be freely combined, or the embodiments can be appropriately changed or omitted.
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Abstract
Description
そのため、従来のDC/DCコンバータを設計する際、このようなスイッチング素子に比較的高い電圧が印加される場合を考慮し、スイッチング素子を選定する必要があり、コスト増加の要因であった。
前記第1および第2の半導体回路にいずれもスイッチング素子の機能を持たせ、
前記第3および第4の半導体回路にいずれもダイオード素子の機能を持たせ、
前記第1および第2の半導体回路に持たせたスイッチング素子のオンオフスイッチング機能によって、入力された前記低圧側平滑コンデンサの電圧を昇圧した電圧に変換して前記高圧側平滑コンデンサに出力する昇圧動作と、
前記第3および第4の半導体回路にいずれもスイッチング素子の機能を持たせ、
前記第1および第2の半導体回路にいずれもダイオード素子の機能を持たせ、
前記第3および第4の半導体回路に持たせたスイッチング素子のオンオフスイッチング機能によって、入力された前記高圧側平滑コンデンサの電圧を降圧した電圧に変換して前記低圧側平滑コンデンサに出力する降圧動作とのうち少なくとも一方の動作が可能なDC/DCコンバータにおいて、
前記制御装置は、第1の演算部と第2の演算部と開閉制御部とを有し、
前記第1の演算部は前記充放電コンデンサの電圧の検出値に予め設定された第1の定数を乗じて第1の算出値を算出し前記第1の算出値と前記高圧側電圧の検出値との差電圧に基づいて第1の演算値を算出し、
前記第2の演算部は前記高圧側電圧の指令値に基づき算出される第2の算出値と前記充放電コンデンサの電圧の検出値との差電圧に基づいて第2の演算値を演算し、
前記開閉制御部は前記第1の演算値と前記第2の演算値とに基づいて通電率を求め、この通電率に基づき前記オンオフスイッチング機能を持たせた前記第1および第2の半導体回路または前記オンオフスイッチング機能を持たせた前記第3および第4の半導体回路の開閉動作を制御することによって、前記高圧側電圧または前記低圧側電圧、及び前記充放電コンデンサの電圧を制御することを特徴とする。
図1~図8は、この発明を実施するための実施の形態1を示すものであり、図1はDC/DCコンバータの構成を示す構成図、図2は図1の制御装置の構成を示す回路図、図3は図1のDC/DCコンバータの動作モードを示す説明図である。図4~図7は図1のDC/DCコンバータの動作説明図である。図8は出力電圧Voutと充放電コンデンサ電圧Vcfとの時間変化を説明する図である。なお、図9は、従来のDC/DCコンバータ(特許文献1)の出力電圧Voutと充放電コンデンサ電圧Vcfとの時間変化を説明する図である。
DC/DCコンバータ100は、コンデンサ装置としての低圧側平滑コンデンサ11(Ci)および高圧側平滑コンデンサ108(Co)と、リアクトル12(L)と、直流電圧変換部101と、電圧センサ103と、電圧センサ104と、電流センサ105と、制御装置109とを有している。
コンデンサ101fは、その一方の端子がスイッチング素子S1のコレクタ端子とスイッチング素子S2のエミッタ端子との接続部である第1接続部101bに、他方の端子がスイッチング素子S3のコレクタ端子とスイッチング素子S4のエミッタ端子との接続部である第3接続部101dに接続されている。
出力電圧暫定目標値Vout**と電圧センサ103にて検出された高圧側電圧の検出値としての出力電圧Voutとが減算器21に入力され、その差である差電圧ΔVoutが第1制御器25に入力される。
また、高圧側電圧の指令値としての出力電圧目標値Vout*に乗算定数が0.5に設定された乗算器29にて0.5倍されて、充放電コンデンサの電圧指令値としての充放電コンデンサ電圧目標値Vcf*が算出される。
充放電コンデンサ電圧目標値Vcf*と充放電コンデンサ電圧Vcfとが減算器23に入力され、その差である差電圧ΔVcfが演算されて、第1制御ブロック24へ出力される。
詳細は後述するが、第2制御器26は充放電コンデンサ電圧目標値Vcf*と充放電コンデンサ電圧Vcfの差電圧ΔVcfを増幅するものである。なお、この実施の形態においてはリアクトルのリプル電流を最小化するため、上記のように充放電コンデンサ電圧目標値Vcf*は出力電圧目標値Vout*の2分の1の値(0.5倍)としている。
図4は、昇圧比Nが2倍未満の場合の、各スイッチング素子S1~S4のゲート信号電圧波形と、リアクトル電流ILの波形、充放電コンデンサ101fの電流Icfの波形、充放電コンデンサ電圧Vcfの波形を示している。また、定常状態では、充放電コンデンサ電圧Vcfは出力電圧Voutの約2分の1の電圧になるように制御されており、入力電圧Vin、出力電圧Vout、充放電コンデンサ電圧Vcfの大小関係は、次のようになっている。
Vout>Vin>Vcf
低圧側平滑コンデンサ11(Ci)→リアクトル12(L)→スイッチング素子S3→充放電コンデンサ101f(Cf)→スイッチング素子S1
低圧側平滑コンデンサ11(Ci)→リアクトル12(L)→スイッチング素子S3→スイッチング素子S4→高圧側平滑コンデンサ108(Co)
低圧側平滑コンデンサ11(Ci)→リアクトル12(L)→スイッチング素子S2→充放電コンデンサ101f(Cf)→スイッチング素子S4→高圧側平滑コンデンサ108(Co)
低圧側平滑コンデンサ11(Ci)→リアクトル12(L)→スイッチング素子S3→スイッチング素子S4→高圧側平滑コンデンサ108(Co)
図5は、昇圧比Nが2倍以上の場合の、各スイッチング素子S1~S4のゲート信号電圧波形と、リアクトル電流ILの波形と、充放電コンデンサ101fの電流(充放電コンデンサ電流)Icfの波形と、充放電コンデンサ電圧Vcfの波形を示している。定常状態では、充放電コンデンサ電圧Vcfは出力電圧Voutの約2分の1の電圧になるように制御されており、入力電圧Vin、出力電圧Vout、充放電コンデンサ電圧Vcfの大小関係は、次のようになっている。
Vout>Vcf>Vin
低圧側平滑コンデンサ11(Ci)→リアクトル12(L)→スイッチング素子S2→スイッチング素子S1
低圧側平滑コンデンサ11(Ci)→リアクトル12(L)→スイッチング素子S3→充放電コンデンサ101f(Cf)→スイッチング素子S1
低圧側平滑コンデンサ11(Ci)→リアクトル12(L)→スイッチング素子S2→スイッチング素子S1
低圧側平滑コンデンサ11(Ci)→リアクトル12(L)→スイッチング素子S2→充放電コンデンサ101f(Cf)→スイッチング素子S4→高圧側平滑コンデンサ108(Co)
図6は、昇圧比Nが2倍未満の場合の、スイッチング素子S1~S4のゲート信号電圧波形と、リアクトル電流ILの波形、充放電コンデンサ電流Icfの波形、充放電コンデンサ電圧Vcfの波形を示している。また、定常状態では、充放電コンデンサ電圧Vcfは出力電圧Voutの約2分の1の電圧になるように制御されており、入力電圧Vin、出力電圧Vout、充放電コンデンサ電圧Vcfの大小関係は、次のようになっている。
Vout>Vin>Vcf
低圧側平滑コンデンサ11(Ci)←リアクトル12(L)←スイッチング素子S3←充放電コンデンサ101f(Cf)←スイッチング素子S1
低圧側平滑コンデンサ11(Ci)←リアクトル12(L)←スイッチング素子S3←スイッチング素子S4←高圧側平滑コンデンサ108(Co)
低圧側平滑コンデンサ11(Ci)←リアクトル12(L)←スイッチング素子S2←充放電コンデンサ101f(Cf)←スイッチング素子S4←高圧側平滑コンデンサ108(Co)
低圧側平滑コンデンサ11(Ci)←リアクトル12(L)←スイッチング素子S3←スイッチング素子S4←高圧側平滑コンデンサ108(Co)
図7は、昇圧比Nが2倍以上で回生動作時の、スイッチング素子S1及びスイッチング素子S2のゲート信号電圧波形と、リアクトル電流ILの波形と、充放電コンデンサ電流Icfの波形と、充放電コンデンサ電圧Vcfの波形を示している。定常状態では、充放電コンデンサ電圧Vcfは出力電圧Voutの約2分の1の電圧になるように制御されており、入力電圧Vin、出力電圧Vout、充放電コンデンサ電圧Vcfの大小関係は、次のようになっている。
Vout>Vcf>Vin
低圧側平滑コンデンサ11(Ci)←リアクトル12(L)←スイッチング素子S2←スイッチング素子S1
低圧側平滑コンデンサ11(Ci)←リアクトル12(L)←スイッチング素子S3←充放電コンデンサ101f(Cf)←スイッチング素子S1
低圧側平滑コンデンサ11(Ci)←リアクトル12(L)←スイッチング素子S2←スイッチング素子S1
低圧側平滑コンデンサ11(Ci)←リアクトル12(L)←スイッチング素子S2←充放電コンデンサ101f(Cf)←スイッチング素子S4←高圧側平滑コンデンサ108(Co)
Vout/Vin=1/(1-D1) (2)
IL=Io/(1-D1) (3)
D1=D2 (4)
リアクトル電流ILが正(力行動作)で、充放電コンデンサ電圧Vcfが目標充放電コンデンサ電圧Vcf*に比べて大きい場合は、充放電コンデンサ電圧Vcfを低下させるため、第2制御器26によって、スイッチング素子S1のONデューティD1を小さく、スイッチング素子S2のONデューティD2を大きくする第2の演算値を出力する。リアクトル電流ILが正(力行動作)で、充放電コンデンサ電圧Vcfが目標充放電コンデンサ電圧Vcf*に比べて小さい場合は、充放電コンデンサ電圧Vcfを上昇させるため、第2制御器26によって、スイッチング素子S1のONデューティD1を大きく、スイッチング素子S2のONデューティD2を小さくする第2の演算値を出力する。
出力電圧Voutを出力電圧目標値Vout*にするために出力電圧目標値Vout*と出力電圧Voutとの差分に基づきフィードバック制御を行う第1制御器25と、充放電コンデンサ電圧Vcfを充放電コンデンサ101fの目標電圧(目標充放電コンデンサ電圧)Vcf*にするために目標充放電コンデンサ電圧Vcf*を、出力電圧Voutの1/2の値に設定し、目標充放電コンデンサ電圧Vcf*と充放電コンデンサ電圧Vcfとの差分に基づきフィードバック制御を行う第2制御器26を備え、出力電圧Voutと充放電コンデンサ電圧Vcfを所望の値に制御している。
時刻T1において、出力電圧目標値Vout*の値がVout1*からVout2*になる急激な指令値変動あり、時刻T2において、出力電圧Voutが、Vout2*に到達し、充放電コンデンサ電圧VcfもVcf2*に到達し、指令値変動による動作が完了したものとする。
一方、第2制御器26は、目標充放電コンデンサ電圧Vcf*(=0.5×Vout)と充放電コンデンサ電圧Vcfとの差分に応じ、スイッチング素子S1のONデューティD1を大きく、スイッチング素子S2のONデューティD2を小さくする第2の演算値を出力する。
そのため、従来のDC/DCコンバータを設計する際、最大差分電圧ΔVmax1を考慮し、ΔVmax1以上の耐圧を有するスイッチング素子を選定する必要がある。
従来のDC/DCコンバータと同様に、スイッチング素子S1がON状態、スイッチング素子S4がOFF状態の時に、スイッチング素子S4に印加される電圧と、スイッチング素子S1がOFF状態、スイッチング素子S4がON状態の時に、スイッチング素子S1に印加される電圧は、出力電圧Voutと充放電コンデンサ電圧Vcfとの差分になる。また、時刻T1および時刻T2に関しても従来のDC/DCコンバータと同様な状態を示す。
一方、第2制御器26は、目標充放電コンデンサ電圧Vcf*(=0.5×Vout*)と充放電コンデンサ電圧Vcfとの差分に応じ、スイッチング素子S1のONデューティD1を大きく、スイッチング素子S2のONデューティD2を小さくする第2の演算値を出力する。
すなわち、本実施の形態におけるDC/DCコンバータを設計する際、最大差分電圧ΔVmax2は出力電圧目標値Vout*の最大値Vout*(max)の1/2となることを考慮し、ΔVmax2以上の耐圧を有するスイッチング素子を選定すればよい。
よって、従来のDC/DCコンバータに比べ安価なスイッチング素子を選定することができるので、DC/DCコンバータのコストを抑えることができる。
なお、前述したように、リアクトルのリプル電流を最小化するため、第1の定数を1.9以上、2.1以下とし、第2の定数に定数0.4以上、0.6以下とした方が、望ましい場合がある。
さらに、本実施の形態1におけるDC/DCコンバータにおいてスイッチング素子S3とS4のスイッチを常時ONとしてスイッチングなしでバッテリ2と電動機3の電力伝送を行う動作方法を取り入れる場合にも、この動作からスイッチングをした昇圧動作に遷移する際にも、出力電圧Voutと充放電コンデンサ電圧Vcfの差が想定以上(Vout*(max)×0.5)に広がることはないので、同様の効果を得られる。
この発明の実施の形態2に係るDC/DCコンバータについて説明する。本実施の形態2では、DC/DCコンバータの構成は、実施の形態1と同様であり、図10は、制御装置の構成を示す回路図であり、図11は、制御装置の制限器30の動作フロー図であり、図12は、出力電圧Voutと充放電コンデンサ電圧Vcfとの時間変化を説明する図である。なお、図1および2と同一番号あるいは同一符号は、実施の形態1に示す構成要素と同一品あるは同等品であるので、その詳細な説明は省略する。
また、電圧値V1には、スイッチング素子の耐圧以下の電圧値を設定し、電圧値V2には、電圧値V1以下の値を設定することにより、出力電圧暫定目標値Vout**は、出力電圧Voutに比べ大きく変わらず、また、スイッチング素子に掛る電圧が、スイッチング素子の耐圧以下にすることができる。
なお、電圧値V1は、この発明における第1の電圧値を、電圧値V2は、この発明における第2の電圧値を、それぞれ示す。
出力電圧暫定目標値Vout**と電圧センサ103にて検出された高圧側電圧の検出値としての出力電圧Voutとが減算器21に入力され、その差である差電圧ΔVoutが第1制御器25に入力される。
また、出力電圧Voutに乗算定数が0.5に設定された乗算器31にて0.5倍されて、充放電コンデンサの電圧指令値としての充放電コンデンサ電圧目標値Vcf*が算出される。
充放電コンデンサ電圧目標値Vcf*と充放電コンデンサ電圧Vcfとが減算器23に入力され、その差である差電圧ΔVcfが演算されて、第1制御ブロック24に出力される。
なお、出力電圧暫定目標値Vout**と乗算定数の0.5とは、それぞれ本発明の特徴を示す第1の算出値と第4の定数とである。同様に、目標充放電コンデンサ電圧Vcf*は、本発明の特徴を示す第4の算出値である。
一方、第2制御器26は、目標充放電コンデンサ電圧Vcf*(=0.5×Vout)と充放電コンデンサ電圧Vcfとの差分に応じ、スイッチング素子S1のONデューティD1を大きく、スイッチング素子S2のONデューティD2を小さくする第2の演算値を出力する。
すなわち、本実施の形態におけるDC/DCコンバータを設計する際、電圧値V1以下を考慮し、電圧値V1以上の耐圧を有するスイッチング素子を選定すればよい。
よって、従来の方法に比べ安価なスイッチング素子を選定することができるので、DC/DCコンバータのコストを抑えることができる。
また、本実施の形態2におけるDC/DCコンバータにおいてスイッチング素子S3とS4のスイッチを常時Onとしてスイッチングなしでバッテリ2と電動機3の電力伝送を行う動作方法を取り入れる場合にも、この動作からスイッチングをした昇圧動作に遷移する際にも、出力電圧Voutと充放電コンデンサ電圧Vcfの差が電圧値V1以上に広がることなないので、同様の効果を得られる。
り、各実施の形態を適宜変更、省略することが可能である。
Claims (13)
- 低圧側電圧を保持する低圧側平滑コンデンサ、負極側端子が前記低圧側平滑コンデンサの負極側端子に接続され高圧側電圧を保持する高圧側平滑コンデンサ、一端が前記低圧側平滑コンデンサの負極側端子に接続された第1の半導体回路、一端が前記第1の半導体回路の他端に接続され他端がリアクトルを介して前記低圧側平滑コンデンサの正極側端子に接続された第2の半導体回路、一端が前記第2の半導体回路の他端に接続された第3の半導体回路、一端が前記第3の半導体回路の他端に接続され他端が前記高圧側平滑コンデンサの正極側端子に接続された第4の半導体回路、一端が前記第1の半導体回路と前記第2の半導体回路との中間接続点に接続され他端が前記第3の半導体回路と前記第4の半導体回路との中間接続点に接続された充放電コンデンサ、および前記各半導体回路を制御する制御装置を備え、
前記第1および第2の半導体回路にいずれもスイッチング素子の機能を持たせ、
前記第3および第4の半導体回路にいずれもダイオード素子の機能を持たせ、
前記第1および第2の半導体回路に持たせたスイッチング素子のオンオフスイッチング機能によって、入力された前記低圧側平滑コンデンサの電圧を昇圧した電圧に変換して前記高圧側平滑コンデンサに出力する昇圧動作と、
前記第3および第4の半導体回路にいずれもスイッチング素子の機能を持たせ、
前記第1および第2の半導体回路にいずれもダイオード素子の機能を持たせ、
前記第3および第4の半導体回路に持たせたスイッチング素子のオンオフスイッチング機能によって、入力された前記高圧側平滑コンデンサの電圧を降圧した電圧に変換して前記低圧側平滑コンデンサに出力する降圧動作とのうち少なくとも一方の動作が可能なDC/DCコンバータにおいて、
前記制御装置は、第1の演算部と第2の演算部と開閉制御部とを有し、
前記第1の演算部は前記充放電コンデンサの電圧の検出値に予め設定された第1の定数を乗じて第1の算出値を算出し前記第1の算出値と前記高圧側電圧の検出値との差電圧に基づいて第1の演算値を算出し、
前記第2の演算部は前記高圧側電圧の指令値に基づき算出される第2の算出値と前記充放電コンデンサの電圧の検出値との差電圧に基づいて第2の演算値を演算し、
前記開閉制御部は前記第1の演算値と前記第2の演算値とに基づいて通電率を求め、この通電率に基づき前記オンオフスイッチング機能を持たせた前記第1および第2の半導体回路または前記オンオフスイッチング機能を持たせた前記第3および第4の半導体回路の開閉動作を制御することによって、前記高圧側電圧または前記低圧側電圧、及び前記充放電コンデンサの電圧を制御するものであるDC/DCコンバータ。 - 前記第2の算出値は、前記高圧側電圧の指令値に予め設定された第2の定数を乗じた値である請求項1に記載のDC/DCコンバータ。
- 低圧側電圧を保持する低圧側平滑コンデンサ、負極側端子が前記低圧側平滑コンデンサの負極側端子に接続され高圧側電圧を保持する高圧側平滑コンデンサ、一端が前記低圧側平滑コンデンサの負極側端子に接続された第1の半導体回路、一端が前記第1の半導体回路の他端に接続され他端がリアクトルを介して前記低圧側平滑コンデンサの正極側端子に接続された第2の半導体回路、一端が前記第2の半導体回路の他端に接続された第3の半導体回路、一端が前記第3の半導体回路の他端に接続され他端が前記高圧側平滑コンデンサの正極側端子に接続された第4の半導体回路、一端が前記第1の半導体回路と前記第2の半導体回路との中間接続点に接続され他端が前記第3の半導体回路と前記第4の半導体回路との中間接続点に接続された充放電コンデンサ、および前記各半導体回路を制御する制御装置を備え、
前記第1および第2の半導体回路にいずれもスイッチング素子の機能を持たせ、
前記第3および第4の半導体回路にいずれもダイオード素子の機能を持たせ、
前記第1および第2の半導体回路に持たせたスイッチング素子のオンオフスイッチング機能によって、入力された前記低圧側平滑コンデンサの電圧を昇圧した電圧に変換して前記高圧側平滑コンデンサに出力する昇圧動作と、
前記第3および第4の半導体回路にいずれもスイッチング素子の機能を持たせ、
前記第1および第2の半導体回路にいずれもダイオード素子の機能を持たせ、
前記第3および第4の半導体回路に持たせたスイッチング素子のオンオフスイッチング機能によって、入力された前記高圧側平滑コンデンサの電圧を降圧した電圧に変換して前記低圧側平滑コンデンサに出力する降圧動作とのうち少なくとも一方の動作が可能なDC/DCコンバータにおいて、
前記制御装置は、第1の演算部と第2の演算部と開閉制御部とを有し、
前記第1の演算部は、前記高圧側電圧の指令値と前記充放電コンデンサの電圧の検出値との差電圧に基づき算出される第3の算出値と前記高圧側電圧の検出値との差電圧に基づいて第1の演算値を算出し、
前記第2の演算部は前記高圧側平滑コンデンサの電圧の検出値に基づき算出される第4の算出値と前記充放電コンデンサの電圧の検出値との差電圧に基づいて第2の演算値を演算し、
前記開閉制御部は前記第1の演算値と前記第2の演算値とに基づいて通電率を求め、この通電率に基づき前記オンオフスイッチング機能を持たせた前記第1および第2の半導体回路または前記オンオフスイッチング機能を持たせた前記第3および第4の半導体回路の開閉動作を制御することによって、前記高圧側電圧または前記低圧側電圧、及び前記充放電コンデンサの電圧を制御するものであるDC/DCコンバータ。 - 前記第3の算出値は、前記高圧側電圧の指令値と前記充放電コンデンサの電圧の検出値との差が予め設定された第1の電圧値より大きい場合、前記充放電コンデンサの電圧の検出値と予め設定された第2の電圧値との和となる値であり、前記高圧側電圧の指令値と前記充放電コンデンサの電圧の検出値との差が前記第1の電圧値以下の場合、前記高圧側電圧の指令値である請求項3に記載のDC/DCコンバータ。
- 前記第4の算出値は、前記高圧側平滑コンデンサの電圧の検出値に予め設定された第4の定数を乗じた値である請求項3に記載のDC/DCコンバータ。
- 前記第1~第4の半導体回路は、全てスイッチング機能を有するものであり、
前記制御装置は、前記第1~第4の半導体回路を開閉制御するものである請求項1から請求項5のいずれか1項に記載のDC/DCコンバータ。 - 前記第1及び第2の半導体回路がスイッチング機能を有するものであるとき前記第3及び第4の半導体回路は一方向導通素子または同期整流回路であり、前記第3及び第4の半導体回路がスイッチング機能を有するものであるとき前記第1及び第2の半導体回路は一方向導通素子または同期整流回路である請求項1から請求項5のいずれか1項に記載のDC/DCコンバータ。
- 前記開閉制御部は、前記第1の演算値と前記第2の演算値との加算値及び前記第1の演算値と前記第2の演算値との減算値に基づいて前記通電率を求めるものである請求項1から請求項7のいずれか1項に記載のDC/DCコンバータ。
- 前記リアクトルを流れる電流の大きさを判定するリアクトル電流判定部を有するものであって、
前記第2の演算部は、前記リアクトル電流判定部の判定結果に応じて前記第2の演算値の大きさを変化させるものである請求項1から請求項8のいずれか1項に記載のDC/DCコンバータ。 - 前記リアクトルを流れる電流の方向を検出するリアクトル電流方向検出部を有するものであって、
前記第2の演算部は、前記リアクトル電流方向検出部の検出結果に応じて前記第2の演算値の極性を変化させるものである請求項1から請求項8のいずれか1項に記載のDC/DCコンバータ。 - 前記リアクトル電流方向検出部は、前記半導体回路の動作状態と前記充放電コンデンサの電圧変化とによって前記リアクトルを流れる電流の方向を検出するものである請求項10に記載のDC/DCコンバータ。
- 前記半導体回路は、ワイドバンドギャップ半導体によって形成された半導体素子を有するものである請求項1から請求項11のいずれか1項に記載のDC/DCコンバータ。
- 前記ワイドバンドギャップ半導体は、炭化珪素、窒化ガリウム系材料またはダイヤモンドである請求項12に記載のDC/DCコンバータ。
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US9893613B1 (en) * | 2016-07-29 | 2018-02-13 | Mitsubishi Electric Corporation | DC/DC converter |
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WO2012014912A1 (ja) * | 2010-07-30 | 2012-02-02 | 三菱電機株式会社 | Dc/dcコンバータ |
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CN107112897A (zh) | 2017-08-29 |
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