JP6444453B2 - Control device and control method for power conversion device - Google Patents

Description

  The present invention relates to a control device and a control method for controlling a power conversion device in which a smoothing capacitor is provided between an output side of a first power conversion circuit and an input side of a second power conversion circuit.

  2. Description of the Related Art Conventionally, there is known a power converter configured to perform power factor improvement control of an AC power supply and convert power from the AC power supply. Such a power conversion device includes a front-stage AC-DC conversion circuit, a rear-stage DC-DC conversion circuit, and a smoothing capacitor connected to a link portion between the AC-DC conversion circuit and the DC-DC conversion circuit. Configured. This smoothing capacitor is provided for smoothing the output power from the power converter.

  In order for the DC-DC conversion circuit to stably output a desired voltage, the capacitance of the smoothing capacitor is determined so that the amplitude value of the ripple voltage component of the smoothing capacitor is within an allowable range.

  For example, when the amplitude value of the ripple voltage component of the smoothing capacitor becomes large and the voltage fluctuation at the input terminal of the DC-DC converter circuit becomes severe, the control of the DC-DC converter circuit becomes unstable, and a desired voltage is obtained. Problems such as inability to occur. Therefore, it is necessary to keep the amplitude value of the ripple voltage component of the smoothing capacitor within the allowable range so that the DC-DC conversion circuit can stably output the voltage within the specification range. Further, an allowable ripple current is set for an electrolytic capacitor mainly used as a smoothing capacitor. Therefore, it is necessary to limit the amplitude value of the ripple voltage component so as to be within this allowable value.

  On the other hand, a capacitor used for smoothing causes a decrease in capacitance due to temperature characteristics, individual differences, life, etc., so that the ripple voltage component in a state where the capacitance as much as possible can be reduced. The amplitude value needs to be within an allowable range. However, under actual use, the capacitance of the smoothing capacitor hardly reaches a minimum value considering the temperature characteristics, individual differences, and the decrease in capacitance due to the lifetime. For this reason, extra capacitance of the smoothing capacitor is mounted, leading to an increase in cost and size of the power converter.

  In such a power conversion device, it is desirable to devise a method for reducing the excess capacitance of the smoothing capacitor by reducing the amplitude value of the ripple voltage component of the smoothing capacitor. As a specific example, a method has been proposed in which the smoothing capacitor voltage control is performed in a control cycle shorter than the system cycle, thereby reducing the amplitude value of the ripple voltage component of the smoothing capacitor and reducing the capacitance of the smoothing capacitor ( For example, see Patent Document 1).

  In the prior art described in Patent Document 1, in a power conversion device including an AC-DC conversion circuit, a DC-DC conversion circuit, and a smoothing capacitor, voltage control of the smoothing capacitor is performed as follows. That is, based on the input current input to the AC-DC conversion circuit or the output current output from the DC-DC conversion circuit, the capacitor voltage of the smoothing capacitor, and the capacitor voltage command value, switching of the DC-DC conversion circuit is performed. The voltage control of the smoothing capacitor is performed by changing the duty ratio of the ON / OFF signal of the element.

JP-A-2015-139337

  Here, in the prior art described in Patent Document 1, the output current from the DC-DC conversion circuit is the same as the amplitude value of the ripple voltage component so that the amplitude value of the ripple voltage component of the smoothing capacitor is within an allowable range. Control that varies with period is performed. Therefore, the ripple is superimposed on the output current as much as the amplitude value of the ripple voltage component of the smoothing capacitor is suppressed.

  As a result, when the load connected to the power converter is, for example, a battery, the battery is deteriorated. Further, when the load is a motor, for example, a ripple is superimposed on the torque output by the motor.

  The present invention has been made in order to solve the above-described problems. The amplitude value of the ripple voltage component of the smoothing capacitor in the power converter is within an allowable range, and the output current from the power converter is reduced. It aims at obtaining the control apparatus and control method of a power converter device which suppress that a ripple is superimposed.

The control device of the power conversion device according to the present invention includes a smoothing capacitor, a first power conversion circuit whose input side is connected to the input power supply, and whose output side is connected to the smoothing capacitor, whose input side is connected to the smoothing capacitor, and whose output side is the load. And a second power conversion circuit connected to the power conversion device, the control device for controlling the power conversion device, the output power becomes the output power command value for controlling the output power to the load of the power conversion device And a power conversion control unit that controls the first power conversion circuit and the second power conversion circuit so that the capacitor voltage becomes the capacitor voltage command value for controlling the capacitor voltage of the smoothing capacitor, and obtains the capacitor voltage and, the obtained capacitor voltage so as to fall within the allowable voltage range based on the capacitor voltage command value, the command value adjusting section for adjusting the output power command value , Bei give a command value adjusting section calculates an amplitude value of the obtained capacitor voltage, the capacitor voltage amplitude is calculated amplitude value, and the allowable ripple current of the smoothing capacitor to define the upper limit of the allowable voltage range The allowable amplitude value determined based on the stability limit of the control system of the second power conversion circuit is compared, and the output power command value is adjusted based on the comparison result .

The control method of the power converter according to the present invention includes a smoothing capacitor, a first power conversion circuit in which an input side is connected to an input power supply, an output side is connected to the smoothing capacitor, an input side is connected to the smoothing capacitor, and an output side is a load. And a second power conversion circuit connected to the power conversion device, the control method for controlling the power conversion device, wherein the output power becomes the output power command value for controlling the output power to the load of the power conversion device And the step of controlling the first power conversion circuit and the second power conversion circuit so that the capacitor voltage becomes the capacitor voltage command value for controlling the capacitor voltage of the smoothing capacitor, and acquiring and acquiring the capacitor voltage capacitor voltage is to fall within allowable voltage range based on the capacitor voltage command value, Bei give a, and adjusting the output power command value In the step of adjusting the output power command value, the amplitude value of the acquired capacitor voltage is calculated, the capacitor voltage amplitude value that is the calculated amplitude value, the upper limit value of the voltage allowable range are defined, the allowable ripple current of the smoothing capacitor, The allowable amplitude value determined based on the stability limit of the control system of the power conversion circuit 2 is compared, and the output power command value is adjusted based on the comparison result .

  Advantageous Effects of Invention According to the present invention, the control of the power converter that suppresses the ripple from being superimposed on the output current from the power converter while keeping the amplitude value of the ripple voltage component of the smoothing capacitor in the power converter within the allowable range. An apparatus and a control method can be obtained.

It is a block diagram which shows the electric power supply system provided with the control apparatus of the power converter device in Embodiment 1 of this invention. FIG. 2 is a block diagram illustrating an arithmetic unit that functions when the AC-DC control unit of FIG. 1 controls an AC-DC conversion circuit according to an output current control mode. FIG. 2 is a block diagram illustrating a computing unit that functions when the DC-DC control unit of FIG. 1 controls a DC-DC conversion circuit according to an output current control mode. FIG. 2 is a block diagram illustrating a computing unit that functions when the DC-DC control unit of FIG. 1 controls a DC-DC conversion circuit according to an output current control mode. FIG. 2 is a block diagram illustrating an arithmetic unit that functions when the AC-DC control unit of FIG. 1 controls an AC-DC conversion circuit according to an input current control mode. FIG. 2 is a block diagram illustrating an arithmetic unit that functions when the DC-DC control unit of FIG. 1 controls a DC-DC conversion circuit according to an input current control mode. It is a flowchart which shows a series of operation | movement of the command value adjustment part of FIG. It is explanatory drawing which shows an example of the behavior of a capacitor | condenser voltage and output power when the command value adjustment part of FIG. 1 performs adjustment which lowers | hangs output power command value. It is a block diagram which shows the electric power supply system provided with the control apparatus of the power converter device in Embodiment 2 of this invention. FIG. 10 is a block diagram illustrating an arithmetic unit that functions when the AC-DC control unit and the DC-DC control unit of FIG. 9 calculate a capacitor voltage command value. It is a flowchart which shows a series of operation | movement of the command value adjustment part of FIG. It is explanatory drawing which shows an example of the behavior of a capacitor | condenser voltage and output electric power when the command value adjustment part of FIG. 9 performs adjustment which reduces an adjustment value. It is explanatory drawing which shows an example of the behavior of a capacitor | condenser voltage and output electric power when the command value adjustment part of FIG. 9 performs adjustment which raises an adjustment value.

  Hereinafter, a control device and a control method of a power converter according to the present invention will be described with reference to the drawings according to a preferred embodiment. In the description of the drawings, the same portions or corresponding portions are denoted by the same reference numerals, and redundant description is omitted. In each embodiment, the case where the present invention is applied to a power conversion device used for supplying power from an AC power source such as a household power source or a commercial power source to a load such as a secondary battery is illustrated. .

Embodiment 1 FIG.
FIG. 1 is a configuration diagram illustrating a power supply system including a control device 2 for a power conversion device according to Embodiment 1 of the present invention. In FIG. 1, the power supply system includes a power conversion device 1, a control device 2 that controls the power conversion device 1, an AC power source 3 as an input power source, and a load 4.

  The power conversion device 1 includes an AC-DC conversion circuit 11 as a first power conversion circuit, a DC-DC conversion circuit 12 as a second power conversion circuit, a smoothing capacitor 13, an input voltage detector 14, An input current detector 15, a capacitor voltage detector 16, an output voltage detector 17, and an output current detector 18 are provided.

  The AC-DC conversion circuit 11 has an input side connected to the AC power supply 3 and an output side connected to the smoothing capacitor 13. The DC / DC conversion circuit 12 has an input side connected to the smoothing capacitor 13 and an output side connected to the load 4. That is, the AC power supply 3 is connected to the input end of the AC-DC conversion circuit 11. The input terminal of the DC-DC conversion circuit 12 and the smoothing capacitor 13 are connected to the output terminal of the AC-DC conversion circuit 11. A load 4 is connected to the output end of the DC-DC conversion circuit 12.

  The AC-DC conversion circuit 11 includes a diode D1, a diode bridge circuit 111 including diodes D11 to D14, a switching element Q1, and a smoothing reactor 112. For example, a MOSFET (Metal Oxide Semiconductor Field Effect Transistor) can be used as the switching element Q1.

  The AC power supply 3 is connected to the diode bridge circuit 111 through the input terminal of the AC-DC conversion circuit 11.

  In the AC-DC conversion circuit 11, the diode D1 is provided on the upper arm on the high voltage side, and the switching element Q1 is provided on the lower arm on the low voltage side. The cathode of the diode D1 is connected to the high voltage side wiring, and the anode thereof is connected to the drain terminal of the switching element Q1 and the smoothing reactor 112. The source terminal of the switching element Q1 is connected to the low voltage side wiring.

  The DC-DC conversion circuit 12 includes a bridge circuit 121 including switching elements Q2 to Q5, a transformer 122 including a primary side winding 122a and a secondary side winding 122b, and diodes D21 to D24. A diode bridge circuit 123 and a smoothing reactor 124 are provided. For example, MOSFETs can be used as the switching elements Q2 to Q5.

  In the bridge circuit 121, the switching element Q2 and the switching element Q4 are provided on the upper arm on the high voltage side, and the switching element Q3 and the switching element Q5 are provided on the lower arm on the low voltage side.

  The drain terminal of the switching element Q2 is connected to the high voltage side wiring, and its source terminal is connected to the drain terminal of the switching element Q3 and one end of the primary side winding 122a. The drain terminal of the switching element Q4 is connected to the high voltage side wiring, and its source terminal is connected to the drain terminal of the switching element Q5 and the other end of the primary side winding 122a. The source terminal of the switching element Q3 and the source terminal of the switching element Q5 are both connected to the low voltage side wiring.

  In the diode bridge circuit 123, the diode D21 and the diode D23 are provided on the upper arm on the high voltage side, and the diode D22 and the diode D24 are provided on the lower arm on the low voltage side.

  The cathode of the diode D21 is connected to the high-voltage side wiring, and its anode is connected to the cathode of the diode D22 and one end of the secondary winding 122b. The cathode of the diode D23 is connected to the high voltage side wiring, and the anode thereof is connected to the cathode of the diode D24 and the other end of the secondary winding 122b. Both the anode of the diode D21 and the anode of the diode D23 are connected to the low-voltage side wiring. The high voltage side wiring is connected to the load 4 via the output terminal of the DC-DC conversion circuit 12 via the smoothing reactor 124.

  The smoothing capacitor 13 is provided at the input end of the DC-DC conversion circuit 12, and has one end connected to the high-voltage side wiring and the other end connected to the low-voltage side wiring. As a result, the smoothing capacitor 13 is connected in parallel with the bridge circuit 121.

  The input voltage detector 14 is provided at the input end of the AC-DC conversion circuit 11 and detects the input voltage Vac input from the AC power supply 3. The input current detector 15 is provided between the connection point connecting the drain of the switching element Q1 and the anode of the diode D1 and the smoothing reactor 112, and detects the input current Iac.

  The capacitor voltage detector 16 is connected in parallel to the smoothing capacitor 13 and detects a capacitor voltage Vc that is a voltage applied to the smoothing capacitor 13.

  The output voltage detector 17 is connected in parallel to the load 4 and detects the output voltage Vout. The output current detector 18 is provided on the low voltage wiring side between the diode bridge circuit 123 and the load 4 and detects the output current Iout output from the DC-DC conversion circuit 12 to the load 4.

  The control device 2 includes, for example, a microcomputer that executes arithmetic processing, a ROM (Read Only Memory) that stores data such as program data and fixed value data, and a RAM that can be sequentially rewritten by updating the stored data ( Random Access Memory).

  The control device 2 includes a command value adjustment unit 21 that transmits an output power command value Pout * for controlling the output power Pout to the load 4 of the power conversion device 1, and an AC-DC that controls the AC-DC conversion circuit 11. A control unit 22 and a DC-DC control unit 23 that controls the DC-DC conversion circuit 12 are provided.

  The command value adjusting unit 21 is set in advance so that the capacitor voltage Vc acquired from the capacitor voltage detector 16 falls within a voltage allowable range based on the capacitor voltage command value Vc * for controlling the capacitor voltage Vc. By adjusting the output power command value, the adjusted output power command value Pout * is generated. The command value adjustment unit 21 transmits the output power command value Pout * to the AC-DC control unit 22 and the DC-DC control unit 23.

  The output power command value Pout * includes an input current command value Iac * for controlling the input current Iac, an output current command value Iout * for controlling the output current Iout, and an output for controlling the output voltage Vout. This is for changing the voltage command value Vout *.

  The AC-DC control unit 22 detects the input current Iac acquired from the input current detector 15, the capacitor voltage Vc acquired from the capacitor voltage detector 16, the input voltage Vac acquired from the input voltage detector 14, and the output voltage detection. The control signal for controlling the duty ratio of the switching element Q1 is generated using the output voltage Vout acquired from the device 17 and the output power command value Pout * received from the command value adjusting unit 21, and the control signal is switched. Transmit to element Q1.

  The DC-DC control unit 23 outputs the output current Iout acquired from the output current detector 18, the capacitor voltage Vc acquired from the capacitor voltage detector 16, the input voltage Vac acquired from the input voltage detector 14, and the output voltage detection. A control signal for controlling the duty ratio of each of the switching elements Q2 to Q5 is generated using the output voltage Vout acquired from the device 17 and the output power command value Pout * received from the command value adjusting unit 21; A control signal is transmitted to each switching element Q2-Q5.

  Next, operations of the AC-DC control unit 22 and the DC-DC control unit 23 of the control device 2 will be described with reference to FIGS.

  Here, the AC-DC control unit 22 and the DC-DC control unit 23 as the power conversion control unit have the output power command value Pout * as the output power Pout and the capacitor voltage command value Vc * as the capacitor voltage Vc. Thus, the AC-DC conversion circuit 11 and the DC-DC conversion circuit 12 are controlled. The AC-DC control unit 22 and the DC-DC control unit 23 control the AC-DC conversion circuit 11 and the DC-DC conversion circuit 12 using the output power command value Pout * and the capacitor voltage command value Vc *. The mode includes an output current control mode and an input current control mode.

  The output current control mode is a mode in which the output current Iout output from the DC-DC conversion circuit 12 to the load 4 is controlled to become the output current command value Iout *. The input current control mode is a mode in which the input current Iac input from the AC power supply 3 to the AC-DC conversion circuit 11 is controlled to be the input current command value Iac *.

  First, a case where the AC-DC control unit 22 operates according to the output current control mode will be described with reference to FIG. FIG. 2 is a block diagram showing an arithmetic unit 24 that functions when the AC-DC control unit 22 of FIG. 1 controls the AC-DC conversion circuit 11 according to the output current control mode.

  When the arithmetic unit 24 provided in the AC-DC control unit 22 controls the AC-DC conversion circuit 11 according to the output current control mode, the input power factor is maintained while maintaining the capacitor voltage Vc at the capacitor voltage command value Vc *. The input current Iac is controlled to be 1.

  The computing unit 24 includes a subtractor 241, a PI controller 242, a multiplier 243, a subtractor 244, a PI controller 245, and a PWM signal generator 246.

  The subtractor 241 calculates a difference between the capacitor voltage Vc detected by the capacitor voltage detector 16 and a preset capacitor voltage command value Vc *. The PI controller 242 calculates the amplitude command value of the input current Iac by performing feedback control, that is, PI control so that the difference calculated by the subtractor 241 becomes zero.

  The multiplier 243 calculates a sine wave input current command value Iac * synchronized with the input voltage Vac based on the amplitude command value of the input current Iac calculated by the PI controller 242. The subtractor 244 calculates the difference between the input current command value Iac * calculated by the multiplier 243 and the input current Iac detected by the input current detector 15.

  The PI controller 245 controls the generation of the PWM signal by the PWM signal generator 246 by performing feedback control, that is, PI control so that the difference calculated by the subtractor 244 becomes zero. The PWM signal generator 246 generates a PWM signal as a control signal for controlling the duty ratio of the switching element Q1 according to the control from the PI controller 245.

  Next, a case where the DC-DC control unit 23 operates according to the output current control mode will be described with reference to FIG. FIG. 3 is a block diagram showing an arithmetic unit 25 that functions when the DC-DC control unit 23 of FIG. 1 controls the DC-DC conversion circuit 12 according to the output current control mode.

  When the arithmetic unit 25 provided in the DC-DC control unit 23 controls the DC-DC conversion circuit 12 according to the output current control mode, the output current Iout becomes the output current command value Iout * or the output power Pout. Is controlled to become the output power command value Pout *.

  The computing unit 25 includes a multiplier 251, a multiplexer 252, a subtracter 253, a PI controller 254, and a PWM signal generator 255.

  The multiplier 251 calculates the output current command value Iout * ′ by multiplying the output power command value Pout * by the inverse number of the output voltage Vout detected by the output voltage detector 17. The multiplexer 252 selects the smaller one of the output current command value Iout * and the output current command value Iout * ′ calculated by the multiplier 251 as the output current command value Iout * ″.

  The subtractor 253 calculates a difference between the output current command value Iout * ″ selected by the multiplexer 252 and the output current Iout detected by the output current detector 18.

  The PI controller 254 controls the generation of the PWM signal by the PWM signal generator 255 by performing feedback control, that is, PI control so that the difference calculated by the subtractor 253 becomes zero. The PWM signal generator 255 generates a PWM signal as a control signal for controlling each duty ratio of the switching elements Q2 to Q5 according to the control from the PI controller 254.

  In the output current control mode, the DC-DC conversion circuit 12 is controlled so that the output voltage Vout becomes the output voltage command value Vout * or the output power Pout becomes the output power command value Pout *. It may be possible. Such control will be described with reference to FIG. FIG. 4 is a block diagram showing a computing unit 26 that functions when the DC-DC control unit 23 of FIG. 1 controls the DC-DC conversion circuit 12 according to the output current control mode.

  The computing unit 26 includes a multiplier 261, a multiplexer 262, a subtractor 263, and a PI controller 264.

  The multiplier 261 calculates the output voltage command value Vout * ′ by multiplying the output power command value Pout * by the reciprocal of the output current Iout detected by the output current detector 18. The multiplexer 262 selects the smaller one of the output voltage command value Vout * and the output voltage command value Vout * ′ calculated by the multiplier 261 as the output voltage command value Vout * ″.

  The subtractor 263 calculates a difference between the output voltage command value Vout * ″ selected by the multiplexer 262 and the output voltage Vout detected by the output voltage detector 17.

  The PI controller 264 calculates the output current command value Iout * by performing feedback control, that is, PI control so that the difference calculated by the subtracter 263 becomes zero. The output current command value Iout * is input to the arithmetic unit 25 of FIG. 3, and the output voltage Vout is controlled to become the output voltage command value Vout * ″. In this case, the multiplexer 252 selects the output current command value Iout * as the output current command value Iout * ″.

  In this way, by configuring the power conversion device 1 to be controlled according to the output current control mode shown in FIGS. 2 to 3, the output current Iout can be obtained using the output power command value Pout * and the capacitor voltage command value Vc *. Can be controlled to a desired value. Further, by configuring the power conversion device 1 to be controlled according to the output current control mode shown in FIGS. 2 to 4, the output voltage Vout is desired using the output power command value Pout * and the capacitor voltage command value Vc *. The value can be controlled.

  Next, the case where the AC-DC control unit 22 operates according to the input current control mode will be described with reference to FIG. FIG. 5 is a block diagram showing a computing unit 27 that functions when the AC-DC control unit 22 of FIG. 1 controls the AC-DC conversion circuit 11 according to the input current control mode.

  When the arithmetic unit 27 included in the AC-DC control unit 22 controls the AC-DC conversion circuit 11 according to the input current control mode, the input current Iac becomes the input current command value Iac * or the output power Pout. Is controlled to be the output power command value Pout *.

  The computing unit 27 includes a multiplier 271, a multiplexer 272, a multiplier 273, a subtracter 274, a PI controller 275, and a PWM signal generator 276.

  The multiplier 271 calculates the input current command value Iac * ′ by multiplying the output power command value Pout * by the inverse of the input voltage Vac detected by the input voltage detector 14. The multiplexer 272 selects the smaller one of the input current command value Iac * and the input current command value Iac * ′ calculated by the multiplier 271 as the amplitude command value of the input current Iac.

  The multiplier 273 calculates a sine wave input current command value Iac * ″ synchronized with the input voltage Vac based on the amplitude command value of the input current Iac selected by the multiplexer 272. The subtractor 274 calculates the difference between the input current command value Iac * ″ calculated by the multiplier 273 and the input current Iac detected by the input current detector 15.

  The PI controller 275 controls the generation of the PWM signal by the PWM signal generator 276 by performing feedback control, that is, PI control so that the difference calculated by the subtracter 274 becomes zero. The PWM signal generator 276 generates a PWM signal as a control signal for controlling the duty ratio of the switching element Q1 in accordance with the control from the PI controller 275.

  Next, a case where the DC-DC control unit 23 operates according to the input current control mode will be described with reference to FIG. FIG. 6 is a block diagram showing a computing unit 28 that functions when the DC-DC control unit 23 of FIG. 1 controls the DC-DC conversion circuit 12 according to the input current control mode.

  When the arithmetic unit 28 provided in the DC-DC control unit 23 controls the DC-DC conversion circuit 12 according to the input current control mode, the input power factor is maintained while maintaining the capacitor voltage Vc at the capacitor voltage command value Vc *. The output current Iout is controlled to be 1.

  The computing unit 28 includes a subtracter 281, a PI controller 282, a subtracter 283, a PI controller 284, and a PWM signal generator 285.

  The subtractor 281 calculates a difference between the capacitor voltage Vc detected by the capacitor voltage detector 16 and a preset capacitor voltage command value Vc *. The PI controller 282 calculates the output current command value Iout * by performing feedback control, that is, PI control so that the difference calculated by the subtractor 281 becomes zero.

  The subtractor 283 calculates a difference between the output current command value Iout * calculated by the PI controller 282 and the output current Iout detected by the output current detector 18.

  The PI controller 284 controls the generation of the PWM signal by the PWM signal generator 285 by performing feedback control, that is, PI control so that the difference calculated by the subtracter 283 becomes zero. The PWM signal generator 285 generates a PWM signal as a control signal for controlling each duty ratio of the switching elements Q2 to Q5 according to the control from the PI controller 284.

  In this way, by configuring the power conversion device 1 to be controlled according to the input current control mode shown in FIGS. 5 and 6, the input current is calculated using the output power command value Pout * and the capacitor voltage command value Vc *. It can be controlled to a desired value.

  Next, operation | movement of the command value adjustment part 21 of the control apparatus 2 is demonstrated, referring FIG. FIG. 7 is a flowchart showing a series of operations of the command value adjusting unit 21 of FIG. Note that the processing in the flowchart of FIG. 7 is repeatedly performed at a sufficiently short period compared to the frequency of the input current Iac, for example.

  In step S101, the command value adjusting unit 21 calculates an amplitude value of the capacitor voltage (hereinafter referred to as a capacitor voltage amplitude value) detected by the capacitor voltage detector 16 during a certain period, and the process proceeds to step S102. move on. Since the detected capacitor voltage includes a ripple voltage component, it has a waveform.

  Various methods are conceivable as a method for calculating the capacitor voltage amplitude value.For example, a method for directly obtaining the amplitude value from the voltage waveform of the detected capacitor voltage, a maximum value of the detected capacitor voltage, and the like. A method for obtaining the average of the sum of the minimum values as the amplitude value can be considered.

  In step S102, the command value adjustment unit 21 determines whether or not the capacitor voltage amplitude value calculated in step S101 is larger than a preset allowable amplitude value. If it is determined that the capacitor voltage amplitude value is larger than the allowable amplitude value, the process proceeds to step S103. If it is determined that the capacitor voltage amplitude value is equal to or smaller than the allowable amplitude value, the process proceeds to step S106. Proceed to

  The allowable amplitude value is determined in consideration of the allowable ripple current of the smoothing capacitor 13 and the stability limit of the control system of the DC-DC conversion circuit 12, for example.

  Specifically, first, a ripple voltage amplitude value that satisfies a predetermined allowable ripple current of the smoothing capacitor 13 is calculated. Subsequently, in the control system design of the DC-DC conversion circuit 12, an input fluctuation amplitude value that becomes a stability limit is calculated, or the input fluctuation amplitude value is obtained from simulation. Finally, the smaller one of the ripple voltage amplitude value and the input fluctuation amplitude value obtained in this way is set as an allowable amplitude value.

  In step S103, the command value adjustment unit 21 performs adjustment to lower the current output power command value Pout *, and the process proceeds to step S104.

  The output power command value Pout * may be lowered in any way. For example, a case where the output power command value Pout * is lowered by a preset value, or the output power command value Pout * is preset. A case where the amount is reduced by the proportion of the ratio is considered.

  Here, adjustment for decreasing the output power command value Pout * will be described with reference to FIG. FIG. 8 is an explanatory diagram showing an example of the behavior of the capacitor voltage Vc and the output power Pout when the command value adjusting unit 21 in FIG. 1 performs the adjustment to lower the output power command value Pout *.

  In FIG. 8, the upper part shows the time change of the capacitor voltage Vc [V], and the lower part shows the time change of the output power Pout [W]. FIG. 8 also shows a preset capacitor voltage command value Vc * and an allowable amplitude value. Furthermore, it is assumed that adjustment is performed to reduce the output power command value Pout * during the shaded portion of FIG.

  As shown in FIG. 8, the allowable amplitude value defines an upper limit value and a lower limit value of a voltage allowable range based on the capacitor voltage command value Vc *. That is, in the allowable voltage range, the difference between the upper limit value and the capacitor voltage command value Vc * and the difference between the capacitor voltage command value Vc * and the lower limit value are equal to each other, and the value becomes the allowable amplitude value.

  As shown in FIG. 8, by adjusting the output power command value Pout *, the capacitor voltage amplitude value does not exceed the allowable amplitude value as the output power Pout decreases. In this way, the capacitor voltage amplitude value is compared with the allowable amplitude value, and if the capacitor voltage amplitude value is larger as a result of the comparison, by adjusting the output power command value Pout *, the ripple voltage component It is possible to make the amplitude value fall within an allowable range.

  As described above, the command value adjustment unit 21 performs adjustment to lower the output power command value Pout * when the capacitor voltage amplitude value is larger than the allowable amplitude value as a comparison result.

  Returning to the description of FIG. 7, in step S104, it is determined whether or not the output power command value Pout * after the adjustment in step S103 is equal to or less than a preset value. If it is determined that the output power command value Pout * is less than or equal to the set value, the process proceeds to step S105. If it is determined that the output power command value Pout * is greater than the set value, the process is performed. End.

  In step S <b> 105, the command value adjustment unit 21 stops driving the power conversion device 1 and the process ends.

  Note that various methods are conceivable as a method for stopping the driving of the power conversion device 1. For example, the command value adjusting unit 21 sets the output power command value Pout * to zero, and the command value adjusting unit 21 is AC−. A method of instructing the DC control unit 22 and the DC-DC control unit 23 to stop driving the power conversion device 1 is conceivable.

  Here, if the adjusted output power command value Pout * is equal to or less than the set value, the ripple voltage of the smoothing capacitor 13 is caused by a significant deterioration of the power conversion device 1 such as a decrease in capacitance due to the life of the smoothing capacitor 13. It is thought that the ingredient has changed. Therefore, in order to prevent further deterioration of the power conversion device 1, the drive of the power conversion device 1 is stopped when the adjusted output power command value Pout * is equal to or less than the set value.

  In step S105, the command value adjustment unit 21 may be configured to issue a warning. Specifically, the command value adjustment unit 21 performs operations such as issuing an alarm, turning on a lamp, and outputting a signal to another control circuit as a warning. With this configuration, it is possible to cope with a case where inconvenience occurs in the load 4, other devices, etc. by stopping the power supply from the power conversion device 1.

  As described above, when the adjusted output power command value Pout * is equal to or less than the set value, the command value adjusting unit 21 stops driving the power conversion device 1 or issues a warning.

  In step S106, the command value adjustment unit 21 determines whether or not power limitation has already been performed. If the command value adjustment unit 21 has previously performed the process of step S103 (that is, the adjustment to lower the output power command value Pout *), the command value adjustment unit 21 determines that the power limitation has already been performed, and the process proceeds to step S107. move on. On the other hand, if the process of step S103 has not been performed before, the command value adjustment unit 21 determines that power limitation has not been performed yet, and the process ends.

  In step S107, the command value adjustment unit 21 performs adjustment to increase the current output power command value Pout *, and the process ends.

  The output power command value Pout * may be increased in any way. For example, a case where the output power command value Pout * is increased by a preset value, or the output power command value Pout * is set in advance. The case where it raises only the part of the ratio done is considered.

  In this way, the command value adjustment unit 21 performs the adjustment to lower the output power command value Pout *, and as a comparison result, when the capacitor voltage amplitude value becomes equal to or less than the allowable amplitude value, the command value adjustment unit 21 sets the output power command value Pout *. Adjust to raise.

  That is, the command value adjustment unit 21 outputs the output when the capacitor voltage amplitude value is reduced by the adjustment to lower the output power command value Pout * and the capacitor voltage amplitude value has a margin with respect to the allowable amplitude value. Adjustment is performed to increase the power command value Pout *. Therefore, it is possible to automatically detect that the usage environment of the power conversion device 1 has been improved, and to allow the power conversion device 1 to output as much output power as possible.

  As described above, as can be seen from the description of FIG. 7, the command value adjusting unit 21 acquires the capacitor voltage Vc so that the acquired capacitor voltage Vc falls within the allowable voltage range based on the capacitor voltage command value Vc *. The output power command value Pout * is adjusted.

  Specifically, the command value adjustment unit 21 calculates the amplitude value of the acquired capacitor voltage Vc, and sets a voltage allowable range based on the capacitor voltage amplitude value that is the calculated amplitude value and the capacitor voltage command value Vc *. The allowable amplitude value that defines the upper limit value and the lower limit value is compared, and the output power command value Pout * is adjusted based on the comparison result.

  In step S102, when the capacitor voltage amplitude value is larger than the allowable amplitude value, the process proceeds to step S103, and a case is shown in which the adjustment is performed to reduce the output power command value Pout *. Even in the case where the capacitor voltage amplitude value is smaller than the allowable amplitude value, the output power command value Pout * may be adjusted to be adjusted as long as the amount of increase of the amplitude exceeds a certain value. With such a configuration, even if the capacitor voltage amplitude value suddenly increases due to an output short circuit abnormality or the like, it can be prevented that the allowable amplitude value is significantly exceeded.

  In step S103, the command value adjustment unit 21 obtains a capacitor voltage and calculates a capacitor voltage amplitude value while performing an adjustment to reduce the output power command value Pout *, and the capacitor voltage amplitude value is set to an allowable amplitude value. Adjustment may be made to lower the output power command value Pout * until it falls below. By comprising in this way, it can prevent that output electric power falls indefinitely and the power converter device 1 can output as large output electric power as possible.

  In step S107, the command value adjustment unit 21 obtains a capacitor voltage and calculates a capacitor voltage amplitude value while performing an adjustment to increase the output power command value Pout *, and the capacitor voltage amplitude value is calculated as an allowable amplitude value. Until it becomes, you may perform the adjustment which raises output electric power command value Pout *. With this configuration, it is possible to prevent the output power from rising and the capacitor voltage from exceeding the allowable amplitude value.

  In the first embodiment, the output power command value Pout * is defined as the command value of the output power Pout, and the output power Pout is adjusted by adjusting the output power command value Pout *. However, the present invention is not limited to this form. By defining variables that multiply the command values Iout *, Vout *, and Iac * of the output current Iout, the output voltage Vout, and the input current Iac, and adjusting these variables, A mode may be realized in which the output power Pout is adjusted by directly adjusting the command values Iout *, Vout *, and Iac *. Specifically, for example, when the output power Pout is not adjusted, the variable is set to 1. When the output power Pout is decreased, the variable is decreased and the command values Iout *, Vout *, and Iac * are reduced. A method of multiplication is conceivable.

  As described above, according to the first embodiment, the capacitor voltage of the smoothing capacitor provided between the AC-DC conversion circuit and the DC-DC conversion circuit is acquired, and the acquired capacitor voltage is based on the capacitor voltage command value. The output power command value is adjusted so as to be within the allowable voltage range.

  As a result, even if there is a possibility that the amplitude value of the ripple voltage component of the smoothing capacitor is out of the allowable range due to a decrease in the capacitance of the smoothing capacitor during the operation of the power converter, it is based on the capacitor voltage. The output power command value is adjusted. Therefore, since the amplitude value of the capacitor voltage including the ripple voltage component is reduced, the power converter can be stably operated.

  In addition, since the output power command value is steadily adjusted regardless of the instantaneous voltage value of the smoothing capacitor, the ripple current depending on the ripple voltage component of the smoothing capacitor is prevented from being superimposed on the load current flowing through the load. be able to. As a result, the amplitude value of the capacitor voltage including the ripple voltage component can be within an allowable range even if the capacitance of the smoothing capacitor is reduced due to a change or deterioration of the ambient temperature. Therefore, it is possible to reduce the capacitance of the smoothing capacitor and reduce the cost and size of the power converter.

Embodiment 2. FIG.
In the first embodiment, the control device 2 configured to adjust the output power command value Pout * so that the amplitude value of the capacitor voltage Vc including the ripple voltage component is within the allowable amplitude value range will be described. did. In contrast, the second embodiment of the present invention is configured to adjust the capacitor voltage command value Vc * so that the amplitude value of the capacitor voltage Vc including the ripple voltage component falls within the allowable amplitude value. The control device 2 will be described. In the second embodiment, description of points that are the same as those of the first embodiment will be omitted, and points different from the first embodiment will be mainly described.

  Here, in the first embodiment, the capacitor voltage command value Vc * is constant, the allowable amplitude values on the positive side and the negative side are made equal to the capacitor voltage command value Vc *, and the output power command value Pout * is set. Since the adjustment is performed to reduce the output power Pout, the output power Pout may be limited more than necessary. Therefore, in the second embodiment, the capacitance of the smoothing capacitor 13 is reduced without changing the output power command value Pout * as much as possible by adjusting the capacitor voltage command value Vc *.

  FIG. 9 is a configuration diagram showing a power supply system including the control device 2 of the power conversion device according to Embodiment 2 of the present invention. Command value adjustment unit 21 transmits output power command value Pout * to AC-DC control unit 22 and DC-DC control unit 23, and further provides adjustment value Vc_add for adjusting capacitor voltage command value Vc *. Send. Note that the initial value of the adjustment value Vc_add is zero.

  AC-DC control unit 22 and DC-DC control unit 23 have an output current control mode and an input current control mode, as in the first embodiment. Further, AC-DC control unit 22 and DC-DC control unit 23 in the second embodiment are configured to calculate capacitor voltage command value Vc * shown in FIGS. 2 and 6 as follows. Yes.

  FIG. 10 is a block diagram showing an arithmetic unit 29 that functions when the AC-DC control unit 22 and the DC-DC control unit 23 of FIG. 9 calculate the capacitor voltage command value Vc *.

  The arithmetic unit 29 provided in each of the AC-DC control unit 22 and the DC-DC control unit 23 includes an adder 291. The adder 291 generates the capacitor voltage command value Vc * by adding the adjustment value Vc_add to the preset original command value Vc_ori *.

  Next, operation | movement of the command value adjustment part 21 of the control apparatus 2 is demonstrated, referring FIG. FIG. 11 is a flowchart showing a series of operations of the command value adjusting unit 21 of FIG.

  In step S <b> 201, the command value adjusting unit 21 determines the positive amplitude value and the negative amplitude value from the amplitude value of the capacitor voltage waveform detected during a certain period by the capacitor voltage detector 16 and the original command value Vc_ori *. Is calculated as the capacitor voltage amplitude value, and the process proceeds to step S202. Specifically, the command value adjustment unit 21 calculates the positive amplitude value of the capacitor voltage waveform as the positive amplitude value with reference to the original command value Vc_ori *, and negatively sets the negative amplitude value of the capacitor voltage waveform. Calculate as side amplitude value.

  In step S202, the command value adjustment unit 21 determines whether or not the positive amplitude value calculated in step S201 is larger than the positive allowable amplitude value. If it is determined that the positive-side amplitude value is greater than the positive-side allowable amplitude value, the process proceeds to step S203, and if it is determined that the positive-side amplitude value is equal to or less than the positive-side allowable amplitude value, The process proceeds to step S206.

  In step S203, the command value adjustment unit 21 determines whether or not the negative side amplitude value calculated in step S201 is larger than the negative side allowable amplitude value. If it is determined that the negative side amplitude value is greater than the negative side allowable amplitude value, the process proceeds to step S204, and if it is determined that the negative side amplitude value is equal to or less than the negative side allowable amplitude value, The process proceeds to step S205.

  In step S204, the command value adjustment unit 21 performs adjustment to lower the current output power command value Pout *, similarly to step S103 in FIG. 7, and the process proceeds to the flowchart shown in FIG.

  In step S205, the command value adjustment unit 21 performs adjustment to lower the adjustment value Vc_add, and the process ends.

  The adjustment value Vc_add may be lowered in any way. For example, a case where the adjustment value Vc_add is lowered by a preset value, a case where the adjustment value Vc_add is lowered by a preset ratio, etc. Can be considered.

  Here, adjustment for lowering the adjustment value Vc_add will be described with reference to FIG. FIG. 12 is an explanatory diagram illustrating an example of the behavior of the capacitor voltage Vc and the output power Pout when the command value adjustment unit 21 in FIG. 9 performs adjustment to lower the adjustment value Vc_add.

  In FIG. 12, the upper part shows the time change of the capacitor voltage Vc [V], and the lower part shows the time change of the output power Pout [W]. In addition, FIG. 12 also shows changes over time in the capacitor voltage command value Vc *, the positive allowable amplitude value, and the negative allowable amplitude value. Furthermore, it is assumed that the capacitor voltage command value Vc * is lowered by performing an adjustment that lowers the adjustment value Vc_add during the shaded portion of FIG.

  As shown in FIG. 12, the positive allowable amplitude value defines the upper limit value of the positive voltage allowable range based on the original command value Vc_ori *, and the negative allowable amplitude value is based on the original command value Vc_ori *. The lower limit of the allowable voltage range on the negative side is defined. That is, in the positive voltage allowable range, the difference between the upper limit value and the original command value Vc_ori * is the positive allowable amplitude value, and in the negative voltage allowable range, the difference between the original command value Vc_ori * and the lower limit value is negative. Side allowable amplitude value. Further, since the original command value Vc_ori * is a constant value, the positive side allowable amplitude value and the negative side allowable amplitude value are also constant values.

  As shown in FIG. 12, the adjustment that lowers the adjustment value Vc_add is performed, so that the positive amplitude value does not exceed the positive allowable amplitude value as the capacitor voltage command value Vc * decreases. Thus, if the positive side amplitude value is larger than the positive side allowable amplitude value and the negative side amplitude value is equal to or smaller than the negative side allowable amplitude value, the capacitor voltage command value Vc * is adjusted to decrease, thereby adjusting the capacitor voltage. The amplitude value can fall within the allowable amplitude value range.

  Thus, the command value adjustment unit 21 determines that the capacitor voltage command value is larger when the positive side amplitude value is larger than the positive side allowable amplitude value and the negative side amplitude value is equal to or smaller than the negative side allowable amplitude value as a comparison result. Adjust to lower Vc *.

  Returning to the description of FIG. 11, in step S206, the command value adjustment unit 21 determines whether or not the negative amplitude value calculated in step S201 is larger than the negative allowable amplitude value. When it is determined that the negative side amplitude value is larger than the negative side allowable amplitude value, the process proceeds to step S207, and when it is determined that the negative side amplitude value is equal to or smaller than the negative side allowable amplitude value, The process proceeds to step S208.

  In step S207, the command value adjustment unit 21 performs adjustment to increase the adjustment value Vc_add, and the process ends.

  The adjustment value Vc_add may be increased in any way. For example, the adjustment value Vc_add is increased by a preset value, the adjustment value Vc_add is increased by a preset ratio, or the like. Can be considered.

  Here, the adjustment for increasing the adjustment value Vc_add will be described with reference to FIG. FIG. 13 is an explanatory diagram illustrating an example of the behavior of the capacitor voltage Vc and the output power Pout when the command value adjustment unit 21 in FIG. 9 performs adjustment to increase the adjustment value Vc_add.

  In FIG. 13, the upper part shows the time change of the capacitor voltage Vc [V], and the lower part shows the time change of the output power Pout [W]. In addition, FIG. 13 also illustrates changes over time in the capacitor voltage command value Vc *, the positive-side allowable amplitude value, and the negative-side allowable amplitude value. Furthermore, it is assumed that the capacitor voltage command value Vc * is increased by performing adjustment to increase the adjustment value Vc_add during the shaded portion of FIG.

  As shown in FIG. 13, the positive side allowable amplitude value defines the upper limit value of the positive voltage allowable range with reference to the original command value Vc_ori *, and the negative side allowable amplitude value is based on the original command value Vc_ori *. The lower limit of the allowable voltage range on the negative side is defined. That is, in the positive voltage allowable range, the difference between the upper limit value and the original command value Vc_ori * is the positive allowable amplitude value, and in the negative voltage allowable range, the difference between the original command value Vc_ori * and the lower limit value is Negative side allowable amplitude value. Further, since the original command value Vc_ori * is a constant value, the positive side allowable amplitude value and the negative side allowable amplitude value are also constant values.

  As shown in FIG. 13, by adjusting the adjustment value Vc_add, the negative amplitude value does not exceed the negative allowable amplitude value as the capacitor voltage command value Vc * increases. Thus, if the positive side amplitude value is equal to or less than the positive side allowable amplitude value and the negative side amplitude value is larger than the negative side allowable amplitude value, the ripple voltage is adjusted by increasing the capacitor voltage command value Vc *. The amplitude value of the component can fall within the allowable amplitude value range.

  Thus, as a comparison result, the command value adjustment unit 21 determines that the capacitor voltage command value when the positive side amplitude value is equal to or smaller than the positive side allowable amplitude value and the negative side amplitude value is larger than the negative side allowable amplitude value. Adjust to increase Vc *.

  Returning to the description of FIG. 11, in step S208, the command value adjustment unit 21 determines whether or not the current adjustment value Vc_add is zero. If it is determined that the adjustment value Vc_add is 0, the process ends. If it is determined that the adjustment value Vc_add is not 0, the process proceeds to step S209.

  In step S209, the command value adjustment unit 21 performs adjustment so that the adjustment value Vc_add becomes 0, and the process ends.

  Thus, after adjusting the capacitor voltage command value Vc *, as a comparison result, when the positive side amplitude value is equal to or less than the positive side allowable amplitude value and the negative side amplitude value is equal to or less than the negative side allowable amplitude value, The capacitor voltage command value Vc * is returned to the original value before adjustment.

  That is, the command value adjustment unit 21 is configured to perform an operation of adjusting the adjustment value Vc_add to be zero when the adjustment value Vc_add is other than zero. Therefore, when the positive side amplitude value and the negative side amplitude value are decreased, the capacitor voltage command value Vc * can be automatically returned to the original command value Vc_ori *.

  As described above, as can be seen from the description of FIG. 11, the command value adjustment unit 21 calculates the positive amplitude value and the negative amplitude value from the acquired voltage waveform of the capacitor voltage Vc and the original command value Vc_ori *, and calculates Positive-side amplitude value that specifies the upper-limit value of the allowable voltage range based on the positive-side amplitude value and negative-side amplitude value, and the capacitor voltage command value Vc *, and the negative-side allowable amplitude that specifies the lower-limit value of the allowable voltage range The capacitor voltage command value Vc * is adjusted based on the comparison result.

  In step S205, the command value adjustment unit 21 obtains a capacitor voltage and calculates a positive amplitude value while performing adjustment to reduce the adjustment value Vc_add, and the positive amplitude value is less than the positive allowable amplitude value. Until the adjustment value Vc_add may be lowered. By configuring in this way, it is possible to prevent the capacitor voltage from falling indefinitely, and to make the capacitor voltage as close to the original command value as possible.

  In step S205, the command value adjustment unit 21 obtains a capacitor voltage and calculates a negative amplitude value while performing an adjustment to reduce the adjustment value Vc_add, and the negative amplitude value is less than the negative allowable amplitude value. Adjustment may be performed to lower the adjustment value Vc_add with the upper limit immediately before. With this configuration, it is possible to prevent the capacitor voltage from being lowered indefinitely, and it is possible to place a margin between the amplitude value of the ripple voltage component of the smoothing capacitor 13 and the allowable amplitude value.

  In step S207, the command value adjustment unit 21 obtains the capacitor voltage and calculates the positive amplitude value while performing adjustment to increase the adjustment value Vc_add, and the positive amplitude value exceeds the positive allowable amplitude value. Up to the adjustment value Vc_add may be adjusted. By configuring in this way, it is possible to prevent the capacitor voltage from rising without limit, and to make the capacitor voltage as close to the original command value as possible.

  In step S207, the command value adjustment unit 21 obtains the capacitor voltage and calculates the positive amplitude value while performing adjustment to increase the adjustment value Vc_add, and the positive amplitude value exceeds the positive allowable amplitude value. You may perform the adjustment which raises the adjustment value Vc_add by making it into an upper limit just before. With this configuration, it is possible to prevent the capacitor voltage from rising without limit, and to place a margin between the amplitude value of the ripple voltage component of the smoothing capacitor 13 and the allowable amplitude value.

  In step S209, when the positive side amplitude value decreases, the command value adjustment unit 21 may perform adjustment to increase the adjustment value Vc_add with the upper limit until the positive side amplitude value becomes the positive side allowable amplitude value. . With this configuration, it is possible to prevent the positive amplitude value from exceeding the allowable amplitude value when the capacitor voltage of the smoothing capacitor 13 is returned.

  In step S209, when the capacitor voltage amplitude value decreases, the command value adjustment unit 21 may perform an adjustment to lower the adjustment value Vc_add with the lower limit until the negative side amplitude value becomes the negative side allowable amplitude value. . With this configuration, it is possible to prevent the negative amplitude value from exceeding the allowable amplitude value when the capacitor voltage of the smoothing capacitor 13 is returned.

  As described above, according to the second embodiment, the capacitor voltage of the smoothing capacitor provided between the AC-DC conversion circuit and the DC-DC conversion circuit is acquired, and the acquired capacitor voltage is within the allowable voltage range. The capacitor voltage command value is adjusted. More specifically, in the second embodiment, as the amplitude value of the acquired capacitor voltage of the smoothing capacitor, the positive side amplitude value and the negative side amplitude value based on a constant original command value are calculated, and the calculated positive side Capacitor voltage command by comparing the amplitude value, negative amplitude value, positive allowable amplitude value, and negative allowable amplitude value, and adjusting the adjustment value to be added to the original command value based on the comparison result Configured to adjust the value.

  As a result, even if there is a possibility that the amplitude value of the ripple voltage component of the smoothing capacitor is out of the allowable range due to a decrease in the capacitance of the smoothing capacitor during the operation of the power converter, based on the capacitor voltage The capacitor voltage command value is adjusted instead of the output power command value. Therefore, the same effects as those of the first embodiment can be obtained, and the output power Pout can be prevented from being restricted more than necessary.

  In the first and second embodiments, the first power conversion circuit is the AC / DC conversion circuit 11 and the second power conversion circuit is the DC / DC conversion circuit 12. Although the case where the invention is applied has been exemplified, the same effect can be obtained by applying the present invention to a power converter of the following form.

  That is, the present invention can also be applied to a power conversion device in which the first power conversion circuit is an AC-DC conversion circuit and the second power conversion circuit is an inverter circuit. The present invention can also be applied to a power conversion device in which the first power conversion circuit is a DC-DC conversion circuit and the second power conversion circuit is a DC-DC conversion circuit. Furthermore, the present invention can also be applied to a power conversion device in which the first power conversion circuit is a DC-DC conversion circuit and the second power conversion circuit is an inverter circuit.

  DESCRIPTION OF SYMBOLS 1 Power converter, 11 AC-DC conversion circuit, 111 Diode bridge circuit, 112 Smoothing reactor, 12 DC-DC conversion circuit, 121 Bridge circuit, 122 Transformer, 122a Primary side winding, 122b Secondary side winding, 123 Diode Bridge circuit, 124 smoothing reactor, 13 smoothing capacitor, 14 input voltage detector, 15 input current detector, 16 capacitor voltage detector, 17 output voltage detector, 18 output current detector, 2 control device, 21 command value adjustment unit , 22 AC-DC controller, 23 DC-DC controller, 24 calculator, 241 subtractor, 242 PI controller, 243 multiplier, 244 subtractor, 245 PI controller, 246 PWM signal generator, 25 calculator 251 Multiplier 252 Multiplexer 253 Subtractor 25 4 PI controller, 255 PWM signal generator, 26 arithmetic unit, 261 multiplier, 262 multiplexer, 263 subtractor, 264 PI controller, 27 arithmetic unit, 271 multiplier, 272 multiplexer, 273 multiplier, 274 subtractor, 275 PI controller, 276 PWM signal generator, 28 calculator, 281 subtractor, 282 PI controller, 283 subtractor, 284 PI controller, 285 PWM signal generator, 29 calculator, 291 adder, 3 AC power supply 4 Load.

Claims (14)

A smoothing capacitor;
A first power conversion circuit having an input side connected to an input power supply and an output side connected to the smoothing capacitor;
A second power conversion circuit having an input side connected to the smoothing capacitor and an output side connected to a load;
A control device for controlling a power conversion device comprising:
The output power becomes the output power command value for controlling the output power to the load of the power converter, and the capacitor voltage becomes the capacitor voltage command value for controlling the capacitor voltage of the smoothing capacitor. A power conversion control unit for controlling the first power conversion circuit and the second power conversion circuit;
A command value adjusting unit that acquires the capacitor voltage and adjusts the output power command value so that the acquired capacitor voltage is within a voltage allowable range;
Equipped with a,
The command value adjustment unit
An amplitude value of the obtained capacitor voltage is calculated, a capacitor voltage amplitude value that is the calculated amplitude value, an upper limit value of the allowable voltage range, an allowable ripple current of the smoothing capacitor, and the second power conversion circuit A control device for a power converter that compares an allowable amplitude value determined based on a stability limit of the control system and adjusts the output power command value based on a comparison result . The command value adjustment unit
The comparison result, if the capacitor voltage amplitude is higher than the allowable amplitude value, the control system for a power converter according to claim 1 for performing an adjustment to reduce the output power command value. The command value adjustment unit
After an adjustment to reduce the output power command value, as a result of the comparison, if the capacitor voltage amplitude is equal to or less than the allowable amplitude value, according to claim 2 to adjust to increase the output power command value Control device for power converter. The command value adjustment unit
The control of the power converter according to any one of claims 1 to 3 , wherein when the output power command value after the adjustment is equal to or less than a set value, the driving of the power converter is stopped or a warning is issued. apparatus. A smoothing capacitor;
A first power conversion circuit having an input side connected to an input power supply and an output side connected to the smoothing capacitor;
A second power conversion circuit having an input side connected to the smoothing capacitor and an output side connected to a load;
A control device for controlling a power conversion device comprising:
The output power becomes the output power command value for controlling the output power to the load of the power converter, and the capacitor voltage becomes the capacitor voltage command value for controlling the capacitor voltage of the smoothing capacitor. A power conversion control unit for controlling the first power conversion circuit and the second power conversion circuit;
A command value adjusting unit that acquires the capacitor voltage and adjusts the capacitor voltage command value so that the acquired capacitor voltage falls within a voltage allowable range;
With
The command value adjustment unit
As the acquired amplitude value of the capacitor voltage, a positive-side amplitude value and a negative-side amplitude value based on a fixed original command value are calculated, the calculated positive-side amplitude value and negative-side amplitude value, and the original command A positive allowable amplitude value that defines the upper limit value of the positive voltage allowable range with reference to the value, and a negative allowable amplitude that specifies the lower limit value of the negative voltage allowable range with respect to the original command value the comparator compares the value based on the comparison result, you adjust the capacitor voltage command value by adjusting the adjustment value to be added to the original command value
Control device for power conversion apparatus. The command value adjustment unit
If the positive side amplitude value is larger than the positive side allowable amplitude value and the negative side amplitude value is equal to or smaller than the negative side allowable amplitude value as the comparison result, adjustment is performed to decrease the capacitor voltage command value. The control apparatus of the power converter device of Claim 5 . The command value adjustment unit
As the comparison result, when the positive side amplitude value is equal to or less than the positive side allowable amplitude value and the negative side amplitude value is larger than the negative side allowable amplitude value, adjustment is performed to increase the capacitor voltage command value. The control apparatus of the power converter device of Claim 5 or 6 . The command value adjustment unit
After adjusting the capacitor voltage command value, as the comparison result, when the positive side amplitude value is less than the positive side allowable amplitude value and the negative side amplitude value is less than the negative side allowable amplitude value, The control device for a power converter according to any one of claims 5 to 7 , wherein the capacitor voltage command value is returned to an original value before adjustment. The power conversion control unit
A control mode for controlling the first power conversion circuit and the second power conversion circuit using the output power command value and the capacitor voltage command value is output from the second power conversion circuit to the load. The control apparatus of the power converter device of any one of Claim 1 to 8. It has an output current control mode which controls so that the said output current may become the output current command value for controlling the output current to be. The power conversion control unit
Using the output power command value and the capacitor voltage command value as a control mode for controlling the first power conversion circuit and the second power conversion circuit, input from the input power source to the first power conversion circuit The control apparatus of the power converter device of any one of Claim 1 to 9. It has an input current control mode which controls so that the said input current may become the input current command value for controlling the input current to be performed. The power conversion control unit
A control mode for controlling the first power conversion circuit and the second power conversion circuit using the output power command value and the capacitor voltage command value is output from the second power conversion circuit to the load. The control apparatus of the power converter device of any one of Claim 1 to 10. It has an output voltage control mode which controls so that the said output voltage may become the output voltage command value for controlling the output voltage to be. The combination of the first power conversion circuit and the second power conversion circuit is any one of the following combinations (A) to (D). (A) The first power conversion circuit is an AC-DC conversion circuit. The second power conversion circuit is a DC-DC conversion circuit (B) the first power conversion circuit is an AC-DC conversion circuit, and the second power conversion circuit is an inverter circuit (C) The first power conversion circuit is a DC-DC conversion circuit, and the second power conversion circuit is a DC-DC conversion circuit. (D) The first power conversion circuit is a DC-DC conversion circuit, and the second power The control device for a power conversion device according to any one of claims 1 to 11 , wherein the conversion circuit is an inverter circuit. A smoothing capacitor;
A first power conversion circuit having an input side connected to an input power supply and an output side connected to the smoothing capacitor;
A second power conversion circuit having an input side connected to the smoothing capacitor and an output side connected to a load;
A control method for controlling a power conversion device comprising:
The output power becomes the output power command value for controlling the output power to the load of the power converter, and the capacitor voltage becomes the capacitor voltage command value for controlling the capacitor voltage of the smoothing capacitor. And controlling the first power conversion circuit and the second power conversion circuit;
Acquiring the capacitor voltage and adjusting the output power command value so that the acquired capacitor voltage is within a voltage allowable range;
Equipped with a,
In the step of adjusting the output power command value,
An amplitude value of the obtained capacitor voltage is calculated, a capacitor voltage amplitude value that is the calculated amplitude value, an upper limit value of the allowable voltage range, an allowable ripple current of the smoothing capacitor, and the second power conversion circuit A control method for a power converter that compares an allowable amplitude value determined based on a stability limit of the control system and adjusts the output power command value based on a comparison result . A smoothing capacitor;
A first power conversion circuit having an input side connected to an input power supply and an output side connected to the smoothing capacitor;
A second power conversion circuit having an input side connected to the smoothing capacitor and an output side connected to a load;
A control method for controlling a power conversion device comprising:
The output power becomes the output power command value for controlling the output power to the load of the power converter, and the capacitor voltage becomes the capacitor voltage command value for controlling the capacitor voltage of the smoothing capacitor. And controlling the first power conversion circuit and the second power conversion circuit;
Acquiring the capacitor voltage and adjusting the capacitor voltage command value so that the acquired capacitor voltage is within a voltage allowable range;
With
In the step of adjusting the capacitor voltage command value,
As the acquired amplitude value of the capacitor voltage, a positive-side amplitude value and a negative-side amplitude value based on a fixed original command value are calculated, the calculated positive-side amplitude value and negative-side amplitude value, and the original command A positive allowable amplitude value that defines the upper limit value of the positive voltage allowable range with reference to the value, and a negative allowable amplitude that specifies the lower limit value of the negative voltage allowable range with respect to the original command value The capacitor voltage command value is adjusted by comparing the value and adjusting the adjustment value to be added to the original command value based on the comparison result.
Control method of power converter.

Images