JP2019176708A - Power converter, heat generation system, load system, and electricity distribution-sending system - Google Patents

Abstract

To provide a power converter, a heat generation system, a load system, and an electricity distribution-sending system which can be controlled more easily.SOLUTION: A power converter 101 is a multi-level power converter including: a plurality of unit converters 108a, 108b, 108c, 108d, and 108e outputting a predetermined voltage; two arms (positive-side converter arms 107RP, 107SP, 107TP and negative-side converter arms 107RN, 107SN, 107TN) serially connected to each other through an AC voltage input-output terminal unit (terminals 102R, 102S, 102T). In the arms, the unit converters 108a, 108b, 108c, 108d, and 108e are serially connected. In at least one arm, the capacitor voltage of the capacitor of at least one unit converter 108a is different from the capacitor voltages of the other unit converters 108b, 108c, 108d, and 108e.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a power conversion device, a power generation system, a load system, and a power transmission / distribution system.

  Modular multi-level that can output high voltage exceeding the withstand voltage of the switching element using a switching element (Insulated-gate bipolar transistor: IGBT, etc.) that can be turned on / off as a power converter connected to the power system A converter (hereinafter referred to as MMC) is known (Non-Patent Document 1).

  In MMC, the output voltage can be changed in multiple stages by connecting in series the unit converters that can output at least two voltages of 0 and a predetermined voltage by switching and adjusting the number of unit converters that output the voltage. . Therefore, in the MMC, the output voltage can be adjusted in more stages as the number of unit converters connected in series is increased. For example, the output waveform can be made closer to a sine wave.

Makoto Sugawara and Yasufumi Akagi: “PWM Control Method and Operational Verification of Modular Multilevel Converter (MMC)”, IEEJ Transactions D, Vol. 957-965

  However, in the MMC, if the gradation of the output voltage is increased, the number of unit converters and the number of control circuits for controlling the unit converters must be increased, and it is difficult to control the MMC such as synchronous control. There was a problem that the cost also increased.

  Then, this invention is made | formed in view of the above problems, and it aims at providing the power converter device, electric power generation system, load system, and power transmission / distribution system which can be controlled more easily than before.

  A power converter according to the present invention is a multi-level power converter having a plurality of unit converters that output a predetermined voltage, and includes two arms connected in series via an AC voltage input / output unit. The plurality of unit converters are connected in series, and the capacitor voltage of at least one of the unit converters is different from that of the other unit converters in at least one of the arms.

  The power generation system of this invention is equipped with said power converter device.

  The load system of this invention is equipped with said power converter device.

  The power transmission / distribution system of the present invention links the power conversion device to a power system.

  According to the present invention, by including a plurality of unit converters having different capacitor voltages in the arm, the unit converters having different capacitor voltages are combined and compared with the case where all the same unit converters are used. The number of converters can be kept the same, the gray scale of the output voltage can be increased, and the number of unit converters required to realize the output voltage of the same gray scale can be reduced. As a result, the number of unit converters and the number of control circuits that control the unit converters can be reduced, and the power converter can be controlled more easily than in the past.

It is the schematic which shows the whole structure of the power converter device which concerns on embodiment of this invention. It is the schematic which shows the unit converter of embodiment of this invention. It is the schematic explaining the balance of the capacitor voltage of this invention. It is the schematic which shows the unit converter of other embodiment of this invention. It is the schematic which shows the unit converter of other embodiment of this invention. It is the schematic which shows the whole structure of the power converter device of other embodiment of this invention.

(1) Overall Configuration of Power Converter of Embodiment of the Invention As shown in FIG. 1, the power converter 101 includes an AC voltage input / output unit (R-phase AC voltage input / output unit, S-phase AC voltage input / output unit, Terminals 102R, 102S, and 102T as T-phase AC voltage input / output units) and R-phase, S-phase, and T-phase of a transformer (not shown in FIG. 1) are connected to each other, and a power system is connected via the transformer. It is linked to 111. In the power conversion device 101, a DC device 110 is connected between a terminal P and a terminal N. The DC device 110 is drawn as a representative of a DC load such as a resistor, a DC power supply, another power conversion device, and the like. Thus, the power conversion device 101 converts the AC power of the power system 111 into DC power and supplies it to the DC device 110, or converts the DC power output from the DC device 110 into AC power and supplies it to the power system 111. A gradation multi-level converter (hereinafter abbreviated as KMC).

  The power conversion device 101 includes three legs 107R (also referred to as R-phase legs) and two legs 107S (also referred to as S-phase legs) having a configuration in which two arms (a positive converter arm and a negative converter arm) are connected in series. A leg 107T (also referred to as a T-phase leg). The three legs 107R, 107S, and 107T are connected in parallel between the connection point NP1 and the connection point NP2. In the leg 107R, the positive converter arm 107RP, the reactor 112, the terminal 102R, the reactor 112, and the negative converter arm 107RN are connected in series in this order between the connection point NP1 and the connection point NP2. It has a configuration.

  Similarly, the leg 107S includes a positive converter arm 107SP, a reactor 112, a terminal 102S, a reactor 112, and a negative converter arm 107SN in series in this order between the connection point NP1 and the connection point NP2. It is configured to be connected to. In the leg 107T, a positive side converter arm 107TP, a reactor 112, a terminal 102T, a reactor 112, and a negative side converter arm 107TN are connected in series in this order between the connection point NP1 and the connection point NP2. It has a configuration.

  The power conversion device 101 has a configuration in which the three-phase AC phases are connected via these terminals 102R, 102S, and 102T, and the three-phase AC phases are star-connected at the connection points NP1 and NP2. . Therefore, the connection points NP1, NP2 are not only the connection points of the legs 107R, 107S, 107T, but also the neutral point of the star connection (hereinafter, the connection point NP1 is referred to as the first neutral point NP1, the connection point NP2). Is also referred to as a second neutral point NP2.). Therefore, assuming that the arm currents flowing through the positive side converter arm 107RP, the positive side converter arm 107SP, and the positive side converter arm 107TP are IRP, ISP, and ITP, respectively, the total value of the arm currents (IRP + ISP + ITP) flows through the DC device 110. It becomes current. Similarly, assuming that the arm currents flowing through the negative side converter arm 107RN, the negative side converter arm 107SN, and the negative side converter arm 107TN are IRN, ISN, and ITN, respectively, the total value of the arm current (IRN + ISN + ITN) also flows through the DC device 110. Equal to current.

  The terminal P is drawn from the first neutral point NP1, and the terminal N is drawn from the second neutral point. In FIG. 1, for the sake of convenience, the terminal P and the terminal N are drawn from a location having the same potential as the first neutral point or the second neutral point. In this embodiment, each leg 107R, 107S, 107T and a current sensor (not shown) are provided between, for example, the first neutral point NP1 and a voltage control unit converter 10 described later, and each positive side conversion is provided. Arm currents IRP, ISP, and ITP flowing through the instrument arms 107RP, 107SP, and 107TP are detected, and whether the currents flowing through the legs 107R, 107S, and 107T are positive or negative is detected. The current sensor detects a current flowing through each of the positive side converter arms 107RP, 107SP, and 107TP as a positive current from the first neutral point NP1 to the second neutral point NP2.

  Subsequently, the positive side converter arms 107RP, 107SP, 107TP and the negative side converter arms 107RN, 107SN, 107TN will be described. Since these arms have the same configuration, the positive side converter arm 107RP will be described as a representative. The positive-side converter arm 107RP includes a voltage control unit converter 10 and five unit converters 108a, 108b, 108c, 108d, and 108e. A direct current flows through the positive converter arm 107RP. The voltage control unit converter 10 and the five unit converters 108a, 108b, 108c, 108d, and 108e can switch the output voltage between a predetermined voltage and zero by a switch operation.

  As shown in FIG. 2, the voltage control unit converter 10 includes a high-side switching element 201H made of, for example, IGBT, a high-side freewheeling diode 202H, a low-side switching element 201L made of, for example, IGBT, and a low-side freewheeling diode 202L. A bidirectional chopper circuit including a capacitor 15. The high side switching element 201H and the high side freewheeling diode 202H are connected to the positive electrode (collector in IGBT) side of the high side switching element 201H and the negative electrode side of the high side freewheeling diode 202H, and the negative electrode (in IGBT) of the high side switching element 201H. The emitter side and the positive side of the high-side freewheeling diode 202H are connected and connected in antiparallel. Similarly, the low-side switching element 201L and the low-side freewheeling diode 202L are connected in antiparallel. Thus, by connecting the freewheeling diode in reverse parallel to the switching element, when a voltage is applied from the negative electrode side to the positive electrode side of the IGBT that is the switching element, a current flows through the freewheeling diode, and from the negative electrode of the IGBT. The IGBT can be protected by preventing a current from flowing through the positive electrode.

  The voltage control unit converter 10 is configured such that the negative side of the high side switching element 201H and the positive side of the low side switching element 201L are connected, and the high side switching element 201H and the low side switching element 201L are connected in series. Yes. A control circuit (not shown) is connected to the high side switching element 201H and the low side switching element 201L, and is turned on / off by a control signal from the control circuit. The capacitor 15 is connected in parallel with the high-side switching element 201H and the low-side switching element 201L connected in series. In the voltage control unit converter 10, a voltage sensor 204 is connected to both ends of the capacitor 15, and the voltage of the capacitor 15 is detected by the voltage sensor 204.

  In the voltage control unit converter 10, a positive terminal is drawn from a connection point X between the capacitor 15 and the high side switching element 201H, and a negative terminal is drawn from a connection point Y between the high side switching element 201H and the low side switching element 201L. ing.

  When the high-side switching element 201H is off and the low-side switching element 201L is on, the voltage control unit converter 10 has a voltage approximately equal to the capacitor voltage of the capacitor 15 between the positive terminal and the negative terminal without depending on the leg current. Is output. In this specification, this state is referred to as a high state. Thus, since the capacitor voltage of the capacitor 15 and the output voltage of the voltage control unit converter 10 are substantially equal to each other, hereinafter, the capacitor voltage of the capacitor 15 detected by the voltage sensor 204 is used as the output of the voltage control unit converter 10. Voltage.

  When the high-side switching element 201H is on and the low-side switching element 201L is off, the voltage control unit converter 10 is short-circuited between the positive electrode terminal and the negative electrode terminal, and the inter-terminal voltage is substantially zero without depending on the leg current. Is equal to In this specification, this state is referred to as a low state.

  In the voltage control unit converter 10, when both the high side switching element 201H and the low side switching element 201L are on, the capacitor 15 is short-circuited. Therefore, such an operation is prohibited.

  In the voltage control unit converter 10, when both the high-side switching element 201H and the low-side switching element 201L are off, the voltage between the positive terminal and the negative terminal depends on the polarity of the current flowing through the voltage control unit converter 10 To do. When the current is positive (when the current flows from the positive terminal to the negative terminal), the output voltage is approximately equal to the capacitor voltage of the capacitor 15. When the current is negative (when the current flows from the negative terminal to the positive terminal), the output voltage between the terminals is approximately equal to zero. Thus, the voltage control unit converter 10 is controlled to a high state and a low state by the operation of the switch.

  The unit converter 108a has the same configuration as that of the voltage control unit converter 10 shown in FIG. The unit converters 108b, 108c, 108d, and 108e are different in the rated voltage of the capacitor from the voltage control unit converter 10, but the other configurations are the same. When the unit converters 108a, 108b, 108c, 108d, and 108e are in a high state, the unit converters 108a, 108b, 108c, 108d, and 108e output a voltage approximately equal to the capacitor voltage of each capacitor 203a, 203b, 203c, 203d, and 203e between the positive terminal and the negative terminal. In the low state, the positive electrode terminal and the negative electrode terminal are short-circuited, and the voltage becomes zero. Similar to the voltage control unit converter 10, the capacitor voltages of the capacitors 203a, 203b, 203c, 203d, and 203e detected by the voltage sensor are set as output voltages of the unit converters 108a, 108b, 108c, 108d, and 108e.

  In the positive side converter arm 107RP, such a voltage control unit converter 10, a unit converter 108a, a unit converter 108b, a unit converter 108c, a unit converter 108d, and a unit converter 108e are provided. It is configured to be connected in series in the forward direction. Here, “in the forward direction” means that the positive terminal and the negative terminal are connected, and the positive terminals or the negative terminals are not connected.

  In this embodiment, the rated voltage of the capacitor 203a is set so that the voltage V (V is an arbitrary voltage) can be output when the unit converter 108a is in the high state (that is, the capacitor voltage becomes V). Selected. Then, the rated voltage of the capacitor 203b is selected so that the unit converter 108b can output a voltage 2V that is twice the output voltage V of the unit converter 108a in the high state, and the unit converter 108c is connected to the unit converter 108b. The rated voltage of the capacitor 203c is selected so that the voltage 4V, which is twice the output voltage 2V, can be output in the high state. Further, the rated voltage of the capacitor 203d is selected so that the unit converter 108d can output a voltage 8V twice as high as the output voltage 4V of the unit converter 108c when the unit converter 108d is in the high state. The rated voltage of the capacitor 203e is selected so that the voltage 16V, which is twice the output voltage 8V, can be output in the high state.

  Thus, in the present embodiment, the positive converter arm 107RP is configured such that the capacitor voltage of the unit converters 108a, 108b, 108c, 108d, 108e is based on the capacitor voltage of the unit converter 108a having the lowest capacitor voltage. The capacitor voltage of the unit converter 108a is two times, four times, eight times, sixteen times, and so on. As a result, the output voltages of the unit converters 108a, 108b, 108c, 108d, and 108e are also different from each other in an equal ratio, such as approximately 2 times, 4 times, 8 times, and 16 times. “Equally different” here means that when there are three unit converters, the capacitor voltage or output voltage of the two unit converters is twice the capacitor voltage or output voltage of one unit converter. Yes, it means that the capacitor voltage or the output voltage is different from each other so that the capacitor voltage or the output voltage of the third unit converter is twice the capacitor voltage or the output voltage of the second unit converter. The capacitor voltage only needs to be approximately equal.

  Here, since the unit converters 108a, 108b, 108c, 108d, and 108e are connected in series, the output voltage of the positive side converter arm 107RP is the output voltage of the unit converter that is in the high state, that is, The value is the sum of the capacitor voltages. Thus, the output voltage of the positive converter arm 107RP becomes a value obtained by adding the capacitor voltages of the unit converters in the high state, so that the unit converters 108a, 108b, 108c, 108d, and 108e are in the high state / low state. By controlling the above and combining the unit converters in the high state, it is possible to output voltages of 32 gradations in increments of V from 0 to 31V. For example, the positive converter arm 107RP can output V by setting only the unit converter 108a to a high state, and can output 5V by setting only the unit converter 108a and the unit converter 108c to a high state. By setting the unit converters 108a, 108b, 108c, 108d, and 108e in the high state, 31V can be output.

  Further, the positive converter arm 107RP includes a voltage control unit converter 10. The voltage control unit converter 10 has a negative terminal connected to a positive terminal of the unit converter 108a. Thus, in the positive side converter arm 107RP, all the unit converters (the voltage control unit converter 10 and the unit converters 108a, 108b, 108c, 108d, 108e) are connected in series. When the capacitor 15 of the voltage control unit converter 10 is in a high state, the output voltage is equal to any of the unit converters 108a, 108b, 108c, 108d, and 108e, that is, any of the other unit converters. Select the rated voltage so that the capacitor voltage is equal. In the present embodiment, as described above, since the voltage control unit converter 10 and the unit converter 108a have the same configuration, the capacitor 15 is the same capacitor as the capacitor 203a of the unit converter 108a. The voltage control unit converter 10 outputs a voltage V when in a high state.

  In the leg 107R, the negative side of the positive converter arm 107RP and the positive side of the negative converter arm 107RN having the same configuration as the positive converter arm 107RP are connected via a reactor 112 or the like. ing. Thus, in the leg 107R, all the unit converters 108a, 108b, 108c, 108d, 108e and the voltage control unit converter 10 are connected in series in the forward direction.

  The reactor 112 controls each leg 107R, 107S in order to prevent an overcurrent from flowing through the legs 107R, 107S, 107T in a period in which the leg voltages VR, VS, VT of the legs 107R, 107S, 107T do not match. , 107T. Further, the reactor 112 attenuates a ripple current due to switching generated in the legs 107R, 107S, and 107T.

  The power conversion device 101 further includes a control unit (not shown). The control unit includes a current sensor for each leg, unit converters 108a, 108b, 108c, 108d, 108e, a voltage sensor 204 provided in the voltage control unit converter 10, and these unit converters 108a, 108b, 108c, 108d, and 108e are connected to the control circuit of the voltage control unit converter 10. The control unit transmits a control signal to the control circuit, and the control circuit controls the switching element of the unit converter, thereby controlling the high state / low state of the unit converter.

  Subsequently, the operation of the power conversion apparatus 101 will be described. The power conversion operation will be described, and then capacitor voltage balance control using the voltage control unit converter 10 will be described. The power conversion operation will be described separately for the case of converting from direct current to alternating current and the case of converting from alternating current to direct current. First, the case where the power conversion device 101 converts direct current to alternating current will be described. In this case, the DC device 110 is assumed to be a DC power transmission line (when the power conversion device 101 is a power conversion device on the power receiving side as viewed from the DC power transmission line), a DC power supply, a motor drive inverter that performs regenerative braking, or the like. is doing.

  Since the operations of the legs 107R, 107S, and 107T are the same, the description will be made focusing on the leg 107R. Here, the capacitors 15, 203 a, 203 b, 203 c, 203 d, and 203 e have been charged to the above-described DC voltage during operation, and 31 V is applied between the terminals P and N by the DC device 110. And In the description of the power conversion operation, the voltage control unit converter 10 is always described as being in a low state. However, even if the voltage control unit converter 10 is used, an AC voltage can be output in a gradation.

  In order to make the DC voltage between the P terminal and the terminal N almost constant, ideally, the total value of the capacitor voltages of the high unit converters of the positive converter arm 107RP and the negative converter arm 107RN is set to It is necessary to keep it constant. Further, in order to make the operation on the AC power system symmetrical with the positive converter arm 107RP and the negative converter arm 107RN, the voltage of the positive converter arm 107RP with the terminal P as the reference potential, particularly the AC voltage component, The voltage of the negative converter arm 107RN with the terminal N as a reference potential, particularly the AC voltage component, needs to be substantially equal.

  Here, the output voltage of the terminal 102R of the leg 107R is expressed by a voltage with the neutral point of the terminal 102R, the terminal 102S, and the terminal 102T as a reference potential. However, for the sake of simplicity, the description will be made assuming that there is no potential fluctuation at the neutral point, ignoring the switching of the other legs. Of the unit converters 108a, 108b, 108c, 108d, 108e of the negative side converter arm 107RN, the unit converters 108a, 108b of the positive side converter arm 107RP are calculated from the total value of the capacitor voltages of the unit converters in the high state. , 108c, 108d, and 108e, the value obtained by subtracting the total value of the capacitor voltages of the unit converters in the high state is approximately equal to a value that is halved. For example, when the DC voltage between the terminal P and the terminal N is 31 V, and only the unit converter 108a of the positive converter arm 107RP is in the high state, the negative converter arm 107RN is the negative converter arm 107RN. Only the unit converter 108a is set to the low state. A value obtained by subtracting the total value V of the capacitor voltage of the high unit converter of the positive converter arm 107RP from the total value 30V of the capacitor voltage of the high unit converter of the negative side converter arm 107RN, 1 of 29V A voltage of / 2 and 14.5 V are output from the terminal 102R. Similarly, when only the unit converter 108a is in the high state in the negative side converter arm 107RN and only the unit converter 108a is in the low state in the positive side converter arm 107RP, -14.5V is output from the terminal 102R. From the -14.5V output state, the unit converter 108a of the negative converter arm 107RN is set to the low state, the unit converter 108b is set to the high state, and only the unit converter 108b of the positive side converter arm 107RP is set to the low state. Thus, -13.5 V is output from the terminal 102R. Furthermore, from the −13.5 V output state, the unit converter 108a and the unit converter 108b of the negative converter arm 107RN are set to the high state, and only the unit converter 108a and the unit converter 108b of the positive converter arm 107RP are low. In this state, −12.5 V is output from the terminal 102R.

  In this way, by controlling the high state / low state of the unit converters 108a, 108b, 108c, 108d, and 108e of the positive converter arm 107RP and the negative converter arm 107RN, the output voltage of the terminal 102R is − It can be changed from 15.5V to + 15.5V in steps of V. Then, the leg 107R changes the output of the terminal 102R at a predetermined time interval in increments of V, so that an alternating current of a sine wave expressed in 32 gradations in increments of V between −15.5V and + 15.5V. Can output voltage. In the leg 107S, a switch operation is performed so that a sine wave whose phase is delayed by 2π / 3 from the AC voltage output from the terminal 102R can be output from the terminal 102S. In the leg 107T, the phase is higher than the AC voltage output from the terminal 102R. By performing a switch operation so that a sine wave delayed by 4π / 3 can be output from the terminal 102T, the power conversion device 101 can output a three-phase alternating current and functions as a multi-level power conversion device.

  Conventionally, in order to output a sinusoidal AC voltage expressed in 32 gradations in steps of V from a leg, a positive converter arm having a configuration in which 31 or more unit converters having a capacitor voltage of V are connected in series. And a negative transducer arm was used. Therefore, 62 or more unit converters and 62 or more control circuits are required for one leg, the power converter is complicated, and it is difficult to control many unit converters synchronously. was there.

  On the other hand, since the power converter 101 includes a plurality of unit converters 108a, 108b, 108c, 108d, and 108e having different capacitor voltages, as compared with a case where unit converters of the same capacitor are used, With a small number of unit converters, it is possible to output a voltage having substantially the same gradation in V increments, the size can be reduced by the reduction in the number of unit converters and control circuits, and the unit converter can be easily controlled synchronously. In particular, since the power converter 101 uses unit converters 108a, 108b, 108c, 108d, and 108e having different capacitor voltages in an equal ratio, there are five positive-side converter arms 107RP and five negative-side converter arms 107RN. The unit converter and 5 control circuits can output 31 grayscale voltages, and unit conversion is possible compared to the conventional case where each arm requires 31 or more unit converters and control circuits. The number of devices and control circuits can be greatly reduced, and control such as synchronous control is further facilitated.

  Next, the case where the power conversion device 101 converts from alternating current to direct current will be described. In this case, the DC device 110 is assumed to be a DC power transmission line (when the power conversion device 101 is a power conversion device on the power transmission side as viewed from the DC power transmission line), a DC load, a motor drive inverter that is driven, and the like. ing. At this time, the power conversion device 101 outputs the total value of the output voltages of the unit converters in the high state among the unit converters included in the leg 107R as a DC voltage between the terminal P and the terminal N.

  Next, capacitor voltage balance control using the voltage control unit converter 10 will be described with reference to FIG. The capacitor voltage balance control method is the same for each positive converter arm 107RP, 107SP, 107TP and each negative converter arm 107RN, 107SN, 107TN. Therefore, the positive converter arm 107RP will be described below as a representative. To do.

  Since the positive converter arm 107RP of this embodiment includes the voltage control unit converter 10, it outputs a voltage substantially equal to any one capacitor voltage of the unit converters 108a, 108b, 108c, 108d, and 108e. In this case, the voltage can be output by two methods. For example, when the positive converter arm 107RP outputs 16V, normally, only the unit converter 108e is set to the high state, and the voltage control unit converter 10 and the unit converters 108a, 108b, 108c, and 108d are set to the low state. . Incidentally, at this time, in the negative converter arm 107RN, only the voltage control unit converter 10 and the unit converter 108e are set to the low state. A DC voltage between the terminal P and the terminal N is 31V, and the neutral point of the terminal 102R, the terminal 102S, and the terminal 102T is expressed as a reference potential. However, for the sake of simplicity, the description will be made assuming that there is no potential fluctuation at the neutral point, ignoring the switching of the other legs. In this case, -0.5V is output from the terminal 102R. Actually, the negative-side converter arm 107RN is also controlled according to the output voltage of the positive-side converter arm 107RP. However, the control method is the same as that in the case of outputting the grayscale voltage described above, and will be described below. Is omitted.

  Here, in the present embodiment, since the positive converter arm 107RP includes the voltage control unit converter 10 whose capacitor voltage is V, the voltage control unit converter 10 and the capacitor voltage are unit converters. The total value of the capacitor voltages of the unit converters 108a, 108b, 108c, and 108d lower than 108e is 16V, which is equal to the capacitor voltage of 16V of the unit converter 108e (see 16V output in FIG. 3). Therefore, even if the unit converter 108e is set to the low state, and instead, the unit converters 108a, 108b, 108c, 108d and the voltage control unit converter 10 are set to the high state, the positive converter arm 107RP is set to 16V. Can output.

  Similarly, the positive converter arm 107RP can output 8V by setting only the unit converter 108d having a capacitor voltage of 8V to a high state. On the other hand, the total value of the capacitor voltage of the voltage control unit converter 10 and the capacitor voltages of the unit converters 108a, 108b, and 108c having a capacitor voltage lower than that of the unit converter 108d is 8V (in FIG. 3). 8V), the voltage converter unit converter 10 and the unit converters 108a, 108b, 108c are set to the high state, and the unit converters 108d, 108e are set to the low state. Can output.

  Further, the positive converter arm 107RP can output 4V by setting only the unit converter 108c having a capacitor voltage of 4V to a high state. On the other hand, the total value of the capacitor voltage of the voltage control unit converter 10 and the capacitor voltage of the unit converters 108a and 108b having a capacitor voltage lower than that of the unit converter 108c is 4V (4V output in FIG. 3). When the voltage converter unit converter 10 and the unit converters 108a and 108b are set to the high state and the unit converters 108c, 108d and 108e are set to the low state, the positive converter arm 107RP can output 4V. .

  Further, the positive converter arm 107RP can output 2V by setting only the unit converter 108b having a capacitor voltage of 2V to a high state. On the other hand, since the total value of the capacitor voltage of the voltage control unit converter 10 and the capacitor voltage of the unit converter 108a having a capacitor voltage lower than that of the unit converter 108b is 2V (see 2V output in FIG. 3). ) Even when the voltage control unit converter 10 and the unit converter 108a are set to the high state and the unit converters 108b, 108c, 108d, and 108e are set to the low state, the positive converter arm 107RP can output 2V.

  In addition, the positive converter arm 107RP can output V by setting only the unit converter 108a whose capacitor voltage is V to the high state. On the other hand, since the capacitor voltage of the voltage control unit converter 10 is V (see V output in FIG. 3), the voltage control unit converter 10 is set to the high state, and the unit converters 108a, 108b, 108c, Even if 108d and 108e are set to the low state, the positive side converter arm 107RP can output V.

  Thus, when the positive side converter arm 107RP outputs a voltage substantially equal to the capacitor voltage of any of the unit converters 108a, 108b, 108c, 108d, and 108e, the voltage can be output in two ways. it can. The positive converter arm 107RP combines the unit converters 108a, 108b, 108c, 108d, 108e and the voltage control unit converter 10 to output a predetermined voltage and to output the predetermined voltage. There are multiple combinations of. For example, the combination of unit converters capable of outputting 16V by the positive side converter arm 107RP is a unit converter 108e (combination 1), unit converters 108a, 108b, 108c, 108d, and a voltage control unit converter 10 (combination). There are two ways: 2).

  Assuming that the direction of the arm current from the terminal P side to the terminal N side is positive, in the power converter 101, when the arm current IRP that flows through the positive converter arm 107RP is positive, When the capacitor is charged and the arm current IRP is negative, the capacitor of the unit converter that is in the high state is discharged. Therefore, for example, when the capacitor voltage of the capacitor 203a of the unit converter 108a is lower than the reference voltage, the unit converter 108a is set to the high state when the arm current IRP is positive, so that the capacitor 203a of the unit converter 108a becomes It is charged and the capacitor voltage can be balanced. On the other hand, when the capacitor voltage is higher than the reference voltage, when the arm current IRP is negative, the unit converter 108a is set to a high state, whereby the capacitor 203a is discharged and the capacitor voltage can be balanced.

  Here, it is assumed that one or more unit converters having a capacitor voltage lower than the reference voltage are present in the unit converters 108a, 108b, 108c, 108d and the voltage control unit converter 10 (for example, the unit converter 108a). In this case, when the total value of the capacitor voltages of the unit converters 108a, 108b, 108c, 108d and the voltage control unit converter 10 is compared with the capacitor voltage of the unit converter 108e, the former is lower. In such a case, in the power converter 101, the arm current IRP of the positive converter arm 107RP is positive, and instead of the unit converter 108e (combination 1) that should be in the high state at the time of 16V output in FIG. The unit converters 108a, 108b, 108c, 108d and the voltage control unit converter 10 (combination 2) are all set to the high state, the output voltage of the positive converter arm 107RP is set to 16V, and the capacitor voltage is lower than the reference voltage. The capacitor 203a of the unit converter 108a is charged. By doing so, the power converter 101 can output 16V from the positive converter arm 107RP, similarly to when the unit converter 108e is set to the high state, so that the waveform of the output voltage of the power converter 101 can be changed. Without distortion, the capacitor of the unit converter whose output voltage is lower than the reference voltage can be charged, and the voltage of the capacitor can be balanced without distortion. Thus, when the power conversion device 101 outputs −0.5 V (predetermined voltage), the unit converter combination (combination 1) is changed to another unit converter combination (combination 2), The capacitor voltages of a plurality of unit converters (unit converters 108a, 108b, 108c, 108d) are balanced, and the difference between the capacitor voltages is controlled.

  Further, when the capacitor voltage of the capacitor 203e of the unit converter 108e falls below the reference voltage, the positive side when the arm current IRP of the positive side converter arm 107RP is positive and the positive side converter arm 107RP outputs 16V. The capacitor voltage of the unit converter 108e can be increased and the capacitor voltage can be balanced by increasing the time ratio during which the unit converter 108e is in the high state without changing the time for the converter arm 107RP to output 16V. Further, when the arm current IRP of the positive converter arm 107RP is negative, each capacitor voltage is optimized by reducing the time ratio when the unit converter 108e is in the high state.

  Further, it is assumed that one or more unit converters having a capacitor voltage higher than the reference voltage exist in the unit converters 108a, 108b, 108c, 108d and the voltage control unit converter 10 (for example, the unit converter 108a). In this case, when the total value of the capacitor voltages of the unit converters 108a, 108b, 108c, 108d and the voltage control unit converter 10 is compared with the capacitor voltage of the unit converter 108e, the latter is lower. In such a case, the power conversion device 101 uses a unit converter in place of the unit converter 108e that should be in a high state at the time of 16V output in FIG. 108a, 108b, 108c, 108d and the voltage control unit converter 10 are all set to the high state, and the capacitor of the unit converter 108a whose capacitor voltage is higher than the reference voltage is discharged. By doing so, the voltage of the capacitor can be balanced without distortion as well.

  Conventionally, since the arm does not include the voltage control unit converter 10, for example, when the output voltage of a certain unit converter is lower than the reference voltage, the output voltage of the unit converter is set within the reference voltage. Therefore, the time for setting the unit converter in the high state is made longer than usual to increase the capacitor charging time, and the capacitor voltage is balanced. For this reason, the output waveform of the power converter is distorted by the amount that the unit converter is in the high state for a longer time than usual.

  On the other hand, in the power conversion device 101 of the present embodiment, since the positive converter arm 107RP includes the voltage control unit converter 10, only one unit converter (for example, the unit converter 108e) is in the high state. At the timing to be set, the same capacitor voltage as that of the unit converter to be set to the high state is set to a unit converter having a lower capacitor voltage than the unit converter to be set to the high state (in this case, unit converters 108a, 108b, 108c, 108d) And the voltage control unit converter 10 can be realized by bringing them all to the high state. Therefore, at the timing when only one unit converter should be in the high state, the unit converter whose voltage is lower than that of the unit converter that should be in the high state and the unit converter 10 for voltage control are all in the high state. Among the unit converters 10 and the voltage control unit converter 10 which are set to the high state according to the positive / negative of the arm current IRP flowing through the positive side converter arm 107RP, the unit converter whose capacitor voltage is lower or higher than the reference voltage. Capacitor can be charged and discharged, and capacitor voltage can be balanced without distortion.

  Assume that the balance between the total value of the capacitor voltages of the unit converters 108a, 108b, 108c and the voltage control unit converter 10 and the capacitor voltage of the unit converter 108d is lost. In this case, at the timing when the unit converter 108d is set to the high state (when the positive converter arm 107RP in FIG. 3 outputs 8V or when the positive converter arm 107RP outputs 24V), instead of the unit converter 108d. The unit converters 108a, 108b, and 108c and the voltage control unit converter 10 are all set to the high state. In this way, the capacitors 203a, 203b, 203c and the capacitor 15 can be charged and discharged according to the sign of the arm current IRP, and the capacitor voltages of the capacitors 203a, 203b, 203c and the capacitor 15 can be balanced without distortion. Can do.

  It is assumed that the balance between the total value of the capacitor voltages of the unit converters 108a and 108b and the voltage control unit converter 10 and the capacitor voltage of the unit converter 108c is lost. At this time, at the timing when the unit converter 108c is set to the high state (when the positive converter arm 107RP in FIG. 3 outputs 4V, or when the positive converter arm 107RP outputs 12V, 20V, and 28V), the unit conversion is performed. Instead of the unit 108c, the unit converters 108a and 108b and the voltage control unit converter 10 are set to the high state. As a result, the capacitors 203a and 203b and the capacitor 15 can be charged / discharged according to the sign of the arm current IRP, and the capacitor voltage can be balanced without distortion.

  Assume that the balance between the total value of the capacitor voltages of the unit converter 108a and the voltage control unit converter 10 and the capacitor voltage of the unit converter 108b is lost. At the timing when the unit converter 108b is set to the high state (when the positive converter arm 107RP in FIG. 3 outputs 2V, or when the positive converter arm 107RP outputs 6V, 10V, 14V, 18V, 22V, and 30V). Instead of the unit converter 108b, the unit converter 108a and the voltage control unit converter 10 are set to the high state. As a result, the capacitor 203a and the capacitor 15 can be charged / discharged according to the sign of the arm current IRP, and the capacitor voltage can be balanced without distortion.

  Assume that the balance between the capacitor voltage of the unit converter 108a and the capacitor voltage of the voltage control unit converter 10 is lost. At the timing when the unit converter 108a is set to the high state (for example, when the positive side converter arm 107RP in FIG. 3 outputs V), the voltage control unit converter 10 is set to the high state. As a result, the capacitor 15 can be charged / discharged according to the sign of the arm current IRP, and the capacitor voltage of the capacitor 15 can be balanced without distortion. At this time, the capacitor voltage of the capacitor 203a can be balanced by setting the unit converter 108a to the high state instead of the voltage control unit converter 10.

  Next, the procedure of the capacitor voltage balance control will be described more specifically. Here, the control by the positive converter arm 107RP will be described as an example. The control unit transmits a control signal to the control circuits of the unit converters of the positive converter arm 107RP and the negative converter arm 107RN to control the high state and the low state of the unit converter. Assume that it is time to set only the unit converter 108e of the converter arm 107RP to the high state (when the positive converter arm 107RP outputs 16V). At this time, the control unit detects the current (arm current IRP) flowing through the positive converter arm 107RP by the current sensor. Subsequently, the control unit converts the unit converters 108a, 108b, 108c, 108d, 108e, and the unit converters 108a, 108b, 108c, 108d, 108e, and the voltage sensors 204 provided in the voltage control unit converter 10 respectively. The capacitor voltage of the voltage control unit converter 10 is detected.

  The control unit calculates the total value of the capacitor voltages of the unit converters 108a, 108b, 108c, 108d and the voltage control unit converter 10, and compares the total value of the capacitor voltage with the capacitor voltage of the unit converter 108e. When the arm current IRP is positive and the total value of the calculated capacitor voltages is lower than the capacitor voltage of the unit converter 108e, the control unit outputs to the unit converter 108e when the next positive converter arm 107RP outputs 16V. Instead, the unit converters 108a, 108b, 108c, 108d and the voltage control unit converter 10 are controlled to be in the high state. On the other hand, when the arm current IRP is positive and the calculated total value is higher than the output voltage of the unit converter 108e, the control unit sets the unit converter 108e when the next positive converter arm 107RP outputs 16V. Go high.

  When the arm current IRP is negative and the calculated total value is higher than the output voltage of the unit converter 108e, the control unit changes to the unit converter 108e when the next positive converter arm 107RP outputs 16V. Thus, the unit converters 108a, 108b, 108c, 108d and the voltage control unit converter 10 are controlled to be in the high state. In other cases, when the next positive side converter arm 107RP outputs 16V, the control unit sets the unit converter 108e to the high state as usual.

  When the capacitor voltages are balanced in this way, the difference between the capacitor voltages of the unit converters is maintained, that is, the equivalence of the capacitor voltages is maintained. In this way, the control unit maintains the difference in capacitor voltage among the plurality of unit converters 108a, 108b, 108c, 108d, 108e, and the voltage control unit converter 10.

(2) Operation and Effect In the above configuration, the power conversion device 101 is a multi-level power conversion device including a plurality of unit converters 108a, 108b, 108c, 108d, and 108e that outputs a predetermined voltage. Two arms (positive converter arms 107RP, 107SP, 107TP and negative converter arms 107RN, 107SN, 107TN) connected in series via the output unit (terminals 102R, 102S, 102T) are provided. The side converter arms 107RP, 107SP, 107TP and the negative side converter arms 107RN, 107SN, 107TN) have a plurality of unit converters 108a, 108b, 108c, 108d, 108e connected in series, and at least one arm is The capacitor of the capacitor of at least one unit converter The sensor voltage is configured to be different from other unit converters.

  Therefore, the power converter 101 includes unit converters having different capacitor voltages, so that unit converters having different capacitor voltages are combined and unit converters are compared with MMCs that use all the same unit converters. Therefore, the number of unit converters necessary for realizing the output voltage of the same gradation can be reduced. As a result, the power conversion apparatus 101 can reduce the number of unit converters and the number of control circuits that control the unit converters, and can be controlled more easily than in the past.

  Further, since the power conversion device 101 is configured so that each of the positive side converter arms 107RP, 107SP, 107TP and the negative side converter arms 107RN, 107SN, 107TN has the voltage control unit converter 10, one unit conversion is performed. The function of the converter (for example, the unit converter 108e) is the same as that of the unit converter (for example, the unit converters 108a, 108b, 108c, and 108d) whose capacitor voltage is smaller than that of the one unit converter. The unit 10 can be substituted, and at the timing of charging / discharging the one unit converter, the unit converter having a smaller capacitor voltage than the one unit converter and the unit converter 10 for voltage control can be charged / discharged. The capacitor voltage can be balanced.

  Further, the power conversion device 101 includes a plurality of unit converters 108a, 108b, 108c, 108d, and 108e each having a capacitor voltage different from each other on the positive side converter arms 107RP, 107SP, and 107TP and the negative side converter arms 107RN, 107SN, and 107TN. In addition, since the voltage control unit converter 10 is included, the apparatus can be easily controlled such as synchronous control, and the voltage of the capacitor can be balanced. That is, the balance control of the capacitor voltages of the unit converters 108a, 108b, 108c, 108d, 108e and the voltage control unit converter 10 can be easily performed.

(3) Other Embodiments The present invention is not limited to the above-described embodiments, and various modifications can be made within the scope of the gist of the present invention. For example, in the above-described embodiment, the unit converters 108a, 108b, 108c, 108d, and 108e in which the positive side converter arms 107RP, 107SP, and 107TP and the negative side converter arms 107RN, 107SN, and 107TN have different capacitor voltages are used. However, the present invention is not limited to this. For example, the positive side converter arm may have unit converters 108a, 108b, 108c, 108d, and 108e, and the negative side converter arm may have 31 unit converters 108a, and each converter arm has. The number of unit converters is not necessarily the same. In addition to the unit converters 108a, 108b, 108c, 108d, and 108e, each converter arm further includes a unit converter that outputs 64V, and a unit converter with a capacitor voltage that is equally different. May be.

  In the above embodiment, the voltage control unit converter 10 and the unit converters 108a, 108b, 108c, 108d, and 108e in each of the positive converter arms 107RP, 107SP, and 107TP and the negative converter arms 107RN, 107SN, and 107TN. However, the present invention is not limited to this, and if all the unit converters are connected in series, the arrangement order may be changed as appropriate.

  In the above embodiment, the case where the capacitor voltages of the unit converters 108a, 108b, 108c, 108d, and 108e are V, 2V, 4V, 8V, and 16V has been described. If the output of the unit converter with a low voltage is V, the output of each unit converter may be V, V, 3V, 3V, 9V, 9V, 27V, 27V, or V, V, V, 4V, 4V, 4V. It is good. Also in these cases, the power conversion device can output a voltage of gradation in increments of V.

  In the above embodiment, the case where the voltage control unit converter 10 whose capacitor voltage is the same V as that of the unit converter 108a has been described. However, the present invention is not limited to this, and the capacitor of the voltage control unit converter is used. The voltage only needs to be equal to the capacitor voltage of any unit converter included in the arm. In the case of the power converter 101, the voltage may be 2V or 4V, for example.

  In the above-described embodiment, the case where the voltage control unit converter 10 is used one by one for each converter arm has been described. However, the present invention is not limited to this, and each arm may include two arms. You may make it provide the unit converter for voltage control of the same capacitor voltage with respect to a unit converter. For example, the arm may have five unit converters with capacitor voltages V, 2V, 4V, 8V, and 16V, and five unit converters with capacitor voltages V, 2V, 4V, 8V, and 16V. Good.

  In the above embodiment, the case where the present invention is applied to the power converter 101 for three-phase alternating current having the three legs 107R, 107S, and 107T has been described. However, the present invention is not limited to this, and for example, only one leg 107R is provided. The present invention may be applied to a single-phase AC current converter.

  In the above embodiment, at the timing when one unit converter outputs a voltage, the voltage of the capacitor of the one unit converter and another unit whose capacitor voltage is lower than that of the one unit converter in the same arm. Although a case has been described where the total value of the capacitor voltage of the converter and the voltage control unit converter is compared to determine whether or not the voltage control unit converter is in the high state, the present invention is not limited to this. I can't. For example, each of the other unit converter and the voltage control unit converter determines whether the capacitor voltage is within the reference voltage, and either of the other unit converter and the voltage control unit converter. In addition, when there is a unit converter or a voltage control unit converter whose capacitor voltage is outside the reference voltage, the voltage control unit converter may be determined to be in a high state together with the other unit converter.

  For example, if the arm current is positive and the capacitor voltage of one of the other unit converter and the voltage control unit converter is lower than the reference voltage, the other unit converter and the voltage control unit converter are The capacitor of the unit converter whose capacitor voltage is lower than the reference voltage is charged. When the arm current is negative and the capacitor voltage of any of the other unit converter and the voltage control unit converter is higher than the reference voltage, the other unit converter and the voltage control unit converter are And discharge the capacitor whose capacitor voltage is higher than the reference voltage. In the above embodiment, the capacitor voltage of the unit converter is compared to determine whether to balance the capacitor voltage. However, whether the capacitor voltage is balanced by comparing the output voltage of the unit converter is determined. You may decide.

  In the above embodiment, the case where the voltage control unit converter 10 shown in FIG. 2 is used has been described. However, the present invention is not limited to this, and for example, the voltage control unit converter 20 shown in FIG. 4 is used. May be. The voltage control unit converter 20 is different from the voltage control unit converter 10 only in the position where the positive terminal and the negative terminal are drawn, and the other configuration is the same as that of the voltage control unit converter 10. In the voltage control unit converter 20, the positive terminal is drawn from the connection point Y between the high side switching element 201H and the low side switching element 201L, and the negative terminal is drawn from the connection point Z between the low side switching element 201L and the capacitor 15. Yes. The voltage control unit converter 20 can also control a high state and a low state by a switching operation.

  When the high-side switching element 201H is on and the low-side switching element 201L is off, the voltage control unit converter 20 generates a voltage approximately equal to the voltage of the capacitor 15 between the positive terminal and the negative terminal without depending on the leg current. Output and goes high.

  When the high-side switching element 201H is off and the low-side switching element 201L is on, the voltage control unit converter 20 is short-circuited between the positive electrode terminal and the negative electrode terminal, and the inter-terminal voltage is substantially zero without depending on the leg current. And become low. The operation when both switches are both on and when both switches are off is the same as that of the voltage control unit converter 10. Further, the unit converters 108a, 108b, 108c, 108d, and 108e may be configured as the voltage control unit converter 20.

  In the above embodiment, the case where the bidirectional converter is used as the unit converters 108a, 108b, 108c, 108d, and 108e and the voltage control unit converter 10 has been described. However, the present invention is not limited to this, for example, FIG. As in the unit converter 70 shown in FIG. 5, the configuration may be a full bridge circuit system. The unit converter 70 is a three-level converter that can output predetermined positive and negative voltages ± V and zero by controlling the switching elements 702XH, 702XL, 702YH, and 702YL. By using such a unit converter 708, the power conversion device can also reverse the polarity between the terminal P and the terminal N.

  In the above embodiment, the case where the three-phase alternating current converted by the power conversion device 101 is connected to the power system 111 via a transformer (not shown) has been described. However, the present invention is not limited to this, and the power shown in FIG. Like the conversion device 501, the transformer 103 is provided as an AC voltage input / output unit, and in addition to the power conversion, the power conversion device 501 transforms the AC power converted from the DC power directly to the power system 111. You may make it use. By providing the transformer 103 in the power conversion device 101, the reactor 112 can be omitted.

  As the transformer 103, for example, a transformer disclosed in Japanese Patent No. 6121582 can be used. The transformer 103 includes iron cores 104R, 104S, 104T, primary windings 105R, 105S, 105T, positive secondary windings 106RP, 106SP, 106TP, and negative secondary windings 106RN, 106SN, 106TN. I have. The iron core 104R, the primary winding 105R, the positive secondary winding 106RP, and the negative secondary winding 106RN are R-phase alternating currents that input and output an alternating voltage between the R-phase of the power system 111 and the power conversion device 501. Functions as a voltage input / output unit. The iron core 104S, the primary winding 105S, the positive secondary winding 106SP, and the negative secondary winding 106SN are S-phase AC that inputs and outputs an AC voltage between the S-phase of the power system 111 and the power converter 501. Functions as a voltage input / output unit. The iron core 104T, the primary winding 105T, the positive secondary winding 106TP, and the negative secondary winding 106TN are T-phase alternating currents that input and output an alternating voltage between the T-phase of the power system 111 and the power converter 501. Functions as a voltage input / output unit.

  The positive secondary winding 106RP is wound around the iron core 104R, the positive secondary winding 106SP is wound around the iron core 104S, and the positive secondary winding 106TP is wound around the iron core 104T. The positive side secondary windings 106RP, 106SP, 106TP have one end connected to the positive side converter arms 107RP, 107SP, 107TP at the connection points RP, SP, TP and the other end connected to the negative side secondary windings 106RN, 106SN. , 106TN. Further, the other ends of the positive side secondary windings 106RP, 106SP, and 106TP are connected to the connection point M and Y-connected.

  The positive secondary winding 106RN is wound around the iron core 104R, the positive secondary winding 106SN is wound around the iron core 104S, and the positive secondary winding 106TN is wound around the iron core 104T. The negative secondary windings 106RN, 106SN, 106TN have one end connected to the negative converter arms 107RN, 107SN, 107TN at the connection points RN, SN, TN, and the other end connected to the positive secondary windings 106RP, 106SP. , 106TP. Further, the other ends of the negative side secondary windings 106RN, 106SN, and 106TN are connected to the connection point M and Y-connected.

  The neutral point of the positive secondary windings 106RP, 106SP and 106TP thus Y-connected and the neutral point of the negative secondary windings 106RN, 106SN and 106TN Y-connected are the connection points M. Electrically connected. The positive side secondary windings 106RP, 106SP, 106TP and the negative side secondary windings 106RN, 106SN, 106TN are magnetically coupled so as to have opposite polarities for each phase. In this way, the DC magnetomotive force generated by the positive secondary windings 106RP, 106SP, 106TP and the DC magnetomotive force generated by the negative secondary windings 106RN, 106SN, 106TN can be offset, and the iron core 104R. , 104S, 104T can be prevented from generating DC magnetic flux.

  Further, primary windings 105RS, 105ST, and 105TR are wound around the iron cores 104R, 104S, and 104T. Primary windings 105RS, 105ST, and 105TR are Δ-connected and connected to power system 111.

  In the transformer 103 shown in FIG. 6, the primary windings 105RS, 105ST, and 105TR are magnetically coupled to have the same polarity as the positive secondary windings 106RP, 106SP, and 106TP. The same effect can be obtained when 105ST and 105TR are magnetically coupled so as to have the same polarity as the negative secondary windings 106RN, 106SN, and 106TN.

  In the above-described embodiment, the case where the power conversion device 101 converts a three-phase AC voltage into a DC voltage or converts a DC voltage into a three-phase AC voltage has been described. However, the present invention is not limited to this, and a single-phase AC voltage can be converted into a DC voltage, or a DC voltage can be converted into a single-phase AC voltage. In this case, any one of the leg 107R, the leg 107S, and the leg 107T of the power conversion device 101 may be used to convert an AC voltage into a DC voltage and convert the DC voltage into an AC voltage. Further, the legs 107S and 107T are removed from the power conversion device 101, and the power conversion device 101 is used as a power conversion device for single-phase AC to convert an AC voltage into a DC voltage and convert a DC voltage into an AC voltage. May be.

  The power conversion devices 101 and 501 of the above embodiment can be used in a power generation system. In this case, instead of the DC device 110, an active power source such as a wind power generator or a solar power generator is connected to the terminal P and the terminal N, for example. In the power generation system, the power conversion device 101 converts DC power obtained from the active power source into AC power and links it to the power system.

  The power conversion devices 101 and 501 can also be used for a load system. Negative In this case, instead of the DC device 110, a power storage system such as a load that consumes active power, a secondary battery that loads and removes active power, an active power load, and a storage battery is connected to the terminals P and N. In the load system, the power conversion devices 101 and 501 can convert the AC power of the power system into DC power and supply active power to the power storage system. Moreover, the power converter device can also supply the active power stored from the power storage system to the power system.

  In addition, the power converters 101 and 501, the power generation system, the power transfer system, and the load system described above are connected to the power system via electric wires, and the generated power is transmitted to various consumers. A power distribution system can also be constructed.

101 Power Converter 10 Voltage Control Unit Converter 102R, 102S, 102T Terminal 107R, 107S, 107T Leg 107RP, 107SP, 107TP Positive Converter Arm 107RN, 107SN, 107TN Negative Converter Arm 108a, 108b, 108c, 108d , 108e Unit converter 110 DC device 111 Power system 112 Reactor 15, 203a, 203b, 203c, 203d, 203e Capacitor NP1 First neutral point NP2 Second neutral point

Claims (15)

A multi-level power conversion device having a plurality of unit converters that output a predetermined voltage,
It has two arms connected in series via an AC voltage input / output unit,
The arm has a plurality of unit converters connected in series,
The at least one arm has a capacitor voltage of at least one unit converter capacitor different from that of the other unit converter. The power conversion device according to claim 1, wherein at least one of the arms includes a plurality of the unit converters having different capacitor voltages in an equal ratio. The power conversion device according to claim 1 or 2, wherein at least one of the arms includes at least four of the unit converters, and capacitor voltages of the four unit converters are different in an equal ratio. The power converter according to any one of claims 1 to 3, wherein at least one of the arms includes at least one voltage control unit converter. The power conversion device according to claim 4, further comprising a control unit that controls a difference between capacitor voltages of the plurality of unit converters. The unit converter and the voltage control unit converter are combined to output a predetermined voltage,
The power converter device according to claim 5, wherein there are a plurality of combinations of unit converters that can output the predetermined voltage. The combination of one of the unit converters is changed to another combination of the unit converters when the predetermined voltage is output, and the difference between the capacitor voltages of the plurality of unit converters is controlled. Power converter. The power converter according to claim 4, wherein a capacitor voltage of the voltage control unit converter is equal to a capacitor voltage of any of the unit converters. A current sensor for detecting a current flowing through at least one of the arms;
A voltage sensor for detecting a capacitor voltage of each of the plurality of unit converters and the voltage control unit converter;
The controller according to claim 4 or 8, further comprising: a controller that determines whether or not the voltage control unit converter is in a high state based on a current detected by the current sensor and a capacitor voltage detected by the voltage sensor. Power converter. The power converter according to claim 1, wherein a direct current flows through the arm. The power converter according to any one of claims 1 to 10, wherein the unit converter is a bidirectional chopper circuit. The AC voltage input / output unit includes an R phase AC voltage input / output unit, an S phase AC voltage input / output unit, and a T phase AC voltage input / output unit.
An R-phase leg comprising the two arms connected in series via the R-phase AC voltage input / output unit;
An S-phase leg comprising two arms connected in series via the S-phase AC voltage input / output unit;
A T-phase leg including the two arms connected in series via the T-phase AC voltage input / output unit;
The power converter according to any one of claims 1 to 11, wherein the R-phase leg, the S-phase leg, and the T-phase leg are connected in parallel.   A power generation system comprising the power conversion device according to any one of claims 1 to 12.   A load system comprising the power conversion device according to claim 1.   The power transmission / distribution system which linked the power converter device of any one of Claims 1-12 to the electric power grid | system.

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