JP6957196B2 - Power converter - Google Patents

Description

An embodiment of the present invention relates to a power conversion device.

Power conversion devices that convert electric power between alternating current and direct current are used for various purposes. In particular, by connecting a large number of predetermined voltage sources in series and switching each voltage source, the presence or absence of a predetermined voltage output can be switched, and the voltage waveform and current waveform of the AC power output from the power converter can be obtained. A modular multi-level converter (hereinafter referred to as MMC) that approaches a sine wave is drawing attention. In such an MMC, a capacitor may be used for one of the purposes of suppressing voltage fluctuations. However, if the capacitance of the capacitor is small, the voltage applied to the switching element may exceed the withstand voltage of the switching element. On the other hand, if the capacitance of the capacitor is increased to suppress the fluctuation of the voltage generated in the capacitor, or if the withstand voltage of the semiconductor element is increased, the cost and size of the power conversion device increase.

Makoto Hagiwara, Hirofumi Akagi, "PWM Control Method and Operation Verification of Modular Multi-Level Converter (MMC)", IEEJ Transactions D, Vol. 128, No. 7, pp. 957-965, July 2008

An object to be solved by the present invention is to provide a power conversion device capable of reducing a fluctuation range of a voltage in a circuit without increasing the cost and size of the device.

The power conversion device of the embodiment includes an arm unit and a control unit. The power conversion device has at least three arm units and a control unit provided corresponding to each phase of the three-phase alternating current. Each arm unit is connected in series to a positive arm in which at least one converter including a switching element and a power storage unit connected in parallel to the switching element is connected in series, and the switching element and the switching. One of the negative arm to which at least one converter consisting of power storage units connected in parallel to the element is connected in series and the three-phase alternating current provided between the positive arm and the negative arm. It has a corresponding AC terminal, and a positive DC terminal and a negative DC terminal provided on the opposite sides of the positive arm and the negative arm from the AC terminal, respectively. The control unit further flows in the same direction on the positive side arm and the negative side arm, and further causes the positive side arm and the control unit to generate a circulating current including a frequency component that is an even multiple of the frequency of the three-phase alternating current. The switching element is controlled so that an AC voltage generated in the opposite direction to the negative arm and containing a frequency component that is an odd multiple (three or more) of the frequency of the three-phase AC is generated , and the three-phase AC is used. A corrected AC voltage command value for including a frequency component that is an odd multiple (three or more) of the frequency is generated, and an AC voltage command value is generated using the corrected AC voltage command value to generate the AC voltage of the three-phase AC. Using the phase difference between the AC current and the AC current and the corrected AC voltage command value, an auxiliary circulating current command value for including a frequency component that is an even multiple of the frequency of the three-phase AC is generated, and the auxiliary circulating current is generated. A DC voltage command value is generated using the command value, and a pulse signal for controlling the switching element is generated using the AC voltage command value and the DC voltage command value .

The figure which shows an example of the electric power system to which the electric power conversion apparatus 1 of 1st Embodiment is applied. The block diagram of the conversion unit C of the 1st Embodiment. The block diagram of the control part 50 of 1st Embodiment. FIG. 1 is for explaining the process performed by the control unit 50 of the first embodiment. FIG. 2 is for explaining the process performed by the control unit 50 of the first embodiment. FIG. 3 is for explaining the process performed by the control unit 50 of the first embodiment. FIG. 4 is for explaining the process performed by the control unit 50 of the first embodiment. The figure for demonstrating the frequency component included in the electric power integral value of the capacitor 30 of 1st Embodiment. The block diagram of the control part 50A of the 2nd Embodiment. The figure for demonstrating the process performed by the control unit 50 of the 3rd Embodiment. The block diagram of the control part 50B of the 4th Embodiment. The block diagram of the correction AC voltage generation part 54B of 4th Embodiment. FIG. 1 is for explaining the process performed by the correction AC voltage generation unit 54B of the fourth embodiment. FIG. 2 is for explaining the process performed by the correction AC voltage generation unit 54B of the fourth embodiment. The block diagram of the power conversion apparatus 1A of the 5th Embodiment. The block diagram of the power conversion apparatus 1B of the sixth embodiment. FIG. 1 for explaining the process performed by the control unit 50 of the sixth embodiment. FIG. 2 is for explaining the process performed by the control unit 50 of the sixth embodiment.

Hereinafter, the power conversion device of the embodiment will be described with reference to the drawings.

(First Embodiment)
First, the first embodiment will be described. FIG. 1 is a diagram showing an example of a power system to which the power conversion device of the first embodiment is applied. As shown in FIG. 1, the power system includes a power conversion device 1 and an AC power supply 2.

The power conversion device 1 is a large-scale solar power generation system in which DC power is supplied via an AC power supply 2 which is a three-phase AC system, a positive DC terminal 3 which is a DC system, and a negative DC terminal 4. , A DC power supply such as an industrial UPS (Uninterruptible Power Supply), or a power conversion device that is connected to other power conversion devices and performs mutual conversion between AC and DC. ..

The AC power supply 2 outputs AC power. The AC power supply 2 is, for example, an AC power system. That is, the power conversion device 1 is used for applications such as a photovoltaic power generation system and a system that converts DC power generated by industrial UPS into AC power. It is also used in long-distance power transmission systems that transmit DC power with low power loss.

As shown in FIG. 1, the power converter 1 includes a positive DC terminal 3, a negative DC terminal 4, an instrument transformer 5, a transformer 6, and three arm units 8 (U-phase arm units). 8-1, V-phase arm unit 8-2, W-phase arm unit 8-3 included) and AC terminal 9 (U-phase AC terminal 9-1, V-phase AC terminal 9-2, W-phase The AC terminal 9-3) is provided.

The positive side DC terminal 3 and the negative side DC terminal 4 are connection terminals connected to a DC load. The instrument transformer 5 lowers the voltage of the AC power supply 2 and outputs it to the control unit 50. The transformer 6 is connected between the AC power supply 2 and the arm unit 8. The transformer 6 converts the voltage of the AC power transmitted from the AC power source 2. The transformer 6 is, for example, an insulated transformer that electrically insulates between the AC power supply 2 and the power converter 1. In the example shown in FIG. 1, such a transformer 6 is provided between the AC power supply 2 and the power conversion device 1, but the power conversion device 1 of the embodiment includes the transformer 6. It doesn't have to be. In this case, the AC power supply 2 and the power conversion device 1 are connected without going through the transformer 6. Further, in the example shown in FIG. 1, the transformer 6 is inside the power conversion device 1, but the transformer 6 may be outside the power conversion device 1.

As shown in FIG. 1, the arm unit 8 includes a positive arm 10P, a negative arm 10N, a positive buffer reactor 40P, a negative buffer reactor 40P, a positive current sensor 7P, and a negative current sensor 7N. And.

When viewed from the side of the positive side connection terminal 3, the arm unit 8 has a positive side arm 10P, a positive side buffer reactor 40P, a positive side current sensor 7P, an AC terminal 9, a negative side current sensor 7N, a negative side buffer reactor 40N, and a negative side. The arms 10N are connected in this order.

The arm unit 8 is connected to the three-phase AC of the AC power supply 2 by the AC terminal 9. In the example of FIG. 1, the arm unit 8 is connected to the three-phase AC of the AC power supply 2 via the AC terminal 9 and the transformer 6. That is, the U-phase AC terminal 9-1 is the U-phase of the AC power supply 2, the V-phase AC terminal 9-2 is the V-phase of the AC power supply 2, and the W-phase AC terminal 9-3 is the W of the AC power supply 2. Each phase is connected via a transformer 6. Further, the positive end of the arm unit 8 is connected to the positive DC terminal 3, and the negative end is connected to the negative DC terminal 4.

The positive side current sensor 7P and the negative side current sensor 7N each measure the current flowing through the place where they are installed. The positive side current sensor 7P and the negative side current sensor 7N output the measured current value to the control unit 50.

The positive buffer reactor 40P and the negative buffer reactor 40N suppress the short-circuit current flowing between the phases of the three-phase alternating current.

Further, each of the positive side arm 10P and the negative side arm 10N is, for example, L (L is an arbitrary natural number) of conversion units C connected in series.

FIG. 2 is a configuration diagram of the conversion unit C of the first embodiment. In the example of FIG. 2, the conversion includes, for example, diodes 21U, 21X, switching elements 22U, 22X, terminals 23U, 23X, a capacitor 30 (an example of a power storage unit), and a voltage sensor 31.

As shown in FIG. 2, in the conversion unit C, the switching elements 22U and 22X are connected in series and are connected in parallel with the capacitor 30. The conversion unit C is, for example, a chopper circuit. The conversion unit C outputs a certain determined voltage (hereinafter, unit voltage) or outputs a zero voltage based on the control from the control unit 50. The conversion unit C outputs the voltage of the capacitor 30 from the terminal 23U when the switching element 22U is on and the switching element 22X is off. Further, the conversion unit C outputs a zero voltage from the terminal 23U when the switching element 22U is off and the switching element 22X is on. Note that "outputting the voltage" means adjusting the voltage of the terminal 23U with respect to the terminal 23X.

The switching elements 22U and 22X are, for example, an IGBT (Insulated Gate Bipolar Transistor) and a MOSET (Metal-Oxide-Semiconductor Field-Effect Transistor). The switching elements 22U and 22X are connected to a cascode. That is, the emitter (source) of the switching element 22U and the collector (drain) of the switching element 22X are connected. Further, it is connected to another conversion unit C via a terminal 23U connected to the collector (drain) of the switching element 22X and a terminal 23X connected to the emitter (source) of the switching element 22X.
The terminal 23U is connected to the terminal 23X of another conversion unit C connected in series to the positive side of its own conversion unit C. Further, the terminal 23X is connected to the terminal 23U of another conversion unit C connected in series to the negative side of its own conversion unit C. If there is no conversion unit C connected to the positive side of its own conversion unit C, the terminal 23U is connected to the positive DC terminal 3. If there is no conversion unit C connected to the negative side of its own conversion unit C, the terminal 23X is connected to the negative DC terminal 4.

The switching elements 22U and 22X can perform on / off control from outside (for example, control unit 50) such as GTO (Gate Turn-Off Thyristor) and GCT (Gate Commutated Turn-off) in addition to IGBTs and MOSFETs. It is a switching element with arc extinguishing ability.

Further, diodes 21U and 21X are connected in antiparallel to each of the switching elements 22U and 22X, respectively. The diodes 21U and 21X are antiparallel diodes.

The voltage sensor 31 measures the voltage of the capacitor 30. The voltage sensor 31 outputs the measured voltage value to the control unit 50.

Returning to FIG. 1, the control unit 50 controls each of the three arm units 8. The current values from the current sensors 7P and 7N in each arm unit 8 are input to the control unit 50, respectively. Further, the voltage values from the voltage sensor 31 of the conversion unit C included in the positive side arm 10P and the negative side arm 10N of each arm unit 8 are input to the control unit 50, respectively. Further, the control unit 50 outputs a switching control signal to each of the switching elements 22U and 22X of each conversion unit C.

Here, the power conversion operation in the power conversion device 1 of the present embodiment will be described by taking the U-phase arm unit 8-1 as an example. Here, the neutral point between the positive DC terminal 3 and the negative DC terminal 4 is set as the reference potential of the DC system.

First, it is defined as follows.
Vu: Voltage of AC terminal 9 in each phase in three-phase AC Iu: Current flowing through AC terminal 9 Vdc: Potential difference between potential of positive DC terminal 3 and reference potential (voltage on DC side)
Idc ... Current flowing on the DC side Vc ... Voltage of the capacitor 30 of the conversion unit C VuP ... Voltage of the positive side arm 10P VuN ... Voltage of the negative side arm 10N IuP ... Current flowing through the positive side arm 10P IuN ... Flowing through the negative side arm 10N Current

At this time, the voltage VuP of the positive arm 10P is represented by the following equation (1).

VuP = -Vu + Vdc / 2 ... (1)

The voltage VuN of the negative arm 10N is represented by the following equation (2).

VuN = + Vu + Vdc / 2 ... (2)

As shown in the above equation (1), the control unit 50 controls the voltage VuP of the positive arm 10P by adjusting the amplitude and phase of the voltage (hereinafter referred to as AC voltage) Vu at the AC terminal 9. Can be done. Further, as shown in the above equation (2), the control unit 50 can control the voltage VuN of the negative arm 10N by adjusting the amplitude and phase of the AC voltage Vu. The control unit 50 performs PWM (Pulse Width Modulation) control that converts the ratio of turning on / off the switching elements 22U and 22X of the conversion unit C into a pulse width corresponding to the voltage output from the conversion unit C. The voltage output from the conversion unit C is controlled. The control unit 50 controls the voltage VuP of the positive side arm 10P and the voltage VuN of the negative side arm 10N by controlling the voltage to be output from each conversion unit C.

On the other hand, paying attention to the voltage Vc of the capacitor 30 of the conversion unit C, in order to output a desired voltage from the conversion unit C, it is necessary to make the average value of the capacitor voltages constant. In order for the average value of the capacitor voltage to be a constant value, at least the integrated value of the power input / output to / from the capacitor 30 in one cycle of three-phase alternating current needs to be zero. When the integrated value of the electric power input / output to / from the capacitor 30 in one cycle of three-phase alternating current is positive, that is, a positive value, the electric charge stored in the capacitor 30 continues to increase. At this time, the voltage Vc of the capacitor 30 continues to increase. Further, when the integrated value of the electric power input / output to the capacitor 30 in one cycle of the three-phase alternating current is negative, that is, a negative value, the electric charge stored in the capacitor 30 continues to decrease. In this case, the voltage Vc of the capacitor 30 continues to decrease. In either case, the power conversion device 1 cannot operate normally.

In order to deal with this, in the power conversion device 1 of the present embodiment, a current for adjusting the voltage Vc of the capacitor 30 is passed through each arm unit 8. The current that adjusts the voltage Vc of the capacitor 30 can be said to be the current that charges and discharges a part of the electric charge stored in the capacitor 30. Here, the direction in which the current flows from the AC power supply 2 to the positive DC terminal 3 and the negative DC terminal 4 and the direction in which the current flows from the negative side to the positive side are defined as the positive direction. In this case, a positive current flows to charge the capacitor 30, and a negative current flows to discharge the capacitor 30. That is, the current that adjusts the voltage Vc of such a capacitor 30 can be said to be an alternating current Iu. It is assumed that the alternating current Iu flows in half to the positive side arm 10P and the negative side arm 10N in each arm unit 8.

At this time, the current IuP flowing through the positive arm 10P is represented by the following equation (3).

IuP = + Iu / 2 + Iz ... (3)

The current IuN flowing through the negative arm 10N is represented by the following equation (4).

IuN = -Iu / 2 + Iz ... (4)

Here, Iz shown in the above equation (3) and the above equation (4) indicates a circulating current. The circulating current Iz is a current that flows in the same direction to the positive side arm 10P and the negative side arm 10N.

Here, since the integrated value of the power input / output to / from the capacitor 30 in one cycle of the three-phase alternating current becomes zero, the following equation (5) is established. Here, ArmP indicates the integrated power value of the positive arm 10P, and PalmP indicates the electric power of the positive arm 10P. Further, the integration interval of the second term of the following equation (5) is one cycle of the three-phase alternating current. Specifically, assuming that the frequency of the three-phase alternating current is ω, the integration interval of the second term of the following equation (5) is from 0 (zero) to ω / (2π).

ArmP = ∫ (ParmP) dt = 0… (5)

Similar to the above equation (5), the following equation (6) also holds for the negative arm 10N. Here, ArmN indicates the integrated power value of the negative arm 10N, and PalmN indicates the power of the negative arm 10N.

ArmN = ∫ (ParmN) dt = 0… (6)

By substituting the above equation (1) and the above equation (3) into the above equation (5), the following equation (7) can be obtained. Here, ω indicates the frequency of the three-phase alternating current, Vurms indicates the effective value of the voltage of the three-phase alternating current, and Irms indicates the effective value of the current of the three-phase alternating current. Here, it is assumed that there is no phase difference between the voltage and the current of the three-phase alternating current, that is, the operation is performed with a power factor of 1.

PalmP
= VuP x IuP
= (-Vu + Vdc / 2) x (+ Iu / 2 + Iz)
= {-√2 x Vurms x sin (ωt) + Vdc / 2} x {+ √2 x Irums x sin (ωt) / 2 + Iz}
= -Vurms x Irums x sin ² (ωt) + (-√2 x Vurms x Iz + √2 x Irums x Vdc / 4) x sin (ωt) + Iz x Vdc / 2
= 1/2 x Vurms x Irums x cos (2ωt) + A x sin (ωt) + (-Vurms x Irums / 2 + Iz x Vdc / 2) ... (7)

Here, in the above equation (7), ^{the relationship of sin 2} (ωt) = {1-cos (2ωt)} / 2 is used. Further, in the above equation (7), A is a predetermined constant (−√2 × Vurms × Iz + √2 × Irums × Vdc / 4).

In the above equation (7), the first term has a second-order frequency component of frequency ω, that is, a coefficient of cos (2ωt), and the second term has a first-order frequency component of frequency ω, that is, sin (ωt). Has a coefficient. In both the first term and the second term, the integral value in the integration interval shown in the second term of the above equation (5) is zero. In the above equation (7), in order for the above equation (5) to be established, the following equation (8) may be established.

(-Vurms x Irums / 2 + Iz x Vdc / 2) = 0 ... (8)

The above equation (8) is solved for Iz, and in the power conversion device 1, there is a relationship in which the power of the AC system and the power of the DC system match, that is, there is a relationship of Vdc × Idc = 3 × Vurms × Irums. By substituting the equation (8) solved for Vdc into the equation solved for Iz, the following equation (9) is established.

Iz = Vurms x Irums / Vdc
= Idc / 3 ... (9)

From the above equation (9), the control unit 50 controls the switching elements 22U and 22X so that a current having a magnitude of 1/3 of the direct current Idc flows as the circulating current Iz, thereby forming one of the three-phase alternating currents. It can be seen that the integrated value of the power input to / from the capacitor 30 becomes zero in the cycle, and the average value of the voltage of the capacitor 30 can be kept constant.

The voltage VuP and the current IuP of the positive arm 10P adjusted by the control unit 50 will be described with reference to FIG. FIG. 4 is a diagram for explaining a process performed by the control unit 50 of the first embodiment. FIG. 4A shows an example of changes in the voltage VuP and the current IuP of the positive arm 10P in one cycle of three-phase alternating current. FIG. 4B shows changes in the voltage VuP of the positive arm 10P in one cycle of the three-phase alternating current, the power PalmP of the positive arm 10P when the current IuP is FIG. 4A, and the power integral value EarmP. An example is shown. The horizontal axis of FIG. 4A shows the phase [deg], the first axis of the vertical axis shows the voltage [V], and the second axis of the vertical axis shows the current [A]. Further, the horizontal axis of FIG. 4B shows the phase [deg], the first axis of the vertical axis shows the electric power [W], and the second axis of the vertical axis shows the work [J].

As shown in FIG. 4A, the voltage VuP of the positive arm 10P has a waveform in which a predetermined DC component is superimposed on an AC component having the same period as the three-phase AC. That is, the voltage VuP of the positive arm 10P has a waveform with an offset in the sine wave. This means that, as shown in the above equation (1), the voltage VuP of the positive arm 10P includes a voltage (-Vu) as an AC component and a voltage (Vdc / 2) as a DC component. ing.

Further, the current IuP of the positive arm 10P has a waveform in which a predetermined DC component is superimposed on an AC component having the same period as the three-phase AC. That is, the current IuP of the positive arm 10P has a waveform with an offset in the sine wave. This means that, as shown in the above equation (3), the current IuP of the positive arm 10P contains a current (Iu / 2) as an AC component and a current (Iz) as a DC component. ..

As shown in FIG. 4B, the power PalmP of the positive arm 10P is the product of the voltage VuP and the current IuP shown in FIG. 4A, and therefore has a periodic waveform in the same period as the three-phase alternating current. It becomes. Specifically, the power waveforms in phase zero [deg] and phase 360 [deg] match, there are valleys in phase 90 [deg] and phase 270 [deg], and there are peaks between the valleys, respectively. It becomes a waveform. Further, the waveform is such that the valley of the phase 270 [deg] is deeper than the valley of the phase 90 [deg]. As shown in the above equation (7), this is a frequency component having a period twice that of the three-phase AC, that is, a waveform having the same phase (for example, valley) in the phase 90 [deg] and the phase 270 [deg]. , A frequency component having the same period as the three-phase AC, that is, a waveform having opposite phases (for example, peak at phase 90 [deg] and valley at phase 270 [deg]) at phase 90 [deg] and phase 270 [deg]. Is a superposed waveform.

Further, since the power integrated value ArmP of the positive arm 10P is the integral of the power PalmP of the positive arm 10P having periodicity in the same period as the three-phase alternating current, the power PalmP of the positive arm 10P is a positive value. The interval increases monotonically from the phase 0 [deg] to the point after the phase 180 [deg]. Further, the power PalmP of the positive arm 10P decreases monotonically from a section where the power PalmP becomes a negative value, that is, a point around the phase 180 [deg] to a point near the time and effort of the phase 360 [deg]. This indicates that the power integral value ArmP of the positive arm 10P has a constant average value in the same cycle as the three-phase alternating current, but the value fluctuates within one cycle.

The control unit 50 will be described with reference to FIG. FIG. 3 is a configuration diagram of the control unit 50. As shown in FIG. 3, the control unit 50 includes a capacitor balance control unit 51, an AC current control unit 52, a circulating current control unit 53, a correction AC voltage generation unit 54, PWM units 55 and 56, and an adder. It includes a to c and a multiplier d.

The capacitor balance control unit 51 adjusts the voltage balance of the capacitor 30 of each conversion unit C in each arm unit 8. This is because the voltage of each capacitor 30 may cause power loss due to switching in the actual power conversion operation, variation in switching timing, variation in voltage detection error, and the like. As for the specific operation of the capacitor balance control unit 51, since the technique already known in non-patent documents and the like is used, detailed description thereof will be omitted here.

The capacitor balance control unit 51 inputs the capacitor voltage from the voltage sensor 31 and calculates the AC effective current command value, that is, the AC current Iu when the power factor is 1. Further, the capacitor balance control unit 51 calculates the circulating current balance. The circulating current balance is a current value for adjusting the variation of the voltage Vc of each capacitor 30. The capacitor balance control unit 51 outputs the calculated effective current command value to the AC current control unit 52. Further, the capacitor balance control unit 51 outputs the calculated circulating current balance to the circulating current control unit 53.

The alternating current control unit 52 adjusts the alternating current Iu flowing through each arm unit 8. The AC current control unit 52 is a command value (AC voltage) of the AC voltage Vu for adjusting the AC current Iu based on the AC current Iu (actually flowing) from the capacitor balance control unit 51 and the AC voltage Vu. Command value) is calculated. That is, the control unit 50 adjusts the AC current Iu by controlling the AC voltage Vu. The AC current control unit 52 outputs the calculated AC voltage command value to the adder a.

The circulation current control unit 53 adjusts the circulation current Iz to be passed through each arm unit 8. A value obtained by adding 1/3 of the DC side current Idc (DC current command value) to the circulating current balance from the capacitor balance control unit 51 is input to the circulating current control unit 53. That is, in the circulating current control unit 53, the command value of the circulating current such that the average value of the voltage Vc of each capacitor 30 becomes constant in one cycle of the three-phase alternating current adjusts the variation of the voltage Vc of each capacitor 30. Then, it is input.

Further, the voltage Vdc (DC voltage command value) on the DC side is input to the circulating current control unit 53. Further, a command value (auxiliary circulation current command value) of the auxiliary circulation current is input to the circulation current control unit 53. The auxiliary circulating current is a current that assists the circulating current Iz. By adding the auxiliary circulating current to the circulating current Iz, not only the average value of the voltage Vc of the capacitor 30 is kept constant, but also the fluctuation range of the voltage Vc of the capacitor 30 is suppressed. The method of suppressing the fluctuation range of the voltage Vc of the capacitor 30 by using the auxiliary circulating current will be described in detail later.

The circulating current control unit 53 of the DC voltage Vdc for adjusting the circulating current Iz based on the circulating current Iz (adjusted for the variation of the voltage Vc of each capacitor 30), the voltage Vdc on the DC side, and the auxiliary circulating current. Calculate the command value. That is, the control unit 50 adjusts the circulating current Iz by controlling the DC voltage Vdc. The circulating current control unit 53 outputs the calculated command value to the multiplier d.

The multiplier d multiplies the command value of the DC voltage Vdc from the circulating current control unit 53 by 1/2. The multiplier d outputs the DC voltage Vdc multiplied by 1/2 to the adder b and the adder c.

The correction AC voltage generation unit 54 generates a command value of the correction AC voltage. The corrected AC voltage is a voltage that corrects the AC voltage Vu. By applying the correction AC voltage to the AC voltage Vu, the fluctuation range of the voltage Vc of the capacitor 30 is suppressed. A method of suppressing the fluctuation range of the voltage Vc of the capacitor 30 by using the corrected AC voltage will be described in detail later. The correction AC voltage generation unit 54 outputs the command value of the generated correction AC voltage to the adder a.

The adder a adds the AC voltage command value from the AC current control unit 52 and the command value of the correction AC voltage from the correction AC voltage generation unit 54. The adder a outputs the added value (command value of the corrected AC voltage Vu) to the adder c and the adder b.

The adder b adds the value obtained by multiplying the command value of the corrected AC voltage Vu from the adder a by -1, and the command value of the DC voltage Vdc obtained by multiplying the command value of the AC voltage Vu from the adder d by 1/2. .. The adder b outputs the added value to the PWM unit 55. The value output by the adder b is the command value of the voltage VuP of the positive arm 10P shown in the above equation (1).

The PWM unit 55 converts the command value of the voltage VuP of the positive arm 10P from the adder b into a pulse width, and generates a pulse signal corresponding to the command value of the positive arm voltage VuP. The PWM unit 55 outputs the generated pulse signal to the switching elements 22U and 22X in the conversion unit C of the positive arm 10P. As a result, the switching elements 22U and 22X perform on / off operations based on the pulse signal. As a result, the voltage VuP of the positive arm 10P is controlled to the value indicated by the command value calculated by the control unit 50.

The adder c adds the command value of the DC voltage Vdc multiplied by 1/2 from the multiplier d and the command value of the corrected AC voltage Vu from the adder a. The adder c outputs the added value to the PWM unit 56. The value output by the adder c is the command value of the voltage VuN of the negative arm 10N shown in the above equation (2).

The PWM unit 56 converts the command value of the voltage VuN of the negative arm 10N from the adder c into a pulse width, and generates a pulse signal corresponding to the command value of the negative arm voltage VuN. The PWM unit 56 outputs the generated pulse signal to the switching elements 22U and 22X in the conversion unit C of the negative arm 10N. As a result, the switching elements 22U and 22X perform on / off operations based on the pulse signal. As a result, the voltage VuN of the negative arm 10N is controlled to the value indicated by the command value calculated by the control unit 50.

(A method of suppressing the fluctuation range of the voltage Vc of the capacitor 30 by using the auxiliary circulating current and the corrected AC voltage)
Here, a method of suppressing the fluctuation range of the voltage Vc of the capacitor 30 by using the auxiliary circulating current and the corrected AC voltage will be described by taking the positive side arm 10P as an example. As shown in the above equation (9), assuming that the circulating current Iz is Idc / 3 (Iz = Idc / 3), the power PalmP of the positive arm 10P has the relationship shown in the following equation (10).

PalmP
= 1/2 x Vurms x Irums x cos (2ωt)
+ (−√2 × Vurms × Idc / 3 + √2 × Irums × Vdc / 4) × sin (ωt)… (10)

On the other hand, since the electrostatic energy U ^{of the capacitor is represented by 1/2 × Cap × V 2} (Cap is the capacitance of the capacitor and V is the voltage of the capacitor), the voltage Vc of the capacitor 30 is the following (11). ) The relationship is shown in the equation. Here, Cap indicates the capacitance of the capacitor 30, Vcini indicates the initial voltage of the capacitor 30, ArmP indicates the power integral value of the positive arm 10P, and N indicates the number of capacitors 30 in the positive arm 10P.

Vc = √ {2 × (Cap × Vcini 2/2 + EarmP / N) / Cap}
≒ Vcini × (1 + ArmP / N / Cap / Vcini ² )… (11)

In the above equation (11), an approximate equation, 1 + √x≈1 + x / 2 (x << 1) is used. That is, the power integral value ArmP of the positive arm 10P is larger than the value obtained by multiplying the number N of the capacitors 30, the capacitance Cap of the capacitors 30 and the square of the initial voltage Vcini of the capacitors 30 (N × Cap × Vcini ² ). I consider it small enough.

From the above equation (11), the fluctuation width ΔVc of the voltage Vc of the capacitor 30 can be expressed by the following equation (12). Here, Cap indicates the capacitance of the capacitor 30, Vcini indicates the initial voltage of the capacitor 30, ArmP indicates the power integral value of the positive arm 10P, and N indicates the number of capacitors 30 in the positive arm 10P.

ΔVc = ΔEarmP / N / Cap / Vcini… (12)

In the above equation (12), if the maximum value of the power integral value ArmP of the positive arm 10P is max (EarmP) and the minimum value of the power integral value ArmP of the positive arm 10P is min (EarmP), ΔEarmP is max (12). ArmP) -min (ArmP). That is, from the equation (12), the fluctuation width ΔVc of the voltage Vc of the capacitor 30 is proportional to the fluctuation width of the power integral value ArmP of the positive arm 10P, and is inversely proportional to the capacitance Cap of the capacitor 30 of the conversion unit C. I understand. The capacitance Cap of the capacitor 30 does not change in one cycle of three-phase alternating current. Therefore, suppressing the fluctuation width ΔEarmP of the power integral value ArmP of the positive arm 10P, that is, suppressing the fluctuation width ΔVc of the voltage Vc of the capacitor 30.

Here, a method of suppressing the fluctuation width ΔEarmP of the integrated power value ArmP by adding an auxiliary circulating current to the circulating current Iz and the AC voltage Vu will be described.

In the present embodiment, the control unit 50 gives the auxiliary circulating current a frequency component that is an even multiple of the frequency of the three-phase alternating current. At this time, the circulating current Iz can be expressed by, for example, the following equation (13). Here, Izaux indicates an auxiliary circulating current, I2 and I4 indicate predetermined constants, and ω indicates a frequency of three-phase alternating current.

Iz = Idc / 3 + Izaux ... (13)
However, Izaux = -I2 × cos (2ωt) -I4 × cos (4ωt)

Further, the control unit 50 gives the corrected AC voltage a frequency component that is an odd multiple of 3 of the frequency of the three-phase AC. At this time, the AC voltage Vu can be expressed by, for example, the following equation (14). Here, V3 indicates a predetermined constant, and ω indicates a frequency of three-phase alternating current. In the following description, this V3 is also simply referred to as V3 or a coefficient ratio V3.

Vu = √2 × Vurms × {sin (ωt) + V3 × sin (3ωt)}… (14)

At this time, the power PalmP of the positive arm 10P can be expressed by the following equation (15). Here, E (M) is a coefficient corresponding to the amplitude of a frequency (Mth-order frequency component) that is M times the frequency ω of the three-phase alternating current. However, M is a natural number.

PalmP
= VuP x IuP
= (-Vu + Vdc / 2) x (+ Iu / 2 + Iz)
= {-√2 x Vurms x {sin (ωt) + V3 x sin (3ωt)} + Vdc / 2}
× {+ √2 × Irums × sin (ωt) / 2 + Idc / 3-I2 × cos (2ωt) -I4 × cos (4ωt)}
= E (1) x sin (ωt) + E (2) x sin (2ωt) + E (3) x sin (3ωt)
+ E (4) x sin (4ωt) + E (5) x sin (5ωt)
+ E (7) x sin (7ωt) ... (15)

In the above equation (15), the waveform of the power PalmP of the positive arm 10P is used by using the formula based on the addition theorem, the relationship of sinα × cosβ = 1/2 × {sin (α + β) + sin (α-β)}. It expresses the frequency component contained in.

When the power PalmP of the positive arm 10P shown in the above equation (15) is integrated, the integrated power value ArmP is obtained. Here, the frequency component of the mth order in the electric power PalmP is integrated so that the amplitude becomes 1 / m. From this, it can be considered that the coefficient having the greatest influence on the fluctuation range of the power integral value ArmP is the coefficient E (1) in the first-order frequency component. The coefficient E (1) is based on the above formula, sinα × cosβ = 1/2 × {sin (α + β) + sin (α−β)}, and is a multiplication of trigonometric functions whose frequency difference is ω, for example. It can be obtained from the number (B1 × B2) calculated by multiplying B1 × sin (ωt) and B2 × cos (2ωt). Here, B1 and B2 are predetermined real numbers.

Here, the following rated voltage and rated current are assumed.
Vurms = 200 / √3 [V]
Irums = 50 / √3 [A]
Vdc = 350 [V]
Idc = 28.6 [A]
ω = 50 [Hz]

In this case, the coefficient ArmP (1) of the first-order frequency component of the power integral value ArmP is expressed by the following equation (16).

ArmP (1) =-(√2 / 4 x Vdc x Irms-√2 / 3 x Vurms x Idc-√2 / 2 x Vurms x I2 + √2 / 2 x Vurms x V3 x I2-√2 / 2 x Vurms × V3 × I4) / ω
=-(6.42-0.26 x I2 + 0.26 x V3 x I2-0.26 x V3 x I4) ... (16)

By setting I2, I4, and V3 to appropriate values from the above equation (16), the coefficient ArmP (1) of the first-order frequency component of the power integral value ArmP can be reduced. By reducing the coefficient EarmP (1) of the first-order frequency component, the fluctuation range of the power integral value ArmP is reduced. That is, by setting the amplitudes I2 and I4 of the frequency components included in the auxiliary circulating current and the coefficient ratio V3 of the amplitudes of the frequency components included in the corrected AC voltage to appropriate values, the fluctuation range of the capacitor 30 is reduced.

An example of suppressing the fluctuation range of the voltage Vc of the capacitor 30 by appropriately combining the amplitudes I2 and I4 of the frequency components included in the auxiliary circulating current and the coefficient ratio V3 of the amplitudes of the frequency components included in the corrected AC voltage. This will be described with reference to FIGS. 5 to 7.

5 to 7 are FIGS. 2 to 4 for explaining the process performed by the control unit 50 of the first embodiment. 5 (a) to 7 (a) show an example of changes in the voltage VuP and the current IuP of the positive arm 10P in one cycle of the three-phase alternating current. 5 (b) to 7 (b) show the electric power of the positive arm 10P when the voltage VuP and the current IuP of the positive arm 10P in one cycle of the three-phase alternating current are (a) in each figure. An example of changes in PalmP and the integrated power value ArmP is shown. 5 (a) to 7 (a) show the phase [deg] on the horizontal axis, the voltage [V] on the first axis of the vertical axis, and the current [A] on the second axis of the vertical axis. Further, the horizontal axis of FIGS. 5 (b) to 7 (b) indicates the phase [deg], the first axis of the vertical axis indicates the electric power [W], and the second axis of the vertical axis indicates the work [J].

In the example of FIG. 5, I2 = 8 [A], I4 = 0 [A], and V3 = 0 [%]. That is, the circulating current Iz includes a secondary frequency component of 8 × cos (2ωt).

As shown in FIG. 5A, in the current IuP of the positive arm 10P, the circulation current Iz does not include the secondary frequency component 8 × cos (2ωt), that is, as compared with the case of FIG. 4A. Therefore, the fluctuation range of the current IuP of the positive arm 10P is reduced. In the voltage VuP of the positive arm 10P, since V3 = 0 [%], the waveform is the same as in the case of FIG. 4A.

As shown in FIG. 5B, in the power PalmP of the positive arm 10P, the fluctuation range of the power PalmP of the positive arm 10P is also reduced by the amount that the fluctuation range of the current IuP of the positive arm 10P is reduced. Further, also in the power integrated value ArmP of the positive arm 10P, the fluctuation range of the power integrated value ArmP of the positive arm 10P is reduced by the amount that the fluctuation range of the power PalmP of the positive arm 10P is reduced.

Further, in the example of FIG. 5, based on the above equation (16), ArmP (1) is -4.34. This is because the absolute value of the first-order coefficient Arm (1) is reduced by about 30% as compared with the case of I2 = 0 [A] (ArmP (1) = −6.42).

In the example of FIG. 6, I2 = 4 [A], I4 = 8 [A], and V3 = 0 [%]. That is, the circulating current Iz includes a second-order frequency component 4 × cos (2ωt) and a fourth-order frequency component 8 × cos (4ωt).

As shown in FIG. 6A, in the current IuP of the positive arm 10P, the circulation current Iz includes only the secondary frequency component 8 × cos (2ωt), that is, as compared with the case of FIG. 5A. By adding the valley portion of the fourth-order frequency component to the peak portion of the waveform, the fluctuation range of the current IuP of the positive arm 10P is reduced particularly in the section from phase 0 [deg] to 180 [deg]. At this time, the fluctuation range of the current IuP of the positive arm 10P is reduced by about 10%.

As shown in FIG. 6B, in the power ParmP of the positive arm 10P, the fluctuation width of the current IuP of the positive arm 10P is reduced, so that the positive arm is in the section from phase 0 [deg] to 180 [deg]. The fluctuation range of the power PalmP of 10P is reduced. However, in this case, the fluctuation range of the power PalmP of the positive arm 10P increases in the section from the phase 180 [deg] to 360 [deg]. Further, in the power integrated value ArmP of the positive arm 10P, the fluctuation range of the power integrated value ArmP of the positive arm 10P is slightly increased as compared with the case of FIG. 5B.

In the example of FIG. 6, based on the above equation (16), ArmP (1) is −5.38. This is because the absolute value of the first-order coefficient ArmP (1) is increased as compared with the case of I2 = 8 [A].

In the example of FIG. 7, I2 = 4 [A], I4 = 8 [A], and V3 = 50 [%]. That is, the circulating current Iz includes the second-order frequency component 4 × cos (2ωt) and the fourth-order frequency component 8 × cos (4ωt), and the AC voltage Vu has the third-order frequency component √2Vurms × 0. Includes 5 × cos (3ωt).

As shown in FIG. 7A, the current IuP of the positive arm 10P is the same as that in FIG. 6A. In the voltage VuP of the positive arm 10P, the fluctuation range of the voltage VuP of the positive arm 10P is reduced as compared with the case where the AC voltage Vu does not include the third-order frequency component, that is, the case of FIG. 4A. This is because the valleys of the waveforms of the third-order frequency components are added to the peaks of the waveforms at the phases 90 [deg] and 270 [deg] that originally existed in the AC voltage Vu.

As shown in FIG. 7B, in the power PalmP of the positive arm 10P, the fluctuation range of the power PalmP of the positive arm 10P is reduced by the amount that the fluctuation range of the voltage VuP of the positive arm 10P is reduced. Further, also in the power integrated value ArmP of the positive arm 10P, the fluctuation range of the power integrated value ArmP of the positive arm 10P is reduced by the amount that the fluctuation range of the power PalmP of the positive arm 10P is reduced.

In the example of FIG. 7, based on the above equation (16), ArmP (1) is -4.36. This is almost the same value as compared with the case of I2 = 8 [A] (ArmP (1) = -4.34).

Comparing the power integral value ArmP of the positive arm 10P in FIG. 7B with the power integral value ArmP of the positive arm 10P in FIG. 5, the power integral value ArmP of the positive arm 10P in FIG. 7B is compared. The fluctuation range is reduced. Therefore, the coefficient EarmP (3) of the first-order frequency component of the power integral value ArmP is derived from the above equation (15). The coefficient ArmP (3) can be expressed by the following equation (17).

ArmP (3) =-(-√2 / 3 x Vurms x V3 x Idc + √2 / 2 x Vurms x I2-√2 / 2 x Vurms x I4) / 3 / ω
=-(-1.65 x V3 + 0.087 x I2-0.087 x I4) ... (17)

In the above equation (17), the values assuming the rated voltage and the rated current are used as described above.

Based on the above equation (17), in the case of FIG. 5, that is, when I2 = 8 [A], I4 = 0 [A], and V3 = 0 [%], ArmP (3) is −0.69. Become. On the other hand, in the case of FIG. 5, that is, when I2 = 4 [A], I4 = 8 [A], and V3 = 50 [%], ArmP (3) is 1.17.

Here, the relationship between ArmP (1) and ArmP (3) will be described with reference to FIG. FIG. 8 is a diagram for explaining a frequency component included in the power integral value ArmP of the capacitor 30. FIG. 8A shows a primary component of the power integral value ArmP of the positive arm 10P in the case of FIG. 5, that is, when I2 = 8 [A], I4 = 0 [A], and V3 = 0 [%]. The tertiary component and the sum of the primary component and the tertiary component are shown, respectively. FIG. 8B shows the primary component of the power integral value ArmP of the positive arm 10P in the case of FIG. 7, that is, when I2 = 4 [A], I4 = 8 [A], and V3 = 50 [%]. The tertiary component and the sum of the primary component and the tertiary component are shown, respectively. 8 (a) and 8 (b) show the phase [deg] on the horizontal axis and the work [J] on the vertical axis.

As shown in FIG. 8A, under the conditions shown in FIG. 5 (I2 = 8 [A], I4 = 0 [A], V3 = 0 [%]), the first order in the power integrated value ArmP of the capacitor 30. The frequency component of is a sine wave in which the phase 0 [deg] and 360 [deg] are valleys and the phase 180 [deg] is peak. The third-order frequency component in the power integrated value ArmP of the capacitor 30 is a sine wave having a valley in phase 0 [deg] and three cycles until the phase 360 [deg]. As a result, the third-order frequency component becomes a peak at a phase of 180 [deg]. The sum of the first-order and third-order frequency components in the power integrated value ArmP of the capacitor 30 is weighted by the valleys of the respective sine waves at the phases 0 [deg] and 360 [deg], and the phase 180 [deg]. In, the peaks of each sine wave are weighted. Therefore, the absolute values of the respective values in the phases 0 [deg], 180 [deg], and 360 [deg] increase. That is, the fluctuation range of the power integral value ArmP increases.

As shown in FIG. 8B, under the conditions shown in FIG. 7 (I2 = 4 [A], I4 = 8 [A], V3 = 50 [%]), the first order in the power integrated value ArmP of the capacitor 30. The frequency component of is a sine wave in which the phase 0 [deg] and 360 [deg] are valleys and the phase 180 [deg] is peak. In the primary component shown in FIG. 8B, the amplitude of the sine wave is slightly increased as compared with FIG. 8A due to the difference in the component ratios of I2 and I4. Further, the third-order frequency component in the power integrated value ArmP of the capacitor 30 has a peak in phase 0 [deg] and becomes a sine wave having three cycles until the phase 360 [deg]. As a result, the third-order frequency component becomes a valley at a phase of 180 [deg]. The sum of the first-order and third-order frequency components in the power integrated value ArmP of the capacitor 30 is the phase in which the first-order valley and the third-order peak are weighted at the phases 0 [deg] and 360 [deg], respectively. At 180 [deg], the first-order peaks and the third-order valleys are weighted, respectively. Therefore, in the phases 0 [deg], 180 [deg], and 360 [deg], the absolute values of the respective values are reduced as compared with FIG. 8A. That is, the fluctuation range of the power integral value ArmP is reduced.

That is, when the symbols of ArmP (1) and ArmP (3) are different, the fluctuation range of the power integral value ArmP tends to decrease. This can be considered in the same manner for ArmP (1) and ArmP (5), and when the symbols of ArmP (1) and ArmP (5) are different, the fluctuation range of the power integral value ArmP is reduced. do. That is, when the symbols of ArmP (1) and ArmP (s) (where s is an odd number of 3 or more) are different, the fluctuation range of the power integral value ArmP is reduced. By reducing the fluctuation range of the power integrated value ArmP, it is possible to reduce the fluctuation range of the capacitor 30 in the voltage Vc.

As described above, in the power conversion device 1 of the first embodiment, the arm units 8-1 to 8-3 (“at least three arm units provided corresponding to each phase of the three-phase alternating current””. Each arm unit 8 is provided with a positive arm 10P and a negative arm 10N connected in series, and each of the positive arm 10P and the negative arm 10N is an example of a capacitor 30 (an example of a "storage unit"). ) And switching elements 22U and 22X (an example of a "switching element"), and has at least one conversion unit C (an example of a "converter") from a location between the positive arm 10P and the negative arm 10N. The power of one phase of the three-phase alternating current is input and output, and the DC power is input and output from the end. Of the current flowing through the arm unit 8, the current flowing in the same direction between the positive arm 10P and the negative arm 10N. The switching elements 22U and 22X are controlled so that a certain circulating current Iz and an alternating current Iu which is a current flowing in the opposite direction between the positive side arm 10P and the negative side arm 10N among the currents flowing through the arm unit 8 are generated. In the control unit 50, an auxiliary circulating current containing an even multiple frequency component (2ω, 4ω, ...) Of the frequency ω of the three-phase alternating current is applied to the circulating current Iz, and the three-phase alternating current A control unit that controls the switching elements 22U and 22X so that a component corresponding to the auxiliary AC voltage including a frequency component (3ω, 5ω, ...) That is an odd multiple (3 or more) of the frequency ω is applied to the AC current Iu. 50 is further provided.

As a result, in the power conversion device 1 of the first embodiment, in addition to the current (Idc / 3) required for power conversion to the circulating current Iz, the auxiliary circulating current is an even multiple of the three-phase alternating current frequency ω. Frequency components (2ω, 4ω, ...) Can be included. By including a frequency component (2ω, 4ω, ...) That is an even multiple of the phase AC frequency ω in the circulating current Iz, the current flowing through the positive side arm 10P and the negative side arm 10N in each arm unit 8. The fluctuation range of IuP and IuN can be reduced. If the fluctuation range of the current is reduced, the fluctuation range of the electric power is reduced. If the fluctuation range of the power is reduced, the fluctuation range of the integrated power value is reduced. It can be said that the fluctuation range of the power integral value is proportional to the voltage Vc of the capacitor 30. Therefore, by including the frequency components (2ω, 4ω, ...) That are even multiples of the phase AC frequency ω in the circulating current Iz, the voltage Vc of the capacitor 30 in the positive side arm 10P and the negative side arm 10N, respectively. The fluctuation range can be reduced. By reducing the fluctuation range of the voltage Vc of the capacitor 30, it is not necessary to increase the capacitance Cap of the capacitor 30 or the withstand voltage of the switching elements 22U and 22X, and the volume of the power converter 1 and the volume of the power converter 1 can be increased. It is possible to suppress the increase in weight. Further, in the power conversion device 1 of the first embodiment, in addition to the voltage required for power conversion to the AC voltage Vu, a frequency component that is an odd multiple (three or more) of the three-phase AC frequency ω as a correction voltage. (3ω, 5ω, ...) Can be included. By including the frequency components (3ω, 5ω, ...) That are odd multiples (3 or more) of the frequency ω in the AC voltage Vu, the voltages of the positive arm 10P and the negative arm 10N in each arm unit 8 are included. The fluctuation range of VuP and VuN can be reduced. If the fluctuation range of the voltage is reduced, the fluctuation range of the electric power is reduced. If the fluctuation range of the power is reduced, the fluctuation range of the integrated power value is reduced. Since it can be said that the fluctuation range of the power integrated value is proportional to the voltage Vc of the capacitor 30, the AC voltage Vu includes a frequency component (3ω, 5ω, ...) That is an odd multiple (3 or more) of the frequency ω. As a result, the fluctuation range of the voltage Vc of the capacitor 30 can be reduced.

Further, the control unit 50 controls the switching elements 22U and 22X so that an auxiliary circulating current having frequency components (2ω, 4ω) twice and four times the frequency ω of the three-phase alternating current is applied to the circulating current Iz. The frequency component (Mω), which is an M multiple of the fundamental frequency (for example, the frequency ω of three-phase alternating current), has an amplitude of 1 / M when integrated. Therefore, the influence of the auxiliary circulating current having a frequency component (2Mω) that is an even multiple (2M times) of the frequency ω on the integrated power value is 1 / 2M. That is, among the frequency components that are even multiples of the frequency ω, the frequency components (2ω, 4ω) that are twice and four times have a large effect on the power integral value. Therefore, in the power conversion device 1 of the first embodiment, double and quadruple frequency components (2ω, 4ω) having a large influence on the power integral value can be added to the circulating current Iz, and each arm unit 8 can be applied. The fluctuation range of the power integral values ArmP and ArmN in the positive arm 10P and the negative arm 10N, respectively, can be further reduced. Therefore, the fluctuation range of the voltage in the circuit can be reduced without increasing the cost and size of the device.

Further, in the power conversion device 1 of the first embodiment, in the control unit 50, the component corresponding to the auxiliary AC voltage having a frequency component (3ω) three times the frequency ω of the three-phase AC is converted into the AC current Iu. The switching elements 22U and 22X are controlled so as to participate. Of the frequency components (3ω, 5ω, ...) That are odd multiples (3 or more) of the frequency ω, the frequency component having the largest amplitude when integrated is the frequency component (3ω) that is three times the frequency ω. Therefore, the frequency component (3ω), which is three times the frequency ω, has the greatest influence on the power integral value. Therefore, in the power conversion device 1 of the first embodiment, three times the frequency components (2ω, 4ω) having a large influence on the power integral value can be applied to the AC voltage Vu, and each of the arm units 8 has its own power conversion device 1. The fluctuation range of the power integral values ArmP and ArmN in the positive side arm 10P and the negative side arm 10N can be further reduced.

(Second Embodiment)
A second embodiment will be described. In the following description, the same components as those in the first embodiment are designated by the same reference numerals, and the description thereof will be omitted. In the first embodiment, it has been described that the phases of the AC voltage Vu and the AC current Iu are in agreement, that is, the power factor is 1, but in reality, the AC voltage depends on the switching operation of the conversion unit C. The phases of Vu and the alternating current Iu do not always match. In the second embodiment, the power conversion device 1 performs switching control so as to reduce the fluctuation range of the voltage Vu of the capacitor 30 even when the phase difference between the AC voltage Vu and the AC current Iu occurs. conduct.

FIG. 9 is a configuration diagram of the control unit 50A of the second embodiment. As shown in FIG. 9, in the second embodiment, the control unit 50A includes an auxiliary circulating current calculation unit 57.

The phase difference θ, which is the difference in the phase of the AC current Iu with respect to the phase of the AC voltage Vu, and the auxiliary AC voltage calculated by the correction AC voltage generation unit 54 are input to the auxiliary circulating current calculation unit 57. The auxiliary circulating current calculation unit 57 calculates the value of I2 in the auxiliary circulating current based on the acquired phase difference θ and the auxiliary AC voltage according to the following equation (18). Here, V3 indicates the coefficient ratio of the third-order frequency component of the corrected AC voltage, θ indicates the phase difference of the AC current Iu with respect to the phase of the AC voltage Vu, and ω indicates the frequency of the three-phase AC.

I2 = (V3 × sin3θ−sinθ) × Idc / 3 × sin (2 (ωt−θ))
+ (V3 × cos3θ−cosθ) × Idc / 3 × cos (2 (ωt−θ))… (18)

Further, the auxiliary circulating current calculation unit 57 calculates the value of I4 in the auxiliary circulating current based on the acquired phase difference θ according to the following equation (19). Here, V3 indicates the coefficient ratio of the third-order frequency component of the corrected AC voltage, θ indicates the phase difference of the AC current Iu with respect to the phase of the AC voltage Vu, and ω indicates the frequency of the three-phase AC.

I4 = −V3 × sin3θ × Idc / 3 × sin (4 (ωt−θ))
+ V3 × cos3θ × Idc / 3 × cos (4 (ωt−θ))… (19)

The auxiliary circulating current calculation unit 57 calculates I2 and I4, respectively, based on the above equations (18) and (19), and generates an auxiliary circulating current command value. When the circulating current Iz to which the auxiliary circulating current based on I2 and I4 shown in the above equations (18) and (19) is added is used, the components having the phase difference θ are canceled when the power PalmP is calculated. .. That is, the phase difference θ does not affect the power PalmP. The auxiliary circulation current calculation unit 57 outputs the generated auxiliary circulation current command value to the circulation current control unit 53.

The phase difference θ is calculated by the control unit 50, a phase difference calculation unit (not shown), or the like. For example, the control unit 50 acquires the AC voltage Vu and the AC current Iu by converting the voltage difference due to the transformer 6 from the voltage and current of the AC power supply 2 acquired from the instrument transformer 5. Alternatively, the control unit 50 may acquire the AC voltage Vu and the AC current Iu by a voltage sensor (not shown) provided between the transformer 6 and each arm unit 8 and a current sensor. The control unit 50 calculates the phase difference θ, which is the difference in the phase of the AC current Iu with respect to the phase of the AC voltage Vu, from the acquired AC voltage Vu and the AC current Iu.

As described above, in the power conversion device 1 of the second embodiment, the auxiliary circulating current calculation unit 57 (an example of the “control unit”) is the position of the AC power voltage Vu and the current Iu in the three-phase AC. The auxiliary circulating current is calculated based on the phase difference θ and the coefficient ratio V3 of the third-order frequency component of the corrected AC voltage (an example of “auxiliary AC voltage”) so that the calculated auxiliary circulating current is added to the circulating current Iz. Controls the switching elements 22U and 22X. As a result, in the power conversion device 1 of the second embodiment, even when a phase difference θ occurs between the voltage Vu and the current Iu of the AC power in the three-phase AC, the auxiliary circulating current calculation unit 57 can be used. I2 and I4 in the auxiliary circulating current can be calculated so that the phase difference θ does not affect the power integrated value. Since the power integrated value does not depend on the phase difference θ, the fluctuation range of the power integrated value can be reduced regardless of the presence or absence of the phase difference θ. Therefore, the power conversion device 1 of the second embodiment has the same effect as that of the first embodiment, and even when there is a phase difference between the voltage and the current of the three-phase alternating current, the voltage of the capacitor 30 The fluctuation range of Vc can be reduced.

(Third Embodiment)
A third embodiment will be described. In the following description, the same components as those in the first embodiment are designated by the same reference numerals, and the description thereof will be omitted. In the first embodiment (particularly, FIG. 8), it has been described that the fluctuation range of the voltage Vu of the capacitor 30 is reduced by setting the coefficient ratio V3 of the third-order frequency component of the corrected AC voltage to an appropriate value. .. As shown in FIG. 8, the larger the coefficient ratio V3, the larger the fluctuation range of the voltage Vu of the capacitor 30 can be reduced. However, the amount of the corrected AC voltage that can be applied to the AC voltage Vu is output by each of the positive arm 10P and the negative arm 10N, which is determined by the withstand voltage of the switching element and the capacitor 30 and the number of conversion units. Is limited by the range of voltage allowed. In the third embodiment, the fluctuation range of the voltage Vu of the capacitor 30 is further reduced in consideration of those restrictions.

In the third embodiment, when the correction AC voltage generation unit 54 generates the command value of the correction AC voltage, the frequency component is 3 times the frequency ω of the three-phase AC, and 9 times the frequency ω, 15 A frequency component of a multiple corresponding to an odd multiple of three such as a multiple is included.

FIG. 10 is a diagram for explaining a process performed by the control unit 50 of the third embodiment. 10 (a) and 10 (b) show an example of the change in the voltage VuP of the positive arm 10P in one cycle of three-phase alternating current. The horizontal axis of FIGS. 10A and 10B shows the phase [deg], and the vertical axis shows the voltage [V].

In the example of FIG. 10A, the coefficient ratio V3 is set to 53%. For example, when the voltage range allowed to be output to the arm is 0 to 350 [V], the voltage Vup of the positive arm 10P causes the positive arm 10P to output in the vicinity of the phase 45 [deg]. It falls below the lower limit of the allowable voltage range.

In the example of FIG. 10B, in addition to the coefficient ratio V3 being 53%, V9 is set to 3% and V15 is set to 4.5%. Here, V9 is the coefficient ratio of the 9th-order frequency component of the corrected AC voltage, and V15 is the coefficient ratio of the 15th-order frequency component of the corrected AC voltage.

By appropriately adding the correction AC voltage in addition to the component of the coefficient ratio V3, the coefficient ratios V9 and V15, the 9th or 15th frequency component is added to the mountainous portion of the sine wave having the 3rd order frequency component. The valley of the sine wave with can be added, and the peak portion of the third-order sine wave can be made a flatter waveform. In the example of FIG. 10B, the portion (phase 45 [deg], etc.) below the voltage range allowed to be output to the arm in the example of FIG. 10A is made into a flatter waveform. be able to. As a result, it is possible to prevent the output of the arm from being out of the range of the voltage range allowed to be output by the arm without changing the coefficient ratio V3 to a small value. The coefficient ratios V9 and V15 may be determined by the voltage Vu of the three-phase alternating current, the range of the voltage allowed to be output to the arm, and the like.

As described above, in the power conversion device 1 of the third embodiment, the correction AC voltage generation unit 54 (an example of the “control unit”) is an odd multiple (3ω) of three of the three-phase AC frequency ω. , 9ω, 15ω ...), and the control unit 50 switches so that the component corresponding to the auxiliary AC voltage calculated by the correction AC voltage generation unit 54 is applied to the AC current Iu. The elements 22U and 22X are controlled. As a result, in the power conversion device 1 of the third embodiment, when the frequency (3ω) that is three times the frequency ω of the three-phase AC is included, the voltage VuP of the positive arm 10P and the voltage VuP of the negative arm 10N are included. Even if the voltage VuN deviates from the voltage range that is allowed to be output to the arm, a frequency (9ω, 15ω, ...) That is an odd multiple of three of the frequency ω can be applied. The voltage range of the voltage VuP of the positive arm 10P and the voltage VuN of the negative arm 10N can be output to the arm without changing the amplitude of the frequency (3ω) three times the frequency ω to a small value. It can be within the range. Therefore, the power conversion device 1 of the third embodiment has the same effect as that of the first embodiment, and can be controlled so that the AC voltage does not exceed the rated voltage.

(Fourth Embodiment)
A fourth embodiment will be described. In the following description, the same components as those in the first embodiment are designated by the same reference numerals, and the description thereof will be omitted. In the third embodiment, when only a frequency component three times the frequency ω is applied to the corrected AC voltage, the voltage VuP of the positive side arm 10P and the voltage VuN of the negative side arm 10N can be output to the arm. Even if it deviates from the permissible voltage range, it is out of the permissible voltage range to be output to the arm by adding a frequency component 9 times or 15 times the frequency ω to the corrected AC voltage. I explained that it is possible to suppress the accident. In the fourth embodiment, the voltage when the correction AC voltage is applied is the range of the voltage range that is allowed to be output to the arm without using the relative relationship of the coefficient ratios V3, V9, and V15. After controlling so as to be inside, the fluctuation range of the voltage Vu of the capacitor 30 is further reduced.

In the fourth embodiment, the correction value of the AC voltage is calculated based on the voltage of the phase having the second largest absolute value among the AC voltages Vu, Vv, and Vw of the three-phase AC. The voltage of the second largest phase is used in the first and third phases, in which the symbols of ArmP (1) and ArmP (3) described in the first embodiment (particularly, FIG. 8) are the same. This is because. That is, when the first and third phases are corrected, the fluctuation width of the voltage Vu of the capacitor 30 is corrected in the direction of further increasing, so that the effect of reducing the fluctuation width cannot be obtained.

FIG. 11 is a configuration diagram of the control unit 50B of the fourth embodiment. As shown in FIG. 11, in the fourth embodiment, a command value (AC voltage command value) of the AC voltage Vu is input from the AC current control unit 52 to the correction AC voltage generation unit 54B. Further, a command value (adjusted DC voltage command value) of the DC voltage Vdc corresponding to the circulation current Iz to which the auxiliary circulating current is added is input to the correction AC voltage generation unit 54B from the circulation current control unit 53.

The corrected AC voltage generation unit 54B calculates the corrected AC voltage based on the input AC voltage Vu command value and the DC voltage Vdc command value, and outputs the corrected AC voltage command value corresponding to the calculated corrected AC voltage. ..

Here, a method in which the correction AC voltage generation unit 54B generates the correction AC voltage command value will be described with reference to FIG. FIG. 12 is a configuration diagram of the correction AC voltage generation unit 54B. As shown in FIG. 12, the correction AC voltage generation unit 54B includes a phase determination unit 541 and a generation unit 547.

The phase determination unit 541 determines the phase having the second largest voltage among the AC voltages Vu, Vv, and Vw of each phase of the three-phase AC, based on the AC voltage command value of each phase of the three-phase AC. As shown in FIG. 12, the phase determination unit 541 includes an absolute value calculation unit 542, a maximum / minimum determination unit 543, an adder 544, an adder unit 545, and a phase determination unit 546.

The absolute value calculation unit 542 calculates the absolute values of the AC voltages Vu, Vv, and Vw. The maximum / minimum determination unit 543 detects the maximum value and the minimum value among the absolute values from the absolute value calculation unit 542. The addition unit 545 adds each absolute value from the absolute value detection unit 542. The adder 544 subtracts the maximum value and the minimum value of the respective absolute values from the value obtained by adding the respective absolute values from the addition unit 545. That is, the value output from the adder 544 is the second largest value among the absolute values of the AC voltages Vu, Vv, and Vw.

The value output from the adder 544 and the command values of the AC voltages Vu, Vv, and Vw are input to the phase determination unit 546. The phase determination unit 546 selects a value whose absolute value matches the value output from the adder 544 from the command values of the AC voltages Vu, Vv, and Vw. Then, the phase determination unit 546 determines which phase of the AC voltage the selected value is. That is, the phase determination unit 546 determines the phase having the second largest absolute value among the AC voltages Vu, Vv, and Vw of each phase of the three-phase AC. The phase determination unit 546 outputs the phase determination result, which is the result of determining the phase, to the generation unit 547.

If the value of the intermediate phase is positive with respect to the phase having the second largest absolute value (hereinafter referred to as the intermediate phase) among the AC voltages Vu, Vv, and Vw of each phase of the three-phase AC, the generation unit 547 has a positive value. If the positive maximum value and the intermediate phase value are negative values, a correction value that becomes a negative minimum value is calculated, and the calculated correction value is output as a command value of the correction AC voltage.

As shown in FIG. 12, the generation unit 547 includes a multiplication selection unit 548, a selection control unit 549, and an adder e. The AC voltage command value of the phase determined by the phase determination unit 541 and the circulating current control operation amount are input to the generation unit 547. That is, when the phase having the second largest absolute value among the AC voltages Vu, Vv, and Vw is the U phase, the generation unit 547 sets the command value of the AC voltage Vu of the U phase and the circulating current control operation amount of the U phase. Is entered. The generation unit 547 acquires the circulating current control operation amount from the circulating current control unit 53.

The multiplication selection unit 548 multiplies the circulating current control operation amount of the intermediate phase by 1/2 and −1/2, respectively. The multiplication selection unit 548 causes the adder e to receive either a value obtained by multiplying the circulating current control operation amount of the intermediate phase by 1/2 or a value obtained by multiplying by −1/2 according to the control from the selection control unit 549. Output.

The selection control unit 549 acquires the code of the voltage of the selection phase, and when the acquired code is a positive value, the value obtained by multiplying the circulating current control operation amount of the intermediate phase by 1/2 from the multiplication selection unit 548. Is output. Further, when the acquired code is a negative value, the selection control unit 549 causes the multiplication selection unit 548 to output a value obtained by multiplying the circulating current control operation amount of the intermediate phase by −1/2.

The adder e subtracts the voltage of the intermediate phase from the value output from the multiplication selection unit 548. Specifically, the adder e calculates a value obtained by subtracting the voltage of the intermediate phase from the value obtained by multiplying the circulating current control operation amount of the intermediate phase by 1/2 when the voltage of the selective phase is a positive value. ..

FIG. 13 is a diagram for explaining a process performed by the control unit of the fourth embodiment. FIG. 13A shows the AC voltage of each phase in the three-phase AC. FIG. 13B shows the phase determination result determined by the phase determination unit 546 in the case shown in FIG. 13A. FIG. 13C shows a command value of the correction AC voltage output by the generation unit 547. The horizontal axes of FIGS. 13 (a) to 13 (c) indicate the phases. The vertical axis of FIG. 13A shows the voltage corresponding to the command value. The vertical axis of FIG. 14A shows the phase, where 1 is the r phase (U phase), 2 is the s phase (V phase), and 3 is the t phase (W phase). The vertical axis of FIG. 13A shows the voltage corresponding to the command value.

As shown in FIG. 13A, the AC voltages of the respective phases in the three-phase AC are 120 [deg] out of phase with each other. As shown in FIG. 13B, the intermediate phase changes in the order of t phase, r phase, and s phase from phase 0 [deg]. As shown in FIG. 13C, the command value of the correction AC voltage is a positive value when the intermediate phase is positive, and the difference between the maximum value and the value of the intermediate phase is output. Further, the command value of the corrected AC voltage is a negative value when the intermediate phase is negative, and the difference between the minimum value and the value of the intermediate phase is output.

FIG. 14 is a second diagram for explaining a process performed by the control unit of the fourth embodiment. FIG. 14A shows an example of changes in the voltage VuP and the current IuP of the positive arm 10P in one cycle of the corrected three-phase alternating current. FIG. 14 (b) shows the power PalmP of the positive arm 10P and the power integral value EarmP when the voltage VuP and the current IuP of the positive arm 10P in one cycle of the three-phase alternating current are shown in FIG. 14 (a). An example of the change of is shown. The horizontal axes of FIGS. 14 (a) and 14 (b) indicate the phase [deg], respectively. The first axis of the vertical axis of FIG. 14A shows the voltage [V], and the second axis of the vertical axis shows the current [A]. The first axis of the vertical axis of FIG. 14B shows the electric power [W], and the second axis of the vertical axis shows the work [J].

As shown in FIG. 14A, the corrected voltage VuP has a waveform that sticks to the upper limit or the lower limit when its own phase is an intermediate phase. If the other phase is an intermediate phase, the value calculated based on the value of the intermediate phase is used for correction. The corrected voltage VuP becomes a lower limit value steeper than the uncorrected voltage VuP which was a sine wave, and then becomes a unique waveform that sticks to the lower limit value. The fluctuation range of the corrected voltage VuP is not reduced because it is the upper and lower limits of the allowable voltage, but after sticking to the lower limit, the voltage VuP becomes zero in a predetermined section centered on the phase 90 [deg]. Since it approaches the voltage, when the voltage VuP is integrated, it does not decrease monotonically, but decreases and increases repeatedly, and the fluctuation range of the integrated power value tends to decrease. An example of the case where the current IuP is I2 = 4 [A] and I4 = 8 [A] is shown.

The corrected voltage VuP has a waveform different from that of the sine wave before correction, but since each of the three phases is corrected based on the same correction value, the line voltage of each of the three phases is corrected. It does not change before and after. That is, the performance as a three-phase alternating current does not deteriorate after the correction.

As shown in FIG. 14B, the corrected power ParmP has a unique waveform, and positive values and negative values alternately swing with the same amount of amplitude in one cycle. The corrected power integrated value ArmP becomes a trapezoidal waveform without continuing to increase or decrease because the power PalmP alternately swings with the same amount of amplitude, and the fluctuation range is reduced. ..

As described above, in the power conversion device 1 of the fourth embodiment, the control unit 50 is an AC input to each of the arm units 8-1 to 8-3 (an example of "at least three arm units"). When the voltage of the intermediate phase is a positive value with respect to the intermediate phase having the second largest absolute value of the amplitude among the voltages of power (Vu, Vv, Vw), the voltage of the intermediate phase is the positive DC terminal 3 (Vu, Vv, Vw). DC between "a positive DC terminal that is the positive end of the arm unit") and a negative DC terminal 4 (an example of a "negative DC terminal that is the negative end of the arm unit") The switching elements 22U and 22X are controlled so as to have a value corresponding to the voltage. Further, the control unit 50 controls the switching elements 22U and 22X so that when the voltage of the intermediate phase is a negative value, the voltage of the intermediate phase becomes a voltage corresponding to the zero voltage.

As a result, in the power conversion device 1 of the fourth embodiment, the control unit 50 integrates the power of the arm unit 8 without taking the trouble of calculating the correction voltage applied to the AC voltage by using the coefficient ratio V3 or the like. The fluctuation range of the value (for example, ArmP) can be reduced. Further, when the intermediate phase is corrected so as to be attached to the upper limit or the lower limit of the voltage, the control of the arm unit of the intermediate phase is turned on or off for all the switching elements 22U and 22X. Therefore, deterioration factors such as the generation of high frequencies caused by switching control can be suppressed. Therefore, the power conversion device 1 of the fourth embodiment has the same effect as that of the first embodiment, and easily and accurately reduces the fluctuation range of the voltage in the circuit without performing complicated arithmetic processing. Can be made to.

(Fifth Embodiment)
A fifth embodiment will be described. In the following description, the same components as those in the first embodiment are designated by the same reference numerals, and the description thereof will be omitted. FIG. 15 is a diagram illustrating a fifth embodiment. As shown in FIG. 15, in the fifth embodiment, a three-winding transformer 6A is provided in place of the transformer 6 and the buffer reactor 40 (40P, 40N). The U-phase, V-phase, and W-phase three-winding transformers 6A are star-connected. The three-winding transformer 6A includes an AC system side winding connected to the three-phase AC side, a first DC system side winding connected in series between the positive side arm 10P and the negative side arm 10N, and a first DC system side winding. It has a second DC system side winding and an iron core (not shown). Each winding is wound around an iron core. The first DC system side winding and the second DC system side winding have the same number of turns and have opposite polarities because the negative electrodes are connected to each other.

Further, the three-winding transformer 6A has a neutral wire between the first DC system side winding and the second DC system side winding of each of the three phases. The neutral wire extends from between the first DC system side winding and the second DC system side winding of each of the three phases and is connected to each other, and has three windings of U phase, V phase and W phase. The line transformers 6A are connected to each other.

By replacing the transformer 6 and the buffer reactor 40 with the three-winding transformer 6A in this way, the DC current Idc in the power converter 1 is changed from the positive arm 10P to the first DC system side winding. , Flows to the negative arm 10N via the second DC system side winding. Therefore, since the first DC system side winding and the second DC system side winding are connected in series with opposite polarities, the DC magnetomotive forces due to the DC currents Idc flowing respectively become opposite polarities and cancel each other out. No DC magnetic flux is generated in the iron core. Furthermore, since the DC magnetomotive force can be canceled within the same phase, the iron core of the three-winding transformer 6A operates without demagnetization or saturation even if an imbalance occurs in the AC system in the event of an accident or the like. Can be done.
The transformer used in the fifth embodiment is a three-winding transformer 6A, but a four-winding transformer for the purpose of suppressing harmonics flowing out to the system may be used.

As described above, the power conversion device 1A of the fifth embodiment further includes a three-winding transformer 6A provided between the positive side arm 10P and the negative side arm 10N, and is further provided with a three-winding transformer. In the vessel 6A, the AC system side winding connected to the three-phase AC, the first series system side winding connected in series between the positive side arm 10P and the negative side arm 10N with opposite polarities, and the second Has a series system side winding and. This eliminates the need to connect the buffer reactor 40, and makes it possible to reduce the size and cost of the device. Further, even for the power conversion device 1A provided with the three-winding transformer 6A, the fluctuation range of the voltage Vu of the capacitor 30 can be reduced as in the other embodiments. Therefore, the power conversion device 1 of the fifth embodiment has the same effect as that of the first embodiment, and the size of the power conversion device 1 can be reduced.

(Sixth Embodiment)
A sixth embodiment will be described. In the following description, the same components as those in the first embodiment are designated by the same reference numerals, and the description thereof will be omitted. FIG. 16 is a diagram illustrating a sixth embodiment. As shown in FIG. 16, in the sixth embodiment, the first and second capacitors 70P, which are connected in series for dividing the positive DC terminal 3 and the negative DC terminal 4 to create a neutral point potential, It has 70N. The switching legs 60P and 60N, which are configured by connecting two switching elements in parallel with the respective capacitors 70P and 70N, are connected.
A conversion unit C is connected in series between the output terminal of the switching leg 60P connected in parallel with the first capacitor 70P and the output terminal of the switching leg 60N connected in parallel with the second capacitor 70N. An arm unit 8A having a positive side arm 10P and a negative side arm 10N (U-phase arm unit 8A-1, V-phase arm unit 8A-2, W-phase arm unit 8A-3) is connected. The number of series of conversion units C may be 1/2 as compared with the power conversion device 1 of the first embodiment. The connection point between the positive arm 10P and the negative arm 10N is the AC output point.

Next, the operation of the power conversion device 1A of the sixth embodiment will be described. The two switching legs 60P and 60N turn on the upper switching element and turn off the lower switching element during a half cycle in which the AC voltage Vu is positive. On the other hand, in the negative half cycle, the lower switching element is turned on and the upper switching element is turned off. As a result, between the output terminals of the two switching legs 60P and 60N, the voltage of the upper capacitor 70P is output in the positive half cycle of the AC voltage, and the voltage of the lower capacitor 70N in the negative half cycle. Is output. Since the voltage of the two capacitors 70P and 70N is about ½ of the DC voltage Idc between the positive DC terminal 3 and the negative DC terminal 4, the output of the two switching legs 60P and 60N is as a result. The distance between the terminals is about 1/2 of the DC voltage.

The output voltage of the positive arm can be expressed by the following equations (20) and (21). Further, the output voltage of the negative arm can be expressed by the following equations (22) and (23). Here, Vu indicates a three-phase AC voltage, Vdc indicates a DC voltage, and ω indicates a three-phase AC frequency.

VuP = -Vu + Vdc / 4 ... (0 [deg] <ωt <180 [deg]) ... (20)
VuP = Vu ... (180 [deg] <ωt <360 [deg]) ... (21)
VuN = Vu ... (0 [deg] <ωt <180 [deg]) ... (22)
VuN = -Vu + Vdc / 4 ... (180 [deg] <ωt <360 [deg]) ... (23)

FIG. 17 shows a normal operation waveform. FIG. 18 shows an operation waveform when the control unit 50 of the first embodiment controls the fluctuation range of the capacitor 30 so as to be reduced. 17 (a) and 18 (a) show an example of changes in the voltage VuP and the current IuP of the positive arm 10P in one cycle of three-phase alternating current. 17 (b) and 18 (b) show the voltage VuP of the positive arm 10P in one cycle of the three-phase alternating current and the positive arm 10P when the current IuP is FIGS. 17 (a) and 18 (a). An example of the change of the power PalmP and the power integrated value ArmP is shown. The horizontal axes of FIGS. 17 (a) and 18 (a) indicate the phase [deg], the first axis of the vertical axis represents the voltage [V], and the second axis of the vertical axis represents the current [A]. Further, the horizontal axes of FIGS. 17 (b) and 18 (b) indicate the phase [deg], the first axis of the vertical axis indicates the electric power [W], and the second axis of the vertical axis indicates the work [J].

As shown in FIG. 17A, the voltage VuP of the positive arm 10P switches the offset (+ Vdc / 4) in the phase 180 [deg], so that the voltage VuP is the power conversion device 1 of the first embodiment. Is output in the range of 1/2. That is, the fluctuation range of the voltage VuP is reduced. Further, as shown in FIG. 17B, the electric power ParmP changes in the phase 180 [deg] with the change of the voltage VuP. The power integral value ArmP becomes maximum at a phase of 180 [deg].
Also in this embodiment, the circulating current includes an auxiliary circulating current having a frequency component that is an even multiple of the system voltage, and the AC voltage is an odd number of 3 or more of the system voltage in addition to the voltage required for normal power conversion. When a double frequency component is included, the capacitor voltage pulsation width can be reduced. For example, FIG. 18 shows the waveforms when I2 = 4A, I4 = 8A, and V3 = 50%. Further, since the distance between the output terminals of the two switching legs is about 1/2 of the DC voltage, the number of units in series of the unit converter is 1/2 as compared with the power converter 1 of the first embodiment. Well, the number of capacitors themselves can be reduced, and it becomes possible to make the size smaller.

In FIG. 16, the number of switching elements used for the switching legs 60P and 60N is one, but two or more switching elements may be connected in series and switched at the same timing. Normally, the voltage ratings of the switching elements used for the switching legs 60P and 60N connected in parallel with the first and second capacitors 70P and 70N and the switching elements 22U and 22X constituting the conversion unit C are different. Therefore, switching elements having different voltage ratings are required, which leads to an increase in cost. On the other hand, the switching elements 22U and 22X constituting the conversion unit C may be connected in series to form the switching legs 60P and 60N. As a result, the switching element constituting the power conversion device 1B can be made single, and the cost can be reduced.

According to at least one embodiment described above, the arm units 8-1 to 8-3 are provided, and in each arm unit 8, the positive side arm 10P and the negative side arm 10N are connected in series, and the positive side arm 10P and the negative side arm 10N are connected in series. Each of the 10P and the negative arm 10N has at least one conversion unit C including a capacitor 30 and switching elements 22U and 22X, and out of three-phase alternating current from a location between the positive arm 10P and the negative arm 10N. One-phase power is input and output, and DC power is input and output from the end, and among the currents flowing through the arm unit 8, the circulating current Iz, which is the current flowing in the same direction between the positive side arm 10P and the negative side arm 10N. The control unit 50 controls the switching elements 22U and 22X so that the alternating current Iu, which is the current flowing in the opposite direction between the positive arm 10P and the negative arm 10N, is generated among the currents flowing through the arm unit 8. Therefore, an auxiliary circulating current containing an even multiple frequency component (2ω, 4ω, ...) Of the three-phase alternating current frequency ω is applied to the circulating current Iz, and an odd multiple of the three-phase alternating current frequency ω. A control unit 50 that controls the switching elements 22U and 22X is further provided so that a component corresponding to the auxiliary AC voltage including (3 or more) frequency components (3ω, 5ω, ...) Is applied to the AC current Iu.

As a result, in the power conversion device 1 of the embodiment, in addition to the current (Idc / 3) required for power conversion to the circulating current Iz, a frequency component that is an even multiple of the three-phase alternating current frequency ω as an auxiliary circulating current. (2ω, 4ω, ...) Can be included. By including a frequency component (2ω, 4ω, ...) That is an even multiple of the phase AC frequency ω in the circulating current Iz, the current flowing through the positive side arm 10P and the negative side arm 10N in each arm unit 8. The fluctuation range of IuP and IuN can be reduced. If the fluctuation range of the current is reduced, the fluctuation range of the electric power is reduced. If the fluctuation range of the power is reduced, the fluctuation range of the integrated power value is reduced. It can be said that the fluctuation range of the power integral value is proportional to the voltage Vc of the capacitor 30. Therefore, by including the frequency components (2ω, 4ω, ...) That are even multiples of the phase AC frequency ω in the circulating current Iz, the voltage Vc of the capacitor 30 in the positive side arm 10P and the negative side arm 10N, respectively. The fluctuation range can be reduced. By reducing the fluctuation range of the voltage Vc of the capacitor 30, it is not necessary to increase the capacitance Cap of the capacitor 30 or the withstand voltage of the switching elements 22U and 22X, and the volume of the power converter 1 and the volume of the power converter 1 can be increased. It is possible to suppress the increase in weight. Further, in the power conversion device 1 of the first embodiment, in addition to the voltage required for power conversion to the AC voltage Vu, a frequency component that is an odd multiple (three or more) of the three-phase AC frequency ω as a correction voltage. (3ω, 5ω, ...) Can be included. By including the frequency components (3ω, 5ω, ...) That are odd multiples (3 or more) of the frequency ω in the AC voltage Vu, the voltages of the positive arm 10P and the negative arm 10N in each arm unit 8 are included. The fluctuation range of VuP and VuN can be reduced. If the fluctuation range of the voltage is reduced, the fluctuation range of the electric power is reduced. If the fluctuation range of the power is reduced, the fluctuation range of the integrated power value is reduced. Since it can be said that the fluctuation range of the power integrated value is proportional to the voltage Vc of the capacitor 30, the AC voltage Vu includes a frequency component (3ω, 5ω, ...) That is an odd multiple (3 or more) of the frequency ω. As a result, the fluctuation range of the voltage Vc of the capacitor 30 can be reduced.

Although some embodiments of the present invention have been described, these embodiments are presented as examples and are not intended to limit the scope of the invention. These embodiments can be implemented in various other forms, and various omissions, replacements, and changes can be made without departing from the gist of the invention. These embodiments and modifications thereof are included in the scope and gist of the invention, as well as in the scope of the invention described in the claims and the equivalent scope thereof.

1 ... Power converter, 2 ... AC power supply, 3 ... Positive DC terminal, 4 ... Negative DC terminal, 8 ... Arm unit, 10P ... Positive arm, 10N ... Negative arm, C ... Conversion unit, 22U, 22X ... Switching element, 30 ... Condenser, 40 ... Buffalo reactor, 50 ... Control unit, 52 ... AC current control unit, 53 ... Circulating current control unit, 54 ... Corrected AC voltage generation unit.

Claims (8)

A power conversion device having at least three arm units and a control unit provided corresponding to each phase of three-phase alternating current.
Each arm unit
A positive arm to which at least one converter consisting of a switching element and a power storage unit connected in parallel to the switching element is connected in series, and
A negative arm which is connected in series to the positive arm and at least one converter including a switching element and a power storage unit connected in parallel to the switching element is connected in series.
An AC terminal corresponding to one of the three-phase ACs provided between the positive arm and the negative arm,
The positive side DC terminal and the negative side DC terminal provided on the opposite side to the AC terminal of each of the positive side arm and the negative side arm,
Have,
The control unit
Further, the positive side arm and the negative side arm are further arranged so that a circulating current that flows in the same direction between the positive side arm and the negative side arm and contains a frequency component that is an even multiple of the frequency of the three-phase alternating current is generated. The switching element is controlled so that an AC voltage generated in the opposite direction and containing a frequency component that is an odd multiple (three or more) of the frequency of the three-phase AC is generated .
A corrected AC voltage command value for including a frequency component that is an odd multiple (three or more) of the frequency of the three-phase AC is generated, and an AC voltage command value is generated using the corrected AC voltage command value.
Using the phase difference between the three-phase AC AC voltage and the AC current and the corrected AC voltage command value, an auxiliary circulating current command value for including an even multiple frequency component of the three-phase AC frequency is obtained. Generate and generate a DC voltage command value using the auxiliary circulating current command value.
A pulse signal for controlling the switching element is generated using the AC voltage command value and the DC voltage command value.
Power converter. The even-numbered frequency component is a frequency component that is twice and four times the frequency of the three-phase alternating current.
The power conversion device according to claim 1. The odd-numbered multiple (three or more) frequency components are three times the frequency component of the three-phase alternating current.
The power conversion device according to claim 1. The odd-numbered multiple (three or more) frequency components are three odd-numbered multiple frequency components of the three-phase alternating current frequency.
The power conversion device according to claim 1. A power conversion device having at least three arm units and a control unit provided corresponding to each phase of three-phase alternating current.
Each arm unit
A positive arm to which at least one converter consisting of a switching element and a power storage unit connected in parallel to the switching element is connected in series, and
A negative arm which is connected in series to the positive arm and at least one converter including a switching element and a power storage unit connected in parallel to the switching element is connected in series.
An AC terminal corresponding to one of the three-phase ACs provided between the positive arm and the negative arm,
The positive side DC terminal and the negative side DC terminal provided on the opposite side to the AC terminal of each of the positive side arm and the negative side arm,
Have,
The control unit
Further, the positive side arm and the negative side arm are further arranged so that a circulating current that flows in the same direction between the positive side arm and the negative side arm and contains a frequency component that is an even multiple of the frequency of the three-phase alternating current is generated. The switching element is controlled so that an AC voltage generated in the opposite direction and containing a frequency component that is an odd multiple (three or more) of the frequency of the three-phase AC is generated .
When the voltage of the intermediate phase having the second largest absolute value of amplitude among the voltages of the AC power of each phase input to each of the at least three arm units is positive, the voltage of the intermediate phase is the arm. The switching element is controlled so as to have a value corresponding to the DC voltage between the positive DC terminal of the unit and the negative DC terminal of the arm unit, and when the voltage of the intermediate phase is negative, the above. The switching element is controlled so that the voltage of the intermediate phase becomes a value corresponding to the zero voltage.
Power converter. The arm unit further comprises a three-winding transformer connected in series in the order of the positive arm, the three-winding transformer, and the negative arm.
The three-winding transformer
The AC system side winding connected to the three-phase AC,
A first series system side winding and a second series system side winding connected in series with the positive side arm and the negative side arm with opposite polarities,
The power conversion device according to any one of claims 1 to 5. A first capacitor and a second capacitor provided between the positive DC terminal and the negative DC terminal and connected in series are further provided.
The arm unit is composed of two switching elements connected in series, a first switching leg connected in parallel with the first capacitor, and two switching elements connected in series. A second switching leg connected in parallel with the second capacitor is further provided.
The positive end of the positive arm is connected to the connecting line between two switching elements connected in series in the first switching leg, and the negative end of the negative arm is the first. Connected to the connecting line between two switching elements connected in series in two switching legs,
The power conversion device according to any one of claims 1 to 6. The two switching elements in the first switching leg, the two switching elements in the second switching leg, and the switching elements included in the converter have the same voltage rating.
The power conversion device according to claim 7.

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