JP6876585B2 - Power converter and power conversion system - Google Patents

Description

The present invention relates to a power conversion device and a power conversion system.

In the power conversion circuit, it is desired to suppress the harmonic current leaking to the power system. The following Patent Document 1 discloses one of the methods for suppressing a harmonic current.

Japanese Patent No. 5865090

The technique of Patent Document 1 achieves a high control gain with respect to a predetermined harmonic order, but does not particularly mention the problem that the transformer included in the power conversion circuit is demagnetized. When demagnetization occurs in the transformer, a second harmonic component is generated, so it is preferable to detect this and eliminate the demagnetization. However, when an attempt is made to suppress the second harmonic component by the technique described in Patent Document 1, not only the second harmonic component to be suppressed but also the second harmonic component for detecting the demagnetized state of the transformer is detected. Similarly, they cancel each other out, causing a problem that the detection accuracy of the demagnetized state is deteriorated.
The present invention has been made in view of the above circumstances, and an object of the present invention is to provide a power conversion device and a power conversion system capable of appropriately suppressing a second harmonic component.

In order to solve the above problems, the power conversion device of the present invention includes a first DC terminal connected to one end of the DC system, a second DC terminal connected to the other end of the DC system, and a three-phase AC system. A transformer having a three-phase primary winding connected to, and a three-phase secondary winding that is staggered and the midpoint of the staggered connection of each phase is connected to the second DC terminal. A three-phase arm each having a device and a plurality of chopper circuits connected in series, one end of which is connected to the first DC terminal and the other end of each is connected to the secondary winding. And a current sensor that detects the arm output current output from each of the three-phase arms, and a voltage command value so as to suppress the negative-phase secondary component contained in the arm output current more than the positive-phase secondary component. It is characterized by having a reverse-phase secondary compensator that outputs, and a chopper circuit control unit that controls a plurality of the chopper circuits based on the voltage command value.

According to the present invention, the second harmonic component can be appropriately suppressed.

It is a block diagram of the power conversion apparatus according to 1st Embodiment of this invention. It is a circuit diagram of the chopper circuit in 1st Embodiment. It is a block diagram of the controller in 1st Embodiment. It is a waveform diagram of a gate signal and a chopper circuit output voltage in 1st Embodiment. It is a waveform figure of each part of the chopper circuit in 1st Embodiment. It is a block diagram of the reverse phase secondary compensator in 1st Embodiment. It is a block diagram of the reverse phase secondary compensator in the 2nd Embodiment. It is a block diagram of the reverse phase secondary compensator in the third embodiment. It is a block diagram of the power conversion apparatus according to 4th Embodiment.

[Outline of Embodiment]
Recent technological developments have made it possible to construct high power converters of several tens to several hundreds of MW using self-excited semiconductor switching elements such as IGBTs. The MMC (Modular Multilevel Converter), in which each phase arm is configured by connecting a chopper circuit in series, has few harmonics leaking to the power system, and its modular structure can flexibly support various voltage and current specifications. Due to its characteristics, it is also attracting attention in the self-excited large-capacity power converter technology. On the other hand, the MMC has an advantage that a buffer reactor is required because a current in which an AC component is superimposed on a direct current flows, and the installation area becomes large.

In order to deal with the above drawbacks, a technique called ZC-MMC (Zero-Sequence Canceling Modular Multilevel Converter; zero-phase canceling MMC) is known. According to this technique, the buffer reactor can be removed from the MMC by staggering the transformer. A current in which an AC component is superimposed on direct current also flows in the arm current of the ZC-MMC, and this current flows into the transformer. However, by applying the staggered connection, the DC component in the transformer core created by the DC current is canceled out, so that magnetic saturation of the transformer core can be avoided in principle. However, different DC components may occur in the U, V, and W phase arm currents due to control errors and individual differences in IGBT characteristics, and the unbalanced arm DC currents may saturate the transformer.

To suppress the demagnetization of the transformer, a method of correcting the arm output voltage so that the DC component of the transformer inflow current approaches zero is often used. However, in ZC-MMC, this method cannot be applied because DC current flows into the transformer in principle. However, this method can be applied to a staggered transformer by calculating the demagnetized state of the transformer and the correction voltage command value of the arm output voltage from the imbalance of the distortion component of the transformer. The main component of this distortion is the second-order harmonics, and according to this method, even a staggered transformer can be operated without causing demagnetization.

By the way, in the chopper circuit which is a unit converter of ZC-MMC, an error occurs in the output voltage depending on the polarity of the output current. This error is due to the dead time. This is because the current polarity changes which of the freewheeling diodes P and N is energized during the dead time period, and the energization of the freewheeling diode also changes the voltage appearing at the chopper output terminal. Since the current is positive and negative asymmetric, a second harmonic voltage is generated in the arm voltage. Since the voltage error due to the dead time is determined by the current flowing through the arm, a three-phase balanced second harmonic voltage is generated in the U phase, the V phase, and the W phase.

When this second-order harmonic voltage is output from the arm, the system current also contains a second-order component. On the other hand, second-order harmonics affect the load on the rotating machine, so it is preferable to suppress them. There are no particular restrictions based on the idea that even-order harmonics basically do not flow out in Japan. However, international standards such as IEC1547 have regulations on even-numbered orders, and set an upper limit of less than 1% of the rated current, which is stricter than odd-numbered orders. Each of the embodiments described below is intended to appropriately suppress a second harmonic voltage that is particularly three-phase balanced.

[First Embodiment]
<Structure of the first embodiment>
FIG. 1 is a block diagram of the power conversion device 1 according to the first embodiment of the present invention.
The power conversion device 1 is connected between the DC power supply 2 (DC system) and the three-phase AC system 3 to convert power in one direction or in both directions. The DC power supply 2 is connected between the positive electrode terminal 5P (first DC terminal) and the negative electrode terminal 5N (second DC terminal) provided in the power conversion device 1.
The power conversion device 1 has a transformer 20 and arms 10u, 10v, and 10w corresponding to each of the U phase, the V phase, and the W phase. The transformer 20 has a primary winding 20a and a secondary winding 20b, and the secondary winding 20b is staggered.

The arm 10u has a plurality of (three in the illustrated example) chopper circuits 10u1, 10u2, 10u3 connected in series. The arms 10v and 10w also have the same number of chopper circuits (unsigned) connected in series. The number of chopper circuits connected in series is not limited to "3". The current sensors 50u, 50v, 50w detect the arm output currents Iu, Iv, Iw of each arm 10u, 10v, 10w, and supply the detection result to the controller 100.

Exciting current detectors 55u, 55v, 55w having two current transformers, respectively, are connected between the primary winding 20a and the secondary winding 20b of the transformer 20. The exciting current detectors 55u, 55v, 55w detect the exciting currents of the U-phase, V-phase, and W-phase of the transformer 20, respectively, and supply the detected values Image, Imagv, and Imagw to the controller 100, respectively. The voltage sensor 56 detects the system voltages Vu, Vv, Vw of the three-phase AC system 3, and supplies the results to the controller 100.

Further, the active power command value Pref and the ineffective power command value Quref are input to the controller 100 from the outside. The controller 100 sends a gate signal GateU, to a chopper circuit (10u1, etc.) of each arm so that the active power and the active power generated by the arms 10u, 10v, and 10w approach the active power command value Pref and the invalid power command value Quref. Outputs GateV and GateW.

Further, the power conversion device 1 includes an operation panel 40. The operation panel 40 performs an on / off operation of the power conversion device 1 and the like. Further, the maintenance information device 42 can be connected to the operation panel 40 as needed. The maintenance information device 42 remotely controls the power conversion device 1 via the operation panel 40 and collects various information of the power conversion device 1.

FIG. 2 is a circuit diagram of the chopper circuit 10u1.
The chopper circuit 10u1 includes two IGBT (Insulated Gate Bipolar Transistor) modules 30P and 30N connected in series, a DC capacitor 34 connected in parallel to these series circuits, and a voltage sensor 36. doing. The ON / OFF state of the IGBT modules 30P and 30N is controlled by the gate signals GP and GN. The gate signals GateU, GateV, and GateW shown in FIG. 1 are generic names for the IGBT gate signals GP and GN in each of the U phase, V phase, and W phase. Further, the terminal voltage of the IGBT module 30N is referred to as a chopper circuit output voltage Vcp. The voltage sensor 36 measures the terminal voltage of the DC capacitor 34 and outputs the result as a voltage detection value Vdc.

Returning to FIG. 1, the other chopper circuits 10u2 and 10u3 in the arm 10u are also configured in the same manner as the above-mentioned chopper circuit 10u1. The voltage detection values Vdc of the three systems output from the chopper circuits 10u1, 10u2, 10u3 are collectively referred to as the DC capacitor voltage detection value Vdcu. Similarly, the voltage detection values Vdc of each of the three systems output from the three chopper circuits (unsigned) in the arms 10v and 10w are collectively referred to as DC capacitor voltage detection values Vdcv and Vdcw. These DC capacitor voltage detection values Vdcu, Vdcv, and Vdcw are supplied to the controller 100.

(Overall configuration of controller 100)
FIG. 3 is a block diagram of the controller 100.
The controller 100 includes hardware as a general computer such as a CPU (Central Processing Unit), a DSP (Digital Signal Processor), a RAM (Random Access Memory), and a ROM (Read Only Memory). , A control program executed by the CPU, a microprogram executed by the DSP, various data, and the like are stored. In FIG. 3, the inside of the controller 100 shows the functions realized by the control program, the micro program, and the like as blocks.

In FIG. 3, the phase detector 101 calculates synchronous sine waves cosωt and sinωt synchronized with the system voltage based on the system voltages Vu, Vv, and Vw. Further, the power calculator 102 calculates the active power calculation value Pfb and the ineffective power calculation value Qfb based on the system voltage Vu, Vv, Vw and the arm output currents Iu, Iv, Iw of the arms 10u, 10v, 10w. calculate. These are the calculated values of the active power and the ineffective power output by the power conversion device 1 to the three-phase AC system 3. The subtractor 103 subtracts the active power calculation value Pfb from the active power command value Pref, and the subtractor 105 subtracts the invalid power calculation value Qfb from the invalid power command value Quref. The active power controller 104 and the ineffective power controller 106 perform proportional integration control (PI control) on the subtraction results of the subtractors 103 and 105 to convert the calculated values Pfb and Qfb into the command values Pref and Quref. The output signal is controlled so that it is brought closer.

The arm output currents Iu, Iv, Iw of the arms 10u, 10v, 10w are supplied to the α-β converter 111. The α-β converter 111 converts the arm output currents Iu, Iv, and Iw, which are three-phase quantities, into the output current values Ialp, Ibet, which are two-phase quantities, based on the following equation (1).

The dq converter 112 converts these output current values Ialp and Ibet into values on rotating coordinates that rotate at the fundamental frequency ω. In this rotating coordinate, the axis of active power is the d-axis and the axis of ineffective power is the q-axis. Then, the rotating coordinates are called dq coordinates. That is, when the output current values Ialp and Ibet and the synchronous sine waves cosωt and sinωt from the phase detector 101 are supplied, the dq converter 112 receives Id_fb and Id_fb based on the following equation (2). Iq_fb and.

Here, Id_fb is the active current output by the arms 10u, 10v, 10w to the transformer 20, and Iq_fb is the reactive current output by the arms 10u, 10v, 10w to the transformer 20.

The subtractor 107 subtracts the active current Id_fb from the output signal of the active power controller 104. Similarly, the subtractor 108 subtracts the reactive current Iq_fb from the output signal of the reactive power controller 106. The current controllers 109 and 110 perform proportional integration control (PI control) on the subtraction results of the subtractors 107 and 108 so that the subtraction results of the subtractors 107 and 108 approach "0". The command value Vd_ref and the invalid voltage command value Vq_ref are output.

By the way, the control system of the controller 100 includes a wasted time element due to the limitation of the calculation cycle of the controller 100 and the switching frequency of the IGBT in the chopper circuit. The upper limit of the control gain used inside the current controllers 109 and 110 is limited because it is restricted by this wasted time element. Therefore, it is difficult to sufficiently compensate for the current deviation caused by the fluctuating disturbance with the current controllers 109 and 110 alone.

The inverse dq converter 114 uses the following equation (3) to convert the effective voltage command value Vd_ref and the invalid voltage command value Vq_ref, which are the values on the rotating coordinates (dq coordinates), output from the current controllers 109 and 110. ), The voltage command values Valp and Vbet, which are the values on the stationary coordinates, are converted.

The reverse phase secondary compensator 113 outputs voltage command value correction terms Valve_h and Vbet_h. The details will be described later. The adder 115 adds the voltage command value Valp and the voltage command value correction term Valp_h, and outputs the result as the voltage command value Valp2. Further, the adder 116 adds the voltage command value Vbet and the voltage command value correction term Vbet_h, and outputs the result as the voltage command value Vbet2.

Based on the following equation (4), the two-phase-three-phase converter 117 sets the two-phase voltage command values Valp2 and Vbet2 to the three-phase voltage command values Vuref, Vvref, and Vwref (these signal names are not shown). Convert to.

The demagnetization suppression controller 125 uses the excitation current detection values Imagu, Imagv, Imagw and the system voltages Vu, Vv, Vw as input signals, and the demagnetization suppression voltage command value for suppressing the demagnetization of the transformer 20. Outputs Vuh, Vvh, and Vwh. The principle of outputting the demagnetization suppression voltage command values Vuh, Vvh, and Vwh is described in detail in, for example, Japanese Patent Application Laid-Open No. 2014-150598. The outline is as follows.

First, a DC component having the same polarity as the demagnetized polarity is superimposed on the exciting current represented by the excited current detection values Image, Imagev, and Imagew. Therefore, the waveform of the exciting current has a peak in the polarized polarity. The exciting current can be separated into a DC component, a fundamental frequency ω component, a second harmonic component having a frequency of 2 ω, and the like. Here, when the transformer 20 is demagnetized to the positive side, the positive peak position of the fundamental wave component of the exciting current and the positive peak position of the second harmonic component substantially coincide with each other. That is, when the transformer 20 is demagnetized to the positive side, if the phase of the fundamental frequency ω is θ1 and the phase of the frequency 2ω of the second harmonic component is θ2, then “θ2-2 × θ1 ≈ 0 [rad”. ] ”Is established.

On the other hand, when the transformer 20 is demagnetized to the negative side, the negative peak position of the fundamental wave component of the exciting current and the negative peak position of the second harmonic component substantially coincide with each other. That is, when the transformer 20 is demagnetized to the negative side, “θ2-2 × θ1 ≈ π [rad]” is established between θ1 and θ2. The demagnetization suppression controller 125 obtains the demagnetization amount γ by, for example, “γ = cos (θ2-2 × θ1)”. That is, if the demagnetization amount γ is a positive value, the demagnetization direction is the “positive side”, and if the demagnetization amount γ is a negative value, the demagnetization direction is the “negative side”. When the demagnetization amount γ is obtained, for example, a well-known proportional integral calculation may be performed on the demagnetization amount γ, and the demagnetization suppression voltage command values Vuh, Vvh, Vwh having the opposite polarity to the demagnetization amount γ may be output.

Further, in FIG. 3, the capacitor voltage balance controller 126 has output voltage command correction values Vdc_hos_u1, Vdc_hos_u2, Vdc_hos_u3, Vdc_hos_v1, based on the DC capacitor voltage detection values Vdcu, Vdcv, Vdcw and arm output currents Iu, Iv, Iw. It outputs Vdc_hos_v2, Vdc_hos_v3, Vdc_hos_w1, Vdc_hos_w2, and Vdc_hos_w3. In the figure, the symbols of these output voltage command correction values are shown in a simplified manner. These output voltage command correction values are correction values for reducing the deviation of each capacitor voltage with respect to the average value of the capacitor voltages.

The adders 118, 119, and 120 include voltage command values Vuref, Vvref, and Vwref (these signal names are not shown) output from the two-phase to three-phase converter 117, and demagnetization suppression voltage command values Vuh for each phase. , Vvh, Vwh and so on. The adders 121_1, 121_2, 121_3 add the addition result (Vuref + Vuh) in the adder 118 and the output voltage command correction values Vdc_hos_u1, Vdc_hos_u2, and Vdc_hos_u3, respectively, and add the results to the PWM modulator 124 (chopper circuit control unit). Supply to.

Similarly, the adder 122_1, 122_2, 122_3 adds the addition result (Vvref + Vvh) in the adder 119 and the output voltage command correction values Vdc_hos_v1, Vdc_hos_v2, and Vdc_hos_v3, respectively, and supplies the result to the PWM modulator 124. .. Similarly, the adder 123_1, 123_2, 123_3 adds the addition result (Vwref + Vwh) in the adder 120 and the output voltage command correction values Vdc_hos_w1, Vdc_hos_w2, and Vdc_hos_w3, respectively, and supplies the result to the PWM modulator 124. ..

In the PWM modulator 124, the addition result in each adder 121_1 to 123_3 is PWM (Pulse Width Modulation) modulated, and the gate signals GateU, GateV, and GateW obtained by this are the arms 10u, 10v, and 10w (see FIG. 1). ) Is supplied to each chopper circuit (10u1, etc.). As a result, the controller 100 turns on / on the gate signals GateU, GateV, and GateW so that the active power calculation value Pfb and the ineffective power calculation value Qfb are brought close to the active power command value Pref and the ineffective power command value Quref. It controls the off state.

(Principle of generating second harmonic components)
The arm output voltages Vau, Vav, and Vaw of the power conversion device 1 include second-order harmonic components that depend on the arm output currents Iu, Iv, and Iw. Hereinafter, the principle of generating this second harmonic component will be described.
FIG. 4 is a diagram showing gate signals GP and GN supplied to the IGBT modules 30P and 30N (see FIG. 2) and chopper circuit output voltages Vcp1 and Vcp2. The chopper circuit output voltage Vcp1 is the chopper circuit output voltage Vcp when the polarity of the arm output current Iu is positive (when it flows in the direction shown in FIG. 2). Further, the chopper circuit output voltage Vcp2 is the chopper circuit output voltage Vcp when the polarity of the arm output current Iu is negative.

Semiconductor switching devices including IGBTs require a finite amount of time to turn on and off. In FIG. 2, if one of the IGBT modules 30P and 30N connected in series is turned on before the other is turned off, a short circuit is formed by the IGBT modules 30P and 30N and the DC capacitor 34, and the IGBT modules 30P and 30N are connected. Overcurrent flows and damages the IGBT modules 30P and 30N. In order to prevent this, a dead time is provided to turn off both the gate signals of the IGBT modules 30P and 30N. In FIG. 4, the period of t1 to t1 + ΔT and t2 to t2 + ΔT corresponds to this dead time.

In FIG. 2, when the polarity of the arm output current Iu is positive, the current during the dead time period flows through the freewheeling diode of the IGBT module 30P. Therefore, as shown in the waveform of the chopper circuit output voltage Vcp1 in FIG. 4, the chopper circuit output voltage Vcp1 during the dead time becomes positive. On the other hand, in FIG. 2, when the polarity of the arm output current Iu is negative, the current during the dead time period flows through the freewheeling diode of the IGBT module 30N. Therefore, as shown in the waveform of the chopper circuit output voltage Vcp2 in FIG. 4, the chopper circuit output voltage Vcp2 during the dead time becomes zero.

FIG. 5 is a waveform diagram of each part of the chopper circuit 10u1. As shown in the figure, the arm output current Iu has a waveform in which an AC component is superimposed on a DC component. As a result, the average voltage error Ve due to the dead time becomes a positive / negative asymmetric waveform as shown in the figure. The positive / negative asymmetric voltage includes even-order harmonics, and the second-order component is the largest among them. This is the principle that the second harmonic is generated due to the dead time.

Here, a little mention is made of an MMC method other than the ZC-MMC other than the present embodiment, that is, an MMC having a buffer reactor. Although not particularly shown, this type of MMC has U-phase, V-phase, and W-phase legs connected in parallel between the positive electrode terminal and the negative electrode terminal of the DC power supply, and in each leg, the arm on the P side. , The P-side reactor, the N-side reactor, and the N-side arm are sequentially connected in series. Then, the connection point between the reactor on the P side and the reactor on the N side is connected to the secondary winding of the transformer, and the voltage at this connection point becomes the phase voltage of the U phase, the V phase, and the W phase.

Also in this type of MMC, a second harmonic component is also generated due to the dead time. However, by arranging the pair of arms and the pair of reactors symmetrically on both the P side and the N side, most of the second harmonic components are canceled out in the phase voltage, and the effect becomes apparent. Does not change. Therefore, it can be said that the problem that the second harmonic component is generated due to the dead time is a phenomenon peculiar to ZC-MMC.

(Reverse phase secondary compensator 113)
Returning to the description of this embodiment. As shown in FIG. 5, the polarity of the voltage error Ve of the arm output voltages Vau, Vav, and Vaw (see FIG. 1) due to the dead time is determined by the polarities of the arm output currents Iu, Iv, and Iw. In the steady state where the system voltages Vu, Vv, and Vw are in equilibrium, the fundamental waves of the arm output currents Iu, Iv, and Iw are in three-phase equilibrium. Therefore, a balanced voltage error Ve having a time difference of 1/3 of the basic period is generated in the U phase, the V phase, and the W phase. Since there is almost no second harmonic component in the three-phase AC system 3 in FIG. 1, a balanced second harmonic current flows through the three-phase AC system 3 due to the voltage error Ve.

One of the features of the power converter 1 of the present embodiment is that it is provided with a reverse phase secondary compensator 113 (see FIG. 3) that intensively compensates for a balanced second harmonic current. The reverse phase secondary compensator 113 sets voltage command value correction terms Valp_h and Vbet_h so as to intensively extract the negative phase secondary components contained in the arm output currents Iu, Iv, and Iw and bring the extraction result close to zero. calculate.

The voltage command value correction terms Valp_h and Vbet_h are added to the voltage command values Valp and Vbet in the adders 115 and 116, respectively, as described above. As a result, the gate signals GateU, GateV, and GateW are set so that the opposite phase component of the second harmonic current approaches zero.

FIG. 6 is a block diagram of the reverse phase secondary compensator 113. The negative phase secondary compensator 113 outputs the negative phase secondary component extraction unit 113A for extracting the negative phase secondary component and the voltage command value correction terms Valve_h and Vbet_h so as to bring the negative phase secondary component close to zero. It includes a voltage command value operation unit 113B. Here, the reverse phase secondary component extraction unit 113A includes an inverse dq converter 1130 (first coordinate converter), an inverse dq converter 1131 (second coordinate converter), and a moving average calculation. It has vessels 1132a and 1132b.

Further, the voltage command value operation unit 113B includes integrators 1133a and 1133b and dq converters 1134 and 1135. Further, as described above, the reverse phase secondary compensator 113 includes output current values Ialp and Ibet obtained by converting arm output currents Iu, Iv and Iw into two-phase quantities, and synchronous sine wave cosωt synchronized with the system voltage. sinωt and are supplied.

The inverse dq converter 1130 operates in the same manner as the inverse dq converter 114 (see FIG. 3) described above. That is, the inverse dq converter 1130 has a current such that Ija = cosωt / Ilp-sinωt / Ibet and Ijb = sinωt / Ialp + cosωt / Ibet based on the output current values Ialp and Ibet and the synchronous sine waves cosωt and sinωt. The values Ija and Ijb are output. Further, the inverse dq converter 1131 is also configured in the same manner as the inverse dq converter 114, and outputs current values Ika and Ikb such that Ika = cosωt ・ Ija-sinωt ・ Ijb and Ikb = sinωt ・ Ija + cosωt ・ Ijb. ..

The inverse dq transformation executed by the inverse dq converters 1130 and 1131 is an operation corresponding to advancing the phase by ωt with respect to the vector on the complex plane, respectively. Therefore, by executing the inverse dq conversion twice, the inverse phase secondary component is converted from the rotation vector rotating on the stationary coordinates to the stationary vector whose coordinates are indicated by the DC quantity. The output current values Ialp and Ibet also include many components other than the negative phase secondary component, that is, the fundamental wave component, the positive phase secondary component, and the like. These other order components appear as harmonics having frequencies that are integral multiples of the fundamental wave at current values Ika and Ikb.

The moving average calculators 1132a and 1132b perform a moving average calculation on the current values Ika and Ikb with the period corresponding to one period of the fundamental wave as a "window". The "period corresponding to one fundamental wave cycle" is, for example, a "period equal to one fundamental wave cycle", but it does not necessarily have to exactly match the "one fundamental wave cycle", and the opposite phase secondary component may be used. The period may be as long as it can be extracted with more emphasis than other components.

As a result, the moving average calculators 1132a and 1132b output the current values Ina and Inb, which are the results of emphasizing the anti-phase secondary components in the current values Ika and Ikb. More preferably, the moving average calculators 1132a and 1132b output current values Ina and Inb, which are the results of removing other orders from the current values Ika and Ikb and extracting only the reverse phase secondary components. The integrators 1133a and 1133b apply predetermined gains to the current values Ina and Inb, perform an integral calculation, and output the results as voltage command values V2re and V2im.

The dq converters 1134 and 1135 operate in the same manner as the dq converter 112 (see FIG. 3). That is, the dq converter 1134 outputs voltage command values Vpa, Vpb such that Vpa = cosωt · V2re + sinωt · V2im and Vpb = −sinωt · V2re + cosωt · V2im. Further, the dq converter 1135 outputs voltage command value correction terms Valp_h and Vbet_h such that Valp_h = cosωt ・ Vpa + sinωt ・ Vpb and Vbet_h = −sinωt ・ Vpa + cosωt ・ Vpb.

By the operation of the dq converters 1134 and 1135, the voltage command values V2re and V2im, which are the values on the rotating coordinates, are converted into the voltage command value correction terms Valp_h and Vbet_h, which are the values on the stationary coordinates. In this way, the reverse phase secondary compensator 113 performs the reverse dq conversion twice on the output current values Ialp and Ibet, and performs a moving average calculation with the period corresponding to one period of the fundamental wave as the "window". By applying, the reverse phase secondary component is mainly extracted. As a result, it is possible to construct a control system having a higher gain than the positive phase secondary component with respect to the negative phase secondary component, and it is possible to selectively control the negative phase second harmonic. In other words, the reverse phase secondary compensator 113 outputs the voltage command values Valve_h and Vbet_h so as to suppress the negative phase secondary component more than the positive phase secondary component.

By the way, in order for the power conversion device 1 (see FIG. 1) to comply with the IEC1547 standard, it is required that the outflow upper limit value of the second harmonic with respect to the three-phase AC system 3 is set to 1%. In order to realize this, it is desirable to suppress the linear error (deviation from the straight line) between the actual current value of the current sensors 50u, 50v, 50w and the output signal to less than 1%. Further, in the steady state, the demagnetization of the transformer can be eliminated by the demagnetization suppression controller 125 (see FIG. 3), so that the secondary is unbalanced in both the arm output currents Iu, Iv, Iw and the system current. Harmonic current almost stops flowing.

As described above, according to the controller 100 of the present embodiment, the reverse phase secondary compensator 113 can suppress the second harmonic caused by the dead time. Further, since the anti-phase secondary compensator 113 can selectively execute the harmonic suppression control for the anti-phase secondary component, it is compatible with the demagnetization suppression control by the demagnetization suppression controller 125. Can be done. Therefore, the second harmonic component flowing out to the three-phase AC system 3 can be effectively reduced by the cooperation of the reverse phase secondary compensator 113 and the demagnetization suppression controller 125.

<Effect of the first embodiment>
As described above, the power conversion device 1 of the present embodiment each has a plurality of chopper circuits connected in series, one end of each is connected to the first DC terminal (5P), and the other end of each. The arm output currents (Iu, Iv, Iw) output from the three-phase arm (10u, 10v, 10w) connected to the secondary winding (20b) and the three-phase arm (10u, 10v, 10w), respectively. ), And the voltage command value (Valp_h) so as to suppress the negative-phase secondary component contained in the arm output current (Iu, Iv, Iw) more than the positive-phase secondary component. , Vbet_h), and a chopper circuit control unit (124) that controls a plurality of chopper circuits based on voltage command values (Valp_h, Vbet_h).
Thereby, the reverse phase secondary component among the second harmonic components can be particularly extracted and suppressed, and the second harmonic component can be appropriately suppressed.

Further, the power conversion device 1 of the present embodiment has a voltage sensor (56) for detecting the system voltage (Vu, Vv, Vw) of the three-phase AC system (3) and a voltage detection detected by the voltage sensor (56). Based on the value, the phase detector (101) that outputs the fundamental wave phase information (cosωt, sinωt) of the system voltage (Vu, Vv, Vw) is further provided, and the reverse phase secondary compensator (113) has. , The reverse phase secondary component extraction unit (113A) that extracts the reverse phase secondary component based on the fundamental wave phase information (cosωt, sinωt) and the arm output current (Iu, Iv, Iw), and the reverse phase secondary component. It has a voltage command value operation unit (113B) that outputs voltage command values (Valp_h, Vbet_h) based on the output signal of the component extraction unit (113A).
Thereby, the opposite phase secondary component can be accurately extracted based on the fundamental wave phase information (cosωt, sinωt) of the system voltage (Vu, Vv, Vw).

Further, the reverse phase secondary component extraction unit (113A) is a first coordinate converter that performs a first coordinate conversion on signals (Ialp, Ibet) corresponding to arm output currents (Iu, Iv, Iw). (1130) and the output signal of the first coordinate converter (1130), the output of the second coordinate converter (1131) and the second coordinate converter (1131) that perform the second coordinate conversion. A mobile averaging calculator that obtains the amount of DC (Ina, Inb) corresponding to the opposite-phase secondary component by performing a moving averaging calculation for the period corresponding to the fundamental wave period of the three-phase AC system (3) on the signal. (1132a, 1132b) and.
Thereby, the amount of DC corresponding to the reverse phase secondary component can be obtained.

Further, according to the present embodiment, the linear error between the actual current value in the current sensor (50u, 50v, 50w) and the output signal of the current sensor (50u, 50v, 50w) is less than 1%. As a result, the reverse phase secondary component can be accurately suppressed.

[Second Embodiment]
Next, the second embodiment of the present invention will be described. In the following description, the parts corresponding to the respective parts of FIGS. 1 to 6 may be designated by the same reference numerals, and the description thereof may be omitted. The overall configuration of this embodiment is the same as that of the first embodiment (FIGS. 1 to 3). However, in the present embodiment, the reverse phase secondary compensator 213 shown in FIG. 7 is applied instead of the reverse phase secondary compensator 113 of the first embodiment. Note that FIG. 7 is a block diagram of the reverse phase secondary compensator 213.
The negative phase secondary compensator 213 outputs the negative phase secondary component extraction unit 213A for extracting the negative phase secondary component and the voltage command value correction terms Valve_h and Vbet_h so as to bring the negative phase secondary component close to zero. It includes a voltage command value operation unit 213B.

Here, the reverse phase secondary component extraction unit 213A includes a phase calculator 1137, a multiplier 1138, a sine wave table 1139, and a Fourier transform unit 1140. Further, the voltage command value operation unit 213B includes integrators 1133a and 1133b and a dq converter 2134.

The phase calculator 1137 obtains the system voltage phase information ωt based on the synchronous sine waves cosωt and sinωt. The multiplier 1138 doubles the system voltage phase information ωt and outputs the phase information 2ωt. The sine wave table 1139 outputs sine wave information cos2ωt and sin2ωt based on the phase information 2ωt.

The Fourier transform unit 1140 executes the Fourier transform operation shown in the following equation (5) on the output current values Ialp and Ibet and the sine wave information cos2ωt and sin2ωt, whereby the real part I2re of the reverse phase secondary component is executed. And the imaginary part I2im are calculated. Note that tow in Equation 5 indicates the current time.

The real part I2re and the imaginary part I2im of the reverse phase secondary component are equivalent to the current values Ina and Inb in FIG. The integrators 1133a and 1133b are the same as those shown in FIG. 6, and perform an integral calculation by applying a predetermined gain to the real part I2re and the imaginary part I2im of the opposite phase secondary component, and the result is the voltage. Output as command values V2re and V2im. The dq converter 2134 outputs voltage command value correction terms Valp_h and Vbet_h such that Valp_h = cos2ωt ・ V2re + sin2ωt ・ V2im and Vbet_h = −sin2ωt ・ V2re + cos2ωt ・ V2im.

In the first embodiment described above (FIG. 6), the dq coordinates were executed twice by the two dq converters 1134 and 1135, but as shown in FIG. 7, a double frequency of 2ω was used. Even when the dq coordinate is performed once, the voltage command value correction terms Valp_h and Vbet_h equivalent to those in FIG. 6 can be obtained.

As described above, according to the present embodiment, the same effect as that of the first embodiment described above is obtained. Further, according to the present embodiment, the reverse phase secondary component extraction unit (213A) sets a frequency twice as high as the fundamental frequency in the three-phase AC system (3) based on the fundamental wave phase information (cosωt, sinωt). Arm output currents (Iu, Iv, Iw) using the double phase information generator (1137, 1138, 1139) that generates the double phase information (cos2ωt, sin2ωt) and the double phase information (cos2ωt, sin2ωt). ), The voltage command value manipulation unit (213B) has a Fourier transform unit (1140) that Fourier transforms the reverse phase secondary component contained in the), and the voltage command value operation unit (213B) is based on the output signal of the Fourier transform unit (1140). The value (Valp_h, Vbet_h) is output. As a result, according to the present embodiment, the number of calculations can be reduced as compared with the first embodiment, and the processing load of the CPU and DSP (not shown) constituting the controller 100 can be reduced. it can.

[Third Embodiment]
Next, a third embodiment of the present invention will be described. In the following description, the parts corresponding to the respective parts of FIGS. 1 to 7 may be designated by the same reference numerals, and the description thereof may be omitted. The overall configuration of this embodiment is the same as that of the first embodiment (FIGS. 1 and 3). However, in the present embodiment, the reverse phase secondary compensator 313 shown in FIG. 8 is applied instead of the reverse phase secondary compensator 113 of the first embodiment. Note that FIG. 8 is a block diagram of the reverse phase secondary compensator 313.

The negative phase secondary compensator 313 outputs the negative phase secondary component extraction unit 313A for extracting the negative phase secondary component and the voltage command value correction terms Valve_h and Vbet_h so as to bring the negative phase secondary component close to zero. It includes a voltage command value operation unit 313B.

Here, the configuration of the reverse phase secondary component extraction unit 313A is the same as that of the reverse phase secondary component extraction unit 113A (see FIG. 6) of the first embodiment. Further, the voltage command value operation unit 313B includes integrators 1133a and 1133b and dq converters 1134 and 1135, similarly to the voltage command value operation unit 113B of the first embodiment. However, in the voltage command value operation unit 313B of the present embodiment, the fixed phase compensator 1136 (phase adjustment unit) is inserted between the integrators 1133a and 1133b and the dq converter 1134.

The significance of providing the fixed phase compensator 1136 and its function will be described below. As described above, the function of the controller 100 (see FIG. 1) is realized by a control program executed by the CPU, a microprogram executed by the DSP, or the like. Therefore, even if the measured values of the arm output currents Iu, Iv, Iw, system voltage Vu, Vv, Vw, etc. are input to the controller 100, the measured values are reflected in the output signals of the gate signals GateU, GateV, GateW, etc. It takes, for example, tens to hundreds of μs.

Further, since the harmonic voltage included in the output voltage is small in the circuit configuration, the MMC is often selected with a low switching frequency. Therefore, even when the current sensors 50u, 50v, 50w detect a current including a reverse phase secondary component, the voltage command value correction terms Valp_h, Vbet_h (see FIG. 3) are the arm output voltages Vau, Vav, Vaw. There is a time delay before it is reflected as (see FIG. 1). Due to this time delay, there is a possibility that the reverse phase secondary components of the arm output currents Iu, Iv, and Iw cannot be sufficiently suppressed, and the controller 100 may become unstable.

In view of the above circumstances, the fixed phase compensator 1136 of the present embodiment attempts to perform phase compensation in order to reduce the phase shift caused by wasted time. Specifically, the fixed phase compensator 1136 performs the calculation shown in the following equation (6) on the voltage command values V2re and V2im which are input signals, and uses the voltage command values V2re2 and V2im2 as the output signals. What you get.

The matrix operation of equation (6) generally delays the phase by δ. However, the harmonics handled in this embodiment are opposite-phase secondary components, and the vector rotation direction is reverse rotation. By performing the phase correction operation shown in the equation (6), it is possible to correct the phase shift with respect to the antiphase secondary component due to the wasted time, and the control stability is improved. The phase difference δ may be a fixed value, but the optimum value of the phase difference δ changes depending on the calculation cycle of the controller 100 and the switching frequency of the chopper circuit (10u1 or the like). Therefore, it is preferable to provide an interface that allows the phase difference δ to be changed from the outside.

Therefore, the power conversion device of the present embodiment includes the operation unit 320 shown in FIG. The operation unit 320 can set the value of the phase difference δ (or cos δ and sin δ) based on the operation of the user. The operation unit 320 may be provided on the operation panel 40 shown in FIG. 1 or on the maintenance information device 42.

As described above, according to the present embodiment, the same effects as those of the first embodiment and the second embodiment described above are obtained. Further, according to the present embodiment, the voltage command value operation unit (313B) includes a phase adjustment unit (1136) that adjusts the phase of the voltage command value (Valp_h, Vbet_h).
As a result, it is possible to reduce the phase shift caused by the delay in the control calculation and the switching of the chopper circuit. Therefore, according to the present embodiment, the control stability with respect to the reverse phase secondary component can be improved as compared with the first and second embodiments.

Further, according to the present embodiment, the phase adjusting unit (1136) is further provided with an operating unit (320) for instructing the phase adjustment amount.
Thereby, an appropriate phase adjustment amount can be instructed depending on the situation.

Further, according to the configuration in which the operation unit (320) is provided on the operation panel (40), the phase adjustment amount can be instructed on the operation panel (40). Further, according to the configuration in which the operation unit (320) is provided in the maintenance information device (42), the phase adjustment amount can be instructed in the maintenance information device (42).

[Fourth Embodiment]
Next, a fourth embodiment of the present invention will be described. In the following description, the parts corresponding to the respective parts of FIGS. 1 to 8 may be designated by the same reference numerals, and the description thereof may be omitted.
FIG. 9 is a block diagram of the power conversion system 1000 according to the present embodiment.
The power conversion system 1000 of the present embodiment is connected between a three-phase AC system 3A (first three-phase AC system) and another three-phase AC system 3B (second three-phase AC system). Power is transmitted in one direction or in both directions between the three-phase AC systems 3A and 3B.

The power conversion system 1000 includes a power conversion device 1A (first power conversion device) and a power conversion device 1B (second power conversion device). The power conversion devices 1A and 1B are configured in the same manner as the power conversion device 1 (see FIG. 1) in the first embodiment, respectively. Therefore, in FIG. 9, the internal configuration of the power conversion devices 1A and 1B is not shown. The transformer 20 in the power converter 1A is connected to the three-phase AC system 3A, and the transformer 20 in the power converter 1B is connected to the three-phase AC system 3B.

The power conversion device 1A has a positive electrode terminal 6P (first DC terminal) and a negative electrode terminal 6N (second DC terminal). Similarly, the power conversion device 1B has a positive electrode terminal 7P (first DC terminal) and a negative electrode terminal 7N (second DC terminal). These are the same as the positive electrode terminal 5P and the negative electrode terminal 5N in the first embodiment. Then, in the present embodiment, the positive electrode terminals 6P and 7P are connected to each other, and the negative electrode terminals 6N and 7N are also connected to each other. That is, the power conversion devices 1A and 1B are connected to each other by a so-called BTB (Back To Back; back-to-back method).

As described above, the power conversion system (1000) of the present embodiment includes a first power conversion device (1A) connected to the first three-phase AC system (3A) and a second three-phase AC system (1A). A second power conversion device (1B) connected to 3B) is provided, and the first power conversion device (1A) and the second power conversion device (1B) are each provided with a first DC terminal (6P). , 7P), the second DC terminal (6N, 7N), and the three-phase primary winding (3B) connected to the first three-phase AC system (3A) or the second three-phase AC system (3B). A transformer (20a) and a three-phase secondary winding (20b) having a staggered connection and a three-phase secondary winding (20b) in which the midpoint of the staggered connection of each phase is connected to a second DC terminal (6N, 7N). Each has a plurality of chopper circuits connected in series with 20), one end of each is connected to a first DC terminal (6P, 7P), and the other end of each is a secondary winding (20b). A current sensor (50u, 50u,) that detects the arm output currents (Iu, Iv, Iw) output from the connected three-phase arms (10u, 10v, 10w) and the three-phase arms (10u, 10v, 10w), respectively. 50v, 50w) and a reverse-phase secondary compensator (113) that outputs voltage command values (Valp_h, Vbet_h) so that the negative-phase secondary components contained in the arm output currents (Iu, Iv, Iw) approach zero. ), And a chopper circuit control unit (124) that controls a plurality of chopper circuits based on voltage command values (Valp_h, Vbet_h), and a first DC terminal (1A) in the first power conversion device (1A). 6P) and the first DC terminal (7P) in the second power conversion device (1B) are connected to each other, and the second DC terminal (6N) and the second DC terminal (6N) in the first power conversion device (1A) are connected to each other. It is characterized in that it is interconnected with a second DC terminal (7N) in the power converter (1B).
As a result, the second harmonic component can be appropriately suppressed even in the back-to-back power conversion system (1000).

[Modification example]
The present invention is not limited to the above-described embodiment, and various modifications are possible. The above-described embodiments are exemplified for the purpose of explaining the present invention in an easy-to-understand manner, and are not necessarily limited to those having all the configurations described. Further, it is possible to replace a part of the configuration of one embodiment with the configuration of another embodiment, and it is also possible to add the configuration of another embodiment to the configuration of one embodiment. Further, it is possible to delete a part of the configuration of each embodiment, or add / replace another configuration. In addition, the control lines and information lines shown in the figure show what is considered necessary for explanation, and do not necessarily show all the control lines and information lines necessary for the product. In practice, it can be considered that almost all configurations are interconnected.

1 Power conversion device 1A Power conversion device (first power conversion device)
1B power converter (second power converter)
2 DC power supply (DC system)
3 Three-phase AC system 3A Three-phase AC system (first three-phase AC system)
3B three-phase AC system (second three-phase AC system)
5P, 6P, 7P positive electrode terminal (first DC terminal)
5N, 6N, 7N Negative electrode terminal (second DC terminal)
10u, 10v, 10w Arm 10u1,10u2,10u3 Chopper circuit 20 Transformer 20a Primary winding 20b Secondary winding 40 Operation panel 42 Maintenance information equipment 50u, 50v, 50w Current sensor 56 Voltage sensor 100 Controller 101 Phase detection Instrument 113, 213, 313 Reverse phase secondary compensator 113A, 213A, 213B Reverse phase secondary component extraction unit 113B, 213B, 313B Voltage command value operation unit 124 PWM modulator (chopper circuit control unit)
320 Operation unit 1000 Power conversion system 1130 Inverse dq converter (first coordinate converter)
1131 inverse dq converter (second coordinate converter)
1132a, 1132b Moving average calculator 1136 Fixed phase compensator (phase adjuster)
1140 Fourier transform

Claims (10)

The first DC terminal connected to one end of the DC system,
A second DC terminal connected to the other end of the DC system,
A three-phase primary winding connected to a three-phase AC system and a three-phase secondary winding that is staggered and the midpoint of the staggered connection of each phase is connected to the second DC terminal. With a transformer,
A three-phase arm, each of which has a plurality of chopper circuits connected in series, one end of which is connected to the first DC terminal and the other end of which is connected to the secondary winding.
A current sensor that detects the arm output current output from each of the three-phase arms, and
A reverse phase secondary compensator that outputs a voltage command value so as to suppress the negative phase secondary component included in the arm output current more than the positive phase secondary component.
A chopper circuit control unit that controls a plurality of the chopper circuits based on the voltage command value,
A power conversion device characterized by having. A voltage sensor that detects the system voltage of the three-phase AC system and
A phase detector that outputs a sine wave synchronized with the system voltage based on the voltage detection value detected by the voltage sensor, and
Have more
The reverse phase secondary compensator is
A reverse phase secondary component extractor that extracts the reverse phase secondary component based on the sine wave and the arm output current,
The power conversion device according to claim 1, further comprising a voltage command value operation unit that outputs the voltage command value based on the output signal of the reverse phase secondary component extraction unit. The reverse phase secondary component extraction unit
A first coordinate converter that performs the first coordinate conversion on the signal corresponding to the arm output current, and
A second coordinate converter that performs a second coordinate conversion on the output signal of the first coordinate converter, and
The output signal of the second coordinate converter is subjected to a moving average calculation for a period corresponding to the fundamental wave period of the three-phase AC system to obtain a DC amount corresponding to the reverse-phase secondary component. The power converter according to claim 2, further comprising an average calculator. The reverse phase secondary component extraction unit
Based on the sine wave , a double phase information generator that generates double phase information having a frequency twice the fundamental frequency in the three-phase AC system, and a double phase information generator.
Using the double phase information, a Fourier transform unit that Fourier transforms the antiphase secondary component included in the arm output current, and a Fourier transform unit.
Have,
The power conversion device according to claim 2, wherein the voltage command value operation unit outputs the voltage command value based on the output signal of the Fourier transform unit. The power conversion device according to claim 2, wherein the linear error between the actual current value in the current sensor and the output signal of the current sensor is less than 1%. The power conversion device according to claim 2, wherein the voltage command value operation unit includes a phase adjustment unit that adjusts the phase of the voltage command value. The power conversion device according to claim 6, further comprising an operation unit for instructing the phase adjustment amount with respect to the phase adjustment unit. It also has an operation panel for operating each part of the power conversion device.
The power conversion device according to claim 7, wherein the operation unit is provided on the operation panel. The power conversion device according to claim 6 , further comprising a maintenance information device for instructing the phase adjustment amount by remote control to the phase adjustment unit. A first power conversion device connected to a first three-phase AC system and a second power conversion device connected to a second three-phase AC system are provided, and the first power conversion device and the said The second power converters are, respectively.
The first DC terminal and
With the second DC terminal,
The first three-phase AC system or the three-phase primary winding connected to the second three-phase AC system is staggered, and the midpoint of the staggered connection of each phase is the second direct current. A transformer with a three-phase secondary winding connected to a terminal, and
A three-phase arm, each of which has a plurality of chopper circuits connected in series, one end of which is connected to the first DC terminal and the other end of which is connected to the secondary winding.
A current sensor that detects the arm output current output from each of the three-phase arms, and
An anti-phase secondary compensator that outputs a voltage command value so that the anti-phase secondary component contained in the arm output current approaches zero.
A chopper circuit control unit that controls a plurality of the chopper circuits based on the voltage command value,
Have,
The first DC terminal in the first power conversion device and the first DC terminal in the second power conversion device are connected to each other, and the second DC terminal in the first power conversion device is connected to each other. A power conversion system characterized in that and the second DC terminal in the second power conversion device are interconnected with each other.

Images