JP2005045999A - Operation method of serial multiplexing three-phase circuit pulse width modulation cyclo-converter arrangement, and serial multiplexing three-phase circuit pulse width modulation cyclo-converter arrangement - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a power converter arrangement and a power converter method of the multiplexing three-phase circuit pulse width modulation cyclo-converter system for driving a high-voltage AC motor which generates high voltage of low distortion by using low-voltage inverter technology. <P>SOLUTION: The serial multiplexing three-phase circuit PWM (pulse width modulation) cyclo-converter arrangement is operated, by using a serial multiplexing three-phase circuit pulse width modulation cyclo-converter constituted by connecting in series single-phase output pulse width modulation cyclo-converters (1 to 9); to short-circuit between single-phase AC terminals of the cyclo-converter at failure, in case any of the cyclo-converters fails; to conduct successively by an equal time interval three sets of double-throw switches consisting of each of the two double-throw switches connected by each phase of three-phase power input terminals (r, s, t) related to the other two-phase cyclo-converter located at the same position in series connection with the failed cyclo-converter. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

  The present invention relates to a power conversion device and a current conversion method for driving a high-voltage AC motor at a variable speed, and more particularly to a pulse width modulation (PWM) control type power conversion device and a current conversion method.

  Conventionally, a variable voltage drive for a high-voltage AC motor has used a system using a high-voltage inverter, or a system in which a step-down transformer and a step-up transformer are connected to the input side and output side of the low-voltage inverter, respectively.

FIG. 6 is a circuit diagram of a drive circuit using a conventional high-voltage inverter, and FIG. 7 is a conceptual diagram showing four-quadrant operation based on the relationship between the torque and speed of the motor. In FIG. 6, reference numeral 10 is a high-voltage AC motor to be driven, 101 is an inverter unit, 102 is a smoothing capacitor unit, 103 is a regenerative converter unit, 104A and 104B are AC reactors, and 105 is a three-phase transformer.
The inverter unit 101 is a neutral point clamp type three-level inverter, which uses a GTO (Gate Turn Off Thyristor, hereinafter referred to as GTO) as a power element to increase the withstand voltage of the element and connect it in series to share the voltage. In other words, variable voltage variable frequency (VVVF) power is supplied from a high-voltage DC power source including the smoothing capacitor unit 102. In order to maintain the GTO voltage sharing, it is necessary to install a well-known snubber circuit. The converter unit that supplies the DC voltage to the smoothing capacitor unit 102 has a large high-voltage inverter generally having a capacity of several hundred kW or more. The braking energy processing during deceleration and the four-quadrant operation shown in FIG. The configuration of the regenerative converter unit 103 is used for forward rotation / reverse rotation). In FIG. 6, two sets of circuits combining thyristors and GTO are used in series connection, and electric and regenerative control are performed according to the direction of DC power. Regenerative converter unit 103 is connected to the secondary winding of three-phase transformer 105 via AC reactors 104A and 104B, and the primary winding of three-phase transformer 105 is connected to a high-voltage commercial power supply to receive power.

FIG. 8 is a circuit diagram of a drive circuit using a conventional low-voltage inverter. In the figure, reference numeral 10 is a high-voltage AC motor to be driven, 106 is an inverter unit, 107 is a smoothing capacitor unit, 108 is a regenerative converter unit, 109 is an AC reactor, 110 is a step-down transformer, and 111 is a step-up transformer.
The inverter unit 106 is an IGBT (Insulated Gate Bipolar Transistor, hereinafter abbreviated as IGBT) and a diode connected in a three-phase bridge circuit, and outputs a voltage and a frequency necessary for driving the electric motor 10 via the step-up transformer 111. Thus, pulse width modulation (hereinafter abbreviated as PWM) is controlled.
Since the inverter unit 106 is a low-voltage inverter, it is connected to the high-voltage AC motor 10 via the step-up transformer 111. The regenerative converter unit 108 also has the same IGBT and diode as the inverter unit 106 connected in a three-phase bridge circuit, and is connected to the secondary winding of the step-down transformer 110 via the AC reactor 109, and the primary winding of the step-down transformer 110. Is connected to a high-voltage commercial power supply to receive power. The DC buses of the regenerative converter unit 108 and the inverter unit 106 are also connected to each other via the smoothing capacitor unit 107. Both the inverter unit 106 and the regenerative converter unit 108 are PWM-controlled.

  In addition, as a motor drive system, for example, a multiple cycloconverter disclosed in “cycloconverter device” disclosed in Japanese Patent Laid-Open No. 6-245511, or a “pulse width control system” disclosed in Japanese Patent Publication No. 7-44834. Although there is a PWM cycloconverter shown in “Power Converter”, it is not intended for driving the above-described high-voltage AC motor.

In addition, the trend of the world is progressing in the direction of energy saving, resource saving, downsizing, high efficiency and voltage / current waveform distortion regulation for environmental improvement, and operation such as improvement of redundancy due to complicated application system. The reliability needs to be improved, and the above-described conventional electric motor drive system is also an object.
However, the high-voltage inverter system and the low-voltage inverter boost system of the above-described prior art examples are all considered from the viewpoints of energy saving, resource saving, downsizing, high efficiency, and suppression of voltage / current wave distortion in terms of environmental improvement. There are some problems.

  In the case of the high-voltage inverter system shown in FIG. 6, a GTO is used in the main circuit element to increase the breakdown voltage. Since GTO is not a high-speed switching element, it is difficult to increase the carrier frequency, and it is impossible to reduce the noise of the inverter drive and to suppress the waveform distortion. In addition, the GTO snubber circuit repeats charging and discharging every time it is switched, and thus has a large loss. Since the circuit configuration uses a high voltage element, it is necessary to ensure insulation of the main circuit, bus bar, etc., and is not suitable for miniaturization. Furthermore, since a GTO drive power supply is required for each GTO and a high voltage is applied between the control power supplies, it is not easy to generate the control power supply, which is a bottleneck in miniaturization.

  On the other hand, the low-voltage inverter boosting method of FIG. 8 is a low-voltage IGBT inverter, so that high-frequency PWM control is possible and noise reduction is possible, but in order to increase the capacity, parallel connection of IGBTs is necessary. There is a parallel balancing policy and a snubber circuit, which makes it difficult to reduce the size. Further, an increase in the loss of the IGBT, bus bar, and snubber circuit due to the increase in current is expected, and it is difficult to reduce the size from the cooling surface. Furthermore, when boosting with a transformer as shown in FIG. 8, the switching speed of the IGBT is fast, that is, dV / dt at the time of switching is large, so switching of PWM control of the inverter by wiring inductance, wiring stray capacitance, transformer inductance, etc. Resonance voltage is generated in synchronism with this, and there is also a drawback that causes breakdown of the electric motor.

As a countermeasure, it has been proposed to insert a filter between the inverter unit 106 and the step-up transformer 111 in FIG. 8 as shown in “Output Filter Circuit of Voltage-Type PWM Inverter” disclosed in Japanese Patent Laid-Open No. 1-72144. Yes. In addition, the voltage / frequency ratio applied to the transformer during low-frequency operation is set to 1.5 to 2 times higher than that near the rated frequency by the inverter to ensure starting torque. There is a problem that a large transformer is required compared to the transformer for use. In addition, when the inverter 106 generates an offset voltage due to variations in IGBT switching characteristics or the like, a DC voltage is applied to the step-up transformer 111, resulting in magnetic saturation and excessive current flowing.

As a countermeasure against harmonic distortion of the output voltage current, the high-voltage inverter is three-level control, and PWM control and amplitude control are used together. However, the low-voltage inverter system is only PWM control and has high harmonic distortion. The high-voltage inverter type regenerative converter 103 in FIG. 6 also has a low-order harmonic distortion due to the 120 ° energization waveform with respect to the power supply voltage, and in the low-voltage inverter type in FIG. The lower harmonics of the current are suppressed, but the higher harmonics remain.

  As described above, the conventional inverter system cannot cope with technical problems such as energy saving, resource saving, downsizing, high efficiency, and suppression of voltage / current waveform distortion for environmental improvement, which are market needs. In addition, none of the methods can cope with the technical problem of improving redundancy, such as operating in a sound part at the time of failure.

  Further, in systems other than the inverter system, the cycloconverter shown in the “cycloconverter device” disclosed in Japanese Patent Application Laid-Open No. 116-2415511 is a power commutation system, and therefore, only 1/3 to 1/2 of the power frequency. The output frequency cannot be increased, and is not suitable for an electric motor drive.

An improved version of this is a PWM cycloconverter disclosed in the “pulse width control type power converter” disclosed in Japanese Patent Publication No. 7-44834. The PWM cycloconverter has the following features.
1) Easy to miniaturize because no DC circuit is required unlike the inverter system.
2) Compared with the inverter system, the number of elements that enter in the path from the power source to the load is small, so that the element loss is small and the efficiency is high.
3) 4-quadrant operation is easy because of AC-AC direct conversion.
However, since this method is also a PWM control power conversion method with three-phase input and three-phase output, low-order harmonics of the power supply current are suppressed, but high-order harmonics remain, and voltage / current waveform distortion is suppressed for both input and output. The technical problem is not solved. In order to drive a high-voltage AC motor, a high-voltage PWM cycloconverter is used by increasing the breakdown voltage of the power element, or a method of boosting with a transformer is adopted. The same problem occurs. Furthermore, in the above-described conventional example, any of the methods has a problem that the operation cannot be continued when some functions are impaired.

JP-A-2-202324 (FIG. 1) JP-A 64-50763 (FIG. 1)

  An object of the present invention is to provide a power conversion apparatus and a power conversion method of a multiplex three-phase pulse width modulation cycloconverter system for driving a high voltage AC motor that generates a low voltage and high voltage using low voltage inverter technology. There is.

The power converter of the multiplex three-phase pulse width modulation cycloconverter system according to the present invention is a power converter that drives a high-voltage AC motor at a variable speed. The power converter includes one set of primary winding and 3 × n sets of secondary One 3-phase transformer with windings, or m (1 ≦ m ≦ n) with one primary winding and 3 × j (j = n / m) secondary windings 3 × n three-phase reactors connected to the three-phase transformer and the secondary winding, respectively, and 3 × n three-phase / single-phase pulse width modulation cycloconverters connected to the three-phase reactors. The primary winding of the transformer is connected to an external AC power source, and the secondary winding is composed of n sets including a three-phase reactor and a three-phase / single-phase pulse width modulation cycloconverter connected in series. Units are arranged between the n sets of secondary windings in each unit. When the angles are different from each other by (60 ° ÷ k) (where 1 ≦ k ≦ n), (when k = 1, the phase difference is 60 ° and the transformer load is a three-phase full-flow rectifier circuit. Three-phase reactor and three-phase / single-phase, in which secondary windings having three units of the same phase electrical angle correspond to each other and are connected in series in each unit. Connected to form n groups including phase pulse width modulation cycloconverters, three-phase / single phase pulse width modulation cycloconverters can flow current in both directions and can be self-conducting and self-interrupting, 6 bidirectional semiconductor switches controlled by pulse width modulation, 3 filter capacitors, a 3 phase AC terminal connected to a 3 phase reactor, and a single phase AC terminal connected to the outside, Bidirectional semiconductor The switch is connected to the three-phase AC terminal and the single-phase AC terminal in a three-phase bridge circuit, the filter capacitor is connected to the three-phase AC terminal in a delta or star connection, and the bidirectional semiconductor switch has a three-phase / single-phase pulse width. The voltage of the AC output that is output to the single-phase AC terminal of the modulation cycloconverter is the same in the same unit, and the electrical angle of the fundamental voltage phase is different by 120 ° between the three sets of units. The single-phase AC terminals of the three-phase / single-phase pulse width modulation cycloconverter in the same unit are connected in series, and either terminal at both ends is star-connected between the three sets of units. Are connected to three input terminals of an external high-voltage AC motor to be driven.
Instead of the three-phase AC reactor, a means for using the leakage inductance of the secondary winding of the three-phase transformer may be provided.

  A bidirectional semiconductor switch of a three-phase / single-phase pulse width modulation cycloconverter includes a semiconductor element having a self-cutoff capability and a diode connected in antiparallel to the semiconductor element so that the flow direction is reversed. The semiconductor switch may be formed by serially connecting two sets of opposite polarities, and includes a semiconductor element having a self-blocking capability and a diode connected in series to the semiconductor element so that the flow direction is the same direction. Two pairs of semiconductor switches may be connected in parallel with opposite polarity, and a semiconductor element having a self-blocking capability is connected to two DC terminals of four diodes connected to a single-phase bridge in the same direction of distribution. The two AC terminals of the single-phase bridge may be formed as input / output terminals.

  A power conversion method using a power converter of a multiple three-phase pulse width modulation cycloconverter system according to the present invention is a power conversion method for variable-speed driving of a high-voltage AC motor. The AC output voltage that is output to the single-phase AC terminal of the three-phase / single-phase pulse width modulation cycloconverter using the two-way semiconductor switch is the same phase for the same unit, and is basically the same between the three sets of units. The high-voltage AC electric motor is driven at a variable speed by controlling the pulse voltage modulation method so that the electrical angles of the wave voltage phases are different from each other by 120 °.

  When operation is performed in a state where m (where 1 ≦ m ≦ n) out of n three-phase / single-phase pulse width modulation cycloconverters in one unit, the failed three-phase / single-phase pulse width modulation cycloconverter The single-phase AC terminal is short-circuited and connected to each of the three-phase AC terminals of the same group of three-phase / single-phase pulse width modulation cycloconverters as the other two units of the failed three-phase / single-phase pulse width modulation cycloconverters The two sets of two bidirectional semiconductor switches are made to conduct and short-circuit one by one sequentially at equal time intervals, and the remaining (nm) three-phase / single-phase pulse width modulation cycloconverters of three units. The high-voltage AC motor may be driven at a variable speed. The current direction of the single-phase AC terminal is detected, and each time the current direction is reversed, one set is sequentially conducted to short-circuit the remaining three units (nm). Three phases The high voltage AC motor may be variable speed drives a single-phase pulse width modulation cycloconverter.

When performing variable speed driving of a high-voltage AC motor using the power converter of the above-described multiple three-phase pulse width modulation cycloconverter system, three units of three-phase / single-phase pulse width modulation cyclo Since each waveform control of the converter is performed, input / output voltage current with a low distortion waveform can be obtained and direct conversion from alternating current to alternating current allows power supply and regeneration to be performed freely and a direct current circuit is provided. Since there are not, there are few components and there are also few elements in series in the path | route from a power supply to a load.
If the leakage inductance of the secondary winding of the three-phase transformer is used, a three-phase AC reactor can also be omitted.
Since each unit is composed of a plurality of three-phase / single-phase pulse width modulation cycloconverters, operation is continued using the remaining three-phase / single-phase pulse width modulation cycloconverters in a healthy group even in the event of a failure. It is possible.

  If the multiple three-phase PWM cycloconverter of the present invention is used, a DC circuit as in the inverter system is not required, which facilitates downsizing and reduces the number of elements entering in the path from the power source to the load, thereby reducing element loss. Since the waveform control of each three-phase / single-phase PWM cycloconverter is performed by the above-mentioned means, the input / output voltage current with a low distortion waveform can be obtained and the power supply and regeneration can be performed for AC-AC direct conversion. It is possible to perform the operation using a healthy part even in the event of a failure.

  Next, embodiments of the present invention will be described with reference to the drawings.

FIG. 1 is a circuit diagram of a driving circuit using a power converter of a multiple three-phase pulse width modulation (hereinafter abbreviated as PWM) cycloconverter system according to the first embodiment of the present invention. In the figure, reference numerals 1 to 9 are three-phase / single-phase PWM cycloconverters, 10 is a high-voltage AC motor to be driven, 11 to 16 are bidirectional semiconductor switches, 17 to 19 are filter capacitors, and 21 to 29 are three-phase AC reactors. , 30 is a three-phase transformer, 31 to 39 are secondary windings of the three-phase transformer 30, and 40 is a primary winding of the three-phase transformer 30.
Since the three-phase / single-phase PWM cycloconverters 1 to 9 have the same structure, the three-phase / single-phase PWM cycloconverter 1 will be described. The three-phase / single-phase PWM cycloconverter 1 includes six bidirectional semiconductor switches 11-16, three filter capacitors 17-19, three-phase AC terminals r, s, t, and single-phase AC terminals u, v. 6 bidirectional semiconductor switches 11 to 16 capable of flowing a current in both directions and capable of self-conduction and self-interruption are connected to three-phase AC terminals r, s, t and single-phase AC terminals u, v. Each is connected to a three-phase bridge circuit, and the filter capacitors 17 to 19 are delta connected to the three-phase AC terminals r, s, and t.

In general, a three-phase / single-phase PWM cycloconverter is a combination of 3 × n, but FIG. 1 shows nine examples where n = 3. In this example, nine three-phase / single-phase PWM cycloconverters 1 to 9 have three-phase AC terminals r, s, and t through nine three-phase AC reactors 21 to 29, respectively. The three-phase transformer 30 has one set of primary winding 40 and nine sets of secondary windings 31 to 39, and the primary winding 40 is connected to an AC power source. The Instead of the three-phase AC reactors 21 to 29, the leakage inductance of the secondary windings 31 to 39 of the three-phase transformer 30 can be used.
n (three in this example) three-phase / single-phase PWM cycloconverter (1 to 3, 4 to 6, 7 to 9 in this example) is composed of one unit as a whole, Single-phase AC terminals u and v are connected in series, either one of u or v terminals at both ends is star-connected between three sets of units, and the other three terminals are the high-voltage DC motor 10 to be driven. Connected to three input terminals.
With the above combination, a power conversion device of a three-phase input, three-phase output multiple PWM cycloconverter system is configured.

  N three-phase / single-phase PWM cycloconverters of each unit (in this example, the fundamental wave voltage of the AC output output to the single-phase AC terminals u, v of 1-3, 4-6, 7-9 is in phase) The three sets of units are controlled so as to generate alternating current outputs whose fundamental voltage phase is 120 degrees out of phase.

Since each of the three-phase / single-phase PWM cycloconverters 1 to (3 × n) (1 to 9 in this example) is a single-phase load, the load balance on the power source side is achieved, and the low-order harmonic current is supplied to the three-phase transformer 30. In order to cancel out the secondary windings of the three-phase transformer 30, the secondary winding of the three-phase transformer 30 is a group of the same order of the 1st to n-th three-phase / single-phase PWM cycloconverters of the three units. (In this example, three groups of 1, 4, 7, and 2, 5, 8 and 3, 6, 9), and under the same conditions so that the induced voltage phases in each group are equal, Winding is performed so that the phase difference is 60 ° ÷ k (1 ≦ k ≦ n, usually k = n) between the groups. In the example of FIG. 1, the primary winding 40 of the three-phase transformer 30 is in a delta connection, and the secondary windings 31, 34, and 37 of the first group are staggered in an electrical angle of 50 ° with respect to the primary winding 40. Delayed, the second group of secondary windings 32, 35, and 38 are star-connected with an electrical angle of 30 ° behind the primary winding 40, and the third group 33, 36, and 39 are staggered for primary winding. The wire 40 is wound with an electrical angle of 10 ° behind the wire 40. Thus, if each three-phase / single-phase PWM cycloconverter is controlled symmetrically, in principle, a power supply harmonic voltage current having a power supply frequency of the 22nd or lower is not generated.
Since n = 3 in the example of FIG. 1, the phase difference between the secondary windings of the three-phase transformer 30 is 60 ° / 3 = 20 °, but if n = 5 (60 ° / 5 = 12 °). Thus, a power supply harmonic voltage current having a power supply frequency of 34th order or lower is not generated.

Next, measures for improving redundancy will be described. A feature of the multiple power conversion device is that a plurality of power converters having the same function are used as in the three-phase / single-phase PWM dice converters 1 to 9 in FIG. The operation can be continued even if the container is disconnected.
Assuming a case where the three-phase / single-phase PWM dice converter 4 in FIG. 1 fails, the single-phase AC terminals u and v are short-circuited by electric wires and bus bars, and the sound three-phase / single-phase PWM dice converters 5 and 6 are used. Generate an output voltage. Since the other units are also operated in a balanced manner, each of the two bidirectional semiconductor switches 11 and 14 connected to the three-phase AC terminals r, s, and t of the three-phase / single-phase PWM dice converter 1 of the same group. , 12 and 15 and 13 and 16 are sequentially connected one by one at equal time intervals and short-circuited, and an output voltage is generated by the three-phase / single-phase PWM dice converters 2 and 3. Similarly, three sets of two bidirectional semiconductor switches connected to the three-phase AC terminals r, s, and t of the three-phase / single-phase PWM dice converter 7 of the same group of the remaining units are sequentially set at equal time intervals one by one. The three-phase / single-phase PWM dice converters 8 and 9 generate an output voltage.
With the above correspondence, a three-phase balanced output voltage can be generated, but the maximum output voltage is 2/3 of the normal one, and two connected to each of the three-phase AC terminals r, s, and t. Instead of conducting and short-circuiting three pairs of bidirectional semiconductor switches one by one at regular time intervals, the current direction of the single-phase AC terminals u and v of the three-phase / single-phase PWM dice converters 1 and 7 is detected. Each time the current direction is reversed, one set can be sequentially conducted and short-circuited.

2 to 4 are circuit diagrams showing specific configuration examples of the bidirectional semiconductor switches 11 to 16 shown in FIG. 2 to 4, reference numerals 51, 52, 55, 56, and 59 are IGBTs, 53, 54, 57, 58, and 60 to 63 are diodes.
FIG. 2 shows a semiconductor switch composed of a semiconductor element having a self-blocking capability such as a transistor, IGBT, FET, etc. (IGBT in this figure) and a diode connected to the semiconductor element so that the flow direction is reversed. Two sets of two series connected in reverse polarity are configured as one bidirectional semiconductor switch. When current flows from A to B, it passes through the IGBT 51 and the diode 54, and when current flows from B to A, it passes through the IGBT 52 and the diode 53.
FIG. 3 shows the function of a bidirectional semiconductor switch comprising a semiconductor element (IGBT in this figure) having a self-blocking capability such as a transistor, IGBT or FET, and a diode connected in series with the semiconductor element so that the flow direction is the same direction. A configuration in which two pairs of semiconductor switches are connected in parallel with opposite polarities is configured as one bidirectional semiconductor switch. When current flows from A to B, it passes through the IGBT 55 and the diode 57, and when current flows from B to A, it passes through the IGBT 56 and the diode 58.
Fig. 4 shows the function of a bidirectional semiconductor switch as a single-phase bridge connection of four diodes, and the flow direction of a semiconductor element (IGBT in this figure) having a self-blocking capability such as a transistor, IGBT, FET, etc. is the same in two DC terminals. It is configured as one bidirectional semiconductor switch that is connected in the direction and uses two AC terminals of the single-phase bridge as input / output terminals. When current flows from A to B, it passes through the diode 60, IGBT 59 and diode 63, and when current flows from B to A, it passes through the diode 62, IGBT 59 and diode 61.

FIG. 5 is a circuit diagram of a drive circuit using a power converter of a multiple three-phase pulse width modulation (hereinafter abbreviated as PWM) cycloconverter system according to the second embodiment of the present invention. In the figure, reference numerals 51 to 59 are three-phase / single-phase PWM cycloconverters, 60 is a high-voltage AC motor to be driven, 61 to 66 are bidirectional semiconductor switches, 67 to 69 are filter capacitors, and 71 to 79 are three-phase AC reactors. , 91, 92, 93 are three-phase transformers, 81-89 are secondary windings of the three-phase transformers 91, 92, 93, and 94, 95, 96 are primary windings of the three-phase transformers 91, 92, 93. .
Since the three-phase / single-phase PWM cycloconverters 51 to 59 have the same structure, the three-phase / single-phase PWM cycloconverter 51 will be described. The three-phase / single-phase PWM cycloconverter 51 includes six bidirectional semiconductor switches 61 to 66, three filter capacitors 67 to 69, three-phase AC terminals r, s and t, and single-phase AC terminals u and v. There are six bidirectional semiconductor switches 61 to 66 that are capable of flowing a current in both directions and capable of self-conduction and self-interruption to three-phase AC terminals r, s, t and single-phase AC terminals u, v. Each of them is connected to a three-phase bridge circuit, and the filter capacitors 67 to 69 are delta connected to the three-phase AC terminals r, s, and t.

In general, there are 3 × n combinations of three-phase / single-phase PWM cycloconverters, but FIG. 5 shows nine examples with n = 3 as in FIG. In this example, the three-phase AC terminals r, s, and t of nine three-phase / single-phase PWM cycloconverters 51 to 59 are connected to one set of primary windings via nine three-phase AC reactors 71 to 79, respectively. And 3 × j (j = n / m) sets of m (1 ≦ m ≦ n) three-phase transformers (n = 3 because m = 3, j = 1 That is, a three-phase transformer 91 having one set of primary winding 94 and three sets of secondary windings 81, 84, 87, one set of primary winding 95 and three sets of secondary windings 82, Connected to nine sets of secondary windings 81-89 of a three-phase transformer 92 having 85, 88, a set of primary winding 96 and a three-phase transformer 93 having three sets of secondary windings 83, 86, 89 The primary windings 94 to 96 of the three three-phase transformers 91 to 93 are connected to an AC power source. Instead of the three-phase AC reactors 71 to 79, the leakage inductances of the secondary windings 81 to 89 of the three three-phase transformers 91 to 93 can be used.
The AC terminals u and v of the three single-phase PWM cycloconverters 51 to 53 are connected in series as one unit. Similarly, the AC terminals u of the three single-phase PWM cycloconverters 54 to 56 and 57 to 59 are used. Two units that connect v in series are provided, and one of the three units is connected to form a star connection, and the other is connected to the high-voltage AC motor 60 that is a load.
With the above combination, a power conversion device of a three-phase input, three-phase output multiple PWM cycloconverter system is configured.

  The fundamental wave voltage of the AC output that is output to the single-phase AC terminals u and v of the three three-phase / single-phase PWM cycloconverters (51 to 53, 54 to 56, and 57 to 59 in this example) of each unit is the same. It is controlled so as to be in phase, and the three sets of units are controlled so as to generate AC outputs in which the electrical angle of the fundamental voltage phase is 120 ° different from each other.

Since each of the three-phase / single-phase PWM cycloconverters 51 to {50+ (3 × n)} (51 to 59 in this example) is a single-phase load, the load balance on the power source side is achieved, and the low-order harmonic current is 3 In order to cancel out the secondary windings of the three-phase transformers 91 to 93, the three-phase transformers 91 to 93 are connected to the AC terminals r, s, and the single-phase PWM cycloconverters 51, 54, and 57 of the first unit. 3 connected to the secondary windings 81, 84, 87 of the three-phase transformer 91 connected to t, as well as the AC terminals r, s, t of the single-phase PWM cycloconverters 52, 55, 58 of the second unit. Secondary windings of the three-phase transformer 93 connected to the secondary windings 82, 85, 88 of the phase transformer 92 and the AC terminals r, s, t of the single-phase PWM cycloconverters 53, 56, 59 of the third unit. 83, 86, 89 are equal in induced voltage phase So as to apply the winding at each same condition. In the example of FIG. 5, the secondary windings 81 to 89 of the three three-phase transformers 91, 92, and 93 are connected in a delta connection, and the primary winding 94 of the three-phase transformer 91 is a staggered connection and the secondary windings 81 and 84 are connected. , 87 with an electrical angle of 50 ° behind. The primary winding 95 of the three-phase transformer 92 is wound with an electrical angle of 30 ° with respect to the secondary windings 82, 85 and 88 in a star connection. The primary winding 96 of the three-phase transformer 93 is wound in a staggered manner with an electrical angle of 10 ° behind the secondary windings 83, 86, and 89.
Thus, if each three-phase / single-phase PWM cycloconverter is controlled symmetrically, in principle, a power supply harmonic voltage current having a power supply frequency of the 22nd or lower is not generated.

Since the measures for improving redundancy and the configuration of the bidirectional semiconductor switch are the same as those in the first embodiment, the description thereof will be omitted.
In the above embodiments, an example of a high-voltage AC motor has been described. However, the power conversion device and power conversion method of the multiplex three-phase PWM cycloconverter system of the present invention are not limited to a high-voltage AC motor, and can be applied to all AC motors.

  As described above, if the multiple three-phase PWM cycloconverter of the present invention is used, it is easy to reduce the size because there is no need for a DC circuit as in the inverter system, and the number of elements that are in series in the path from the power source to the load is small. Therefore, the element loss is low and the efficiency is high, and the waveform control of each three-phase / single-phase PWM cycloconverter is performed by the above-described means, so that the input / output voltage current with a low distortion waveform can be obtained and the AC-AC direct conversion is possible. Power can be supplied and regenerated freely, and operation is possible using a sound part even in the event of a failure.

  As described above, the power conversion apparatus of the multiplex three-phase pulse width modulation cycloconverter system of the present invention and the power conversion method using the power conversion apparatus are energy saving, resource saving and downsizing for environmental improvement which are market needs. It can respond to technical issues such as higher efficiency and voltage-current waveform distortion regulation, and it has the effect of increasing redundancy and improving operation reliability, so it is widely used for control of AC motors that require variable speed drive There is a possibility of being used.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a circuit diagram of a drive circuit using a power converter of a multiple three-phase pulse width modulation (hereinafter abbreviated as PWM) cycloconverter system according to a first embodiment of the present invention. FIG. 2 is a circuit diagram showing an example of a specific configuration of the bidirectional semiconductor switch shown in FIG. 1. FIG. 2 is a circuit diagram showing an example of a specific configuration of the bidirectional semiconductor switch shown in FIG. 1. FIG. 2 is a circuit diagram showing an example of a specific configuration of the bidirectional semiconductor switch shown in FIG. 1. It is a circuit diagram of the drive circuit using the power converter device of the multiplexing 3 phase pulse width modulation cycloconverter system of the 2nd example of the present invention. It is a circuit diagram of the drive circuit using the high voltage inverter of the prior art example. It is a conceptual diagram showing 4 quadrant driving | operation by the relationship between the torque and speed of an electric motor. It is a circuit diagram of the drive circuit using the low voltage inverter of a prior art example.

Explanation of symbols

1-9, 51-59 Three-phase / single-phase PWM cycloconverter
10, 60 High-voltage AC motor to be driven
11-16, 61-66 Bidirectional semiconductor switch
17-19, 67-69 Filter capacitor
21-29, 71-79 3-phase AC reactor
30, 91-93 three-phase transformer
31-39, 81-89 Secondary winding of three-phase transformer 30
40, 94-96 Primary winding of three-phase transformer 30
51, 52, 55, 56, 59 IGBT
53, 54, 57, 58, 60-63 Diode
101 Inverter section
102 Smoothing capacitor unit
103 Regenerative converter
104A, 104B AC reactor
105 3-phase transformer
106 Inverter section
107 Smoothing capacitor unit
108 Regenerative converter
109 AC reactor
110 Step-down transformer
111 step-up transformer

Claims (10)

In a power converter for driving a high-voltage AC motor at a variable speed, the power converter includes a single three-phase transformer having a set of primary windings and 3 × n sets of secondary windings, and the secondary winding. 3 × n three-phase reactors respectively connected to the three-phase reactors, and 3 × n three-phase / single-phase pulse width modulation cycloconverters respectively connected to the three-phase reactors, and the primary winding of the three-phase transformer The line is connected to an external AC power source, and the secondary winding is composed of 3 units including the 3-phase reactor and the 3-phase / single-phase pulse width modulation cycloconverter connected in series. The electrical angles between the n pairs of the secondary windings in each unit are different from each other by (60 ° ÷ k) (where 1 ≦ k ≦ n), and the three units have the same phase Secondary windings with electrical angles correspond to each other And connected in series to form n groups including the three-phase reactor and the three-phase / single-phase pulse width modulation cycloconverter connected in series in each unit, and the three-phase / single-phase pulse width modulation cyclo The converter is capable of passing current in both directions and is capable of self-conduction and self-interruption, and is connected to six bidirectional semiconductor switches controlled by pulse width modulation, three filter capacitors, and the three-phase reactor 3 A six-way bidirectional semiconductor switch connected to the three-phase AC terminal and the single-phase AC terminal in a three-phase bridge circuit, respectively, and a filter capacitor; Is connected to a three-phase AC terminal in a delta or star connection, and the bidirectional semiconductor switch is connected to the single phase of the three-phase / single-phase pulse width modulation cycloconverter. The voltage of the AC output output to the AC terminal is controlled to be the same in the same unit, and the electrical angle of the fundamental voltage phase is different by 120 ° between the three units. The single-phase AC terminals of the three-phase / single-phase pulse width modulation cycloconverter in the unit are connected in series, and either terminal at both ends is star-connected between the three sets of units, and the other three The terminal is connected to three input terminals of the external high-voltage AC motor to be driven, and the power converter of the multiplex three-phase pulse width modulation cycloconverter system. In a power converter for driving a high-voltage AC motor at a variable speed, the power converter has m pieces (1 ≦ 1) having one primary winding and 3 × j (j = n / m) secondary windings. m.ltoreq.n) three-phase transformer, 3.times.n three-phase reactors connected to the secondary winding, and 3.times.n three-phase / single-phase pulse width modulation cyclones respectively connected to the three-phase reactors. A converter, wherein the primary winding of the three-phase transformer is connected to an external AC power source, and the secondary winding is connected in series with the three-phase reactor and the three-phase / single-phase pulse width modulation cyclones. Including the converter, the n sets are organized into 3 units, and the electrical angle between the n sets of the secondary windings in each unit is (60 ° ÷ k) (where 1 ≦ k ≦ n ) Each phase is different and the electrical angle of the same phase of the three units Secondary windings corresponding to each other and connected to form a group of n including the three-phase reactor and the three-phase / single-phase pulse width modulation cycloconverter connected in series in each unit. The three-phase / single-phase pulse width modulation cycloconverter is capable of flowing current in both directions, and capable of self-conduction and self-interruption, and six bidirectional semiconductor switches controlled by pulse width modulation and three filters A capacitor, a three-phase AC terminal connected to the three-phase reactor, and a single-phase AC terminal connected to the outside, and the six bidirectional semiconductor switches are connected to the three-phase AC terminal and the single-phase AC terminal. Each is connected to a three-phase bridge circuit, the filter capacitor is delta or star connected to the three-phase AC terminal, and the bidirectional semiconductor switch is the three-phase / single-phase pulse width variable. The voltage of the AC output output to the single-phase AC terminal of the tuned cycloconverter is the same phase in the same unit, and the electrical angle of the fundamental voltage phase is different by 120 ° between the three sets of units. The single-phase AC terminals of the three-phase / single-phase pulse width modulation cycloconverter in the same unit are connected in series, and either terminal at either end is star-connected between the three sets of units. And the other three terminals are connected to the three input terminals of the external high-voltage AC motor to be driven, which is a multiple three-phase pulse width modulation cycloconverter type power converter. The multiple three-phase pulse width modulation cycloconverter type power converter according to claim 1, further comprising means for using a leakage inductance of the secondary winding of the three-phase transformer instead of the three-phase AC reactor. A multiple three-phase pulse width modulation cycloconverter type power converter characterized by the above. 3. The multiple three-phase pulse width modulation cycloconverter type power converter according to claim 2, further comprising means for using a leakage inductance of the secondary winding of the three-phase transformer instead of the three-phase AC reactor. A multiple three-phase pulse width modulation cycloconverter type power converter characterized by the above. 5. The power converter of the multiple three-phase pulse width modulation cycloconverter system according to claim 1, wherein the bidirectional semiconductor switch of the three-phase / single-phase pulse width modulation cycloconverter is a self-conversion unit. A semiconductor switch comprising a semiconductor element having a blocking capability and a diode connected in reverse parallel to the semiconductor element so that the flow direction is reversed is formed by serially connecting two sets of reverse polarity. A multiple three-phase pulse width modulation cycloconverter power converter. 5. The power converter of the multiple three-phase pulse width modulation cycloconverter system according to claim 1, wherein the bidirectional semiconductor switch of the three-phase / single-phase pulse width modulation cycloconverter is white. A semiconductor switch comprising a semiconductor element having a self-blocking capability and a diode connected in series with the semiconductor element so that the flow direction is the same direction is formed by two sets of parallel switches connected in reverse polarity. A multiple three-phase pulse width modulation cycloconverter power converter. 5. The multiple three-phase pulse width modulation cycloconverter type power conversion device according to claim 1, wherein the bidirectional semiconductor switch of the three-phase / single-phase pulse width modulation cycloconverter is a single-phase power converter. The two DC terminals of the four diodes connected to the phase bridge are connected so that a semiconductor element having a self-blocking capability is in the same direction of flow, and the two AC terminals of the single-phase bridge are connected to the input / output terminals. A multiple three-phase pulse width modulation cycloconverter type power conversion device, characterized in that 5. A power conversion method for variable-speed driving of a high-voltage AC motor, wherein the bidirectional semiconductor uses the power converter of the multiple three-phase pulse width modulation cycloconverter system according to any one of claims 1 to 4. The AC output voltage output to the single-phase AC terminal of the three-phase / single-phase pulse width modulation cycloconverter is the same phase in the same unit, and the fundamental voltage phase between the three sets of units is the same. A power conversion method using a multiplex three-phase pulse width modulation cycloconverter system, wherein the high-voltage AC motor is driven at a variable speed by controlling the electrical angle to be 120 ° different from each other by a pulse width modulation system. . 9. The power conversion method of a multiple three-phase pulse width modulation cycloconverter system according to claim 8, wherein m (where 1 ≦ m ≦ n) of the three units of the three-phase / single-phase pulse width modulation cycloconverters. When operating in the state of failure, the single-phase AC terminal of the failed three-phase / single-phase pulse width modulation cycloconverter is short-circuited, and the other two units of the failed three-phase / single-phase pulse width modulation cycloconverter The three groups of two bidirectional semiconductor switches connected to each of the three-phase AC terminals of the three-phase / single-phase pulse width modulation cycloconverter of the same group as in the above are sequentially short-circuited at equal time intervals one by one. And the high-voltage AC motor is driven at a variable speed by the remaining three (n−m) three-phase / single-phase pulse width modulation cycloconverters. A power conversion method using a pulse width modulated cycloconverter. 9. The power conversion method of a multiple three-phase pulse width modulation cycloconverter system according to claim 8, wherein m (where 1 ≦ m ≦ n) of the three units of the three-phase / single-phase pulse width modulation cycloconverters. When operating in the state of failure, the single-phase AC terminal of the failed three-phase / single-phase pulse width modulation cycloconverter is short-circuited, and the other two units of the failed three-phase / single-phase pulse width modulation cycloconverter The three-phase / single-phase pulse width modulation cycloconverters of the same group as described above are connected to each of the three-phase AC terminals, and two bidirectional semiconductor switches are connected to detect the current direction of the single-phase AC terminal. Each time the current direction is reversed, one set is sequentially conducted and short-circuited, and the high-voltage AC current is generated by the remaining three (n−m) three-phase / single-phase pulse width modulation cycloconverters. A power conversion method of a multiple three-phase pulse width modulation cycloconverter system, characterized in that the motive is driven at a variable speed.

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