AC/AC converter

A solid-state AC-AC converter converts an AC waveform to another AC waveform, where the output voltage and frequency can be set arbitrarily.

Categories

Fig 1: Classification of three-phase AC-AC converter circuits.[1]

Referring to Fig 1, AC-AC converters can be categorized as follows:

DC link converters

Fig 2: Topology of (regenerative) voltage-source inverter AC/DC-AC converter[3]
Fig 3: Topology of current-source inverter AC/DC-AC converter[4][5]

There are two types of converters with DC link:

Any dynamic braking operation required for the motor can be realized by means of braking DC chopper and resistor shunt connected across the rectifier. Alternatively, an anti-parallel thyristor bridge must be provided in the rectifier section to feed energy back into the AC line. Such phase-controlled thyristor-based rectifiers however have higher AC line distortion and lower power factor at low load than diode-based rectifiers.

An AC-AC converter with approximately sinusoidal input currents and bidirectional power flow can be realized by coupling a pulse-width modulation (PWM) rectifier and a PWM inverter to the DC-link. The DC-link quantity is then impressed by an energy storage element that is common to both stages, which is a capacitor C for the voltage DC-link or an inductor L for the current DC-link. The PWM rectifier is controlled in a way that a sinusoidal AC line current is drawn, which is in phase or anti-phase (for energy feedback) with the corresponding AC line phase voltage.

Due to the DC-link storage element, there is the advantage that both converter stages are to a large extent decoupled for control purposes. Furthermore, a constant, AC line independent input quantity exists for the PWM inverter stage, which results in high utilization of the converter’s power capability. On the other hand, the DC-link energy storage element has a relatively large physical volume, and when electrolytic capacitors are used, in the case of a voltage DC-link, there is potentially a reduced system lifetime.

Cycloconverters

Main article: Cycloconverter

A cycloconverter constructs an output, variable-frequency, approximately sinusoid waveform by switching segments of the input waveform to the output; there is no intermediate DC link. With switching elements such as SCRs, the output frequency must be lower than the input. Very large cycloconverters (on the order of 10 MW) are manufactured for compressor and wind-tunnel drives, or for variable-speed applications such as cement kilns.

Matrix converters

Fig 4: Topology of the Conventional Direct Matrix Converter [6][7]
Fig 5: Topology of the indirect matrix converter [8][9][10]

In order to achieve higher power density and reliability, it makes sense to consider Matrix Converters that achieve three-phase AC-AC conversion without any intermediate energy storage element. Conventional Direct Matrix Converters (Fig. 4) perform voltage and current conversion in one single stage.

There is the alternative option of indirect energy conversion by employing the Indirect Matrix Converter (Fig. 5) or the Sparse matrix converter which was invented by Prof. Johann W. Kolar from the ETH Zurich. As with the DC-link based VSI and CSI controllers (Fig. 2 and Fig. 3), separate stages are provided for voltage and current conversion, but the DC-link has no intermediate storage element. Generally, by employing matrix converters, the storage element in the DC-link is eliminated at the cost of a larger number of semiconductors. Matrix converters are often seen as a future concept for variable speed drives technology, but despite intensive research over the decades they have until now only achieved low industrial penetration. However, citing recent availability of low-cost, high performance semiconductors, one larger drive manufacturer has over past few years been actively promoting matrix converters.[11]

See also

References

  1. J. W. Kolar, T. Friedli, F. Krismer, S. D. Round, “The Essence of Three-Phase AC/AC Converter Systems”, Proceedings of the 13th Power Electronics and Motion Control Conference (EPE-PEMC'08), Poznan, Poland, pp. 27 – 42, Sept. 1 - 3, 2008.
  2. Lee, M. Y. (2009). Three-level Neutral-point-clamped Matrix Converter Topology (PDF). University of Nottingham. p. 8.
  3. I. Takahashi, Y. Itoh, “Electrolytic Capacitor-Less PWM Inverter“, in Proceedings of the IPEC’90, Tokyo, Japan, , pp. 131 – 138, April 2 – 6, 1990.
  4. K. Kuusela, M. Salo, H. Tuusa, “A Current Source PWM Converter Fed Permanent Magnet Synchronous Motor Drive with Adjustable DC-Link Current“, in Proceedings of the NORPIE’2000, Aalborg, Denmark, pp. 54 – 58, June 15 – 16, 2000.
  5. M. H. Bierhoff, F. W. Fuchs, “Pulse Width Modulation for Current Source Converters – A Detailed Concept,“ in Proceedings of the 32nd IEEE IECON’06, Paris, France, Nov. 7–10, 2006.
  6. L. Gyugyi, B. R. Pelly, “Static Power Frequency Changers - Theory, Performance, & Application“, New York: J. Wiley, 1976.
  7. W. I. Popow, “Der zwangskommutierte Direktumrichter mit sinusförmiger Ausgangsspannung,“ Elektrie 28, No. 4, pp. 194 – 196, 1974
  8. J. Holtz, U. Boelkens, “Direct Frequency Converter with Sinusoidal Line Currents for Speed-Variable AC Motors“, IEEE Transactions Industry Electronics, Vol. 36, No. 4, pp. 475–479, 1989.
  9. K. Shinohara, Y. Minari, T. Irisa, “Analysis and Fundamental Characteristics of Induction Motor Driven by Voltage Source Inverter without DC Link Components (in Japanese)“, IEEJ Transactions, Vol. 109-D, No. 9, pp. 637 – 644, 1989.
  10. L. Wei, T. A. Lipo, “A Novel Matrix Converter Topology with Simple Commutation“, in Proceedings of the 36th IEEE IAS’01, Chicago, USA, vol. 3, pp. 1749–1754, Sept. 30 – Oct. 4, 2001.
  11. Swamy, Mahesh; Kume, Tsuneo (Dec 16, 2010). "Present State and Futuristic Vision of Motor Drive Technology" (PDF). Power Transmission Engineering (www.powertransmission.com). Retrieved Apr 2012.
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