FEASIBILITY OF BOTH VECTOR CONTROL AND DISPLACEMENT FACTOR CORRECTION BY VOLTAGE-SOURCE TYPE AC-AC MATRIX CONVERTER

被引：13

作者：

KAZERANI, M

OOI, BT

机构：

[1] Department of Electrical Engineering, McGill University, Montreal

来源：

IEEE TRANSACTIONS ON INDUSTRIAL ELECTRONICS | 1995年 / 42卷 / 05期

基金：

加拿大自然科学与工程研究理事会;

关键词：

D O I：

10.1109/41.464616

中图分类号：

TP [自动化技术、计算机技术];

学科分类号：

0812 ;

摘要：

This paper shows that by transforming both sides of the matrix converter to the d-q-o frames of their respective frequencies, there is significant simplification in the transformation matrix which enables the network of one side to be integrated to the other. Thus, it is possible to design for operation with field vector control on the motor side and unity displacement factor on the supply side. Laboratory experimental and digital simulation results are presented to substantiate the theory. The matrix converter used in the test is based on three modules of voltage-source SPWM converters [1] to implement the nine switches and it has the innovative feature that the SVC voltages (for displacement factor improvement) can be derived from the zero-sequence voltages.

引用

页码：524 / 530

页数：7

共 14 条

[1] Kazerani M., Ooi B.T., Direct ac–ac matrix converter based on three-phase voltage-source converter modules, Proc. IEEE IECON '93, 2, pp. 812-817
[2] Gyugyi L., Pelly B.P., Static Power Frequency Changers: Theory, Performance and Application, (1976)
[3] Venturini M., Alesina A., The generalized transformer: A new bidirectional sinusoidal waveform frequency converter with continuously adjustable input power factor, Proc. IEEE Power Electron. Specialists, pp. 242-252, (1980)
[4] Burany N., Safe control of four-quadrant switches, Proc. IEEE Ind. Applicat. Soc. Conf., pp. 1190-1194, (1989)
[5] Huber L., Borojevic D., Space vector modulation with unity power factor for forced commutated cycloconverters, Proc. IEEE Ind. Applicat. Soc. Conf., 1, pp. 1032-1041, (1991)
[6] Roy G., April G.E., Direct frequency changer operating under a new scalar control algorithm, IEEE Trans. Power Electron, 6, 1, pp. 100-107, (1991)
[7] Holmes D.G., Lipo A., Implementation of a controlled rectifier using ac–ac matrix converter theory, IEEE Trans. Power Electron, 7, 1, pp. 240-250, (1992)
[8] Ziogas P.D., Khan S.I., Rashid M.H., Some improved forced commutated cycloconverter structures, IEEE Trans. Ind. Applicat, IA-21, 5, pp. 1242-1253, (1985)
[9] Tenti P., Malesani L., Rossetto L., Optimum control of N-input K-output matrix converters, IEEE Trans. Power Electron, 7, 4, pp. 707-713, (1992)
[10] Ooi B.T., Kazerani M., Application of dyadic matrix converter theory in conceptual design of dual field vector and displacement factor controls, IEEE Ind. Applicat. Soc. Conf. Rec., 2, pp. 903-910, (1994)

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