Harmonic modelling of controlled converters using averaged differential equation method
محورهای موضوعی : مدل سازی انرژی های تجدیدپذیرatila eskandarnezhad 1 , Nowruz Abdollahi 2
1 - Department of Electrical Engineering, Aliabad Katoul Branch, Islamic Azad University, Aliabad Katoul, Iran
2 - Department of Electrical Engineering, Aliabad Katoul Branch, Islamic Azad University, Aliabad Katoul, Iran
کلید واژه: numerical equation, line commutaion, harmonic model,
چکیده مقاله :
Modeling helps the designer to get a correct understanding of the variables in the system and to make the final hardware accurately. This article presents a mathematical numerical method based on recursive differential equations to calculate voltage and current harmonics, which can be applied to converters that have semiconductor switches with line commutation, such as thyristor, triac, diode, Dyak, Gto, Sith, etc. The characteristic curves of these switches are all non-linear, so they cannot be modeled with conventional linear methods. In the proposed method, the characteristic curve of the switch is first considered, and then the current-voltage relational diagram of the switch is extracted. Then the impedance and transfer matrices related to the linear elements are determined by the method of mesh and knot theory. Then, the block diagram of the converter system, which includes differential operators, is determined. In converters with line commutation, the key fire angle is known and the main problem is that the off angle is dependent on the circuit conditions at any moment. Here, by applying the recursive differential calculation method based on the multivariable Rang-Kottai equation, the instantaneous values of the converter parameters are calculated. After performing the calculations, the off angle of the keys is determined and after that the range of harmonics can be determined up to the desired component and the final numerical model is extracted. Finally, the simulation results have been compared with the proposed analytical-algebraic method, which shows the efficiency of this method in estimating the voltage and current of switches.
[1] Nilsson SL, de Mattos Tenório AR, Sen S, Taylor A, Xu S, Zhao G, Song Q, Lei B ,"Application examples of the thyristor series capacitor". Flexible Transmission Systems: FACTS: 585–643, 2020.
[2] G. T. Sayah, A. H. A. Zekry, H. F. Ragaie and F. A. Soliman, “A SPICE model of a thyristor with high injection effects and conductivity modulation,” in Proc. 15th Int. Conf. on Microelectronics (ICM), pp. 344-347, Cairo, Egypt, Dec. 2003.
[3] She X, Huang AQ, Lucía Ó, Ozpineci B, "Review of silicon carbide power devices and their applications". IEEE Trans Ind Electron 64:8193–8205, 2017.
[4] J. Wang, Y. Du, S. Bhattacharya, and A. Q. Huang, "Characterization, modeling of 10-kV SiC JBS diodes and their application prospect in X-ray generators," IEEE Energy
[5] Vazquez S, Leon JI, Franquelo LG, Rodriguez J, Young HA, Marquez A, Zanchetta P ,"Model predictive control: a review of its applications in power electronics". IEEE Electron Mag 16–31, 2014.
[6] Paisana, J. and Abreu Santos, H., "Applications of phase‐plane analysis to thyristor modeling ", COMPEL- The international journal for computation and mathematics in electrical engineering, Vol. 26 No. 4, pp. 1134-1141, 2007.
[7] Z. Song, Y. Huo, and Y. Pang, “The research on transient analysis and auxiliary circuit of power thyristor,” in proc. 4th. Int. Conf. on Electric Utility, DRPT, pp. 1667-1670, Shandong, China, 2011.
[8] C. P. Basso, Switch Mode Power Supplies: SPICE Simulation and Practical Designs, 1nd Edition, McGraw - Hill, pp. 100-108, 2008.
[9] S. B. Tiab, L. N. Hulley, Z. Wu, and W. Shepherd, “Thyristor switch model for power electronic circuit simulation in modified SPICE2,” IEEE Trans.Power Electronic, vol.7, no.3, pp.568, 1992.
[10] J. Bernardes, and D. Dahlgren, “Modeling and analysis of thyristor and diode reverse recovery in railgun pulsed power circuits,” in Proc. Conf. on Pulsed Power, pp. 79-82, Montery, USA, 2005.
[11] Zhou C-N, Yue R-F, Wang Y, Zhang J, Dai G, Li J-T ,"10-kV 4H-SiC gate turn-off thyristors with space-modulated buffer trench three-step JTE". IEEE Electron Device Letters 39:1199–1202, 2018.
[12] A. K. Agarwal, Q. C. J. Zhang, R. Callanan, C. Capell, A. A. Burk, "9 kV, 1 cm2 SiC gate turn-off thyristors," in Materials Science Forum, pp. 1017–1020, 2010.
Conversion Congress and Exposition, pp. 1488–1493, 2009.
[13] S.R.Sanders, “Justification of the Describing Function Method for Periodically Switched Circuits”, IEEE Conf., pp. 1887-1890, 1992.
[14] S. Chiniforoosh, J. Jatskevich, V. Dinavahi, R. Iravani, J. A. Martinez, A. Ramirez, “Dynamic average modeling of line-commutated converters for power systems applications,” IEEE PES General Meeting, PES ’09,pp. 1-8, July 2009