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Estudio comparativo de técnicas PWM de banda de histéresis para el control de corriente en filtros activos de potencia paralelos

dc.creatorMurillo-Yarce, Duberney
dc.creatorMarulanda-Durango, Jesser J.
dc.creatorEscobar-Mejía, Andrés
dc.date2018-09-14
dc.date.accessioned2021-03-18T21:11:21Z
dc.date.available2021-03-18T21:11:21Z
dc.identifierhttps://revistas.itm.edu.co/index.php/tecnologicas/article/view/1058
dc.identifier10.22430/22565337.1058
dc.identifier.urihttp://test.repositoriodigital.com:8080/handle/123456789/11748
dc.descriptionThis paper evaluates the performance of an active power filter using three hysteresis band current control techniques: fixed-band, adaptive-band, and Space Vector Modulation. The characteristics of each method, along with their behaviour under different operating conditions, are studied by means of time domain simulations. The pq theory is used in all the cases to calculate the current reference, and a proportional controller is implemented to regulate the voltage in the dc bus. Based on the results, the PWM techniques evaluated in this work enable a reduction in the harmonic content of the supply grid currents that ranges from 31% without compensation to 6% after the active power filter is connected. The adaptive hysteresis band method exhibited the worst performance in the elimination of harmonics in grid currents; furthermore, it presented the largest reduction of variations in the switching frequency and requires more calculation time because the band width must be computed at each iteration. In turn, the fixed hysteresis band alternative is the most widely recommended for applications that involve parallel filters because it has a simpler structure that enables its implementation. Finally, the technique that combines space vector modulation and hysteresis band current control produced highly-variable switching frequencies and a more complex implementation.en-US
dc.descriptionEl presente artículo evalúa el desempeño de un filtro activo empleando tres diferentes técnicas de control de corriente de banda de histéresis: banda fija, banda adaptativa y con modulación por vector espacial. En la comparación se estudian las características de cada técnica y mediante simulación se evalúa su desempeño y operación. En todos los casos se emplea la teoría pq para el cálculo de las corrientes de referencia y se emplea un controlador proporcional para regular la tensión del bus de continua. De acuerdo con los resultados, las técnicas PWM evaluadas permiten una reducción del contenido armónico de la corriente de la red de alimentación de 31 % sin compensación, a un 6 %, considerando el filtro activo de potencia. La técnica de banda adaptativa de histéresis presenta el más bajo desempeño en la reducción de armónicos en las corrientes de la red. Además, se tiene que el método de banda fija de histéresis es el más recomendado para aplicaciones de filtros paralelo debido a que posee una estructura más simple que permite su implementación. Los resultados tambien muestran que la técnica de banda adaptativa de histéresis es la que presenta mayor reducción en las variaciones de la frecuencia de conmutación, requiriendo mayor número de operaciones, ya que requiere calcular el ancho de banda en cada iteración. Mientras que la técnica de modulación por vector espacial y banda de histéresis presenta frecuencias de conmutación altamente variables y mayor complejidad en su implementación.es-ES
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dc.languagespa
dc.publisherInstituto Tecnológico Metropolitano (ITM)en-US
dc.relationhttps://revistas.itm.edu.co/index.php/tecnologicas/article/view/1058/1066
dc.relationhttps://revistas.itm.edu.co/index.php/tecnologicas/article/view/1058/1081
dc.relationhttps://revistas.itm.edu.co/index.php/tecnologicas/article/view/1058/1218
dc.relationhttps://revistas.itm.edu.co/index.php/tecnologicas/article/view/1058/1239
dc.relation/*ref*/S. Munir and Y. W. Li, “Residential Distribution System Harmonic Compensation Using PV Interfacing Inverter,” IEEE Trans. Smart Grid, vol. 4, no. 2, pp. 816–827, Jun. 2013. [2] S. D. Chakrabortty, N. Zaveri, and D. Rayajiwala, “Analysis of various control techniques of shunt active filter,” in 2014 International Conference on Green Computing Communication and Electrical Engineering (ICGCCEE), 2014, pp. 1–6. [3] A. A. Gómez, D. M. Yarce, and R. L. S. Cárdenas, “Prototipo para la compensación de armónicos en sistemas trifásicos,” Rev. Tecnura, vol. 20, no. 50, pp. 96–105, 2016.
dc.relation/*ref*/J. J. M. Durango, A. E. Mej\’\ia, and A. A. Gómez, “Estudio comparativo de cinco estrategias de compensación de armónicos en filtros activos de potencia,” Rev. Tecnura, vol. 21, no. 52, pp. 15–31, 2017. [5] T. Demirdelen, M. Inci, K. C. Bayindir, and M. Tumay, “Review of hybrid active power filter topologies and controllers,” in 4th International Conference on Power Engineering, Energy and Electrical Drives, 2013, pp. 587–592. [6] A. M. Hava and N. O. Çetin, “A Generalized Scalar PWM Approach With Easy Implementation Features for Three-Phase, Three-Wire Voltage-Source Inverters,” IEEE Trans. Power Electron., vol. 26, no. 5, pp. 1385–1395, May 2011. [7] M. Kale and E. Ozdemir, “An adaptive hysteresis band current controller for shunt active power filter,” Electr. Power Syst. Res., vol. 73, no. 2, pp. 113–119, Feb. 2005. [8] I. A. Altawil, K. A. Mahafzah, and A. A. Smadi, “Hybrid active power filter based on diode clamped inverter and hysteresis band current controller,” in 2012 2nd International Conference on Advances in Computational Tools for Engineering Applications (ACTEA), 2012, pp. 198–203. [9] S. Xu, J. Zhang, and X. Hu, “Optimal control for shunt active power filter based on adaptive-hysteresis controller and droop controller,” in 2014 17th International Conference on Electrical Machines and Systems (ICEMS), 2014, pp. 3404–3410. [10] M. Kale and E. Ozdemir, “A novel adaptive hysteresis band current controller for shunt active power filter,” in Proceedings of 2003 IEEE Conference on Control Applications, 2003. CCA 2003., 2003, vol. 2, pp. 1118–1123. [11] P. Karuppanan, S. R. Prusty, and K. Mahapatra, “Adaptive-hysteresis current controller based active power filter for power quality enhancement,” in International Conference on Sustainable Energy and Intelligent Systems (SEISCON 2011), 2011, pp. 1–6. [12] S. Swain, P. C. Panda, and B. D. Subudhi, “Three phase shunt Active Power Filter using a new Weighted Adaptive Hysteresis Band Current Controller,” in 2014 International Conference on Circuits, Power and Computing Technologies [ICCPCT-2014], 2014, pp. 781–786. [13] A. Sabo, N. I. Abdulwahab, M. A. M. Radzi, N. F. Mailah, and N. F. A. A. Rahman, “A modified digital hysteresis and artificial neural network (ANN) algorithms in single phase shunt active power filter control,” in 2014 IEEE Innovative Smart Grid Technologies - Asia (ISGT ASIA), 2014, pp. 198–203. [14] G. Adam, A. G. Stan, and G. Livint, “An adaptive hysteresis band current control for three phase shunt active power filter U sing Fuzzy logic,” in 2012 International Conference and Exposition on Electrical and Power Engineering, 2012, pp. 324–329. [15] R. J. Patel, J. C. Patel, and P. J. Patel, “Comparison of vector-based hysteresis current control schemes for three-phase three wire shunt active power filter,” in 2012 IEEE 5th India International Conference on Power Electronics (IICPE), 2012, pp. 1–6. [16] A. R. Mohanty and A. K. Kapoor, “Performance evaluation of HCC and SVPWM current controllers for shunt APF under fault conditions,” in Power Electronics (IICPE), 2010 India International Conference on, 2011, pp. 1–8. [17] S. R. Prusty, S. K. Ram, B. D. Subudhi, and K. K. Mahapatra, “Performance analysis of adaptive band hysteresis current controller for shunt active power filter,” in 2011 International Conference on Emerging Trends in Electrical and Computer Technology, 2011, pp. 425–429. [18] V. Khadkikar, A. Chandra, and B. Singh, “Digital signal processor implementation and performance evaluation of split capacitor, four-leg and three H-bridge-based three-phase four-wire shunt active filters,” IET Power Electron., vol. 4, no. 4, p. 463, 2011. [19] H. Akagi, Y. Kanazawa, K. Fujita, and A. Nabae, “Generalized theory of instantaneous reactive power and its application,” Electr. Eng. Japan, vol. 103, no. 4, pp. 58–66, Jul. 1983. [20] C. Y. Hsu and H. Y. Wu, “A new single-phase active power filter with reduced energy-storage capacity,” IEE Proc. - Electr. Power Appl., vol. 143, no. 1, p. 25, 1996. [21] B. K. Bose, “An adaptive hysteresis-band current control technique of a voltage-fed PWM inverter for machine drive system,” IEEE Trans. Ind. Electron., vol. 37, no. 5, pp. 402–408, 1990. [22] L. P. Ling and N. A. Azli, “SVM based hysteresis current controller for a three phase active power filter,” in PECon 2004. Proceedings. National Power and Energy Conference, 2004., 2004, pp. 132–136. [23] A. Luo, Z. Shuai, M. Li, M. T. Chau, L. Zhou, and T. N. Nguyen, “Generalised design method for improving control quality of hybrid active power filter with injection circuit,” IET Power Electron., vol. 7, no. 5, pp. 1204–1215, May 2014. [24] M. Ucar and E. Ozdemir, “Control of a 3-phase 4-leg active power filter under non-ideal mains voltage condition,” Electr. Power Syst. Res., vol. 78, no. 1, pp. 58–73, Jan. 2008.
dc.rightshttps://creativecommons.org/licenses/by-nc-sa/4.0/en-US
dc.sourceTecnoLógicas; Vol. 21 No. 43 (2018); 91-106en-US
dc.sourceTecnoLógicas; Vol. 21 Núm. 43 (2018); 91-106es-ES
dc.source2256-5337
dc.source0123-7799
dc.subjectActive power filtersen-US
dc.subjectcurrent control techniquesen-US
dc.subjectharmonic compensationen-US
dc.subjecthysteresis banden-US
dc.subjectvector modulationen-US
dc.subjectBanda de histéresises-ES
dc.subjectcompensación de armónicoses-ES
dc.subjectfiltros activoses-ES
dc.subjectmodulación vectoriales-ES
dc.subjecttécnicas de control de corrientees-ES
dc.titleA comparative study of hysteresis band PWM techniques for current control in shunt active power filtersen-US
dc.titleEstudio comparativo de técnicas PWM de banda de histéresis para el control de corriente en filtros activos de potencia paraleloses-ES
dc.typeinfo:eu-repo/semantics/article
dc.typeinfo:eu-repo/semantics/publishedVersion
dc.typeArticlesen-US
dc.typeArtículoses-ES


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