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GÜÇ KALİTESİ SORUNLARINI ÇÖZMEK İÇİN FOTOVOLTAIK (PV) PANEL DESTEKLİ BİRLEŞİK GÜÇ KALİTESİ DÜZENLEYİCİSİ İÇİN YENİ BİR DENETLEYİCİ

Year 2021, Volume: 7 Issue: 1, 14 - 24, 29.06.2021
https://doi.org/10.22531/muglajsci.833386

Abstract

Bu çalışmada, enerji sistemlerindeki güç kalitesi sorunlarını çözmek için fotovoltaik (PV) panel destekli üç fazlı birleşik güç kalitesi düzenleyicisinde (PV-UPQC) senkron referans çerçevesine (SRF) dayanan yeni bir denetleyici önerilmiştir. PV panel sistemi tarafından üretilen enerji ile beslenen seri ve paralel aktif güç filtreleri, PV-UPQC sisteminde birlikte kullanılmaktadır. Önerilen denetleyicide, güç sisteminin dört farklı noktasından ölçüm değerleri alınır. Elde edilen değerler ve PV paneller tarafından üretilen DC gerilim, referans akım ve gerilim değerlerinin hesaplanmasında kullanılmaktadır. Aktif filtrelerde kullanılan anahtarların PWM sinyalleri hareketli ortalama filtre ve uzay vektör-PWM yöntemleri kullanılarak üretilmektedir. Her iki filtrede de kullanılan algoritma iki bölümden oluşmaktadır. Birincisi, maksimum gerilimin PV panellerinden elde edildiği mppt algoritması ve ikincisi, referans akımın veya gerilimin elde edildiği SRF tabanlı önerilen denetleyici algoritmasıdır. Önerilen denetleyicinin simülasyon ve deneysel çalışmaları yapılmıştır. Elde edilen sonuçlar incelendiğinde, üç fazlı PV-UPQC için önerilen denetleyici, akım ve gerilimdeki harmoniklerin azaltılmasında geleneksel SRF tabanlı denetleyiciden daha iyi sonuçlar vermektedir.

References

  • Ram, J.P., Rajasekar, N. and Miyatake, M., “Design and overview of maximum power point tracking techniques in wind and solar photovoltaic systems: A review”, Renewable and Sustainable Energy Reviews, Vol.73, 1138-1159, 2017.
  • Brenna, M., Faranda, R. and Tironi, E. “A new proposal for power quality and custom power improvement: OPEN UPQC”, IEEE T. Power Delivery, Vol.24, No.4, 2107-2116, 2009.
  • Dash, S.K. and Ray, P.K. “Design and analysis of grid connected photovoltaic fed unified power quality conditioner”, International Journal of Emerging Electric Power Systems, Vol.17, No.3, 301-310, 2016.
  • Devassy, S. and Singh, B. “Modified pq-theory-based control of solar-PV-integrated UPQC-S”, IEEE T. Industry Applications, Vol.53, No.5, 5031-5040, 2017.
  • Khadkikar, V. and Chandra, A. “A new control philosophy for a unified power quality conditioner (UPQC) to coordinate load-reactive power demand between shunt and series inverters”, IEEE T. Power Delivery, Vol.23, No.4, 2522-2534, 2008.
  • Akçay, M. T., and Arifoğlu, U., “Anlık Güç Kuramı ile Dengesiz Yükler İçin SAGF Uygulaması”, Haliç University, Journal of Science, Vol.2, No.1, 1-16, 2019.
  • Akçay, M. T., and Kocaarslan, I., “1500 V DC Beslemeli Raylı Sistemlerde Gerilim Harmoniği Probleminin AGT Tabanlı Paralel Aktif Güç Fitresi ile Çözümü”, International Journal of Advances in Engineering and Pure Sciences, Vol.32, No.4, 365-373, 2020.
  • Cavalcanti, M.C., Azevedo, G.M.S., Amaral, B.A., Neves, F.A.S., “A photovoltaic generation system with unified power quality conditioner function”, IEEE Annual Conference of Industrial Electronics Society, 2005, 750-755.
  • Dharmalingam, R., Dash, S.S., Senthilnathan, K., Mayilvaganan, A.B., and Chinnamuthu, S., “Power quality improvement by unified power quality conditioner based on CSC topology using synchronous reference frame theory”, The Scientific World Journal, Vol.2014, 1-7, 2014.
  • Kesler, M., and Ozdemir, E., “Synchronous-reference-frame-based control method for UPQC under unbalanced and distorted load conditions”, IEEE T. Industrial Electronics, Vol.58, No.9, 3967-3975, 2010.
  • Onal, Y., Ucgun, H., “Low Total Harmonic Distortion and High Power Factor in Parallel Active Power Filter”, International Journal of Scientific and Technological Research, Vol.5, No.2, 52-62, 2019.
  • Dash, S.K., and Ray, P.K., “Novel PV‐tied UPQC topology based on a new model reference control scheme and integral plus sliding mode dc‐link controller”, International Transactions on Electrical Energy Systems, Vol.28, No.7, 1-26, 2018.
  • Mesbahi, N., Ouari, A., Abdeslam, D.O., Djamah, T., and Omeiri, A., “Direct power control of shunt active filter using high selectivity filter (HSF) under distorted or unbalanced conditions”, Electric Power Systems Research, No.108, 113-123, 2014.
  • Rao, K., and Srikanth, K. S., “Improvement of power quality using fuzzy logic controller in grid connected photovoltaic cell using UPQC”, International Journal of Power Electronics and Drive Systems, Vol.5, No1, 101-111, 2014.
  • Pal, Y., Swarup, A., and Singh, B., “Star-hexagon transformer supported UPQC”, International Journal of Electrical and Electronics Engineering, Vol.5, No.1, pp.63-68, 2011.
  • Reisi, A. R., Moradi, M. H., and Showkati, H., “Combined photovoltaic and unified power quality controller to improve power quality”, Solar Energy, Vol.88, 154-162. 2013.
  • Khadkikar, V., Agarwal, P., Chandra, A., Barry, A., and Nguyen, T., “A simple new control technique for unified power quality conditioner (UPQC)”, In: Proc. 11th IEEE ICHQP, 2004, 289–93.
  • Bouzelata, Y., Kurt, E., Chenni, R., and Altın, N., “Design and simulation of a unified power quality conditioner fed by solar energy”, International journal of hydrogen energy, Vol.40, No.44, 15267-15277, 2015.
  • Cheung, V.S.P., Yeung, R.S.C., Chung, H.S.H., and Lo, A.W.L., “A transformer-less unified power quality conditioner with fast dynamic control”, IEEE T. Power Electr., Vol.33, No.5, 3926-3937, 2017.
  • Palanisamy, K., Kothari, D.P., Mishra, M.K., Meikandashivam, S., and Raglend, I.J., “Effective utilization of unified power quality conditioner for interconnecting PV modules with grid using power angle control method”, International journal of electrical power & energy systems, 48, 131-138, 2013.
  • da Silva, S.A.O., and Negrão, F.A., “Single-phase to three-phase unified power quality conditioner applied in single-wire earth return electric power distribution grids”, IEEE T. Power Electr., Vol.33, No.5, 3950-3960, 2017.
  • Devassy, S., and Singh, B., “Design and performance analysis of three-phase solar PV integrated UPQC”, IEEE T. Industry Applications, Vol.54, No.1, 73-81, 2017.
  • Badran, M.A., Tahir, A.M., and Faris, W.F., “Digital implementation of space vector pulse width modulation technique using 8-bit microcontroller”, World Applied Sciences Journal, Vol.21, 21-28, 2013.
  • Celanovic, N., Boroyevich, D., “A fast space-vector modulation algorithm for multilevel three-phase converters”, IEEE transactions on industry applications, Vol.37, No.2, 637-641, 2001.
  • Shankar, M., Monisha, S., Shesna, H., Vignesh, T., Sikkandar, N., Sundaramoorthi, S., and Venkatesh, S., “Implementation of space vector pulse width modulation technique with genetic algorithm to optimize unified power quality conditioner”, American Journal of Applied Sciences, Vol.11, No.1, 152-159, 2014.
  • Villalva, M.G., Gazoli, J.R., and Ruppert, F.E., “Comprehensive approach to modeling and simulation of photovoltaic arrays”, IEEE Transactions on power electronics, Vol.24, No.5, 1198-1208, 2009.
  • Kota, V.R., and Bhukya, M.N., “A novel linear tangents based P&O scheme for MPPT of a PV system”, Renewable and Sustainable Energy Reviews, Vol.71, 257-267, 2017.
  • Monteiro, L.F., Aredes, M., and Neto, J.M., “A control strategy for unified power quality conditioner”, IEEE International Symposium on Industrial Electronics, Vol.1, 391-396, 2003.

A NEW CONTROLLER FOR PHOTOVOLTAIC PANEL FED UNIFIED POWER QUALITY CONDITIONER TO POWER QUALITY IMPROVEMENT

Year 2021, Volume: 7 Issue: 1, 14 - 24, 29.06.2021
https://doi.org/10.22531/muglajsci.833386

Abstract

In this study, a new controller based on the synchronous reference frame (SRF) in a photovoltraic (PV) panel supported three-phase unified power quality conditioner (PV-UPQC ) is proposed to solve power quality problems in power systems. The serial and parallel active power filters fed with energy by PV panels are used together in the PV-UPQC system. In the proposed controller, measurement values are taken from four different points of the power system. The obtained values and DC voltage generated by PV panels are used to calculate the reference current and voltage values. PWM signals of switches used in active filters are produced using moving average filter and space vector-PWM. The algorithm used in both filters consists of two parts. The first is the mppt algorithm, in which the maximum voltage is obtained from the PV panels, and the second is the SRF-based proposed algorithm, where the reference current or voltage is obtained. Simulation and experimental studies of the proposed controller are applied. When the results obtained are examined, the proposed controller for three-phase PV-UPQC gives better results than the traditional SRF based controller in attenuation of harmonics in current and voltage.

References

  • Ram, J.P., Rajasekar, N. and Miyatake, M., “Design and overview of maximum power point tracking techniques in wind and solar photovoltaic systems: A review”, Renewable and Sustainable Energy Reviews, Vol.73, 1138-1159, 2017.
  • Brenna, M., Faranda, R. and Tironi, E. “A new proposal for power quality and custom power improvement: OPEN UPQC”, IEEE T. Power Delivery, Vol.24, No.4, 2107-2116, 2009.
  • Dash, S.K. and Ray, P.K. “Design and analysis of grid connected photovoltaic fed unified power quality conditioner”, International Journal of Emerging Electric Power Systems, Vol.17, No.3, 301-310, 2016.
  • Devassy, S. and Singh, B. “Modified pq-theory-based control of solar-PV-integrated UPQC-S”, IEEE T. Industry Applications, Vol.53, No.5, 5031-5040, 2017.
  • Khadkikar, V. and Chandra, A. “A new control philosophy for a unified power quality conditioner (UPQC) to coordinate load-reactive power demand between shunt and series inverters”, IEEE T. Power Delivery, Vol.23, No.4, 2522-2534, 2008.
  • Akçay, M. T., and Arifoğlu, U., “Anlık Güç Kuramı ile Dengesiz Yükler İçin SAGF Uygulaması”, Haliç University, Journal of Science, Vol.2, No.1, 1-16, 2019.
  • Akçay, M. T., and Kocaarslan, I., “1500 V DC Beslemeli Raylı Sistemlerde Gerilim Harmoniği Probleminin AGT Tabanlı Paralel Aktif Güç Fitresi ile Çözümü”, International Journal of Advances in Engineering and Pure Sciences, Vol.32, No.4, 365-373, 2020.
  • Cavalcanti, M.C., Azevedo, G.M.S., Amaral, B.A., Neves, F.A.S., “A photovoltaic generation system with unified power quality conditioner function”, IEEE Annual Conference of Industrial Electronics Society, 2005, 750-755.
  • Dharmalingam, R., Dash, S.S., Senthilnathan, K., Mayilvaganan, A.B., and Chinnamuthu, S., “Power quality improvement by unified power quality conditioner based on CSC topology using synchronous reference frame theory”, The Scientific World Journal, Vol.2014, 1-7, 2014.
  • Kesler, M., and Ozdemir, E., “Synchronous-reference-frame-based control method for UPQC under unbalanced and distorted load conditions”, IEEE T. Industrial Electronics, Vol.58, No.9, 3967-3975, 2010.
  • Onal, Y., Ucgun, H., “Low Total Harmonic Distortion and High Power Factor in Parallel Active Power Filter”, International Journal of Scientific and Technological Research, Vol.5, No.2, 52-62, 2019.
  • Dash, S.K., and Ray, P.K., “Novel PV‐tied UPQC topology based on a new model reference control scheme and integral plus sliding mode dc‐link controller”, International Transactions on Electrical Energy Systems, Vol.28, No.7, 1-26, 2018.
  • Mesbahi, N., Ouari, A., Abdeslam, D.O., Djamah, T., and Omeiri, A., “Direct power control of shunt active filter using high selectivity filter (HSF) under distorted or unbalanced conditions”, Electric Power Systems Research, No.108, 113-123, 2014.
  • Rao, K., and Srikanth, K. S., “Improvement of power quality using fuzzy logic controller in grid connected photovoltaic cell using UPQC”, International Journal of Power Electronics and Drive Systems, Vol.5, No1, 101-111, 2014.
  • Pal, Y., Swarup, A., and Singh, B., “Star-hexagon transformer supported UPQC”, International Journal of Electrical and Electronics Engineering, Vol.5, No.1, pp.63-68, 2011.
  • Reisi, A. R., Moradi, M. H., and Showkati, H., “Combined photovoltaic and unified power quality controller to improve power quality”, Solar Energy, Vol.88, 154-162. 2013.
  • Khadkikar, V., Agarwal, P., Chandra, A., Barry, A., and Nguyen, T., “A simple new control technique for unified power quality conditioner (UPQC)”, In: Proc. 11th IEEE ICHQP, 2004, 289–93.
  • Bouzelata, Y., Kurt, E., Chenni, R., and Altın, N., “Design and simulation of a unified power quality conditioner fed by solar energy”, International journal of hydrogen energy, Vol.40, No.44, 15267-15277, 2015.
  • Cheung, V.S.P., Yeung, R.S.C., Chung, H.S.H., and Lo, A.W.L., “A transformer-less unified power quality conditioner with fast dynamic control”, IEEE T. Power Electr., Vol.33, No.5, 3926-3937, 2017.
  • Palanisamy, K., Kothari, D.P., Mishra, M.K., Meikandashivam, S., and Raglend, I.J., “Effective utilization of unified power quality conditioner for interconnecting PV modules with grid using power angle control method”, International journal of electrical power & energy systems, 48, 131-138, 2013.
  • da Silva, S.A.O., and Negrão, F.A., “Single-phase to three-phase unified power quality conditioner applied in single-wire earth return electric power distribution grids”, IEEE T. Power Electr., Vol.33, No.5, 3950-3960, 2017.
  • Devassy, S., and Singh, B., “Design and performance analysis of three-phase solar PV integrated UPQC”, IEEE T. Industry Applications, Vol.54, No.1, 73-81, 2017.
  • Badran, M.A., Tahir, A.M., and Faris, W.F., “Digital implementation of space vector pulse width modulation technique using 8-bit microcontroller”, World Applied Sciences Journal, Vol.21, 21-28, 2013.
  • Celanovic, N., Boroyevich, D., “A fast space-vector modulation algorithm for multilevel three-phase converters”, IEEE transactions on industry applications, Vol.37, No.2, 637-641, 2001.
  • Shankar, M., Monisha, S., Shesna, H., Vignesh, T., Sikkandar, N., Sundaramoorthi, S., and Venkatesh, S., “Implementation of space vector pulse width modulation technique with genetic algorithm to optimize unified power quality conditioner”, American Journal of Applied Sciences, Vol.11, No.1, 152-159, 2014.
  • Villalva, M.G., Gazoli, J.R., and Ruppert, F.E., “Comprehensive approach to modeling and simulation of photovoltaic arrays”, IEEE Transactions on power electronics, Vol.24, No.5, 1198-1208, 2009.
  • Kota, V.R., and Bhukya, M.N., “A novel linear tangents based P&O scheme for MPPT of a PV system”, Renewable and Sustainable Energy Reviews, Vol.71, 257-267, 2017.
  • Monteiro, L.F., Aredes, M., and Neto, J.M., “A control strategy for unified power quality conditioner”, IEEE International Symposium on Industrial Electronics, Vol.1, 391-396, 2003.
There are 28 citations in total.

Details

Primary Language English
Subjects Engineering
Journal Section Journals
Authors

Yasemin Önal 0000-0003-0173-0948

Publication Date June 29, 2021
Published in Issue Year 2021 Volume: 7 Issue: 1

Cite

APA Önal, Y. (2021). A NEW CONTROLLER FOR PHOTOVOLTAIC PANEL FED UNIFIED POWER QUALITY CONDITIONER TO POWER QUALITY IMPROVEMENT. Mugla Journal of Science and Technology, 7(1), 14-24. https://doi.org/10.22531/muglajsci.833386
AMA Önal Y. A NEW CONTROLLER FOR PHOTOVOLTAIC PANEL FED UNIFIED POWER QUALITY CONDITIONER TO POWER QUALITY IMPROVEMENT. MJST. June 2021;7(1):14-24. doi:10.22531/muglajsci.833386
Chicago Önal, Yasemin. “A NEW CONTROLLER FOR PHOTOVOLTAIC PANEL FED UNIFIED POWER QUALITY CONDITIONER TO POWER QUALITY IMPROVEMENT”. Mugla Journal of Science and Technology 7, no. 1 (June 2021): 14-24. https://doi.org/10.22531/muglajsci.833386.
EndNote Önal Y (June 1, 2021) A NEW CONTROLLER FOR PHOTOVOLTAIC PANEL FED UNIFIED POWER QUALITY CONDITIONER TO POWER QUALITY IMPROVEMENT. Mugla Journal of Science and Technology 7 1 14–24.
IEEE Y. Önal, “A NEW CONTROLLER FOR PHOTOVOLTAIC PANEL FED UNIFIED POWER QUALITY CONDITIONER TO POWER QUALITY IMPROVEMENT”, MJST, vol. 7, no. 1, pp. 14–24, 2021, doi: 10.22531/muglajsci.833386.
ISNAD Önal, Yasemin. “A NEW CONTROLLER FOR PHOTOVOLTAIC PANEL FED UNIFIED POWER QUALITY CONDITIONER TO POWER QUALITY IMPROVEMENT”. Mugla Journal of Science and Technology 7/1 (June 2021), 14-24. https://doi.org/10.22531/muglajsci.833386.
JAMA Önal Y. A NEW CONTROLLER FOR PHOTOVOLTAIC PANEL FED UNIFIED POWER QUALITY CONDITIONER TO POWER QUALITY IMPROVEMENT. MJST. 2021;7:14–24.
MLA Önal, Yasemin. “A NEW CONTROLLER FOR PHOTOVOLTAIC PANEL FED UNIFIED POWER QUALITY CONDITIONER TO POWER QUALITY IMPROVEMENT”. Mugla Journal of Science and Technology, vol. 7, no. 1, 2021, pp. 14-24, doi:10.22531/muglajsci.833386.
Vancouver Önal Y. A NEW CONTROLLER FOR PHOTOVOLTAIC PANEL FED UNIFIED POWER QUALITY CONDITIONER TO POWER QUALITY IMPROVEMENT. MJST. 2021;7(1):14-2.

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