A Harmonic Detection for Grid Connected PV System under non linear load using cuk converter

International Journal of Electrical and Electronics Engineering
© 2020 by SSRG - IJEEE Journal
Volume 7 Issue 3
Year of Publication : 2020
Authors : S.Kaushik, B.E, Cladwin Annan.C , B.E, M.MadhuriChithra,M.E, J.Kalyan Kumar, B.E, C.Suresh, B.E
: 10.14445/23488379/IJEEE-V7I3P102
pdf
Citation:
MLA Style:

S.Kaushik, B.E, Cladwin Annan.C , B.E, M.MadhuriChithra,M.E, J.Kalyan Kumar, B.E, C.Suresh, B.E, "A Harmonic Detection for Grid Connected PV System under non linear load using cuk converter" SSRG International Journal of Electrical and Electronics Engineering 7.3 (2020): 6-11.

APA Style:

S.Kaushik, B.E, Cladwin Annan.C , B.E, M.MadhuriChithra,M.E, J.Kalyan Kumar, B.E, C.Suresh, B.E,(2020). A Harmonic Detection for Grid Connected PV System under non linear load using cuk converter. SSRG International Journal of Electrical and Electronics Engineering 7(3), 6-11.

Abstract:

This paper proposes a Grid connected PV system using AI controlled CUK converter. Due to the presence of power electronics components in the converter and the inverter harmonics gets occurs in the devices. By using Cuk converter and different types of controller (PI, Fuzzy Logic Controller (FLC), FLC with PI and ANN controller) used in the inverter to reduce the harmonic occurs on the devices. In MATLAB simulink by using FFT analysis harmonics get detected and THD values are mentioned. Simulation results for grid connected PV system for various controllers are presented.Moreover, a Fast Fourier Transform (FFT) analysis is also included in harmonics detection control for injection of extracted solar PV power to the distribution system under grid connected mode and to improve the dynamic behaviour under climate changes. Simulation results of pv system based microgrid are presented under numerous operating states.

References:

[1] Shitole et al., "Grid Interfaced Distributed Generation System With Modified Current Control Loop Using Adaptive Synchronization Technique", IEEE Trans. Ind. Infor, vol. 13, no. 5, pp. 2634-2644, Oct. 2017.
[2] Singh, S. Kumar, C. Jain, "Damped-SOGI-Based Control Algorithm for Solar PV Power Generating System", IEEE Trans. Ind. Appl., vol. 53, no. 3, pp. 1780-1788, May-June 2017. [3] Teng, W. Huang, T. Hsu, C. Wang, "Novel and Fast Maximum Power Point Tracking for Photovoltaic Generation", IEEE Trans. Ind. Electron., vol. 63, no. 8, pp. 4955-4966, Aug. 2016. [4] A. Shitole et al., "Grid Interfaced Distributed Generation System With Modified Current Control Loop Using Aadaptive Synchronization Technique", IEEE Trans. Ind. Infor, vol. 13, no. 5, pp. 2634-2644, Oct. 2017. [5] Huang, R. Kaushik, "An Improved Delayed Signal Cancellation PLL for Fast Grid Synchronization under Distorted and Unbalanced Grid Condition", IEEE Trans. Ind. Appl. Early Access, 2017.
[6] Nabeel Alawadhi, A. Elnady, “Mitigation of Power Quality Problems Using Unified Power Quality Conditioner by an Improved Disturbance Extraction Technique”, 2017 International Conference on Electrical and Computing Technologies and Applications (ICECTA).
[7] Verma, A. K., Singh, B., & Shahani, D. T. (2013). “Current Synchronous Detection based control of grid interfaced Solar Photovoltaic power generating system”, 2013 Annual IEEE India Conference (INDICON).
[8] Verma, A. K., & Singh, B. (2016), “Harmonics and reactive current detection in a grid interfaced PV distribution system”, 2016 IEEE 6th International Conference on Power Systems (ICPS). doi:10.1109/icpes.2016.7584244
[9] Qicheng Huang, Student Member, IEEE, and Kaushik Rajashekara, Fellow, IEEE „„An Improved Delayed Signal Cancellation PLL for Fast Grid Synchronization under Distorted and Unbalanced Grid Condition‟‟ 2017 IEEE conference.
[10] Disturbance Extraction Technique”, 2017 International Conference on Electrical and Computing Technologies and Applications (ICECTA).
[11] Verma, A. K., Singh, B., & Shahani, D. T. (2013). “Current Synchronous Detection based control of grid interfaced Solar Photovoltaic power generating system”, 2013 Annual IEEE India Conference (INDICON).
[12] Verma, A. K., & Singh, B. (2016), “Harmonics and reactive current detection in a grid interfaced PV distribution system”, 2016 IEEE 6th International Conference on Power Systems (ICPS). doi:10.1109/icpes.2016.7584244
[13] Qicheng Huang, Student Member, IEEE, and Kaushik Rajashekara, Fellow, IEEE „„An Improved Delayed Signal
Cancellation PLL for Fast Grid Synchronization under Distorted and Unbalanced Grid Condition‟‟ 2017 IEEE conference.
[14] M. Kabir, Y. Mishra, G. Ledwich, Z. Y. Dong and K. Wong, “Coordinated Control of Grid-Connected Photovoltaic Reactive Power and Battery Energy Storage Systems to Improve the Voltage Profile of a Residential Distribution Feeder,” IEEE Trans. Ind. Infor., vol. 10,no. 2, pp. 967-977, May 2014 
[15] M. Kabir, Y. Mishra, G. Ledwich, Z. Y. Dong and K. Wong, “Coordinated Control of Grid-Connected Photovoltaic Reactive Power and Battery Energy Storage Systems to Improve the Voltage Profile ofa Residential Distribution Feeder,” IEEE Trans. Ind. Infor., vol. 10,no. 2, pp. 967-977, May 2014.
[16] E.Koutroulis, K. Kalaitzakis, and N. C. Voulgaris, “Development of A Microcontroller- Based Photovoltaic Maximum Power Point Tracking Control System”, Transactions on power Electronics, IEEE, vol. 16, August 2002, pp. 46 - 54.
[17] M. G. Villalva, J. R. Gazoli and E. Ruppert F. “Analysis and Simulation of The P&O MPPT Algorithm using Alinearized Array Model”, Power electronics conference, Brazil, 2009.
[18] A. Safri and S. Mekhilef. “Incremental Conductance MPPT Method for PV Systems”, Electrical and Computer Engineering (CCECE). 2011, Canada.
[19] T. Bennett, A. Zilouchian, and R. Messenger, “Perturb and Observe versus Incremental Conductance MPPT Algorithms”, IEEE Transactions On Power Systems.
[20] R. Rawat and S.S.Chandel, “Hill Climbing Techniques For Tracking Maximum Power Point In Solar Photovoltaic Systems-A Review”, (IJSDGE), ISSN No.: 2315-4721, V-2,I-1,2, 2013.
[21] U. R. Yaragatti, A. N. Rajkiran, and B. C. Shreesha, “A Novel Method of Fuzzy Controlled Maximum Power Point Tracking in Photovoltaic Systems”, in Proceedings of IEEE International Conference on Industrial Technology, pp. 1421-1426, 2005.
[22] S.B.Kjaer and J.K.Pedersen, “A Review of Single-Phase Grid-Connected Inverters for Photovoltaic Modules”, VOL.41,NO.5,.
[23] Pandiarajan and R.Muthu, “Mathematical Modeling of Photovoltaic Modulewith Simulink”, ICEES2011,3-5 Jan2011.
[24] T. Tran-Quoc, C. Kieny and S. Bacha, “Behaviour of Grid-Connected Photovoltaic Inverters in Islanding Operation”, 2011 IEEE Trondheim PowerTech.
[25] N.Kroutikova, C.A.Hernandez-Aramburo and T.C.Green, “State-spacemodel of grid-connected inverters under current control mode”, IET Electr. Power Appl.,2007,1,(3),pp.329–338.
[26] A.S.Khalifa and E.F.El Saadany, “Control of Three Phase Grid Connected Photovoltaic Power Systems”, IEEEpp.1–7,September2010.
[27] G.M.S.Azevedo, M.C.Cavalcanti, K.C.Oliveira, F.A.S.NevesandZ.D.Lins, “Evaluation of Maximum Power Point Tracking Methods for Grid Connected Photovoltaic Systems”,IEEE2008.

Key Words:

cuk converter, fuzzy logic, voltage source converter