A novel hybrid control strategy for grid-connected PV- battery system under different operating conditions

• Autorzy: Pandey Pawan Kumar , Khatib Ziad El , Kumar Ramesh , Singla Manish , Safaraliev Murodbek , Kamalov Firuz

Identyfikatory

DOI

10.15199/48.2024.09.56

Warianty tytułu

PL

Nowa hybrydowa strategia sterowania dla systemu baterii fotowoltaicznych podłączonego do sieci w różnych warunkach pracy

• Języki publikacji: EN

Abstrakty

EN

This paper presents a new hybrid controller for grid-connected photovoltaic (PV)/Battery systems to handle power fluctuations. To lessen the difficulties brought on by power fluctuations at the DC-link of grid-connected PV/Battery systems, a novel hybrid voltage source converter (VSC) controller and bi-directional battery controller have been designed. The suggested controller efficiently handles problems on the DC and AC sides of the system through performance analysis, improving power quality and reducing harmonic dispersion. In this paper, three cases of PV input environments are analyzed. Furthermore, the performance of the hybrid controller is assessed under a range of environmental situations, indicating its versatility. The MATLAB/Simulink simulation results verify that the suggested controller is effective in improving the grid-connected PV/Battery systems' performance.

PL

W artykule przedstawiono nowy sterownik hybrydowy do systemów fotowoltaicznych (PV)/baterii podłączonych do sieci, umożliwiający obsługę wahań mocy. Aby zmniejszyć trudności spowodowane wahaniami mocy w obwodzie prądu stałego systemów fotowoltaicznych/akumulatorów podłączonych do sieci, zaprojektowano nowatorski hybrydowy sterownik konwertera źródła napięcia (VSC) i dwukierunkowy sterownik akumulatora. Proponowany sterownik skutecznie radzi sobie z problemami po stronie prądu stałego i przemiennego systemu poprzez analizę wydajności, poprawę jakości energii i redukcję rozproszenia harmonicznych. W tym artykule przeanalizowano trzy przypadki środowisk wejściowych PV. Co więcej, wydajność sterownika hybrydowego ocenia się w różnych sytuacjach środowiskowych, co wskazuje na jego wszechstronność. Wyniki symulacji MATLAB/Simulink potwierdzają, że sugerowany sterownik skutecznie poprawia wydajność systemów PV/baterii podłączonych do sieci.

Słowa kluczowe

EN

PV-Battery system; hybrid VSC controller; solar energy; renewable energy sources; energy storage

PL

system PV-Battery; hybrydowy sterownik VSC; energia słoneczna; odnawialne źródła energii; magazynowanie energii

• Wydawca: Wydawnictwo SIGMA-NOT
• Czasopismo: Przegląd Elektrotechniczny
• Rocznik: 2024
• Tom: R. 100, nr 9
• Strony: 287--291
• Opis fizyczny: Bibliogr. 28 poz., rys.

Twórcy

autor

Pandey Pawan Kumar

• Department Electrical Engineering, Gyan Ganga Institute of Technology and Sciences Jabalpur, Jabalpur, Madhya Pradesh 482003 India

• https://orcid.org/0000-0002-5157-2485

autor

Khatib Ziad El

• Department of Electrical Engineering, Canadian University Dubai, Dubai 117781, United Arab Emirates

autor

Kumar Ramesh

• Department of interdisciplinary courses in Engineering, Chitkara University Institute of Engineering and Technology, Chitkara University, Punjab, India 140401

• https://orcid.org/0000-0001-9822-8246

autor

Singla Manish

• Department of interdisciplinary courses in Engineering, Chitkara University Institute of Engineering and Technology, Chitkara University, Punjab, India 140401

• https://orcid.org/0000-0003-1028-2729

autor

Safaraliev Murodbek

• Department of Automated Electrical Systems, Ural Federal University, 19, Mira Street, Yekaterinburg, 620002, Russian Federation

• https://orcid.org/0000-0003-3433-9742

autor

Kamalov Firuz

• Department of Electrical Engineering, Canadian University Dubai, Dubai 117781, United Arab Emirates

• https://orcid.org/0000-0003-3946-0920

Bibliografia

• [1] Kim M, Bae S. Decentralized control of a scalable photovoltaic (pv)-battery hybrid power system. Applied Energy (2017),188, 444–55.
• [2] Merabet A, Ahmed K T, Ibrahim H, Beguenane R, Ghias A . Energy management and control system for laboratory scale microgrid based wind-pv-battery. IEEE Trans Sustain Energy Jan. (2017), 8(1):145–54.
• [3] Ahadi A, Kang S - K, Lee J - H. A novel approach for optimal combinations of wind, pv, and energy storage system in diesel-free isolated communities. Applied Energy (2016),170, 101–15.
• [4] Gupta, Anupma, Vipan Kumar, Shonak Bansal, Mohammed H . Alsharif, Abu Jahid, and Ho - Shin Cho. "A Miniaturized Tri-Band Implantable Antenna for ISM/WMTS/Lower UWB/Wi-Fi Frequencies." Sensors 23, no. 15 (2023): 6989
• [5] Bo D, Li YD, Zheng ZD. Energy management of hybrid DC and AC bus linked microgrid. In: Proceedings of power electronics for distributed generation systems, Hefei, China; (2009), p. 713–6.
• [6] M. Sharmaetal., "Miniaturized Quad-Port Conformal Multi-Band (QPC-MB) MIMO Antenna for On-Body Wireless Systems in Microwave-Millimeter Bands," in IEEE Access, vol. 11, pp. 105982-105999, 2023, doi: 10.1109/ACCESS.2023.3318313.
• [7] Tina G M, Pappalardo F. Grid-connected photovoltaic system with battery storage system into market perspective. In: Proceedings of sustainable alternative energy, Valencia, Spain; (2009), p. 1–7.
• [8] Wang W L, Ge B M , B i D Q, Sun D S. Grid-connected wind farm power control using VRB-based energy storage system. In: Proceeding of energy conversion congress and exposition, Atlanta, USA; (2010), p. 3772–7.
• [9] Jayasinghe S D G, Vilathgamuwa D M, Madawala U K. A battery energy storage interface for wind power systems with the use of grid side inverter. In: Proceeding of energy conversion congress and exposition, Atlanta, USA; (2010), p. 3786–91.
• [10] Ge Baoming, Wang Wenliang, B i Daqiang, Rogers Craig B, et. al. Energy storage system-based power control for grid-connected wind power farm. Int J Electr Power Energy Syst (2013), 44(1):115–22.
• [11] Sebastian R. Modelling and simulation of a high penetration wind diesel system with battery energy storage. Int J Electr Power Energy Syst 2011; 33(3):747–67.
• [12] Liu X, Wang P , Loh P C. A hybrid AC/DC microgrid and its coordination control. IEEE Trans Smart Grid June (2011), 2(2):278–86.
• [13] Ma T, Cintuglu M H, Mohammed O A. Control of hybrid ac/dc microgrid involving energy storage and pulsed loads. IEEE Trans Ind Appl (2017)б 53(1):567–75.
• [14] Mahmud N, Zahedi A, Mahmud A. A cooperative operation of novel pv inverter control scheme and storage energy management system based on anfis for voltage regulation of grid-tied pv system. IEEE Trans Ind Inform (2017),13(5):2657–68.
• [15] Rahimi - Eichi H, Baronti F, Chow M - Y. Online adaptive parameter identification and state-of-charge coestimation for lithium-polymer battery cells. IEEE Trans Ind Electron (2014), 61(4):2053–61.
• [16] Wang L, Wang L, Liao C. Research on improved EKF algorithm applied on estimate EV battery SOC. In: Proc. of Asia-Pacific Power and Energy Engineering Conf .,2010, p. 1– 4.
• [17] P.K. Pandey, and K .S. Sandhu, “Multi Diode Modelling of PV Cell,” Power Electronics (IICPE). 2014 IEEE 6th India International Conference, (2014), pp. 1-4,.
• [18] J Hua, Y Shana, Y Xub and J M Guerreroc. A coordinated control of hybrid ac/dc microgrids with PV-windbattery under variable generation and load conditions. Electrical Power and Energy Systems. (2019), 104, 583–592.
• [19] Asanova S.M., et. al. Optimization of the structure of autonomous distributed hybrid power complexes and energy balance management in them, International Journal of Hydrogen Energy 46.70 (2021), 34542-34549.
• [20] Safaraliev M. Kh., Odinaev I .N., Ahyoev J.S., Rasulzoda Kh. N., Otashbekov R.A. Energy Potential Estimation of the Region’s Solar Radiation Using a Solar Tracker, Applied Solar Energy 56 (2020), 270-275.
• [21] Asanov M.S. et al., The use of Petri computing networks for optimization of the structure of distribution networks to minimize power losses. Energy Reports, 6 (2020), 1337-1343
• [22] Dzhuraev S., Beryozkina S., Kamolov M., Safaraliev M., Zicmane I., Nazirov K., & Sultonov S. Computation of the zero-wire current under an asymmetric nonlinear load in a distribution network. Energy Reports, (2022), 8, 563-573.
• [23] Ghulomzoda A. et al., Recloser-Based Decentralized Control of the Grid with Distributed Generation in the Lahsh District of the Rasht Grid in Tajikistan, Central Asia, Energies, 13 (2020), p. 3673.
• [24] Asanov M.S. et al., Algorithm for calculation and selection of micro hydropower plant taking into account hydrological parameters of small watercourses mountain rivers of Central Asia, Int. J. Hydrogen Energy, 46 (2021), № 75, 37109-37119.
• [25] Ghulomzoda A. et al, A Novel Approach of Synchronization of Microgrid with a Power System of Limited Capacity. Sustainability, 13(2021), p. 13975.
• [26] P.K. Pandey, and K.S. Sandhu, “Analysis of Integrated Grid-Connected PV/Battery System under Various Operating Conditions,” Design Engineering, vol. 2021, Issue 07, pp. 9909-9918, (2021).
• [27] P. Pandey, K.S. Sandhu, “Integrated Grid-connected Hybrid Power Generating System with Optimized PLL-based Power Control,” Walailak Journal of Science and Technology (WJST), vol. 18(16), (2021), pp. 1-18.
• [28] Q Jia, G Yan, Y CAI, Y Liand J Zhang. Small-signal stability analysis of photovoltaic generation connected to weak AC grid. J. Mod. Power Syst. Clean Energy. (2019), p. 254– 267.

Uwagi

Opracowanie rekordu ze środków MNiSW, umowa nr POPUL/SP/0154/2024/02 w ramach programu "Społeczna odpowiedzialność nauki II" - moduł: Popularyzacja nauki i promocja sportu (2025).