ACO control of three-level series active power filter based fuel cells

Masmoudi, Mohamed; Tedjini, Hamza; Nasri, Abdelfatah

doi:10.15199/48.2023.06.01

Artykuł - szczegóły

Tytuł artykułu

ACO control of three-level series active power filter based fuel cells

Autorzy

Masmoudi Mohamed , Tedjini Hamza , Nasri Abdelfatah

Wybrane pełne teksty z tego czasopisma

http://pe.org.pl/

Identyfikatory

DOI

10.15199/48.2023.06.01

Warianty tytułu

Kontrola ACO trójpoziomowych ogniw paliwowych opartych na filtrze mocy czynnej

Języki publikacji

Abstrakty

Hydrogen has been generally accepted as a power source with productivity with zero emissions ideal for the development of mobile power and stationary electricity. This paper presented an integration of PEMFC into a series filter for preventing the propagation of harmonics and minimizing the current ripple and preserving the AC micro-grid. For better performance, the ants' colony optimization algorithm is used on the software side and three-level NPC in the hardware parts of this filter.

Wodór jest powszechnie akceptowany jako źródło energii o wydajności z zerową emisją, idealne do rozwoju mobilnej i stacjonarnej energii elektrycznej. W artykule przedstawiono integrację PEMFC z filtrem szeregowym w celu zapobiegania propagacji harmonicznych i minimalizacji tętnienia prądu oraz zachowania mikrosieci prądu przemiennego. Aby uzyskać lepszą wydajność, algorytm optymalizacji kolonii mrówek jest używany po stronie oprogramowania, a trzypoziomowy NPC w części sprzętowej tego filtra

Słowa kluczowe

PEMFC ant colony optimization AC microgrid series active power filters three-level NPC inverter

optymalizacja kolonii mrówek mikrosieć AC filtr mocy aktywnej serii trójpoziomowy falownik NPC

Wydawca

Wydawnictwo SIGMA-NOT

Czasopismo

Przegląd Elektrotechniczny

Rocznik

2023

Tom

R. 99, nr 6

Strony

1--6

Opis fizyczny

Bibliogr. 26 poz., rys., wykr.

Twórcy

autor

Masmoudi Mohamed

University TAHRI Mohamed, Bechar 08000

autor

Tedjini Hamza

University TAHRI Mohamed, Bechar 08000

https://orcid.org/0000-0003-1955-951X

autor

Nasri Abdelfatah

University TAHRI Mohamed, Bechar 08000

Bibliografia

1. N. Behzad, H. M. Alireza, B. Andrea, R. Fabio, C. Andrea, Mathematical modelling and parametric study on a 30 kWel high temperature PEM fuel cell based residential micro cogeneration plant,Int J of Hydrogen Energy; pp.1569-1583, (2015).
2. L. James, Fuel Cell Systems Explained, Second Edition, (2003).
3. D. Huiwen , L. Qi , C. Youlong, Z. Yanan, C. Weirong, Nonlinear controller design based on cascadeadaptive sliding mode control for PEM fuel cell air supply systems, Int J of HydrogenEnergy (2018).
4. A. S. Azuki, M. Azah, M. A. Hannan, S. Hussain, A 50kW PEM fuel cell Inverter-Based Distributed Generation System for GridConnected and Islanding Operation, IEEE, pp.4244-4547,(2009).
5. X. Du, L. Zhou, H. Lu, M. H. Tai, DC link active power filter for three-phase diode rectifier, IEEE Trans. Ind. Electron., 59, 3,pp.1430–1442, (2012).
6. M. Angulo, Ruiz-Caballero D A, Lago J, Heldwein M L, Mussa S A. Active power filter control strategy with implicit closedloop current control and resonant controller, IEEE Trans. Ind. Electron., 60, 7, pp. 2721–2730, (2013).
7. J. A. Munoz, J. R. Espinoza, C. R. Baier, L. A. Moran, E. E., P. E. Melin, and D. G. Sbarbaro, Design of a discrete-time linear control strategy for a multicell UPQC, IEEE Trans. Ind. Electron., 59, 10, 3797–3807, (2012).
8. C. S. Lam, W. H. Choi, M. C. Wong, and Y. D. Han, Adaptive dc-link voltage-controlled hybrid active power filters for reactive power compensation, IEEE Trans. Power Electron., 27, 4, 1758–1772, Apr. (2012).
9. A. Kularni, S. Giddey,Materials Issues and Recent Developments in Molten Carbonate Fuel Cells,Springerlink,
10. A. Solovyev, I. Ionov, A. Lauk, S. Linnik, A. Shipilova, E. Smolyanskiy, Fabrication and performance investigation of 3-cell SOFC stack based on anode-supported cells with magnetron sputtered electrolyte, J of Electrochemical Energy Conversion and Storage, 2018.
11. A. Balbay, C. Saka,Semi-methanolysis reaction of potassium borohydride with phosphoric acid for effective hydrogen production, Int J Hydrogen Energy, pp.1-8, (2018).
12. O. Schmidt, A. Gambhir, I. Staffell, A. Hawkes, J. Nelson, S. Few,Future cost and performance of water electrolysis: An expert elicitation study, Int J Hydrogen Energy, 42, pp. 30470-30492, (2017).
13. H. Lund, E. Munster, Integrated energy systems and local energy markets, Energy Policy, 34, pp. 1152–60, (2006).
14. ME. Baran, NRDC. Mahajan, Distribution for industrial system: opportunities and challenges, IEEE Transactions on Industry Applications, 39,6, pp.1596–1601,(2003).
15. C. Rosario, D.R. Francesco,L. Roberto, S. Adolfo, and T. Alfredo, Modeling Waveform Distortion Produced by High Speed AC Locomotive Converters, IEEE Power Tech Conference,Bologna, Italy, (2003). 16. K. Górecki, K. Rogowski, R. Beniak, Three-level NPC Inverter SVM Implementation on Delfino DSC, IFAC-Papers OnLine, 52, 27, pp.252-256, (2019).
17. J.Sathya Priya, K.Saravanan, A.R.Sathyabama, Optimized evolutionary algorithm and supervised ACO mechanism to mitigate attacks and improve performance of adhoc network, Computer Communications, 154, pp. 551-558, (2020).
18. S.Arun, T.Manigandan, Design of ACO based PID controller for zeta converter using reduced order methodology, Microprocessors and Microsystems, 81, (2021).
19. K. Abdelfatah, G. Arnaud, B. Alexandre De, B. Olivier, H. Daniel, K. Zoubir, A review on DC/DC converter architectures for power fuel cell applications,J Energy Conversion and Management, pp. 716–730, (2015).
20. O. Burak, M. T. Leon, D. Zhong, Multiple Input Converters for Fuel Cells, IEEE, pp. 7803-8486, (2004).
21. Uzunoglu M, Alam M. S. Dynamic Modeling, Design, and Simulation of a Combined PEM Fuel Cell and Ultra capacitor System, for Stand-Alone Residential Applications, IEEE trans. on Energy Conversion, 21,3, (2006).
22. Liu C, Amy Johnson, and Jih-Sheng Lai,A Novel Three-Phase High-Power Soft-Switched DC/DC Converter for Low-Voltage Fuel Cell Applications, IEEE trans. on Industry Applications,41,6, (2005).
23. O.Burak, M. T. Leon, D. Zhong, Optimum Fuel Cell Utilization with Multilevel Inverters, IEEE Power Electronics Specialists Conference Aachen, Germany, (2004).
24. X. Yu, M. R. Starke, L. M. Tolbert and B. Ozpineci, Fuel cell power conditioning for electric power applications: a summary, IET Electr. Power Appl., September (2007).
25. D. Huiwen, L. Qi, C. Youlong, Z. Yanan, C. Weirong, Nonlinear controller design based on cascadeadaptive sliding mode control for PEM fuel cell air supply systems, Int J of HydrogenEnergy (2018).
26. S. Yu Jin , Analysis and Design Of High Fequency Link Power Conversions Systems For Fuel Cell Power Conditioning, Phd thesis, University of Birmingham, August (2004).

Uwagi

Opracowanie rekordu ze środków MEiN, umowa nr SONP/SP/546092/2022 w ramach programu "Społeczna odpowiedzialność nauki" - moduł: Popularyzacja nauki i promocja sportu (2022-2023).

Typ dokumentu

Bibliografia

Identyfikator YADDA

bwmeta1.element.baztech-c56a6226-6ea5-4992-95fc-1d9f02958804