REVIEW OF RENEWABLE ENERGY HYBRID SYSTEMS FOR ALTERNATIVE SOLUTIONS, 1-9.

Zeinab Alfakih, Joseph Kesserwani, Chawki Lahoud, and Elias Rachid

References

  1. [1] K. Majumdar, P.K. Roy, and S. Banerjee, Framework ofhybrid renewable energy with conventional power generationscheduling using novel metaheuristic optimization algorithm,International Journal of Power and Energy Systems, 42(10),2022, 1–11.
  2. [2] . IRENA’s Energy Transition Support to Strengthen ClimateAction, IRENA’s Energy, International Renewable EnergyAgency, Abu Dhabi, UAE, 2021.
  3. [3] Y. Sawle, S.C. Gupta, and A.K. Bohre, Review of hybridrenewable energy systems with comparative analysis of off-gridhybrid system, Renewable and Sustainable Energy Reviews, 81,2018, 2217–2235.
  4. [4] F. Rajaee, M.A. Vaziri Rad, K. Aliyon, A. Kasaeian, and O.Mahian, Techno-economic evaluation of an organic rankinecycle-based multi-source energy system for 100%-renewablepower supply: A rural case study, Sustainable Cities andSociety, 89, 2023, 104290.
  5. [5] D. Silva Herran and T. Nakata, Design of decentralizedenergy systems for rural electrification in developing countriesconsidering regional disparity, Applied Energy, 91(1), 2012,130–145.
  6. [6] Y.-W. Chong, W. Ismail, K. Ko, and C.-Y. Lee, Energyharvesting for wearable devices: A review, IEEE SensorsJournal, 19(20), 2019, 9047–9062.
  7. [7] N.A. Ludin, N.I. Mustafa, M.M. Hanafiah, M.A. Ibrahim,M. Asri Mat Teridi, S. Sepeai, A. Zaharim, and K. Sopian,Prospects of life cycle assessment of renewable energy from solarphotovoltaic technologies: A review, Renewable and SustainableEnergy Reviews, 96, 2018, 11–28.
  8. [8] W.G. Santika, M. Anisuzzaman, P.A. Bahri, G.M. Shafiullah,G.V. Rupf, and T. Urmee, From goals to joules: A quantitativeapproach of interlinkages between energy and the sustainabledevelopment goals, Energy Research & Social Science, 50, 2019,201–214.
  9. [9] W. Mao, S. Yang, and X. Gao, Modelling and optimizationof green energy systems based on complementary integrationof renewable energy, 1-9., International Journal of Power andEnergy Systems, 44(10), 2024, 0524.
  10. [10] G. Notton, M. Muselli, and A. Louche, Autonomous hybridphotovoltaic power plant using a back-up generator: A casestudy in a Mediterranean island, Renewable Energy, 7(4), 1996,371–391.7
  11. [11] H. Borhanazad, S. Mekhilef, V. G. Ganapathy, M. Modiri-Delshad, and A. Mirtaheri, Optimization of micro-grid systemusing MOPSO, Renewable Energy, 71, 2014, 295–306.
  12. [12] R. Sontag and A. Lange, Cost effectiveness of decentralizedenergy supply systems taking solar and wind utilizationplants into account, Renewable Energy, 28(12), 2003,1865–1880.
  13. [13] V. Trillat Berdal, B. Souyri, and G. Fraisse, Experimentalstudy of a ground-coupled heat pump combined withthermal solar collectors, Energy and Buildings, 38, 2006,1477–1484.
  14. [14] K.-H. Lee, D.-W. Lee, N.-C. Baek, H.-M. Kwon, and C.-J.Lee, Preliminary determination of optimal size for renewableenergy resources in buildings using RETScreen, Energy, 47(1),2012, 83–96.
  15. [15] L.A. Wong, V.K. Ramachandaramurthy, P. Taylor, J.B.Ekanayake, S.L. Walker, and S. Padmanaban, Review on theoptimal placement, sizing and control of an energy storagesystem in the distribution network, Journal of Energy Storage,21, 2019, 489–504.
  16. [16] J. Jurasz, F.A. Canales, A. Kies, M. Guezgouz, and A. Beluco,A review on the complementarity of renewable energy sources:Concept, metrics, application and future research directions,Solar Energy, 195, 2020, 703–724.
  17. [17] R.M. Elavarasan, The motivation for renewable energy andits comparison with other energy sources: A review, EuropeanJournal of Sustainable Development Research, 3(1), 2019, 1–19.
  18. [18] T.-Z. Ang, M. Salem, M. Kamarol, H.S. Das, M.A. Nazari, andN. Prabaharan, A comprehensive study of renewable energysources: Classifications, challenges and suggestions, EnergyStrategy Reviews, 43, 2022, 100939.
  19. [19] Power Sector: Executive Summary for the Month of Jun, 2017.Central Electricity Authority New Delhi, June 2017.
  20. [20] T. Falope, L. Lao, D. Hanak, and D. Huo, Hybrid energysystem integration and management for solar energy: A review,Energy Conversion and Management: X, 21, 2024, 100527.
  21. [21] R LunaRubio, M TrejoPerea, D Vargas V´azquez, and G.JR´ıosMoreno, Optimal sizing of renewable hybrids energysystems: A review of methodologies, Solar Energy, 86, 2012,1077–1088.
  22. [22] A. Abdelkader, A. Rabeh, D. Mohamed Ali, and J. Mohamed,Multi-objective genetic algorithm based sizing optimization ofa stand-alone wind/PV power supply system with enhancedbattery/supercapacitor hybrid energy storage, Energy, 163,2018, 351–363.
  23. [23] G. Emmi, A. Zarrella, and M. De Carli, A heat pump coupledwith photovoltaic thermal hybrid solar collectors: A casestudy of a multi-source energy system, Energy Conversion andManagement, 151, 2017, 386–399.
  24. [24] M. Zaibi, H. Cherif, G´erard. Champenois, B. Sareni, X.Roboam, and J. Belhadj, Sizing methodology based on designof experiments for freshwater and electricity production frommulti-source renewable energy systems, Desalination, 446,2018, 94–103.
  25. [25] E.S. Barbieri, Y.J. Dai, M. Morini, M. Pinelli, P.R. Spina, P.Sun, and R.Z. Wang, Optimal sizing of a multi-source energyplant for power heat and cooling generation, Applied ThermalEngineering, 71(2), 2014, 736–750.
  26. [26] Siksnelyte-Butkiene, E.K. Zavadskas, and D. Streimikiene,Multi-criteria decision-making (MCDM) for the assessmentof renewable energy technologies in a household: A review,Energies, 13(5), 2020, 1164.
  27. [27] V. Tavares Nascimento, J.R. Martinez-Bola˜nos, M.E. MoralesUdaeta, A.L. Veiga Gimenes, V.B. Riboldi, and T. Ji, Energystorage system design in the light of multisource solution froma viability analysis, Designs, 6(2), 2022, 38.
  28. [28] M. Berger, D. Radu, R. Fonteneau, R. Henry, M. Glavic, X.Fettweis, M. Le Du, P. Panciatici, L. Balea, and D. Ernst,Critical time windows for renewable resource complementarityassessment, Energy, 198, 2020, 117308.
  29. [29] T Haque and M.T Iqbal, A Comparison of AC and DCCoupled Remote Hybrid Power systems, Memorial Universityof Newfoundland, St. John’s, NL, 2020.
  30. [30] K. Shivarama Krishna and K. S. Kumar, A review on hybridrenewable energy systems, Renewable and Sustainable EnergyReviews, 52, 2015, 907–916.
  31. [31] T Ma, H Yang, and L Lu, Development of hybrid batterysupercapacitor energy storage for remote area renewable energysystems, Applied Energy, 153, 2015, 56–62.
  32. [32] M.T. Arif, A.M.T Oo, A.B.M.S. Ali, and M.F. Islam,Significance of storage and feasibility analysis of renewableenergy with storage system, Presented at the Power and EnergySystems, ACTA Press, 2010.
  33. [33] T. Bocklisch, Hybrid energy storage systems for renewableenergy applications, Energy Procedia, 73, 2015, 103–111.
  34. [34] Y. Yang, S. Bremner, C. Menictas, and M. Kay, Modellingand optimal energy management for battery energy storagesystems in renewable energy systems: A review, Renewable andSustainable Energy Reviews, 167, 2022, 112671.
  35. [35] C. Acar, A comprehensive evaluation of energy storage optionsfor better sustainability, International Journal of EnergyResearch, 42(12), 2018, 3732–3746.
  36. [36] Z. Lu, J. Yu, L. Sun, Y. Xiong, B. Yang, R. Yin, and L. Wang,Capacity optimisation configuration of hybrid energy storagesystem considering primary frequency regulation output ofwind farm, 1-11., International Journal of Power and EnergySystems, 44(10), 2024, 0529.
  37. [37] G Bridge, B ¨Ozkaynak, and E Turhan, Energy infrastructureand the fate of the nation: Introduction to special issue, EnergyResearch & Social Science, 41, 2018, 1–11.
  38. [38] M. Talaat, A. Elgarhy, M.H. Elkholy, and M.A. Farahat,Integration of fuel cells into an off-grid hybrid system usingwave and solar energy, International Journal of ElectricalPower & Energy Systems, 130, 2021, 106939.
  39. [39] M.S.R. Tito, T.T. Lie, and T. Anderson, Sizing optimization ofwind-photovoltaic hybrid energy systems under transient load,International Journal of Power and Energy Systems, 4(33),2013.
  40. [40] E.M. Nfah, H. Jeanmart, and P.M.T. Heteu, Sizing ofphotovoltaic hybrid power systems for remote villages,Presented at the Power and Energy Systems, ACTA Press,2010.A. Algieri, P. Morrone, D. Perrone, S. Bova, and T. Castiglione,Analysis of multi-source energy system for small-scale domesticapplications Integration of biodiesel, solar and wind energy,Energy Reports, 6, 2020, 652–659.
  41. [41] E. Niringiyimana, S. WanQuan, and G. Dushimimana,Feasibility study of a hybrid PV/Hydro system for remote areaelectrification in Rwanda, Journal of Renewable Energy, 2022,2022, 1–11.
  42. [42] R. Al Afif, Y. Ayed, and O.N. Maaitah, Feasibility and optimalsizing analysis of hybrid renewable energy systems: A case studyof al-Karak, Jordan, Renewable Energy, 204, 2023, 229–249.
  43. [43] T.O. Araoye, E.C. Ashigwuike, M.J. Mbunwe, O.I. Bakinson,and T.I. Ozue, Techno-economic modeling and optimal sizing ofautonomous hybrid microgrid renewable energy system for ruralelectrification sustainability using HOMER and grasshopperoptimization algorithm, Renewable Energy, 229, 2024, 120712.
  44. [44] E. Gul, G. Baldinelli, P. Bartocci, T. Shamim, P. Domenighini,F. Cotana, J. Wang, F. Fantozzi, and F. Bianchi, Transitiontoward net zero emissions - integration and optimization ofrenewable energy sources: Solar, hydro, and biomass with thelocal grid station in central Italy, Renewable Energy, 207, 2023,672–686.
  45. [45] S. Ghandehariun, A.M. Ghandehariun, and N. Bahrami Ziabari,Complementary assessment and design optimization of a hybridrenewable energy system integrated with open-loop pumpedhydro energy storage, Renewable Energy, 227, 2024, 120557.
  46. [46] T. Ma and M.S. Javed, Integrated sizing of hybrid PV-wind-battery system for remote island considering the saturationof each renewable energy resource, Energy Conversion andManagement, 182, 2019, 178–190.
  47. [47] A.Y. Hatata, G. Osman, and M.M. Aladl, An optimizationmethod for sizing a solar/wind/battery hybrid power systembased on the artificial immune system, Sustainable EnergyTechnologies and Assessments, 27, 2018, 83–93.
  48. [48] S. Mertens, Design of wind and solar energy supply, to matchenergy demand, Cleaner Engineering and Technology, 6, 2022,100402.
  49. [49] J.H. Slusarewicz and D.S. Cohan, Assessing solar and windcomplementarity in Texas, Renewables: Wind, Water, andSolar, 5(1), 2018.8
  50. [50] E. Kabalci, Design and analysis of a hybrid renewable energyplant with solar and wind power, Energy Conversion andManagement, 72, 2013, 51–59.
  51. [51] G Ren, J Wan, J Liu, and D Yu, Spatial and temporalassessments of complementarity for renewable energy resourcesin China, Energy, 177, 2019, 262–275.
  52. [52] T.S. Le, T.N. Nguyen, D.K. Bui, and T.D. Ngo, Optimal sizingof renewable energy storage: A techno-economic analysis ofhydrogen, battery and hybrid systems considering degradationand seasonal storage, Applied Energy, 336, 2023, 120817.
  53. [53] A. Ortiz, D. Negandhi, SR. Mysorekar, SK. Nagaraju, J.Kiesecker, C. Robinson, P. Bhatia, A. Khurana, J. Wang, andF. Oviedo, J.L. Ferres, An artificial intelligence dataset forsolar energy locations in India, Scientific Data, 9(1), 2022,497.
  54. [54] P. Bayer, L. Dolan, and J. Urpelainen, Global patternsof renewable energy innovation, Energy for SustainableDevelopment, 17, 2013, 288–295.
  55. [55] Medium-Term Renewable Energy Market Report 2013,IEA, Paris, 2013. https://www.iea.org/reports/medium-term-renewable-energy-market-report-2013, Licence: CC BY 4.0.
  56. [56] S. Hostettler, A. Gadgil, and E. Hazboun (Eds.), SustainableAccess to Energy in the Global South. (Cham: Springer, 2015)3–9,.
  57. [57] P. Igeland, L. Schroeder, M. Yahya, Y. Okhrin, and G.S. Uddin,The energy transition: The behavior of renewable energy stockduring the times of energy security uncertainty, RenewableEnergy, 221, 2024, 119746.
  58. [58] J.Z. Wang, G.F. Feng, and C.P. Chang, How does politicalinstability affect renewable energy innovation? RenewableEnergy, 230, 2024, 120800.
  59. [59] L.V. Kochtcheeva, Renewable energy: Global challenges,https://www.e-ir.info/2016/05/27/renewable-energy-global-challenges,(May 2016).
  60. [60] U.T. Umoh and I.J. Ekpoh, Renewable energy resources barriersin Africa, Presented at the Power and Energy Systems, ACTAPress, 2008.
  61. [61] S. M¨uller, A. Brown, and S. ¨Olz, Renewable energy: Policyconsiderations for deploying renewables, OECD/IEA, Paris,November 2011.
  62. [62] P. Mundra, A. Arya, and S.K. Gawre, Assessing the impactof renewable purchase obligation on Indian power sector,International Journal of Power and Energy Systems, 40(4),2020, 208– 212.
  63. [63] Lebanon: Derisking Renewable Energy Investment, UnitedNations Development Programme, New York, NY and Beirut,December 2017.
  64. [64] IEA Statistics © OECD/IEA, https://www.iea.org/data-and-statistics, (2014).
  65. [65] World Bank, https://documents1.worldbank.org/curated/en/235831562864951356/text/Concept-Project-Information-Document-PID-Lebanon-Electricity-Transmission-Project-P170769.txt, (2019)
  66. [66] UNRWA, https://www.unrwa.org/where-we-work/lebanon,(2014).

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