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dc.contributor.authorEl-Khozondar, Hala-
dc.contributor.authorEl-batta, Fady-
dc.contributor.authorEl-Khozondar, Rifa-
dc.contributor.authorNassar, Yasser-
dc.contributor.authorAlramlawi, Mansour-
dc.contributor.authorAlsadi, Samer-
dc.date.accessioned2022-12-13T10:14:16Z-
dc.date.available2022-12-13T10:14:16Z-
dc.date.issued2022-11-23-
dc.identifier.citationEl‐Khozondar, H. J., El‐Batta, F., El‐Khozondar, R. J., Nassar, Y., Alramlawi, M., & Alsadi, S. (2020). Standalone hybrid PV/Wind/Diesel‐electric generator system for a COVID‐19 Quarantine Center. Environmental Progress & Sustainable Energy, e14049.‏en_US
dc.identifier.urihttps://scholar.ptuk.edu.ps/handle/123456789/1008-
dc.description.abstractThis work is motivated by the need in overcoming the electricity crisis in Gaza, which is initiated due to political reasons and the spread of COVID-19. Building quarantine centers is one of the most important means used in combating the COVID-19, but connecting these centers to the electricity distribution network at the appropriate time is not always possible and increases the burden on the local utility company. This article proposed a hybrid off-grid energy system (HES) to effectively energize the quarantine COVID-19 center in Gaza economically and environmentally. To achieve this aim, the estimated load profile of the quarantine center is fed to the HOMER-Pro program. In addition, the various systems components are introduced to the program, then modeled, and optimized. The developed approach was tested using a real case study considering realistic input data. HOMER-Pro program is used to simulate and optimize the system design. The results revealed the potential of the HES to provide environment friendly, cost-effective, and affordable electricity for the studied quarantine center, as compared to just the diesel generators system. For the considered case study, it is found that the PV-wind-diesel generators HES can cover the connected load with the lowest cost ($ 0.348/kWh) in comparison to other possible HES structures. Taking into consideration the price of harmful emissions, the wining system shows a reduction of 54.89% of the cost of energy (CoE) compared to other systems. For the considered case study, it is found that a combination of 150 kW PV, 200 kW wind, and two diesel generators with capacities of 500 and 250 kW can hold 100% of the electrical load required to keep the quarantine COVID-19 center in operation. The initial capital cost of this HES is $510,576 where the share of wind energy, solar PV, inverter, and diesel electric generators are $320,000, $83,076, $25,000, and $82,500, respectively. The replacemen cost ($55,918) is due to diesel generators. The total operation and maintainance cost (O&M) is $268,737, that is, 25.6% for wind turbines, 1.2% for inverters, and 70.7% for diesel electric generators. The PV/wind/diesel generators HES generate 1,659,038 kWh of electricity. The total energy requirement of 1,442,553 kWh, which means a surplus of 212,553 kWh of energy/year. The total energy (kWh) is an integration of energy sources which are 427,276 (25.8%), 274,500 (16.5%), and 857,263 57.7%), due to wind, solar and diesel generators respectively. The cost of yearly consumed fuel is $437,828.769. The payback period for the winning system is 1.8 years. Finally, it is proved that the developed approach gives a reasonable solution to the decision-makers to find a fast, economic and reliable solution to energize the quarantine centers.en_US
dc.publisherAmerican Institute of Chemical Engineersen_US
dc.relation.ispartofseries2022;1-18-
dc.subjectCOVID-19 quarantine centeren_US
dc.subjectHOMER-proen_US
dc.subjecthybrid energy systemen_US
dc.subjectPalestineen_US
dc.subjectsolar energyen_US
dc.subjectwind energyen_US
dc.titleStandalone hybrid PV/wind/diesel-electric generator system for a COVID-19 quarantine centeren_US
dc.typeArticleen_US
dc.identifier.doi10.1002/ep.14049-
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