用于COVID-19隔离中心的独立混合光伏/风能/柴油发电系统

IF 2.1 4区 环境科学与生态学 Q3 ENGINEERING, CHEMICAL Environmental Progress & Sustainable Energy Pub Date : 2022-11-28 DOI:10.1002/ep.14049
Hala J. El-Khozondar, Fady El-batta, Rifa J. El-Khozondar, Yasser Nassar, Mansour Alramlawi, Samer Alsadi
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引用次数: 11

摘要

由于政治原因和新冠疫情的扩散,需要克服加沙的电力危机,这是这项工作的动力。建立隔离中心是应对新冠肺炎最重要的手段之一,但在适当的时候将隔离中心连接到配电网并不总是可能的,这增加了当地公用事业公司的负担。本文提出了一种混合离网能源系统(HES),以有效地为加沙隔离COVID-19中心提供经济和环境上的能源。为了实现这一目标,隔离中心的估计负荷概况被提供给HOMER-Pro程序。此外,将各种系统组件引入到程序中,然后进行建模和优化。使用考虑实际输入数据的真实案例研究对开发的方法进行了测试。采用HOMER-Pro程序对系统设计进行仿真和优化。结果显示,与柴油发电机系统相比,HES系统有潜力为所研究的检疫中心提供环保、经济、负担得起的电力。对于所考虑的案例研究,发现与其他可能的HES结构相比,光伏-风力-柴油发电机HES可以以最低的成本(0.348美元/千瓦时)覆盖连接负载。考虑到有害排放物的价格,与其他系统相比,wining系统的能源成本(CoE)降低了54.89%。在考虑的案例研究中,发现150千瓦的光伏,200千瓦的风力和两台容量为500千瓦和250千瓦的柴油发电机的组合可以满足隔离COVID-19中心运行所需的100%电力负荷。该系统的初始资本成本为510,576美元,其中风能、太阳能光伏、逆变器和柴油发电机的份额分别为320,000美元、83,076美元、25,000美元和82,500美元。更换费用(55 918美元)是柴油发电机的费用。总运行维护成本(O&M)为268,737美元,其中风力涡轮机占25.6%,逆变器占1.2%,柴油发电机占70.7%。HES的光伏/风力/柴油发电机发电量为1,659,038千瓦时。总能源需求为1,442,553千瓦时,即每年剩余能源212,553千瓦时。总能量(kWh)是能源的综合,风能、太阳能和柴油发电机分别为427,276(25.8%)、274,500(16.5%)和857,263(57.7%)。每年消耗的燃料费用为437,828.769美元。中奖制度的投资回收期为1.8年。最后证明,该方法为决策者提供了一个合理的解决方案,为检疫中心寻找一个快速、经济、可靠的解决方案。
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Standalone hybrid PV/wind/diesel-electric generator system for a COVID-19 quarantine center

This 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.

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来源期刊
Environmental Progress & Sustainable Energy
Environmental Progress & Sustainable Energy 环境科学-工程:化工
CiteScore
5.00
自引率
3.60%
发文量
231
审稿时长
4.3 months
期刊介绍: Environmental Progress , a quarterly publication of the American Institute of Chemical Engineers, reports on critical issues like remediation and treatment of solid or aqueous wastes, air pollution, sustainability, and sustainable energy. Each issue helps chemical engineers (and those in related fields) stay on top of technological advances in all areas associated with the environment through feature articles, updates, book and software reviews, and editorials.
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