太阳能-沼气混合系统,用于后 COVID-19 时代的农村能源供应

IF 2.9 4区 环境科学与生态学 Q3 ENERGY & FUELS Clean Energy Pub Date : 2024-01-09 DOI:10.1093/ce/zkad070
O. K. Overen, Kechrist Obileke, Edson L Meyer, G. Makaka, Oliver O. Apeh
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引用次数: 0

摘要

用于农村电气化的家用太阳能系统在设计时往往考虑到能源供应有限的问题,这是该技术的一个缺点。此外,农村社区中不加控制的牲畜粪便会造成环境卫生和健康风险。牲畜排泄物可以通过沼气池来补充太阳能,为服务不足的农村社区提供充足、可持续的电力供应,同时实现废物管理。因此,本研究提出了一种太阳能-沼气混合系统,为农村社区的后科维德恢复计划提供更有活力的能源供应和废物管理。研究采用了参数研究方法,包括使用综合环境解决方案虚拟环境软件应用程序和数学模型来设计所需的家庭负荷和混合系统规模。研究结果表明,家庭日耗电量为 6.6 千瓦时,相当于每月 206.40 千瓦时。1.2 kWp 和 1.2 立方米的太阳能-沼气混合系统足以为房屋供电。从财务角度看,该系统的初始投资总成本为 5777.20 美元,净现值为 6566.78 美元,净利润为 4443.6 美元,投资回收期为 14 年零 8 个月,平准化能源成本为 0.21 美元/千瓦时;其中包括 60% 的初始投资和维护成本补贴。建议采用能源绩效合同和能源即服务(energy-as-a-service)的方式来有效运行和操作该系统。这项研究成功揭示了拟议的太阳能-沼气混合系统的设计、规格和升级机制。还需要开展更多研究,以揭示该系统的功效、性能差距以及受益者对该技术的看法。
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A hybrid solar–biogas system for post-COVID-19 rural energy access
Solar home systems for rural electrification are often designed with a limited energy supply, which presents a drawback for the technology. Furthermore, uncontrolled livestock faeces in rural communities constitute environmental sanitation and health risks. Livestock excrement can be used through a biogas digester to supplement solar energy to provide adequate and sustainable electricity access to underserved rural communities while achieving waste management. Therefore, this study presents a hybrid solar–biogas system for a more dynamic energy supply and waste management for post-Covid recovery plans in rural communities. A parametric research approach that involves the use of the Integrated Environment Solution Virtual Environment software application and mathematical models to design the desired household load and the hybrid system sizing is used in the study. The findings show that the daily household energy consumption was 6.6 kWh, equivalent to 206.40 kWh/month. A 1.2-kWp and 1.2-m3 hybrid solar–biogas system was found to adequately power the house. Financially, the total initial investment cost of the system was $5777.20 with a net present value of $6566.78, net profit of $4443.6, a payback period of 14 years and 8 months, and a levelized cost of energy of $0.21/kWh; these include a 60% initial investment and maintenance costs subsidy. Energy performance contracting and energy-as-a-service were recommended to effectively run and operate the system. The study successfully revealed the design, specifications and upscaling mechanism of the proposed hybrid solar–biogas system. More research is required to unveil the efficacy of the system, the performance gap and the perception of the technology by the beneficiaries.
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来源期刊
Clean Energy
Clean Energy Environmental Science-Management, Monitoring, Policy and Law
CiteScore
4.00
自引率
13.00%
发文量
55
期刊最新文献
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