Your search keyword '"Dagbasi A"' showing total 2 results

1. Optimal design and sensitivity analysis of distributed biomass‐based hybrid renewable energy systems for rural electrification: Case study of different photovoltaic/wind/battery‐integrated options in Babadam, northern Cameroon.

Author

Yimen, Nasser, Monkam, Louis, Tcheukam‐Toko, Denis, Musa, Bashir, Abang, Roger, Fombe, Lawrence Fon, Abbasoglu, Serkan, and Dagbasi, Mustafa

Subjects

RENEWABLE energy sources, RURAL electrification, HYBRID power systems, SENSITIVITY analysis, DIESEL electric power-plants, SUSTAINABLE development, ANAEROBIC digestion

Abstract

It is commonly recommended to incorporate diesel generators into distributed hybrid renewable energy systems (HRESs) to lower the system's total cost and make the generated electricity affordable. Due to the environmental and economic issues associated with fossil fuel use, biomass power technologies (BPT) appear to be an attractive alternative to diesel generators. The HOMER software was used to model, simulate, and optimise two photovoltaic/wind/battery systems integrated with different BPT (anaerobic digestion or gasification) to satisfy the electrical needs of Babadam, a remote community in northern Cameroon. The results indicated that the anaerobic digester integrated system's overall optimal architecture included a 98.1 kW photovoltaic array, a 30 kW biogas generator, and 200 batteries, with a cost of energy (COE) of $0.347/kWh. On the other hand, the gasifier integrated option is made up of an 81.8 kW photovoltaic array, a 15 kW syngas generator, and 200 batteries and has a COE of $0.319/kW. Additionally, compared to the PV/Wind/Battery system, integrating the biogas (resp. syngas) generator showed a potential COE decrease of 29% (resp. 40%). The sensitivity analysis highlighted the validity of this COE reduction potential everywhere in sub‐Saharan Africa, leading to the conclusion that integrating BPT into HRESs can effectively contribute to Sustainable Development Goal 7. [ABSTRACT FROM AUTHOR]

Published

2022

2. Optimal Sizing and Techno-Economic Analysis of Hybrid Renewable Energy Systems—A Case Study of a Photovoltaic/Wind/Battery/Diesel System in Fanisau, Northern Nigeria.

Author

Yimen, Nasser, Tchotang, Theodore, Kanmogne, Abraham, Abdelkhalikh Idriss, Idriss, Musa, Bashir, Aliyu, Aliyu, Okonkwo, Eric C., Abba, Sani Isah, Tata, Daniel, Meva'a, Lucien, Hamandjoda, Oumarou, and Dagbasi, Mustafa

Subjects

RURAL electrification, HYBRID power systems, NET present value, DIESEL electric power-plants, PAYBACK periods, GREENHOUSE gas analysis, GENETIC algorithms

Abstract

Hybrid Renewable Energy Systems (HRESs) have been touted as an appropriate way for supplying electricity to remote and off-grid areas in developing countries, especially in sub-Saharan Africa (SSA), where rural electrification challenges are the most pronounced. This study proposes a two-step methodology for optimizing and analyzing a stand-alone photovoltaic/wind/battery/diesel hybrid system to meet the electricity needs of Fanisua, an off-grid and remote village of northern Nigeria. In the first step, the MATLAB environment was used to run simulations and optimize the system via the genetic algorithm. Then, techno-economic and emissions analysis was carried out in the second step to compare the proposed system to the existing traditional modes of rural electrification in sub-Saharan Africa, namely, the grid-extension and diesel generator. The break-even distance parameter was adopted in the comparison with grid-extension. Besides, the hypothetical project of replacing the diesel generator by the optimal system was analyzed using the Simple Payback Period (SPP) and Net Present Value (NPV) parameters. The resulting optimal design architecture included an 89.271-kW photovoltaic array, a 100.31-W diesel generator, and 148 batteries with a total annualized cost (TAC) and cost of energy (COE) of USD 43,807 and USD 0.25/kWh, respectively. The break-even distance found was 16.2 km, while the NPV and SPP of the hypothetical project were USD 572,382 and 2.8 years, respectively. The savings in carbon dioxide (CO2) emissions of the proposed system compared to the grid extension and the diesel generator were found to be 85,401.08 kg/year and 122,062.85 kg/year, respectively. This study highlighted the role that solar PV-based HRESs could play in the sustainable electricity supply in rural areas of sub-Saharan Africa. [ABSTRACT FROM AUTHOR]

Published

2020