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An Energy Production System Powered by Solar Heat with Biogas Dry Reforming Reactor and Solid Oxide Fuel Cell
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作者 Akira Nishimura Ryotaro Sato Eric Hu 《Smart Grid and Renewable Energy》 CAS 2023年第5期85-106,共22页
In this paper, an energy system consisting of solar collector, biogas dry reforming reactor and solid oxide fuel cell (SOFC) has been proposed. The heat produced from the concentrating solar collector is used to drive... In this paper, an energy system consisting of solar collector, biogas dry reforming reactor and solid oxide fuel cell (SOFC) has been proposed. The heat produced from the concentrating solar collector is used to drive a biogas dry reforming reactor in order to produce H<sub>2</sub> as a fuel for SOFC, in such as system. The aim of this study is to clarify the impact of climate data on the performance of solar collector with various sizes/designs. The temperature of heat transfer fluid produced by the solar collector is calculated by adopting the climate data for Nagoya city in Japan in 2021. The amount of H<sub>2</sub> produced from the biogas dry reforming reactor and the power generated by SOFC were simulated. The results show the temperature of heat transfer fluid (T<sub>fb</sub>) and T<sub>fb</sub> ratio (a) based on the length of absorber (dx) = 1 m have a peak near the noon following the trend of solar intensity (I). Results also revealed that a increases with increase in dx. It is found that the differences of T<sub>fb</sub> and a between dx = 2 m and dx = 3 m are larger than those between dx = 1 m and dx = 2 m. It is revealed that T<sub>fb</sub> and a are higher in spring and summer. dx = 4 m is the optimum length of solar absorber. The amount of H<sub>2</sub> produced from the biogas dry reforming reactor as well as the power generated by SOFC is the highest in August, resulting that it is prefer to produce H<sub>2</sub> and to generate SOFC in summer. 展开更多
关键词 Solar Collector Fluid Temperature Climate Data biogas Dry reforming H2 Production SOFC
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Valorization of Agricultural Residues for Hydrogen-Based Electricity Generation towards Circular Bioeconomy
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作者 Patience Afi Seglah Komikouma Apelike Wobuibe Neglo 《Open Journal of Energy Efficiency》 2024年第2期57-78,共22页
Global crises, notably climate shocks, degraded ecosystems, and growing energy demand, enforce sustainable production and consumption pathways. A circular bioeconomy offers the opportunities to actualize resource and ... Global crises, notably climate shocks, degraded ecosystems, and growing energy demand, enforce sustainable production and consumption pathways. A circular bioeconomy offers the opportunities to actualize resource and eco-efficiency enhancement, valorization of waste streams, reduction of fossil energy and greenhouse gas (GHG) emissions. Albeit biomass resources are a potential feedstock for bio-hydrogen (bio-H2) production, Ghana’s agricultural residues are not fully utilized. This paper examines the economic and environmental impact of bio-H2 electricity generation using agricultural residues in Ghana. The bio-H2 potential was determined based on biogas steam reforming (BSR). The research highlights that BSR could generate 2617 kt of bio-H2, corresponding to 2.78% of the global hydrogen demand. Yam and maize residues contribute 50.47% of the bio-H2 produced, while millet residues have the most negligible share. A tonne of residues could produce 16.59 kg of bio-H2 and 29.83 kWh of electricity. A total of 4,705.89 GWh of electricity produced could replace the consumption of 21.92% of Ghana’s electricity. The economic viability reveals that electricity cost is $0.174/kWh and has a positive net present value of $2135550609.45 with a benefit-to-cost ratio of 1.26. The fossil diesel displaced is 1421.09 ML, and 3862.55 kt CO2eq of carbon emissions decreased corresponding to an annual reduction potential of 386.26 kt CO2eq. This accounts for reducing 10.26% of Ghana’s GHG emissions. The study demonstrates that hydrogen-based electricity production as an energy transition is a strategic innovation pillar to advance the circular bioeconomy and achieve sustainable development goals. 展开更多
关键词 Agricultural Residues biogas Steam reforming BIO-HYDROGEN ELECTRICITY Circular Bioeconomy
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Comparative Studies of Non-noble Metal Modified Mesoporous M-Ni-CaO-ZrO2 (M=Fe, Co, Cu) Catalysts for Simulated Biogas Dry Reforming 被引量:5
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作者 Changzhen Wang Yin Zhang +1 位作者 Yongzhao Wang Yongxiang Zhao 《Chinese Journal of Chemistry》 SCIE CAS CSCD 2017年第1期113-120,共8页
The present work is aimed to improve the performance of Ni-based catalysts for biogas dry reforming by adding a second non-noble metal (Fe, Co, Cu) into a previously studied mesoporous Ni-CaO-ZrO2 nanocomposite. Bio... The present work is aimed to improve the performance of Ni-based catalysts for biogas dry reforming by adding a second non-noble metal (Fe, Co, Cu) into a previously studied mesoporous Ni-CaO-ZrO2 nanocomposite. Biogas was simulated with equivalent methane and carbon dioxide for the dry reforming reaction. X-ray diffraction (XRD), X-ray photoelectron spectroscopy (XPS), N2 adsorption, temperature-programmed reduction (TPR), thermogravi- metric analysis (TGA), and transmission electron microscopy (TEM) measurements were taken to characterize the structural and textual properties of the bimetallic catalysts as well as the accumulated carbon deposition. The addition of Fe leads to a less ordering growth of mesopores of Fe-Ni-CaO-ZrO2 sample, and the existence of Cu results in a relatively larger portion of free NiO in Cu-Ni-CaO-ZrO2. Compared with Fe and Cu, the presence of Co could efficiently form a beneficial dual metal effect and enhance the strong metal support interaction between Ni and CaO-ZrO2, thus enhancing the activity and stability of the catalyst in biogas dry reforming reaction. 展开更多
关键词 nickel catalyst non-noble metal modified bimetallic catalyst biogas dry reforming carbon deposition
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