TY  - JOUR
AU  - Zhu, Pengfei
AU  - Wu, Zhen
AU  - Yao, Jing
AU  - Guo, Leilei
AU  - Yan, Hongli
AU  - Nyamsi, Serge Nyallang
AU  - Kurko, Sandra V.
AU  - Yang, Fusheng
AU  - Zhang, Zaoxiao
PY  - 2021
UR  - https://vinar.vin.bg.ac.rs/handle/123456789/9931
AB  - In order to uncover the inner working mechanism and performance of solid oxide fuel cell (SOFC) with biomass gasification syngas as fuel, a two dimensional SOFC multi-physical field model is established. This study makes up for the deficiency that the previous studies of coupling biomass gasification unit and SOFC stack mostly stay at the system level. The results show that the SOFC fueled by the syngas produced from gasification of biomass with steam as the agent has the best performance. The peak power density could achieve approximately 10240 W m−2. With the improvement of operating temperature, the peak power density of SOFC will be increased. At the temperature of 1123 K, the peak power density could achieve about 15128 W m−2. The average reaction rate of water gas shift (WGS) reaction is −29.73 mol m−3 s−1 when the operating temperature is 1123 K. This indicates that the WGS reaction will proceed in reverse direction at high temperatures, thereby reducing the hydrogen concentration. In addition, increase in the anode flux and decrease in the cell length lead to the increase of SOFC current density. In general, this work could provide guidance for the optimization and practical application of SOFC using biomass syngas as fuel.
T2  - Journal of Power Sources
T1  - Multi-physics field modeling of biomass gasification syngas fueled solid oxide fuel cell
VL  - 512
SP  - 230470
DO  - 10.1016/j.jpowsour.2021.230470
ER  - 

@article{
author = "Zhu, Pengfei and Wu, Zhen and Yao, Jing and Guo, Leilei and Yan, Hongli and Nyamsi, Serge Nyallang and Kurko, Sandra V. and Yang, Fusheng and Zhang, Zaoxiao",
year = "2021",
abstract = "In order to uncover the inner working mechanism and performance of solid oxide fuel cell (SOFC) with biomass gasification syngas as fuel, a two dimensional SOFC multi-physical field model is established. This study makes up for the deficiency that the previous studies of coupling biomass gasification unit and SOFC stack mostly stay at the system level. The results show that the SOFC fueled by the syngas produced from gasification of biomass with steam as the agent has the best performance. The peak power density could achieve approximately 10240 W m−2. With the improvement of operating temperature, the peak power density of SOFC will be increased. At the temperature of 1123 K, the peak power density could achieve about 15128 W m−2. The average reaction rate of water gas shift (WGS) reaction is −29.73 mol m−3 s−1 when the operating temperature is 1123 K. This indicates that the WGS reaction will proceed in reverse direction at high temperatures, thereby reducing the hydrogen concentration. In addition, increase in the anode flux and decrease in the cell length lead to the increase of SOFC current density. In general, this work could provide guidance for the optimization and practical application of SOFC using biomass syngas as fuel.",
journal = "Journal of Power Sources",
title = "Multi-physics field modeling of biomass gasification syngas fueled solid oxide fuel cell",
volume = "512",
pages = "230470",
doi = "10.1016/j.jpowsour.2021.230470"
}

Zhu, P., Wu, Z., Yao, J., Guo, L., Yan, H., Nyamsi, S. N., Kurko, S. V., Yang, F.,& Zhang, Z.. (2021). Multi-physics field modeling of biomass gasification syngas fueled solid oxide fuel cell. in Journal of Power Sources, 512, 230470.
https://doi.org/10.1016/j.jpowsour.2021.230470

Zhu P, Wu Z, Yao J, Guo L, Yan H, Nyamsi SN, Kurko SV, Yang F, Zhang Z. Multi-physics field modeling of biomass gasification syngas fueled solid oxide fuel cell. in Journal of Power Sources. 2021;512:230470.
doi:10.1016/j.jpowsour.2021.230470 .

Zhu, Pengfei, Wu, Zhen, Yao, Jing, Guo, Leilei, Yan, Hongli, Nyamsi, Serge Nyallang, Kurko, Sandra V., Yang, Fusheng, Zhang, Zaoxiao, "Multi-physics field modeling of biomass gasification syngas fueled solid oxide fuel cell" in Journal of Power Sources, 512 (2021):230470,
https://doi.org/10.1016/j.jpowsour.2021.230470 . .

TY  - JOUR
AU  - Wu, Zhen
AU  - Zhu, Pengfei
AU  - Yao, Jing
AU  - Kurko, Sandra V.
AU  - Ren, Jianwei
AU  - Tan, Peng
AU  - Xu, Haoran
AU  - Zhang, Zaoxiao
AU  - Ni, Meng
PY  - 2021
UR  - https://vinar.vin.bg.ac.rs/handle/123456789/9565
AB  - Advanced efficient energy conversion technology using clean alternative fuel contributes to the alleviation of the energy crisis and environmental deterioration. In this situation, a novel methanol utilization technology for power generation based on hybrid fuel cell system is proposed in this work. The hybrid system consists of a solid oxide fuel cell (SOFC), a gas processing unit (GP) and a proton exchange membrane fuel cell (PEMFC). Thermodynamic analysis of the system shows that the energy conversion efficiency and exergy efficiency are both higher than the previously reported standalone or hybrid energy systems using methanol as fuel, which are 66.2% and 54.2% respectively. Besides, no recirculation ratio of anode off-gas and moderate fuel utilization of about 0.5 are suggested for the SOFC component to balance the power distribution and improve the efficiency. Afterwards, this hybrid fuel cell system is also investigated from thermo-economic and techno-economic perspectives. Take Northwest China as a case, the 1 MWe methanol-fed power plant has a specific electric energy cost of 0.5594 CNY/kWh, much lower than the methanol steam reforming-PEMFC power plant (2.4 CNY/kWh). At the same time, the sensitivity analyses reveal that the cost of the hybrid power system is not sensitive to the market price fluctuation. With financial subsidies for existing renewable power plants, the payback period can be shortened to 1.4 year and the annual return on investment is about 3.58%. These results reveal that this two-stage fuel cell hybrid system is a kind of efficient and economically methanol to power conversion technology, especially for small power scale. © 2021 Elsevier Ltd
T2  - Energy Conversion and Management
T1  - Methanol to power through high-efficiency hybrid fuel cell system: Thermodynamic, thermo-economic, and techno-economic (3T) analyses in Northwest China
VL  - 232
SP  - 113899
DO  - 10.1016/j.enconman.2021.113899
ER  - 

@article{
author = "Wu, Zhen and Zhu, Pengfei and Yao, Jing and Kurko, Sandra V. and Ren, Jianwei and Tan, Peng and Xu, Haoran and Zhang, Zaoxiao and Ni, Meng",
year = "2021",
abstract = "Advanced efficient energy conversion technology using clean alternative fuel contributes to the alleviation of the energy crisis and environmental deterioration. In this situation, a novel methanol utilization technology for power generation based on hybrid fuel cell system is proposed in this work. The hybrid system consists of a solid oxide fuel cell (SOFC), a gas processing unit (GP) and a proton exchange membrane fuel cell (PEMFC). Thermodynamic analysis of the system shows that the energy conversion efficiency and exergy efficiency are both higher than the previously reported standalone or hybrid energy systems using methanol as fuel, which are 66.2% and 54.2% respectively. Besides, no recirculation ratio of anode off-gas and moderate fuel utilization of about 0.5 are suggested for the SOFC component to balance the power distribution and improve the efficiency. Afterwards, this hybrid fuel cell system is also investigated from thermo-economic and techno-economic perspectives. Take Northwest China as a case, the 1 MWe methanol-fed power plant has a specific electric energy cost of 0.5594 CNY/kWh, much lower than the methanol steam reforming-PEMFC power plant (2.4 CNY/kWh). At the same time, the sensitivity analyses reveal that the cost of the hybrid power system is not sensitive to the market price fluctuation. With financial subsidies for existing renewable power plants, the payback period can be shortened to 1.4 year and the annual return on investment is about 3.58%. These results reveal that this two-stage fuel cell hybrid system is a kind of efficient and economically methanol to power conversion technology, especially for small power scale. © 2021 Elsevier Ltd",
journal = "Energy Conversion and Management",
title = "Methanol to power through high-efficiency hybrid fuel cell system: Thermodynamic, thermo-economic, and techno-economic (3T) analyses in Northwest China",
volume = "232",
pages = "113899",
doi = "10.1016/j.enconman.2021.113899"
}

Wu, Z., Zhu, P., Yao, J., Kurko, S. V., Ren, J., Tan, P., Xu, H., Zhang, Z.,& Ni, M.. (2021). Methanol to power through high-efficiency hybrid fuel cell system: Thermodynamic, thermo-economic, and techno-economic (3T) analyses in Northwest China. in Energy Conversion and Management, 232, 113899.
https://doi.org/10.1016/j.enconman.2021.113899

Wu Z, Zhu P, Yao J, Kurko SV, Ren J, Tan P, Xu H, Zhang Z, Ni M. Methanol to power through high-efficiency hybrid fuel cell system: Thermodynamic, thermo-economic, and techno-economic (3T) analyses in Northwest China. in Energy Conversion and Management. 2021;232:113899.
doi:10.1016/j.enconman.2021.113899 .

Wu, Zhen, Zhu, Pengfei, Yao, Jing, Kurko, Sandra V., Ren, Jianwei, Tan, Peng, Xu, Haoran, Zhang, Zaoxiao, Ni, Meng, "Methanol to power through high-efficiency hybrid fuel cell system: Thermodynamic, thermo-economic, and techno-economic (3T) analyses in Northwest China" in Energy Conversion and Management, 232 (2021):113899,
https://doi.org/10.1016/j.enconman.2021.113899 . .