Reversible solid-oxide cell stack based power-to-x-to-power systems: Comparison of thermodynamic performance. (1st October 2020)
- Record Type:
- Journal Article
- Title:
- Reversible solid-oxide cell stack based power-to-x-to-power systems: Comparison of thermodynamic performance. (1st October 2020)
- Main Title:
- Reversible solid-oxide cell stack based power-to-x-to-power systems: Comparison of thermodynamic performance
- Authors:
- Wang, Ligang
Zhang, Yumeng
Pérez-Fortes, Mar
Aubin, Philippe
Lin, Tzu-En
Yang, Yongping
Maréchal, François
Van herle, Jan - Abstract:
- Highlights: A decomposition-based method for optimally deploying grid-balancing plants. Power-to-x-to-power pathways evaluated for H2, CH4, CH3 OH, syngas and NH3 . Power-to-x efficiency (53–69%) ranks as CH4 > CH3 OH > NH3 > H2 > syngas. X-to-power efficiency (66–80%) ranks as syngas > H2 > CH4 > CH3 OH > NH3 . Round-trip efficiency (38–48%) ranks as CH4 > syngas > H2 > CH3 OH > NH3 . Abstract: The increasing penetration of variable renewable energies poses new challenges for grid management. The economic feasibility of grid-balancing plants may be limited by low annual operating hours if they work either only for power generation or only for power storage. This issue might be addressed by a dual-function power plant with power-to-x capability, which can produce electricity or store excess renewable electricity into chemicals at different periods. Such a plant can be uniquely enabled by a solid-oxide cell stack, which can switch between fuel cell and electrolysis with the same stack. This paper investigates the optimal conceptual design of this type of plant, represented by power-to-x-to-power process chains with x being hydrogen, syngas, methane, methanol and ammonia, concerning the efficiency (on a lower heating value) and power densities. The results show that an increase in current density leads to an increased oxygen flow rate and a decreased reactant utilization at the stack level for its thermal management, and an increased power density and a decreased efficiency atHighlights: A decomposition-based method for optimally deploying grid-balancing plants. Power-to-x-to-power pathways evaluated for H2, CH4, CH3 OH, syngas and NH3 . Power-to-x efficiency (53–69%) ranks as CH4 > CH3 OH > NH3 > H2 > syngas. X-to-power efficiency (66–80%) ranks as syngas > H2 > CH4 > CH3 OH > NH3 . Round-trip efficiency (38–48%) ranks as CH4 > syngas > H2 > CH3 OH > NH3 . Abstract: The increasing penetration of variable renewable energies poses new challenges for grid management. The economic feasibility of grid-balancing plants may be limited by low annual operating hours if they work either only for power generation or only for power storage. This issue might be addressed by a dual-function power plant with power-to-x capability, which can produce electricity or store excess renewable electricity into chemicals at different periods. Such a plant can be uniquely enabled by a solid-oxide cell stack, which can switch between fuel cell and electrolysis with the same stack. This paper investigates the optimal conceptual design of this type of plant, represented by power-to-x-to-power process chains with x being hydrogen, syngas, methane, methanol and ammonia, concerning the efficiency (on a lower heating value) and power densities. The results show that an increase in current density leads to an increased oxygen flow rate and a decreased reactant utilization at the stack level for its thermal management, and an increased power density and a decreased efficiency at the system level. The power-generation efficiency is ranked as methane (65.9%), methanol (60.2%), ammonia (58.2%), hydrogen (58.3%), syngas (53.3%) at 0.4 A/cm 2, due to the benefit of heat-to-chemical-energy conversion by chemical reformulating and the deterioration of electrochemical performance by the dilution of hydrogen. The power-storage efficiency is ranked as syngas (80%), hydrogen (74%), methane (72%), methanol (68%), ammonia (66%) at 0.7 A/cm 2, mainly due to the benefit of co-electrolysis and the chemical energy loss occurring in the chemical synthesis reactions. The lost chemical energy improves plant-wise heat integration and compensates for its adverse effect on power-storage efficiency. Combining these efficiency numbers of the two modes results in a rank of round-trip efficiency: methane (47.5%) > syngas (43.3%) ≈ hydrogen (42.6%) > methanol (40.7%) > ammonia (38.6%). The pool of plant designs obtained lays the basis for the optimal deployment of this balancing technology for specific applications. … (more)
- Is Part Of:
- Applied energy. Volume 275(2020)
- Journal:
- Applied energy
- Issue:
- Volume 275(2020)
- Issue Display:
- Volume 275, Issue 2020 (2020)
- Year:
- 2020
- Volume:
- 275
- Issue:
- 2020
- Issue Sort Value:
- 2020-0275-2020-0000
- Page Start:
- Page End:
- Publication Date:
- 2020-10-01
- Subjects:
- Electrical storage -- Power-to-x -- Reversible solid-oxide cell -- Ammonia -- Methanol -- Sector coupling
Power (Mechanics) -- Periodicals
Energy conservation -- Periodicals
Energy conversion -- Periodicals
621.042 - Journal URLs:
- http://www.sciencedirect.com/science/journal/03062619 ↗
http://www.elsevier.com/journals ↗ - DOI:
- 10.1016/j.apenergy.2020.115330 ↗
- Languages:
- English
- ISSNs:
- 0306-2619
- Deposit Type:
- Legaldeposit
- View Content:
- Available online (eLD content is only available in our Reading Rooms) ↗
- Physical Locations:
- British Library DSC - 1572.300000
British Library DSC - BLDSS-3PM
British Library HMNTS - ELD Digital store - Ingest File:
- 13917.xml