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Feasibility of Using sCO2 Turbines to Balance Load in Power Grids with a High Deployment of Solar Generation

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  • Bennett, Jeffrey A.
  • Fuhrman, Jay
  • Brown, Tyler
  • Andrews, Nathan
  • Fittro, Roger
  • Clarens, Andres F.

Abstract

Solar photovoltaic power generation capacity is growing rapidly, increasing the need for dynamic load balancing when solar production dips. This balancing might be delivered using energy storage and/or advanced power generation cycles, that are compact, dynamic, and highly efficient, such as supercritical carbon dioxide (sCO2) cycles. Here, the load balancing capability of a sCO2 combined cycle plant was compared to open cycle and steam combined cycle gas turbines. A characteristic-based transient model was developed to evaluate the impact of machinery ramp rates, minimum part loads, and cycle efficiencies. High resolution demand and solar irradiance data from the University of Virginia campus, before and after installation of a major solar project, was used to represent low and high levels of solar deployment in the grid. The results suggest that under high deployment of solar power, sCO2 cycles and steam combined cycle systems with ramp rates greater than 5.75%/minute can balance load and provide comparable levelized costs of electricity ($0.057/kWh). Solar curtailment was driven by the minimum part load capabilities. A sCO2 cycle with a minimum part load of 30% was predicted to have a curtailment of 15% in the high solar scenario without a battery, and 4% with a 30 MWh battery.

Suggested Citation

  • Bennett, Jeffrey A. & Fuhrman, Jay & Brown, Tyler & Andrews, Nathan & Fittro, Roger & Clarens, Andres F., 2019. "Feasibility of Using sCO2 Turbines to Balance Load in Power Grids with a High Deployment of Solar Generation," Energy, Elsevier, vol. 181(C), pages 548-560.
    • Handle: RePEc:eee:energy:v:181:y:2019:i:c:p:548-560
    DOI: 10.1016/j.energy.2019.05.143
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    1. Crespi, Francesco & Gavagnin, Giacomo & Sánchez, David & Martínez, Gonzalo S., 2017. "Supercritical carbon dioxide cycles for power generation: A review," Applied Energy, Elsevier, vol. 195(C), pages 152-183.
    2. Das, Barun K. & Al-Abdeli, Yasir M. & Kothapalli, Ganesh, 2017. "Optimisation of stand-alone hybrid energy systems supplemented by combustion-based prime movers," Applied Energy, Elsevier, vol. 196(C), pages 18-33.
    3. Walnum, Harald Taxt & Nekså, Petter & Nord, Lars O. & Andresen, Trond, 2013. "Modelling and simulation of CO2 (carbon dioxide) bottoming cycles for offshore oil and gas installations at design and off-design conditions," Energy, Elsevier, vol. 59(C), pages 513-520.
    4. Kalantar, M. & Mousavi G., S.M., 2010. "Dynamic behavior of a stand-alone hybrid power generation system of wind turbine, microturbine, solar array and battery storage," Applied Energy, Elsevier, vol. 87(10), pages 3051-3064, October.
    5. Dufo-López, Rodolfo & Bernal-Agustín, José L. & Yusta-Loyo, José M. & Domínguez-Navarro, José A. & Ramírez-Rosado, Ignacio J. & Lujano, Juan & Aso, Ismael, 2011. "Multi-objective optimization minimizing cost and life cycle emissions of stand-alone PV–wind–diesel systems with batteries storage," Applied Energy, Elsevier, vol. 88(11), pages 4033-4041.
    6. Denholm, Paul & Hand, Maureen, 2011. "Grid flexibility and storage required to achieve very high penetration of variable renewable electricity," Energy Policy, Elsevier, vol. 39(3), pages 1817-1830, March.
    7. Huber, Matthias & Dimkova, Desislava & Hamacher, Thomas, 2014. "Integration of wind and solar power in Europe: Assessment of flexibility requirements," Energy, Elsevier, vol. 69(C), pages 236-246.
    8. Ueckerdt, Falko & Brecha, Robert & Luderer, Gunnar, 2015. "Analyzing major challenges of wind and solar variability in power systems," Renewable Energy, Elsevier, vol. 81(C), pages 1-10.
    9. Zahedi, A., 2011. "Maximizing solar PV energy penetration using energy storage technology," Renewable and Sustainable Energy Reviews, Elsevier, vol. 15(1), pages 866-870, January.
    10. Kasaei, Mohammad Javad & Gandomkar, Majid & Nikoukar, Javad, 2017. "Optimal management of renewable energy sources by virtual power plant," Renewable Energy, Elsevier, vol. 114(PB), pages 1180-1188.
    11. Nosratabadi, Seyyed Mostafa & Hooshmand, Rahmat-Allah & Gholipour, Eskandar, 2017. "A comprehensive review on microgrid and virtual power plant concepts employed for distributed energy resources scheduling in power systems," Renewable and Sustainable Energy Reviews, Elsevier, vol. 67(C), pages 341-363.
    12. Luo, Xing & Wang, Jihong & Dooner, Mark & Clarke, Jonathan, 2015. "Overview of current development in electrical energy storage technologies and the application potential in power system operation," Applied Energy, Elsevier, vol. 137(C), pages 511-536.
    13. de Groot, Mats & Crijns-Graus, Wina & Harmsen, Robert, 2017. "The effects of variable renewable electricity on energy efficiency and full load hours of fossil-fired power plants in the European Union," Energy, Elsevier, vol. 138(C), pages 575-589.
    14. Bajpai, Prabodh & Dash, Vaishalee, 2012. "Hybrid renewable energy systems for power generation in stand-alone applications: A review," Renewable and Sustainable Energy Reviews, Elsevier, vol. 16(5), pages 2926-2939.
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    2. Bennett, Jeffrey A. & Fitts, Jeffrey P. & Clarens, Andres F., 2022. "Compressed air energy storage capacity of offshore saline aquifers using isothermal cycling," Applied Energy, Elsevier, vol. 325(C).
    3. Bennett, Jeffrey A. & Simpson, Juliet G. & Qin, Chao & Fittro, Roger & Koenig, Gary M. & Clarens, Andres F. & Loth, Eric, 2021. "Techno-economic analysis of offshore isothermal compressed air energy storage in saline aquifers co-located with wind power," Applied Energy, Elsevier, vol. 303(C).
    4. Yang, Jingze & Chi, Hetian & Cheng, Mohan & Dong, Mingqi & Li, Siwu & Yao, Hong, 2023. "Performance analysis of hydrogen supply using curtailed power from a solar-wind-storage power system," Renewable Energy, Elsevier, vol. 212(C), pages 1005-1019.
    5. Li, Qingshan & Wang, Chenfang & Wang, Chunmei & Zhou, Taotao & Zhang, Xianwen & Zhang, Yangjun & Zhuge, Weilin & Sun, Li, 2023. "Comparison of organic coolants for boiling cooling of proton exchange membrane fuel cell," Energy, Elsevier, vol. 266(C).

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