Ancillary Service by Tiered Energy Storage Systems
Publication: Journal of Energy Engineering
Volume 148, Issue 1
Abstract
Due to intermittent characteristics and lack of inertia and damping properties, high penetration of renewable energy sources in power grids could bring about a series of security issues related to power system stability and control. In many countries and regions, therefore, power regulators tend to request self-frequency control ancillary services (FCAS) of renewable power generation, which could introduce further obstacles to utilize clean and inexhaustible wind power, solar energy, and the like in large scale. This paper aims to address such a challenge by presenting a tiered energy storage system (TESS) for self-provision of frequency regulation services. The TESS is composed of different types of energy storage devices aimed at rapid response speed, sufficient storage capacity, and acceptable investment/operation costs. The proposed method can be applied for the FCAS of power grids with high-penetration renewable energy integration. Based on the real wind power generation and electricity demand, simulations were carried out to demonstrate the feasibility of the self-FCAS by the developed TESS.
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Data Availability Statement
All data, models, and codes (except for the TESS control component) that support the findings of this study are available from the corresponding author upon reasonable request.
References
AEMC (Australian Energy Market Commission) Reliability Panel. 2017. “The frequency operating standard.” Accessed March 1, 2021. https://www.aemc.gov.au/sites/default/files/content/c2716a96-e099-441d-9e46-8ac05d36f5a7/REL0065-The-Frequency-Operating-Standard-stage-one-final-for-publi.pdf.
Australia Energy Market Operator. 2015. “Guide to ancillary services in the national electricity market.” Accessed March 1, 2021. https://www.lga.sa.gov.au/__data/assets/pdf_file/0025/472813/Guide-to-Ancillary-Services-in-the-National-Electricity-Market.pdf.
Blaabjerg, F., and K. Ma. 2017. “Wind energy systems.” Proc. IEEE 105 (11): 2116–2131.
Cai, B., P. Vo, S. Sritharan, and E. S. Takle. 2021. “Wind energy potential at elevated hub heights in the US Midwest region.” J. Energy Eng. 147 (4): 04021023. https://doi.org/10.1061/(ASCE)EY.1943-7897.0000760.
Conlon, M. F. 2003. “Notes for frequency control.” Accessed March 1, 2021. https://pdfcoffee.com/notes-for-frequency-control-pdf-free.html.
ESA (US Energy Storage Association). 2020. Mechanical energy storage. Washington, DC: ESA.
Hasan, N. S., M. Y. Hassan, M. S. Majid, and H. A. Rahman. 2012. “Mathematical model of compressed air energy storage in smoothing 2MW wind turbine.” In Proc., IEEE Int. Power Engineering and Optimization Conf., 339–343. New York: IEEE. https://doi.org/10.1109/PEOCO.2012.6230886.
He, P., F. Wen, G. Ledwich, Y. Xue, and J. Huang. 2015. “Investigation of the effects of various types of wind turbine generators on power-system stability.” J. Energy Eng. 141 (3): 04014007. https://doi.org/10.1061/(ASCE)EY.1943-7897.0000176.
Huang, J., M. Negnevitsky, and Z. Jiang. 2018. “Tiered energy storage system for auxiliary service of power systems with wind farms.” Accessed March 1, 2021. http://www.ijtrd.com/papers/IJTRD19221.pdf.
Jiang, P., and P. Li. 2017. “Research and application of a new hybrid wind speed forecasting model on BSO algorithm.” J. Energy Eng. 143 (1): 04016019. https://doi.org/10.1061/(ASCE)EY.1943-7897.0000362.
Liang, L., J. Li, and D. Hui. 2010. “An optimal energy storage capacity calculation method for 100MW wind farm.” In Proc., 2010 Int. Conf. on Power System Technology (POWERCON 2010), 1–4. New York: IEEE. https://doi.org/10.1109/POWERCON.2010.5666426.
Luo, X., J. Wang, C. Krupke, Y. Wanga, Y. Sheng, J. Li, Y. Xu, D. Wang, S. Miao, and H. Chen. 2016. “Modelling study, efficiency analysis and optimisation of large-scale adiabatic compressed air energy storage systems with low-temperature thermal storage.” Appl. Energy 162 (4): 589–600. https://doi.org/10.1016/j.apenergy.2015.10.091.
Mears, L. D., H. L. Gotschall, T. Key, and H. Kamath. 2003. EPRI-DOE handbook of energy storage for transmission and distribution applications. Washington, DC: Dept. of Energy.
Mongird, K., V. Fotedar, V. Viswanathan, V. Koritarov, P. Balducci, B. Hadjerioua, and J. Alam. 2019. Energy storage technology and cost characterization report. Washington, DC: HydroWIRES, US Department of Energy.
Riesz, J. J., F. S. Shiao, J. B. Gilmore, D. Yeowart, A. Turley, and J. A. Rose. 2011. Frequency control ancillary service requirements with wind generation—Australian projections. Brisbane, Australia: ROAM Consulting.
Sun, W., and Y. Liang. 2015. “Least-squares support vector machine based on improved imperialist competitive algorithm in a short-term load forecasting model.” J. Energy Eng. 141 (4): 04014037. https://doi.org/10.1061/(ASCE)EY.1943-7897.0000220.
Wang, J., K. Lu, L. Ma, J. Wang, M. Dooner, S. Miao, J. Li, and D. Wang. 2017. “Overview of compressed air energy storage and technology development.” Energies 10 (7): 991. https://doi.org/10.3390/en10070991.
Xu, J., and T. Liu. 2021. “Optimal hourly scheduling for wind–hydropower systems with integrated pumped-storage technology.” J. Energy Eng. 147 (3): 04021013. https://doi.org/10.1061/(ASCE)EY.1943-7897.0000728.
Zheng, J., F. Wen, G. Ledwich, and J. Huang. 2014. “Risk control in transmission system planning with wind generators.” Int. Trans. Elect. Energy Syst. 24 (2): 227–245. https://doi.org/10.1002/etep.1692.
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© 2021 American Society of Civil Engineers.
History
Received: Mar 26, 2021
Accepted: Sep 14, 2021
Published online: Oct 18, 2021
Published in print: Feb 1, 2022
Discussion open until: Mar 18, 2022
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