THERMAL SCIENCE
International Scientific Journal
STUDY ON THE CHARACTERISTICS OF MOLTEN SALT HEAT STORAGE IN THE FAST PEAK REGULATION OF COAL-FIRED POWER UNIT
ABSTRACT
The load variation rate of the coal-fired power unit in China is generally around 2%, and the new technology is needed to further improve the load variation rate and to increase the peak regulation benefits. In this paper, the molten salt is utilized to constructed the “Carnot battery” based on the coal-fired power unit, in order to increase the load variation rate of the coal-fire power units, and the regulatory characteristics of the molten salt system during load variation processes and the coupling characteristics with the boiler and turbine are investigated. The results indicate that, the load variation rate in the 20-100% load can be improved to 6% Pe per minute for a 300 MW coal-fired power unit when molten salt system with power of 301 MW and thermal storage duration of 83.6 MWh is coupled, in which the maximum molten salt temperature is, and the steam produced by molten salt is added into the low pressure cylinder of turbine. The average power generation efficiency of the “Carnot battery” constructed by the boiler and molten salt during the variable load regulation process is 38.72%, and the average power generation efficiency of the molten salt system is 24.57%. This study indicates that the small-scale molten salt systems can be used to improve the load variation rate of the coal-fired power units.
KEYWORDS
PAPER SUBMITTED: 2023-12-17
PAPER REVISED: 2024-01-08
PAPER ACCEPTED: 2024-01-11
PUBLISHED ONLINE: 2024-03-10
THERMAL SCIENCE YEAR
2024, VOLUME
28, ISSUE
Issue 5, PAGES [3825 - 3834]
- Li, G. M., et al., Hybrid Forecasting System Considering the Influence of Seasonal Factors under Energy sustainable Development Goals, Measurement, 211 (2023), 112607
- Feng, S. D., et al., Multi-Objective Optimization of Coal-Fired Power Units Considering Deep Peaking Regulation in China, Environ Sci. Pollut. Res. Int., 30 (2023), 4, pp. 10756-10774
- Cui, R. Y., et al., A Plant-by-Plant Strategy for High-Ambition Coal Power Phaseout in China, Nature Communications, 12 (2021), 1, 1468
- Wang, J. J., et al., Flexibility Transformation Decision-Making Evaluation of Coal-Fired Thermal Power Units Deep Peak Shaving in China, Sustainability, 13 (2021), 4, 1882
- Fan, Q. W., et al., Present Situation and Key Problem Analysis in Parameters Increasing Reformation Technology for Active Coal-fired Thermal Power Units (in Chinese), Journal of Engineering for Thermal Energy and Power, 37 (2022), 6, pp. 12-18+39
- Zhang, Z., et al., Influence of Thermal Power Plant Ancillary Peak Regulation on Power System with High Proportion Of Renewable Energy (in Chinese), Power and Energy, 39 (2018), 3, pp. 373-376
- Yu, W. J., et al., Research and Challenge of Coal Power Technology Development in China under the Background of Dual Carbon Strategy (in Chinese), Journal of China Coal Society, 48 (2023), 7, pp. 2641-2656
- Wang, X., et al., Advances and Prospects In Thermal Energy Storage: A Critical Review (in Chinese), Chinese Science Bulletin, 62 (2017), 5, 1602
- Gong, Z. Q., et al. Research and Evaluation on the Flexible Peaking Performance of Coal-fired Power Plants Coupled with Thermal Storage (in Chinese), Proceedings of the CSEE, Lisbon, Portugal, 2023, pp. 1-13
- Yong, Q. Q., et al., Retrofitting Coal-Fired Power Plants for Grid Energy Storage by Coupling with Thermal Energy Storage, Applied Thermal Engineering, 215 (2022), 119048
- Fan, Q. W., et al., Research on Decoupling of Heat and Power of Industrial Steam Supply Unit Based on Heat Storage Process (in Chinese), Turbine Technology, 61 (2019), 3, pp. 221-223+188
- Li, J., et al., Flexible Modification Technology and Application Prospect of Thermal Power Unit Based on High Temperature Molten Salt Heat Storage (in Chinese), Southern Energy Construction, 8 (2021), 3, pp. 63-70
- Wang, H., et al., Hundred-Megawatt Molten Salt Heat Storage System for Deep Peak Shaving of Thermal Power Plant (in Chinese), Energy Storage Science and Technology, 10 (2021), 5, pp. 1760-1767
- Zhang, X. R., et al., Performance Analysis and Comparison of Multi-Type Thermal Power-Heat Storage Coupling Systems (in Chinese), Energy Storage Science and Technology, 10 (2021), 5, pp. 1565-1578
- Zhou, K., et al., Research Progress on the Coupling Technology of Coal-Fired Power Generation-Physical Thermal Storage and Analysis for the System Peaking Capacity (in Chinese), Clean Coal Technology, 28 (2022), 3, pp. 159-172
- Barrasso, M., et al., Latest Advances in Thermal Energy Storage for Solar Plants, Processes, 11 (2023), 6, 1832
- Ju, W. P., et al., Comparison of Thermo-Electric Decoupling Techniques for Heating Units (in Chinese), Thermal Power Generation, 47 (2018), 9, pp. 115-121
- Kosman, W., Rusin, A., The Application of Molten Salt Energy Storage to Advance the Transition from Coal to Green Energy Power System, Energies, 13 (2020), 9, 2222
- Lu, Y. W., et al., Laminar Natural-Convection Heat Transfer Characteristics of Molten Salt Around Horizontal Cylinder, Energy Procedia, 69 (2015), May, pp. 681-688
- Pfleger, N., et al., Thermal Energy Storage - Overview and Specific Insight into Nitrate Salts for Sensible and Latent Heat Storage, Beilstein Journal of Nanotechnology, 6 (2015), July, pp. 1487-1497
- Zhou, X. H., et al., Application Research of Steam Extraction Molten Salt Heat Storage Technology in Coal-fired Power Generation Flexibility Transformation (in Chinese), Scientific and Technological Innovation, (2023), 22, pp. 53-56
- Garbrecht, O., et al., Increasing Fossil Power Plant Flexibility by Integrating Molten-Salt Thermal Storage, Energy, 118 (2017), Jan., pp. 876-883
- Chen, C. X., et al., Study of Combined Heat And Power Plant Integration With Thermal Energy Storage for Operational Flexibility, Applied Thermal Engineering, 219 (2023), 119537