[1] Yuan Y., Cai F., Yang L., Renewable energy investment under carbon emission regulations. Sustainability, 2020, 12: 1–15.
[2] Zhang H., Liang W., Liu J., et al., Modeling and energy efficiency analysis of thermal power plant with high temperature thermal energy storage (HTTES). Journal of Thermal Science, 2020, 29(4): 1025–1035.
[3] Zhang M., Yang Z., Liu L., et al., Impact of renewable energy investment on carbon emissions in China - An empirical study using a nonparametric additive regression model. Science of the Total Environment, 2021, 785: 1–11.
[4] Wang Y., Lou S., Wu Y., et al., Flexible operation of retrofitted coal-fired power plants to reduce wind curtailment considering thermal energy storage. IEEE Transactions on Power Systems, 2020, 35(2): 1178–1187.
[5] Wang Y., Lou S., Wu Y., et al., Coordinated planning of transmission expansion and coal-fired power units flexibility retrofits to accommodate the high penetration of wind power. IET Generation Transmission & Distribution, 2019, 13(20): 4702–4711.
[6] Ioannis A., Dimitrios R., Sotirios K., et al., Review of process modeling of solid-fuel thermal power plants for flexible and off-design operation. Energies, 2020, 13(24): 1–41.
[7] Zhou Y., Wang D., An improved coordinated control technology for coal-fired boiler-turbine plant based on flexible steam extraction system. Applied Thermal Engineering, 2017, 125: 1047–1060.
[8] Wang C., Zhao Y., Liu M., et al., Peak shaving operational optimization of supercritical coal-fired power units by revising control strategy for water-fuel ratio. Applied Energy, 2018, 216: 212–223.
[9] Zhang K., Zhao Y., Liu M., et al., Flexibility enhancement versus thermal efficiency of coal-fired power units during the condensate throttling processes. Energy, 2021, 218: 1–14.
[10] Wang W., Liu J., Zeng D., et al., Flexible electric power control for coal-fired units by incorporating feedwater bypass. IEEE Access, 2019, 7: 91225–91233.
[11] Zhao Y., Wang C., Liu M., et al., Improving operational flexibility by regulating extraction steam of high pressure heaters on a 660 MW supercritical coal-fired power unit: A dynamic simulation. Applied Energy, 2018, 212: 1295–1309.
[12] Wang W., Jing S.G., Sun Y., et al., Combined heat and power control considering thermal inertia of district heating network for flexible electric power regulation. Energy, 2019, 169: 988–999.
[13] Yoshiba F., Hanai Y., Watanabe I., et al., Methodology to evaluate contribution of thermal power plant flexibility to power system stability when increasing share of renewable energies: Classification and additional fuel cost of flexible operation. Fuel, 2021, 292: 1–10.
[14] Wang C., Song J., Zhu L., et al., Peak shaving and heat supply flexibility of thermal power plants. Applied Thermal Engineering, 2021, 193: 1–8.
[15] Richter M., Oeljeklaus G., Görner K., Improving the load flexibility of coal-fired power units by the integration of a thermal energy storage. Applied Energy, 2019, 236: 607–621.
[16] Trojan M., Taler D., Dzierwa P., et al., The use of pressure hot water storage tanks to improve the energy flexibility of the steam power unit. Energy, 2019, 173: 926–936.
[17] Li D., Wang J., Study of supercritical power plant integration with high temperature thermal energy storage for flexible operation. Journal of Energy Storage, 2018, 20: 140–152.
[18] Krüger M., Muslubas S., Loeper T., et al., Potentials of thermal energy storage integrated into steam power plants. Energies, 2020, 13(9): 1–13.
[19] Sun Y., Xu C., Xin T., et al., A comprehensive analysis of a thermal energy storage concept based on low-rank coal pre-drying for reducing the minimum load of coal-fired power plants. Applied Thermal Engineering, 2019, 156: 77–90.
[20] Gu Y., Xu J., Chen D., et al., Overall review of peak shaving for coal-fired power units in China. Renewable and Sustainable Energy Reviews, 2016, 54: 723–731.
[21] Wei H., Lu Y., Yang Y., et al., Research on influence of steam extraction parameters and operation load on operational flexibility of coal-fired power plant. Applied Thermal Engineering, 2021, 195: 1–10.
[22] Wu Y., Li Y., Lu Y., et al., Novel low melting point binary nitrates for thermal energy storage applications. Solar Energy Materials & Solar Cells, 2017, 164: 114–121.
[23] Verda V., Colella F., Primary energy savings through thermal storage in district heating networks. Energy, 2011, 36: 4278–4286.
[24] Wu J., Hou H., Hu E., et al., Performance improvement of coal-fired power generation system integrating solar to preheat feed water and reheated steam. Solar Energy, 2018, 163: 461–470.
[25] Zhai R., Liu H., Li C., et al., Analysis of a solar-aided coal-fired power generation system based on thermo-economic structural theory. Energy, 2016, 102: 375–387.
[26] Wu J., Hou H., Yang Y., The optimization of integration modes in solar aided power generation (SAPG) system. Energy Conversion and Management, 2016, 126: 774–789.
[27] Zhang N., Hou H., Yu G., et al., Simulated performance analysis of a solar aided power generation plant in fuel saving operation mode. Energy, 2019, 166: 918–928.
[28] Liu H., Zhai R., Patchigolla K., et al., Off-design thermodynamic performances of a combined solar tower and parabolic trough aided coal-fired power unit. Applied Thermal Engineering, 2021, 183: 1–15.