TY - JOUR
TI - Peak shaving performance analysis of coal-fired units coupled with a molten salt-water heat storage system
AU - Nie Shenqiang
AU - Ma Jianlong
AU - Wang Feng
AU - Dong Xiaoming
AU - Gu Qunhao
AU - Su Hongjie
JN - Thermal Science
PY - 2025
VL - 29
IS - 5
SP - 3925
EP - 3936
PT - Article
AB - With the rapid development of the renewable energy industry, thermal power units are increasingly required to provide peak shaving support within the power system. The integration of heat storage technology has emerged as a key strategy for enhancing the operational flexibility of coal-fired power units. However, existing solutions primarily rely on single-stage molten salt heat storage and release, which imposes limitations on overall heat storage capacity and efficiency. This study proposes a two-stage molten salt-water heat storage system and utilizes Ebsilon simulation software to model a 660 MW coal-fired unit. Three different heat storage and release schemes for the coupled molten salt-water system are comparatively analyzed in terms of peak shaving performance and thermal efficiency. The results indicate that Scheme 1 (heat storage via main steam extraction) achieves the highest peak shaving performance. When the heat storage power is 120 MW, its peak shaving capacity reaches 60 MW. Scheme 3 (heat storage via intermediate-pressure cylinder exhaust extraction) exhibits the highest thermal efficiency, reaching 40.5% at a heat storage power of 40 MW, with the efficiency increasing as the storage capacity grows. When the heat release power is 50 MW, Scheme 1 (Hot section: deaerator outlet → boiler feedwater, Cold section: feedwater pump outlet → 5# heater inlet) demonstrates the highest thermoelectric conversion ratio (29.9%), while Scheme 3 (Hot section: 5# heater inlet → deaerator inlet, Cold section: feedwater pump outlet → 6# heater inlet) records the lowest overall thermal efficiency (38.4%) and the highest coal consumption per unit of electricity generation (301.2 g/kW).
DO - 10.2298/TSCI241125068N
ER -