Developing Flue Gas-Driven Molten-Salt-Heat-Exchanger for Flexible Operation of Coal-Fired Power Plant

IF 11.6 1区工程技术 Q1 ENGINEERING, MULTIDISCIPLINARY

Engineering Pub Date : 2025-09-06 DOI:10.1016/j.eng.2025.09.001

Jinliang Xu, Hongliang Su, Xinyu Dong, Xiongjiang Yu, Chao Liu, Yan Wang, Jian Xie, Wei Wang, Yupu Yu, Qinghua Wang, Yuguang Niu, Jizhen Liu, Ying Huang, Zhengshun Zhang, Anyou Dong, Yan Pan, Hao Wu

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引用次数: 0

Abstract

The large-scale utilization of renewable energy challenges the stability and safety of the grid; thus, the flexibility of coal-fired power plants should be increased to balance unstable renewable energies. To achieve this, a heat storage system (HSS) is integrated into a power plant. This is the first study utilizing furnace flue gas to drive a molten-salt-heat-exchanger (MSHE). Compared to steam-vapor-driven MSHE, flue gas-driven technology avoids the pinch temperature limitation (PTL) and simplifies the system configuration. In this study, we demonstrate the concept, design, fabrication, and experiments of the MSHE. The novelties include: ① finned tubes to balance the thermal resistances between the flue gas side and the molten salt side; ② a weak angle design to ensure gravity-driven recession of the molten salt; and ③ a modular design to ensure even temperature distribution at the outlet of the tube bundles. A heat transfer correlation is developed for molten salt, covering a wide range of Reynolds numbers. An experimental setup is constructed to collect data and verify the effectiveness of the MSHE. The measured overall heat transfer coefficients matched the predictions well, with deviations of less than 10%. The measured heat power reached 320 kW, exceeding the 300 kW design target. We demonstrate the heat transfer between the flue gas and molten salt to compensate for the heat release from the HSS to the environment, reducing electricity consumption in the standby stage of the system. The modular design of the MSHE ensures minimal temperature deviations of < 4 K among different tubes, avoiding local overheating-induced decomposition of the molten salt. Based on the 300 kW MSHE results, a 10 MW MSHE is designed, fabricated, and integrated into a 350 megawatt electric (MWe) coal-fired plant to achieve a higher load variation rate of 6% Pe·min⁻¹ for a coal-fired power plant.

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燃煤电厂柔性运行烟气驱动熔盐换热器的研制

可再生能源的大规模利用对电网的稳定性和安全性提出了挑战；因此，应提高燃煤电厂的灵活性，以平衡不稳定的可再生能源。为了实现这一目标，一个储热系统（HSS）被集成到发电厂中。这是首次利用炉烟气驱动熔盐热交换器（MSHE）的研究。与蒸汽驱动MSHE相比，烟气驱动技术避免了夹点温度限制（PTL），简化了系统配置。在本研究中，我们展示了MSHE的概念、设计、制造和实验。其新颖之处包括：①利用翅片管平衡烟气侧和熔盐侧的热阻；②弱角度设计，保证了重力驱动熔盐的衰退；③采用模块化设计，保证管束出口温度分布均匀。建立了熔盐传热关系式，涵盖了广泛的雷诺数范围。建立了一个实验装置来收集数据并验证MSHE的有效性。测量的总传热系数与预测吻合良好，偏差小于10%。实测热功率达到320千瓦，超过了300千瓦的设计目标。我们演示了烟气和熔盐之间的传热，以补偿HSS向环境释放的热量，减少系统待机阶段的电力消耗。MSHE的模块化设计确保了不同管之间的最小温度偏差为4 K，避免了局部过热引起的熔盐分解。在300千瓦MSHE实验的基础上，设计、制造了一个10兆瓦的MSHE，并将其集成到一个350兆瓦的燃煤电厂中，以实现燃煤电厂6% Pe·min−1的更高负荷变化率。

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来源期刊

Engineering Environmental Science-Environmental Engineering

自引率

1.60%

发文量

335

审稿时长

35 days

期刊介绍： Engineering, an international open-access journal initiated by the Chinese Academy of Engineering (CAE) in 2015, serves as a distinguished platform for disseminating cutting-edge advancements in engineering R&D, sharing major research outputs, and highlighting key achievements worldwide. The journal's objectives encompass reporting progress in engineering science, fostering discussions on hot topics, addressing areas of interest, challenges, and prospects in engineering development, while considering human and environmental well-being and ethics in engineering. It aims to inspire breakthroughs and innovations with profound economic and social significance, propelling them to advanced international standards and transforming them into a new productive force. Ultimately, this endeavor seeks to bring about positive changes globally, benefit humanity, and shape a new future.