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电加热固体颗粒储热技术研究进展OA

Research progress on electrically heated solid particle thermal energy storage technology

中文摘要英文摘要

[目的]在"碳达峰""碳中和"背景下,我国可再生能源装机规模持续攀升,但其间歇性、波动性特征,对电力系统长时储能能力和灵活调峰性能提出了更高要求.电加热高温固体颗粒储热技术凭借加热温度高、储热温区宽、材料成本低、介质热稳定性好、系统环境友好且与新能源和煤电系统耦合潜力突出等优势,受到行业广泛关注.为明确该技术的发展现状、关键瓶颈及未来研究方向,本文对其研究进展进行了系统梳理与综述.[分析]本文围绕电阻加热和感应加热两类典型方式,系统梳理了其基本原理、传热特征、适用颗粒材料及代表性装置核心参数,重点对比了间接电阻加热、直接电阻加热和感应加热三类技术在电热转换效率、温度均匀性、设备复杂度、材料适配性及工程放大可行性方面的差异;总结了管式、板式、流化床和移动床等典型加热装置的适用场景和技术特点;进一步分析了高温颗粒流动传热机理、电加热效率优化、颗粒材料高温稳定性、系统全生命周期成本控制以及与燃煤机组耦合运行过程中的关键问题.现有研究表明,电阻加热技术成熟度较高、结构相对简单,在大规模颗粒储热系统中具有较好的工程可实施性;感应加热具有非接触、响应速度快和高温适应性强等显著优势,但在当前仍存在电磁转换效率偏低、设备成本较高、线圈冷却难度大和材料选择受限等技术挑战.[结论]综上,电加热高温固体颗粒储热技术是支撑新能源高比例消纳和煤电灵活调峰改造的重要潜在技术路径.未来研究重点需要聚焦高温颗粒多场耦合流动与换热机理、低成本高性能颗粒材料开发、模块化电加热装置、高效保温与热损控制技术,以及储热系统多环节协同调控策略等核心方向,加快推动该技术实现规模化、工业化与商业化的应用发展.

[Objective]With the rapid growth of renewable energy under the goals of carbon peaking and carbon neutrality,power systems face increasing demand for long-duration energy storage and flexible peak regulation.Electrically heated solid particle thermal energy storage(TES)is a promising option because it offers high operating temperature,wide storage temperature range,low-cost storage media,good thermal stability,clean electric-to-thermal conversion,and strong potential for integration with renewable energy systems and coal-fired power plants.This paper aims to clarify the research progress,major bottlenecks,and future directions of this technology.[Analysis]This paper reviews electrically heated solid particle TES from the perspectives of heating principles,representative devices,application scenarios,and key scientific and engineering issues.Two major routes,resistance heating and induction heating,are discussed in detail.For resistance heating,both indirect and direct modes are considered.Indirect resistance heating transfers heat from electric heating elements to particles through conduction,convection,and radiation.It has advantages such as simple structure,mature equipment,and good controllability,but it also suffers from additional thermal resistance and heat loss.Direct resistance heating allows conductive particles or conductive particle networks to generate Joule heat directly,which improves heating compactness and electric-to-thermal efficiency,while also introducing challenges related to conductivity stability,local overheating,oxidation resistance,and the formation of reliable conductive paths.Induction heating provides non-contact heating and rapid thermal response,and is attractive for high-temperature applications.However,its performance depends strongly on frequency,magnetic field intensity,coil design,particle size,electrical conductivity,magnetic permeability,and temperature-dependent material properties.In addition,induction heating systems often face higher equipment cost,cooling demand,and lower overall efficiency in practical applications.Representative devices for solid particle heating,including tubular heaters,plate heaters,fluidized-bed heaters,and moving-bed heaters,are also summarized.Tubular and plate heaters are relatively mature and suitable for small-and medium-scale systems,whereas fluidized-bed and moving-bed configurations show better heat transfer performance and greater potential for high-power and continuous operation.At the same time,they involve more complex issues such as particle flow stability,pressure drop,abrasion,temperature uniformity,and model accuracy.This paper further discusses key challenges,including high-temperature particle flow and heat transfer mechanisms,optimization of electric heating efficiency,durability of particle materials under thermal cycling,cost control,and coordinated operation with coal-fired power plants.[Conclusion]Electrically heated solid particle TES is a promising technical route for renewable energy integration,long-duration energy storage,and flexible operation of coal-fired power plants.Resistance heating is currently more mature and economically competitive,while induction heating has advantages in non-contact heating,rapid response,and high-temperature adaptability,but still requires progress in efficiency improvement,cost reduction,and particle material matching.Future research should focus on multi-field coupled particle flow and heat transfer,low-cost and high-performance particle materials,modular electric heating devices,heat loss control,and coordinated control strategies,so as to promote the scale-up,industrialization,and commercialization of this technology.

余跃;宋国良

中国科学院工程热物理研究所煤炭高效低碳利用全国重点实验室,北京 100190||中国科学院大学工程科学学院,北京 100049中国科学院工程热物理研究所煤炭高效低碳利用全国重点实验室,北京 100190||中国科学院大学工程科学学院,北京 100049

电加热固体颗粒储热电阻加热感应加热

electric heatingsolid particle thermal energy storageresistance heatinginduction heating

《热力发电》 2026 (6)

1-14,14

中国科学院战略性先导科技专项课题(XDA29010100) Strategic Priority Research Program of the Chinese Academy of Science(XDA29010100)

10.19666/j.rlfd.202510048

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