23 October 2025, Volume 44 Issue 10

    

• Select all
  |

Special Issues for Physical Energy Storage
• Select
  Preface of special issues of physical energy storage

  Advanced Technology of Electrical Engineering and Energy. 2025, 44(10): 1-2.

  Abstract ( ) Download PDF ( )   Knowledge map   Save
• Select
  Research status and development trends of key technologies for large-scale pumped storage power stations

  WANG Gui, GAO Hongjun, LI Deyou, ZHANG Haichen

  Advanced Technology of Electrical Engineering and Energy. 2025, 44(10): 3-13. https://doi.org/10.12067/ATEEE2412008

  Abstract ( ) Download PDF ( )   Knowledge map   Save

  Driven by the national dual carbon goals and the establishment of a new power system dominated by renewable energy, large-scale pumped storage power stations (defined as those with a total installed capacity ≥ 1 200 MW) have become critical components for integrating renewable energy into the new power system. This has led to unprecedented rapid development, accompanied by a significant transformation in the role of pumped storage technology. Technological parameters are also advancing towards higher specifications, such as larger capacity, higher head, and broader load range. This paper first provides a brief introduction to the fundamental principles of pumped storage power stations, with a focused analysis of the development status and challenges of large-scale pumped storage power stations (total installed capacity ≥ 1 200 MW) both domestically and internationally. Subsequently, it examines high-parameter pumped storage units (defined as those with a unit capacity ≥ 300 MW, head > 700 m, or load variation range > 40%), discussing research progress in key unit-level technologies (such as ultra-high head hydraulic design, large-capacity structural strength, and wide-range control strategies). The paper also identifies current research shortcomings and key technical problems that need to be addressed. Finally, considering China’s current context, it proposes key research and development directions encompassing the system integration of large-scale power stations and core technologies for high-parameter units, along with recommendations for accelerating the development of key technologies for large-scale pumped storage power stations. This aims to provide theoretical guidance for the advancement of pumped storage technology in China and support the implementation of the national dual carbon goals.
• Select
  Review of development of new pumped storage systems

  NIE Zipan, XIAO Liye, ZHANG Jingye, YE Hua, QIU Qingquan, JI Hao

  Advanced Technology of Electrical Engineering and Energy. 2025, 44(10): 14-25. https://doi.org/10.12067/ATEEE2502018

  Abstract ( ) Download PDF ( )   Knowledge map   Save

  Pumped storage is a large-scale long-term energy storage system with the best comprehensive performance, which will provide important support for the new power system dominated by new energy. However, the resources of pumped storage sites in our country are seriously insufficient, and are far from meeting the actual demand. At the same time, the seasonal output of new energy fluctuates greatly, which does not match the seasonal changes of power load, and puts forward a higher demand for the development of large-scale cross-seasonal energy storage. In view of this, research on new pumped storage systems has been carried out at home and abroad in recent years, dedicated to solving the above problems by expanding the resources and models of pumped storage. This paper defines and classifies new pumped energy storage systems, including underground pumped storage, underwater pumped storage, semi-underground pumped storage, cross-seasonal and cross-regional pumped storage, and energy storage systems based on compressed air/pumped water.
• Select
  Overview and prospect of underwater compressed air energy storage

  CHEN Laijun, LIU Hanchen, WANG Zichen, CUI Sen, MEI Shengwei

  Advanced Technology of Electrical Engineering and Energy. 2025, 44(10): 26-39. https://doi.org/10.12067/ATEEE2412006

  Abstract ( ) Download PDF ( )   Knowledge map   Save

  With the gradual promotion of the construction of the new power system, offshore wind power, tidal energy, and other offshore renewable energies have made considerable progress. At the same time, the demand for flexible underwater energy storage resources has become increasingly urgent. Therefore, this paper reviews the research progress and development prospects of underwater compressed air energy storage. Firstly, the basic principles and technical features of underwater compressed air energy storage systems are introduced. Secondly, the representative demonstration projects and current development status of underwater compressed air energy storage systems at home and abroad are summarized. Thirdly, the key technologies of underwater compressed air energy storage are outlined, including underwater gas storage, heat storage, anchoring, and other assistant operation technologies. Finally, based on the current technical bottlenecks, the future research direction and application research focus of underwater compressed air energy storage are clarified. This paper aims to provide reference for the research in the field of underwater energy storage and to improve the coordinated development of offshore renewable energy and energy storage technology.
• Select
  Research and engineering application progress of carbon dioxide energy storage technology

  XIE Yonghui, WANG Ding, ZHANG Di

  Advanced Technology of Electrical Engineering and Energy. 2025, 44(10): 40-49. https://doi.org/10.12067/ATEEE2503036

  Abstract ( ) Download PDF ( )   Knowledge map   Save

  Carbon dioxide energy storage technology stands out as an efficient, stable, flexible and cost-effective solution in the realm of novel energy storage technologies. It provides powerful safeguard for the new energy system construction of China, and has promising prospects for future development. The paper first introduced the overall research progress of CO2 energy storage. And then, the basic principles and advantages, engineering applications as well as improvement ideas of gas-liquid phase change CO2 energy storage system were illustrated. Finally, the future prospects of CO2 energy storage technologies were outlined, providing valuable insights and references for subsequent research in this field.
• Select
  Research progress of gravity energy storage technology

  QIU Qingquan, XIAO Liye, LUO Xiaoyue, LIN Yuxin, NIE Zipan, ZHANG Jingye, JING Liwei, TENG Yuping

  Advanced Technology of Electrical Engineering and Energy. 2025, 44(10): 50-61. https://doi.org/10.12067/ATEEE2502014

  Abstract ( ) Download PDF ( )   Knowledge map   Save

  Gravity energy storage technology based on solid weights is expected to become one of the important energy storage technologies in the water-scarce areas in the future due to its advantages of independent of water resources, flexible location and abundant resources, high efficiency, and no self-discharge, and can well meet the demand of energy storage technology for new energy power system. However, due to the discreteness and non-fluidity of solid objects, power fluctuations will occur during the load/unload and acceleration/deceleration process of solid objects, and will simultaneously have a certain impact on mechanical transmission and power grid systems. In addition, the heavy-load lifting machinery is still difficult to meet the needs of energy storage systems in terms of power, efficiency and stability currently. This paper first introduces the principle and classification of solid gravity energy storage technology, and puts forward the key scientific and technical problems that need to be solved. And then, aimed at three typical gravity energy storage technologies, such as underground shaft, ground building and mountain slope, the research status and challenges of the key technologies such as heavy load lifting, automatic connection and horizontal transfer, grid connection and power smoothing are analyzed, and then the engineering application status of three technologies are given. Finally, the future development trend of three gravity energy storage technologies is forecast.
• Select
  Molten salt thermal storage technology

  WU Yuting, ZHANG Cancan, LU Yuanwei, SANG Lixia, CHEN Xia, DU Yanjun

  Advanced Technology of Electrical Engineering and Energy. 2025, 44(10): 62-76. https://doi.org/10.12067/ATEEE2412019

  Abstract ( ) Download PDF ( )   Knowledge map   Save

  Molten salt heat storage utilizes liquid salt to absorb heat as the temperature increases and release heat as the temperature decreases. The molten salt used for heat storage is generally a eutectic mixed salt formed by mixing two or more inorganic salts in a certain proportion, which has the advantages of wide liquid temperature range, large temperature difference, high heat storage density, and long service life. Molten salt thermal storage generally uses a dual tank liquid sensible heat storage scheme, which has the advantages of constant inlet and outlet parameters of the heat storage and release heat exchanger/electric heater, small temperature difference between hot fluid outlet and hot salt tank, and simple control. It has a wide range of application scenarios in the fields of solar thermal power generation, peak shaving system of coal-fired unit aided by molten salt heat storage, molten salt direct/heat pump thermal storage and power generation, molten salt thermal storage for heating and steam supply, compressed air energy storage and compressed heat storage, etc. It is a medium to long term energy storage technology with low-cost, large capacity and long-life. The key technologies and difficulties of molten salt thermal storage are the research and development of mixed molten salt and its composite thermal storage materials with low melting point, high decomposition temperature, low corrosion, low-cost and thermally stable, the research and development of large inlet and outlet temperature difference molten salt heat exchangers and high-voltage molten salt electric heaters, and the integrated regulation and optimization of a new energy system coupled with molten salt thermal storage. At present, more than 30 integrated large capacity thermal storage solar thermal power plants have been put into commercial operation worldwide (with a total installed capacity of over 3 million kilowatts). The longest molten salt thermal storage solar thermal power plant has been successfully operating for 18 years. In recent years, in China, Huaneng Weijiamao, Guoxin Jingjiang, Huaneng Haimen, Shandong Dezhou and other thermal power plants have successively built several molten salt thermal storage peak shaving demonstration projects. At the same time, several molten salt thermal storage heating and steam supply demonstration projects have also been built in Hebei, Beijing, Zhejiang and other places. The Liaohe Oilfield has built an electric molten salt energy storage injection test station. At present, Beijing University of Technology has successfully developed a series of low melting point, high decomposition temperature, wide liquid temperature range mixed molten salt optimization formulas with melting points between 100~160 ℃ and decomposition temperatures between 560~740 ℃, and has been widely used in molten salt heat transfer and storage engineering for a long time. Zhejiang Green Storage, Huayuan Frontline and other companies have successively developed high-voltage molten salt electric heaters.
• Select
  Overview of development of solar seasonal thermal storage technology

  WANG Zhifeng, YANG Xudong, YANG Ming, WANG Dengjia, JIAO Qingtai, LI Xiaoxia, GUO Fang, YUAN Guofeng, YANG Junfeng, DU Donghui, KAN Xinyu, LEI Dongqiang, WANG Kezhen

  Advanced Technology of Electrical Engineering and Energy. 2025, 44(10): 77-106. https://doi.org/10.12067/ATEEE2508031

  Abstract ( ) Download PDF ( )   Knowledge map   Save

  In the 1980s, Sweden pioneered the construction of megawatt-scale seasonal thermal storage systems under the framework of the International Energy Agency, making this technology popular worldwide. Empirical evidence demonstrates that seasonal thermal storage can eliminate the source-load mismatch in large-scale solar heating systems, enhance the solar fraction and heat supply stability, and reduce heat prices to levels comparable to those of coal-fired systems. For China, this technology holds strategic significance in alleviating energy supply-demand contradictions and improving the utilization efficiency of renewable energy. Since 2017, seasonal thermal storage in China has entered a period of rapid growth: a series of high-level applied basic research and technology demonstration projects have been successively implemented, driving a relatively rapid decline in thermal storage costs. This paper systematically reviews the development trajectory over more than 40 years: first, it analyzes the “heat collection-storage-release” energy chain; then, it summarizes three thermal storage methods—sensible heat, latent heat, and thermochemical—and details key materials, particularly anti-seepage materials, thermal storage media, heat exchangers, system integration, and intelligent control technologies; finally, it introduces and analyzes some representative projects. Looking to the future, long-life low-cost solar seasonal thermal storage will achieve applications on the scale of tens of millions of square meters in clean heating for northern urban areas, heat supply for industrial parks, and agricultural drying, providing a paradigm for China’s “dual carbon” goals.
• Select
  Research progress on thermal conductivity enhancement of carbon-based composite thermal energy storage materials and their application in battery thermal management systems

  LUO Shenghao, LING Ziye, FANG Xiaoming, ZHANG Zhengguo

  Advanced Technology of Electrical Engineering and Energy. 2025, 44(10): 107-116. https://doi.org/10.12067/ATEEE2412024

  Abstract ( ) Download PDF ( )   Knowledge map   Save

  Temperature significantly influences the performance of power batteries, with an optimal operating range of 20~50 ℃. To effectively control the battery temperature rise and prevent thermal runaway, passive battery thermal management systems based on thermal energy storage technology have proven to be an effective solution. However, the low thermal conductivity of traditional inorganic or organic thermal storage materials often limits their application, making it crucial to enhance their thermal conductivity. This paper reviews the research progress on using carbon nanotubes, carbon fibers, graphene, and expanded graphite to improve the thermal conductivity of thermal energy storage materials. Among those, expanded graphite exhibits excellent adsorption properties for organic thermal storage materials and, after hydrophilic modification, significantly enhances the adsorption capability for hydrated inorganic salt thermal storage materials. This enables the preparation of expanded graphite composite thermal storage material powders. Through compression processing, continuous carbon-based thermal conduction pathways are formed within these composite materials, increasing their thermal conductivity by more than an order of magnitude compared to the original organic or inorganic thermal storage materials, which is far superior to other carbon-based materials such as carbon nanotubes, carbon fibers, and graphene. By introducing natural rubber into organic/expanded graphite-based composite thermal storage materials, a flexible insulating network can be formed, resulting in a dual-network encapsulated structure of flexible composite phase change thermal storage materials. These materials can effectively control the temperature rise of batteries and improve the temperature consistency between cells. Hydrated inorganic salt/expanded graphite composite thermal storage materials possess both phase change and chemical thermal storage capabilities, with a thermal storage density an order of magnitude higher than that of phase change thermal storage, providing a novel solution for mitigating battery thermal runaway. Looking ahead, further development of novel flexible thermal storage materials with both phase change and chemical thermal storage functionalities is required to meet the thermal management demands of batteries across a wide temperature range.
• Select
  Overview of supercapacitors: Mechanisms, materials, devices, and safety characteristics

  SUN Xuewen, ZHANG Keliang , LI Chen , REN Fujian , SUN Xianzhong , LIU Hongquan, WANG Kai, ZHANG Xiong, MA Yanwei

  Advanced Technology of Electrical Engineering and Energy. 2025, 44(10): 117-135. https://doi.org/10.12067/ATEEE2412028

  Abstract ( ) Download PDF ( )   Knowledge map   Save

  With the global increase in demand for sustainable energy, energy storage technology has become a key factor in achieving the green energy transition. Supercapacitors, as an important electrochemical energy storage device, have shown broad application prospects in fields such as consumer electronics, grid frequency regulation, rail transportation, electric buses, military, and aerospace, due to their excellent fast charge-discharge capability, high power density, and long cycle life. This paper mainly reviews the three basic types of supercapacitors: electric double-layer capacitors, pseudocapacitors, and hybrid supercapacitors, analyzing their energy storage mechanisms and electrode materials, with a focus on the development and classification of lithium-ion capacitors. Additionally, this paper introduces new types of supercapacitor devices and their applications, and compares the safety characteristics of lithium-ion capacitors with lithium-ion batteries, highlighting the significant advantages of lithium-ion capacitors in terms of safety.
• Select
  Research progress on flywheel energy storage and rotor fatigue life analysis

  HU Dongxu, DAI Xingjian, REN Junhui, LI Wen, XU Yujie, CHEN Haisheng

  Advanced Technology of Electrical Engineering and Energy. 2025, 44(10): 136-148. https://doi.org/10.12067/ATEEE2411056

  Abstract ( ) Download PDF ( )   Knowledge map   Save

  Flywheel energy storage technology as an efficient and long-lasting physical energy storage method effectively addresses the grid volatility issues caused by renewable energy sources such as wind and solar power. It is an essential part of the modern energy transition. However, the widespread application of flywheel energy storage faces technical challenges, including high costs and rotor fatigue life issues. This paper reviews the development and application of flywheel energy storage technology, with a focus on the design optimization and fatigue life analysis of flywheel rotors. To enhance energy storage density and reduce costs, significant research has been conducted on rotor shape and structural optimization, including designs for various types of disk-shaped and cylindrical structures. Frequent charging and discharging during high-speed operation cause stress variations, which in turn affect the rotor’s fatigue life. Therefore, predicting rotor fatigue life has become a key area of research. Traditional stress-strain-based fatigue life prediction methods have certain limitations under complex loading and multi-axial fatigue conditions. However, recent advancements in new prediction methods based on energy approaches, critical plane methods, and neural networks have shown stronger adaptability and accuracy. In particular, combining traditional methods with artificial intelligence technologies has greatly improved the accuracy of fatigue life predictions. In summary, significant progress has been made in materials, structural optimization, and fatigue life prediction for flywheel energy storage technology. However, challenges such as cost control and long-life design still need to be addressed in order to promote its widespread adoption in large-scale energy storage and grid frequency regulation applications.