全院士阵容!《新能源系统与装备(英文)》创刊号论文上线
近日,《新能源系统与装备(英文)》期刊创刊号已正式上线,论文全部来源于院士团队。期刊首期汇集了刘吉臻院士、舒印彪院士、杨勇平院士、汤广福院士、王秋良院士、叶思宇院士共6位院士团队的论文,主题包括:新型电力系统发展方向与关键技术、特高压输电技术发展与展望、太阳能辅助燃煤发电研究进展、VSC-HVDC海上风电关键技术与进展、用于超导磁体的REBCO超导带性能研究进展、PEMWE和AI协同加速绿氢革命。
《Renewable Energy System and Equipment》(《新能源系统与装备(英文)》)是由教育部主管,西安交通大学与西安高压电器研究院股份有限公司联合主办的英文期刊,王秋良院士担任主编,荣命哲教授担任执行主编。16位院士组成顾问委员会,刘吉臻院士担任顾问委员会主任。期刊入选“中国科技期刊卓越行动计划高起点新刊”。期刊采用OA(开放获取)模式由爱思唯尔负责在ScienceDirect?平台出版发行,初期版面费全免。
【主编简介】
主编 王秋良
王秋良,中国科学院院士,强电磁工程与技术专家,中国科学院电工研究所研究员、教授、博士生导师,西安交通大学兼职教授,《Renewable Energy System and Equipment》期刊主编。长期致力于强电磁装备基础理论与工程技术的研究,重点涉及复杂电磁结构的极高磁场超导磁体基础科学与技术问题,解决了在特种科学仪器等国家重大需求方面的科学与技术问题,取得了一系列创新的科学研究成果,以第一完成人获得国家技术发明二等奖2项(2013年,2017年),国家科技进步二等奖1项(2009年)。
执行主编 荣命哲
荣命哲,西安交通大学电气工程学院教授、博士生导师,国家杰出青年基金获得者,入选国家级人才计划,973项目首席科学家,国家自然科学基金委创新群体带头人,教育部创新团队负责人,国家重点研发计划项目负责人。兼任教育部科技委委员,中国电工技术学会副理事长,《中国电工技术学报》常务副主编和《Renewable Energy System and Equipment》期刊执行主编。长期致力于电力装备设计数字化、材料环保化、技术直流化、运维智能化等基础理论及关键技术研究。以第一完成人获国家技术发明二等奖和国家科技进步二等奖各1项,第二完成人获国家科技进步奖二等奖2项,以第一完成人获国家级教学成果二等奖2项,以第一完成人获省部级科技奖励3项,荣获第三届全国创新争先奖、“高景德”科技成就奖等荣誉。
【编委会】
Associate Editors-in-Chief
副主编
Editorial Board Members
编委
【顾问委员会】
1.华北电力大学刘吉臻院士团队论文
Development direction, technical issues, and key construction tasks for new power system
Qinghua Wang, Yujing Huang, Yankai Zhu, Jizhen Liu, Zhongming Du
North China Electric Power University, Beijing 102206
Abstract
The implementation of green energy transformation, clean energy power replacement and supply, and the construction of the new power system are the primary driving forces for achieving strategic goals of carbon peak and carbon neutrality in China. The construction of the new power system is in a critical period of initiation and development, and it is necessary to clarify the direction of future development, clarify the current technical challenges and key technical issues, and determine the key technical tasks for the future. In this context, this study analyzes the development direction, technical issues, and key construction tasks of the new power system. Firstly, the development challenges of the new power system are analyzed from two aspects: the current situation of flexible regulation resources and the safety issues related to frequency and voltage. Secondly, the direction of technological innovation is analyzed from four aspects: the multiple power sources complementarity technology, power source and power grid collaborative technology, power supply and load interaction technology, and flexible and intelligent control technology. On this basis, three major technical issues are sorted out. Finally, the key construction tasks of the basic theory, flexible power generation, and collaborative control are detailed.
原文链接:
https://www.sciencedirect.com/science/article/pii/S2950208X24000012
引用此文:
Qinghua Wang, Yujing Huang, Yankai Zhu, Jizhen Liu, Zhongming Du. Development direction, technical issues, and key construction tasks for new power system. Renewable Energy System and Equipment, 2025, 1(1), 1-7. https://doi.org/10.1016/j.rese.2024.03.001
2. 国家电网公司舒印彪院士团队论文
Development and prospect of UHV transmission technology
Peng Lia, Yinbiao Shub, Chen Gua, Tianyang Liuc,d, Liang Zhaod
a China Electric Power Research Institute, Beijing 100192
b State Grid Corporation of China, Beijing 100031
c State Key Laboratory of Alternate Electrical Power System with Renewable Energy Sources, North China Electric Power University, Beijing 102206
d China Huaneng Group Carbon Neutrality Research Institute, Beijing 100031
Abstract
Since 2009, ultra-high voltage (UHV) transmission technology has been promoted and applied in China. Over the years, with the accumulation of experience in the construction and operation of UHV projects and the continuous deepening of scientific and technological innovation, UHV technology and key equipment have made great progress. This paper introduces the main achievements of UHV technology innovation from various perspectives including electromagnetic environment, overvoltage and insulation coordination, external insulation and major equipment such as converter transformers, converter valves and gas-insulated transmission lines (GIL).
原文链接:
https://www.sciencedirect.com/science/article/pii/S2950208X24000024
引用此文:
Peng Li, YinbiaoShu, Chen Gu, Tianyang Liu, Liang Zhao. Development and prospect of UHV transmission technology. Renewable Energy System and Equipment, 2025, 1(1), 8-19. https://doi.org/10.1016/j.rese.2024.03.002
3. 华北电力大学杨勇平院士团队论文
Research progress of solar aided coal-fired power generation (SACPG) system
Yuanhui Wanga, Liqiang Duana,b,c, Shuaiyu Jia, Jiaping Guoa, Zhaoxia Duana, Chenxi Lva, Hanfei Zhanga,b,c, Yongping Yanga,b,c
a School of Energy, Power and Mechanical Engineering, North China Electric Power University, Beijing 102206
b State Key Laboratory of Alternate Electric Power System with Renewable Energy Sources (NCEPU), National Thermal Power Engineering & Technology Research Center, North China Electric Power University, Beijing 102206
c Beijing Laboratory of New Energy Storage Technology, North China Electric Power University, Beijing 102206
Abstract
Solar aided coal-fired power generation (SACPG) is the most efficient and economical technology for reducing coal resource consumption and increasing solar energy efficiency by integrating solar thermal with conventional coal-fired power generation systems. This paper reviews the recent research progress of solar aided coal-fired power generation systems, including integration schemes, analytical methods, optimization methods and engineering applications. Firstly, according to the solar collector type, the integration schemes are categorized into trough, tower, combined trough-tower and non-concentrating flat plate, and the application of energy storage technology in the SACPG system is introduced. Secondly, the performance analysis of the complementary system is introduced including energy analysis, exergy analysis, environmental performance analysis and economic performance analysis, followed by a detailed summary of multiple solar contribution evaluation methods and optimization methods, and an analysis of the principle of each evaluation method. Finally, the current engineering application cases of solar aided coal-fired power stations in the world are summarized, and the outlook for the future development of SACPG system is presented.
原文链接:
https://www.sciencedirect.com/science/article/pii/S2950208X24000036
引用此文:
Yuanhui Wang, Liqiang Duan, Shuaiyu Ji, Jiaping Guo, Zhaoxia Duan, Chenxi Lv, Hanfei Zhang, Yongping Yang. Research progress of solar aided coal-fired power generation (SACPG) system. Renewable Energy System and Equipment, 2025, 1(1), 20-34. https://doi.org/10.1016/j.rese.2024.04.001
4. 怀柔实验室汤广福院士团队论文
Key technologies and development trends of VSC-HVDC transmission for offshore wind power
Zhiyuan Hea, Jie Yangc, Guangfu Tangc, Yuexi Yanga, Zhenyu Dub, Sheng Zhangb
a State Key Laboratory of Advanced Power Transmission Technology (China Electric Power Research Institute Co., Ltd.), Beijing 100192
b China Beijing Key Laboratory of DC Grid Technology and Simulation (China Electric Power Research Institute Co., Ltd.), Beijing 100192
c Beijing Huairou Laboratory, Huairou District, Beijing 101400
Abstract
Developing offshore wind power, particularly in deep waters, is recognized as a vital approach to tackling the energy crisis and facilitating a low-carbon transition. VSC-HVDC transmission, leveraging its technological prowess, has emerged as the principal means for transmitting large-scale, remotely located offshore wind energy. In recent years, numerous VSC-HVDC grid interconnection projects for offshore wind farms have been commissioned globally, with the technology itself continually advancing and improving. This paper, in light of prevailing technological trends, provides a comprehensive overview of the advancements in key technologies within VSC-HVDC transmission tailored to the requirements of offshore wind power evacuation, encompassing system topology, operating modes, control and protection systems, essential equipment, and platform configurations. It further details the profiles of representative offshore wind power VSC-HVDC transmission and grid connection projects currently operational or under construction, and delves into the prospective development trajectories and future research avenues for offshore wind power VSC-HVDC transmission technology.
原文链接:
https://www.sciencedirect.com/science/article/pii/S2950208X24000061
引用此文:
Zhiyuan He, Jie Yang, Guangfu Tang, Yuexi Yang, Zhenyu Du, Sheng Zhang. Key technologies and development trends of VSC-HVDC transmission for offshore wind power. Renewable Energy System and Equipment, 2025, 1(1), 35-49. https://doi.org/10.1016/j.rese.2024.09.001
5. 中科院电工所王秋良院士团队论文
Research progress on the properties of REBCO superconductor tapes for the application of superconducting magnet
Zili Zhanga, Benzhe Zhoua, Lei Wanga,b, Jianhua Liua,b,c, Qiuliang Wanga,b
a Institute of Electrical Engineering, Chinese Academy of Sciences, Beijing 100190
b University of Chinese Academy of Sciences, Beijing 100049
c Key Laboratory of High Density Electromagnetic Power and Systems, Chinese Academy of Sciences, Institute of Electrical Engineering, Chinese Academy of Sciences, Beijing 100190
Abstract
In this paper, we want to briefly review the progress of research on the properties of REBCO superconductor tapes, especially for the superconducting magnet. Firstly, we will introduce the progress of the RBCO superconducting magnet. Then, we will discuss what kind of properties the REBCO superconducting magnet requires and their relevance. Based on these requirements, we individually introduce the research progress of these properties, including the measurement method, measurement equipment, data resources, and whether it is enough for the magnet design. We hope this paper can give initial guidance to the REBCO superconducting magnet designer and tape investigator on the properties of REBCO commercial tape.
原文链接:
https://www.sciencedirect.com/science/article/pii/S2950208X24000048
引用此文:
Zili Zhang, Benzhe Zhou, Lei Wang, Jianhua Liu, Qiuliang Wang. Research progress on the properties of REBCO superconductor tapes for the application of superconducting magnet. Renewable Energy System and Equipment, 2025, 1(1), 50-60. https://doi.org/10.1016/j.rese.2024.10.001
6. 广州大学叶思宇院士团队论文
Accelerating the green hydrogen revolution: The synergy of PEMWE and AI
Ning Wanga, Huanxin Xianga, Ling Menga, Chunmei Tanga, Zhun Dongb, Yunsong Yangb, Lei Dua, Siyu Yea,b
a Huangpu Hydrogen Energy Innovation Center, School of Chemistry and Chemical Engineering, Guangzhou University, Guangzhou 510006
b SinoHykey Technology Company, Ltd., Guangzhou 510760
Abstract
The urgent need to address rising CO2 levels and climate change has driven a global shift towards low-carbon and zero-carbon energy sources. Green hydrogen energy produced through water electrolysis has become as a crucial technology in this transition. Proton exchange membrane water electrolyzers (PEMWEs) emerging as a frontrunner in green hydrogen production technologies, have attracted significant attention due to their efficiency and compatibility with renewable energy sources. In this perspective, the components and challenges of PEMWEs are discussed, demonstrating the need for innovative research to overcome the existing limitations in key materials, such as electrocatalysts, membranes, membrane electrode assemblies (MEAs), stacks, and systems. Moreover, the synergistic potential of Artificial Intelligence (AI) and PEMWE research in terms of discovery and optimization of key materials, design and optimization of MEA, cell, and stack-level management are highlighted. While emphasizing AI's transformative potential in advancing PEMWE technology, we also pointed out the challenges in integrating AI with PEMWE research. This perspective underscores the pivotal role of AI-PEMWE synergy in advancing green hydrogen production and global carbon neutrality efforts.
原文链接:
https://www.sciencedirect.com/science/article/pii/S2950208X2400005X
引用此文:
Ning Wang, Huanxin Xiang, Ling Meng, Chunmei Tang, Zhun Dong, Yunsong Yang, Lei Du, Siyu Ye. Accelerating the green hydrogen revolution: The synergy of PEMWE and AI. Renewable Energy System and Equipment, 2025, 1(1), 61-66. https://doi.org/10.1016/j.rese.2024.10.002
