Session 2: Next-Generation Power Equipment and Its Grid-Integration Performance: From Structural Optimization to System Coordination “新一代电力装备及其并网性能:从结构优化到系统协同”
The development of new-type power systems imposes unprecedented requirements on core power apparatus. Conventional equipment, originally designed for synchronous generator-dominated systems and passive load behaviors, faces critical challenges in insulation reliability, power conversion flexibility, and grid-connection stability under conditions of high renewable energy penetration and widespread adoption of power electronic interfaces. The performance of next-generation power apparatus—including advanced transformers, power electronic converters, solid-state switches, and flexible AC transmission system (FACTS) devices—is no longer determined solely by its intrinsic electromagnetic or dielectric properties. Instead, the dynamic interaction between apparatus and the grid, characterized by multi-timescale energy conversion and fault response behaviors, has become a decisive factor for overall system security and efficiency. This session aims to bridge the gap between apparatus-level innovation and system-level integration, inviting contributions that address the entire chain from physical design and material enhancement to operational control, grid-support capability, and lifecycle management.
新型电力系统的建设对核心电力装备提出了前所未有的要求。传统装备原本面向同步机主导系统与无源负荷特性设计,在高比例可再生能源渗透及电力电子接口广泛应用的条件下,在绝缘可靠性、电能变换灵活性及并网稳定性等方面面临严峻挑战。新一代电力装备(包括先进变压器、电力电子变换器、固态开关及柔性交流输电装置等)的性能不再仅由其本体的电磁或介电特性决定。相反,装备与电网之间的动态交互(表现为多时间尺度的能量变换与故障响应行为)已成为决定系统整体安全性与效率的关键因素。本专题旨在弥合装备级创新与系统级集成之间的鸿沟,诚邀从物理设计、材料优化到运行控制、并网支撑及全生命周期管理的全链条研究成果。
Topics (Including but not limited to)
- Structural optimization, advanced insulation materials, and multi-physics modeling for next-generation power apparatus such as high-power-density transformers, reactors, and solid-state switches.
新一代电力装备(如高功率密度变压器、电抗器及固态开关)的结构优化、先进绝缘材料与多物理场建模技术。 - High-efficiency power conversion topologies (AC/DC, DC/DC, DC/AC) and advanced modulation strategies for grid-interfaced apparatus, including power electronic transformers.
并网型装备(含电力电子变压器)的高效电能变换拓扑(AC/DC、DC/DC、DC/AC)与先进调制策略。 - Advanced control methods for power electronic apparatus under grid disturbances, such as AI-enabled control, hybrid physics-informed model predictive control, and coordinated multi-apparatus support for frequency and voltage regulation.
电网扰动下电力电子装备的先进控制方法,如人工智能控制、混合物理信息模型预测控制以及面向频率/电压调节的多装备协同支撑。 - Grid-integration performance and interaction stability of converter-interfaced apparatus, covering small-signal impedance modeling, fault ride-through capability, fault current contribution, and power quality mitigation.
变流器型并网装备的并网性能与交互稳定性,涵盖小信号阻抗建模、故障穿越能力、故障电流贡献及电能质量抑制。 - Reliability, online condition monitoring, and intelligent operation & maintenance of power electronic apparatus, including failure mechanisms, digital twin-based state sensing, and AI-driven predictive maintenance.
电力电子装备的可靠性、在线状态监测与智能运维,包括失效机理、基于数字孪生的状态感知以及人工智能驱动的预测性维护。 - System-level integration, planning, and digitalization for apparatus-grid systems, considering equipment degradation, operational resilience, multi-timescale simulation, and hardware-in-the-loop testing.
面向装备-电网系统的系统级集成、规划与数字化,兼顾装备性能衰减、运行弹性、多时间尺度仿真及硬件在环测试。
Chair: Dr. Qilong Wang, State Grid Shanghai Municipal Electric Power Company, China
Dr. Qilong Wang received his Bachelor of Engineering degree in Electrical Engineering from North China Electric Power University in 2020, and his Ph.D. degree in Electrical Engineering from Zhejiang University in 2025. He is currently working at the Electric Power Research Institute of State Grid Shanghai Municipal Electric Power Company. His research focuses on novel power apparatus and system performance enhancement, fault analysis, protection and control. He has presided over one project of the National Natural Science Foundation of China (NSFC), and has participated as a core member in the National Key R&D Program of China, the Zhejiang Provincial Natural Science Foundation, and the headquarters technology projects of State Grid Corporation of China. He has been successively selected into the Zhejiang University Doctoral Academic Rising Star Program, the Zhejiang Provincial Xinmiao Talent Program, and the Zhejiang University Excellent Doctoral Dissertation Cultivation Program. As the first author, he has published 8 SCI journal papers (including 4 in CAS Q1/Q2 Top journals) and 6 EI/core journal papers, and has been authorized or filed 10 invention patents. He has received numerous awards, including the Doctoral National Scholarship, the Wang Guosong Scholarship (the highest honor in Electrical Engineering at Zhejiang University), the Best Paper Award and Best Presentation Award at IEEE international conferences, and the First Prize in the East China Division of the University Electrical and Electronic Engineering Innovation Competition. He has served as a session chair for IEEE international conferences and acts as a reviewer for renowned journals in the fields of electrical engineering and physics, including IEEE TDEI, IEEE TPEL, CSTE, and EPSR.
Critical Dates/重要日期
| Submission of Full Paper: | July 15th, 2026 |
| 投稿截止日: | 2026年7月15日 |
| Notification Deadline | August 15th, 2026 |
| 通知书发送: | 2026年8月15日 |
| Registration Deadline: | August 30th, 2026 |
| 注册截止日: | 2026年8月30日 |
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2026 10th International Conference on Smart Grid and Smart Cities (ICSGSC)