Power Systems Protection, Control of Bulk Power and Renewable Energy Integrated Systems, and Real Time Simulations

电力系统保护、大容量电力和可再生能源集成系统的控制以及实时仿真

• 批准号: RGPIN-2015-06578
• 负责人: Gokaraju, Ramakrishna(Rama)
• 金额: $ 2.19万
• 依托单位: University of Saskatchewan
• 依托单位国家: 加拿大
• 项目类别: Discovery Grants Program - Individual
• 财政年份: 2016
• 资助国家: 加拿大
• 起止时间: 2016-01-01 至 2017-12-31
• 项目状态: 已结题
• 来源: https://www.nserc-crsng.gc.ca/ase-oro/Details-Detailles_eng.asp?id=614230
• 关键词: Power; Systems; Protection; Control; Bulk

The electric power grid is undergoing rapid modernization in terms of its operation. Communications and electronic hardware technologies are playing a major role in facilitating the realization of the modern grid. The candidate’s research program deals with protection and control of large power systems and renewable energy systems (e.g., wind and solar power) and uses real-time measurements, electromagnetic simulations, and practical testing and verification using hardware-in-the-loop simulations. His research has developed new methods for power systems protective relaying and control as well as renewable energy systems, such as novel real-time transient stability prediction/out of step protection using state-plane analysis, adaptive relaying for generator protection, accurate dynamic phasor models for wind generators, and adaptive control of power systems. The research proposed herein will now move to methodologies for practical implementation of the proposed techniques using state-of-the-art communication technologies and hardware implementation using low latency electronics hardware such as field programmable gate arrays (FPGAs) and testing using power hardware-in-the-loop (PHIL). He will also develop models for renewable energy systems to design relevant protections and controls. During the next five years, the candidate’s graduate students will focus on four short-term objectives: (1) Transient stability protection and voltage instability protection, including implementation of state plane methods for transient stability prediction using state-of-the-art IEC 61850-enabled communication and realistic comparisons with other industry methods; (2) Experimental testing using PHIL, including creation of a novel test platform with actual machines and real-time simulator and investigation of the performance of new relaying and control methodologies developed in my laboratory and their interaction with other manufacturer protection and control functions; (3) Modeling of generator protection/control to improve dynamic models and investigate their performance using electromagnetic transient (EMT) models; and (4) Modeling and integration of renewable energy by implementing dynamic phasor models on a real-time simulation platform, testing their accuracy using field recordings, and investigating the impact of wind and solar photovoltaics (PV) on transient stability. The proposed research program will lead to scientific advancements and contribute to the industry know-how for designing new system protection and control schemes. It will  help in making the power systems more secure and improve the operation of renewable energy integrated power systems. The research program will also focus on the training of highly qualified persons (HQP) and provide a source of HQP for the industry.

电网的运行正在经历快速现代化，通信和电子硬件技术在促进现代电网的实现中发挥着重要作用。候选人的研究项目涉及大型电力系统和可再生能源系统的保护和控制。他的研究开发了电力系统继电保护和控制以及可再生能源的新方法。能源系统，例如作为使用状态平面分析的新型实时暂态稳定性预测/失步保护、发电机保护的自适应继电、风力发电机的精确动态相量模型以及电力系统的自适应控制，本文提出的研究现在将转向用于电力系统的方法。他将使用最先进的通信技术实际实施所提出的技术，并使用低延迟电子硬件（例如现场可编程门阵列（FPGA））进行硬件实施，并使用功率硬件在环（PHIL）进行测试。还开发模型未来五年，候选人的研究生将重点关注四个短期目标：（1）暂态稳定保护和电压不稳定保护，包括实施暂态稳定预测的状态平面方法。使用最先进的 IEC 61850 通信并与其他行业方法进行实际比较；(2) 使用 PHIL 进行实验测试，包括使用实际机器和实时模拟器创建新颖的测试平台，并研究我的实验室开发的新继电和控制方法及其与其他制造商保护和控制功能的交互；(3) 发电机保护/控制建模，以改进动态模型并使用电磁瞬态 (EMT) 模型研究其性能；以及 (4) 建模通过在实时仿真平台上实施动态相量模型，使用现场记录测试其准确性，并研究风能和太阳能光伏（PV）对瞬态稳定性的影响，拟议的研究计划将带来科学进步。并做出贡献设计新系统保护和控制方案的行业专业知识将有助于提高电力系统的安全性并改善可再生能源综合电力系统的运行。 HQP）并为行业提供HQP来源。