Online Monitoring of Smart Grid Infrastructures Using Power Line Communications

使用电力线通信在线监控智能电网基础设施

• 批准号: RGPIN-2019-03965
• 负责人: Lampe, Lutz
• 金额: $ 4.01万
• 依托单位: University of British Columbia
• 依托单位国家: 加拿大
• 项目类别: Discovery Grants Program - Individual
• 财政年份: 2022
• 资助国家: 加拿大
• 起止时间: 2022-01-01 至 2023-12-31
• 项目状态: 已结题
• 来源: https://www.nserc-crsng.gc.ca/ase-oro/Details-Detailles_eng.asp?id=752162
• 关键词: Online; Monitoring; Smart; Grid; Infrastructures

One of the tenets of smart power grids is the availability of pervasive and real-time monitoring and control of system parameters for the integration of distributed generation and improved reliability and efficiency of electricity supply. Beyond the operational grid features, real-time monitoring and control can be extended to grid assets. This includes transmission lines and underground cables, and equipment such as transformers and switchgear. Asset monitoring typically requires the implementation of dedicated sensing devices and a communication link to a control centre at which the sensor information is processed. Asset monitoring also involves significant human intervention and often is done only after a fault occurred or in a maintenance that requires the asset to be taken out of operation. In this research proposal, we will investigate and develop the use of power line communication (PLC) for online monitoring of grid assets. The underlying paradigm is that the PLC signals, whose primary purpose is to carry data, travel through the grid and thus enable inference about its properties. This applies to transmission lines and cables, through which PLC signals propagate, and extends to connected assets which affect the signal propagation and may generate distinct signal signatures in case of anomalies. The main expected benefit of the proposed approach is that monitoring would occur real-time and continuously without any service interruption and human intervention, i.e., PLC enables true online monitoring, which is not available today. It also means that degradation of e.g. cable health can be detected before a fault occurs and preventative measures and targeted maintenance of components can be scheduled. This will provide significant economic benefits for system operators and service-level improvement for consumers. The proposed research will focus on cable aging and fault monitoring as a concrete and difficult application case. The main objective is to develop a framework for PLC -enabled grid monitoring that consists of a PLC transmission front--end and an information processing back--end, which together achieve autonomous classification and severity estimation for cable degradation. The research program will thoroughly address the main challenges in achieving this objective. These include modelling of degradation mechanisms based on physical principles, extraction of features from PLC signals which are indicative of infrastructure status, combining of features from many measurements and integration of machine learning methods for automated inference, studying the feasibility of the proposed methods with commercially available PLC products, and experimental verification of models and methods. The research will further be extended to other grid-infrastructure monitoring tasks and will also be evaluated in terms of best complementing the existing monitoring methods.

智能电网的原则之一是对系统参数进行普遍、实时的监测和控制，以集成分布式发电，并提高供电的可靠性和效率。可以扩展到电网资产，这包括输电线路和地下电缆以及变压器和开关设备等设备，通常需要实施专用传感设备和与处理传感器信息的控制中心的通信链路。监测还涉及大量的人为干预，并且经常仅在发生故障或需要停止运行的维护时进行。在本研究提案中，我们将研究和开发使用电力线通信 (PLC) 进行电网资产在线监控的范例。 PLC 信号的主要目的是传输数据，通过网格传输，从而能够推断其属性。这适用于 PLC 信号传播的传输线和电缆，并延伸到影响信号传播和连接的资产。可能会产生不同的信号特征所提出的方法的主要预期好处是可以实时、连续地进行监控，而无需任何服务中断和人为干预，即 PLC 可以实现真正的在线监控，而这也意味着当今无法实现的。例如，可以在故障发生之前检测到电缆的健康状况，并可以安排预防措施和有针对性的组件维护，这将为系统运营商带来显着的经济效益，并提高消费者的服务水平。作为一个具体且困难的应用案例。主要目标是开发一个支持 PLC 的电网监测框架，该框架由 PLC 传输前端和信息处理后端组成，结合了电缆退化的自主分类和严重性估计。​该研究计划将彻底解决实现这一目标的主要挑战，包括基于物理原理的退化机制建模、从指示基础设施状态的 PLC 信号中提取特征、结合许多测量的特征以及集成机器学习方法以进行自动推理、研究。所提出方法的可行性该研究将进一步扩展到其他电网基础设施监测任务，并根据现有监测方法的最佳补充进行评估。