CAREER: A Multiphysics Framework for Modeling, Analysis, and Experimentation of Power Systems and Power Electronics

职业：电力系统和电力电子建模、分析和实验的多物理场框架

• 批准号: 2314415
• 负责人: Brian Johnson
• 金额: $ 50万
• 依托单位: University of Texas at Austin
• 依托单位国家: 美国
• 项目类别: Continuing Grant
• 财政年份: 2022
• 资助国家: 美国
• 起止时间: 2022-10-01 至 2027-02-28
• 项目状态: 未结题
• 来源: https://www.nsf.gov/awardsearch/showAward?AWD_ID=2314415&HistoricalAwards=false
• 关键词: CAREER; Multiphysics; Framework; Modeling; Analysis

Today, power systems are conceptualized as a convoluted tangle of passive components, power electronics, rotating machinery, and control loops at various scales. Each subsystem is typically studied in a myopic manner with specifically tailored methods. In this proposal, we show how closed-loop multiphysics energy systems can be unified under a circuit theoretic framework and prototyped effectively with power electronics emulation. Since power electronics and their closed-loop control action can be modeled as equivalent circuits, models are obtained that effectively bridge the power electronics and power systems divide, from the converter-level (Watts) to the system-level (Megawatts). Research themes are uniquely poised at the confluence of circuits, control, and power such that project outcomes will address fundamental challenges in the design of sustainably-powered future systems. The proposed techniques naturally yield a variety of learning opportunities where complex systems and their controls can be straightforwardly depicted and their actual behavior becomes obvious once seen as a circuit. Accordingly, this framework codifies numerous topics within electrical engineering so that students can seamlessly apply concepts across their educational experience.The project will develop modeling and experimentation frameworks that allow for the study of energy dynamics in modern systems. The underlying approach is based on first showing that well-known circuit laws are naturally embedded in control feedback paths for power electronics. This allows for a direct translation of controller dynamical behavior into equivalent circuit representations for converters; extensions are further made for heterogeneous systems containing power electronics, sensors, and machinery. What emerges is a comprehensive framework for closed-loop power systems and electronics modeling where energy acts as the fundamental link between subsystem models. Research thrusts focus on: developing equivalent circuit models for multiphysics systems with closed-loop cyber controls; formulating circuit models for complex power systems with massive utilization of electronics and their accompanying fast controls; and outlining a suite of experimental methodologies for emulation of multiphysics power systems and electromechanics.This award reflects NSF's statutory mission and has been deemed worthy of support through evaluation using the Foundation's intellectual merit and broader impacts review criteria.

如今，电力系统被概念化为各种规模的无源元件、电力电子设备、旋转机械和控制回路的错综复杂的组合。每个子系统通常都是通过专门定制的方法以短视的方式进行研究。在本提案中，我们展示了如何在电路理论框架下统一闭环多物理场能源系统，并通过电力电子仿真有效地进行原型设计。由于电力电子器件及其闭环控制动作可以建模为等效电路，因此获得的模型可以有效地弥合电力电子器件和电力系统之间的鸿沟，从转换器级（瓦）到系统级（兆瓦）。研究主题独特地集中在电路、控制和电源的融合上，以便项目成果将解决可持续供电的未来系统设计中的基本挑战。所提出的技术自然会产生各种学习机会，可以直接描述复杂的系统及其控制，并且一旦将其视为电路，它们的实际行为就会变得显而易见。因此，该框架将电气工程中的众多主题编入法典，以便学生可以在其教育经历中无缝应用概念。该项目将开发建模和实验框架，以便研究现代系统中的能量动力学。基本方法首先表明众所周知的电路定律自然地嵌入到电力电子设备的控制反馈路径中。这允许将控制器动态行为直接转换为转换器的等效电路表示；进一步对包含电力电子、传感器和机械的异构系统进行了扩展。出现的是闭环电力系统和电子建模的​​综合框架，其中能源充当子系统模型之间的基本链接。研究重点是：开发具有闭环网络控制的多物理场系统的等效电路模型；为复杂电力系统制定电路模型，大量使用电子设备及其伴随的快速控制；并概述了一套用于仿真多物理场电力系统和机电学的实验方法。该奖项反映了 NSF 的法定使命，并通过使用基金会的智力优点和更广泛的影响审查标准进行评估，被认为值得支持。