Comparing Thermal Library Modeling Suites for Integrated Modeling of Nuclear Power Plant and Power Grids

2023 11th Workshop on Modelling and Simulation of Cyber-Physical Energy Systems (MSCPES) Pub Date : 2023-05-09 DOI:10.1109/MSCPES58582.2023.10123419

Asad Ullah Amin Shah, Kyle Warns, Junyung Kim, M. Aguilera, L. Vanfretti, Hyun Gook Kang

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Abstract

Decarbonization efforts in the United States has resulted in the increasing interest in flexible operation of nuclear power plants or thermal storage-based hybrid energy systems integrated with the power grid. Consequently, the need for rapid and effective modeling and simulation of such integrated systems is becoming critical. This requires modeling a approach that offers capabilities for multi-domain simulation that allows to model coupled phenomena accurately. This work focused on developing a proof of concept of such multi-domain models by designing a nominal model of a nuclear power plant balance of plant (BOP) system using the Modelica libraries. To model the thermofluidic domain, three libraries are evaluated, namely, ORNL’s TRANSFORM, Modelon’s ThermalPower, and Casella’s ThermoPower. Next, the thermofluidic model is coupled with an electrical grid model built using the OpenIPSL. To understand the tradeoffs of each library, the response of each different model to power transients in the nuclear power plant was analyzed. Simulation results and modeling methods were compared. The BOP model in TRANSFORM was found to be stiff and may require more detailed component models, e.g. condenser and feed water heater, to model the BOP more realistically and rapidly.

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核电厂与电网集成建模的热库建模套件比较

在美国，脱碳的努力导致人们对核电厂的灵活运行或与电网相结合的基于热储存的混合能源系统的兴趣日益增加。因此，对这种集成系统进行快速有效的建模和仿真的需求变得至关重要。这需要建模一种方法，该方法提供多域仿真功能，允许对耦合现象进行精确建模。这项工作的重点是通过使用Modelica库设计核电站电厂平衡(BOP)系统的标称模型，开发这种多领域模型的概念证明。为了对热流体域进行建模，评估了三个库，即ORNL的TRANSFORM, Modelon的ThermalPower和Casella的ThermoPower。接下来，热流体模型与使用OpenIPSL建立的电网模型相耦合。为了了解每个库的权衡，分析了每个不同模型对核电厂功率暂态的响应。仿真结果与建模方法进行了比较。TRANSFORM中的防喷器模型被认为是僵硬的，可能需要更详细的组件模型，例如冷凝器和给水加热器，以更真实和快速地模拟防喷器。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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2023 11th Workshop on Modelling and Simulation of Cyber-Physical Energy Systems (MSCPES)

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