@misc{3d445feab0124dea8d7e9d58134c3a1e,
title = "Studying the Impact of IBR Modeling on the Commonly Applied Transmission Line Protective Elements",
abstract = "It is a well-accepted fact that detailed inverter-based resource (IBR) models are needed for electromagnetic transient (EMT) studies, especially for protection studies and protection designs. However, it is not clear which modeling aspects should be included in the EMT model to accurately represent the IBR fault responses. Therefore, this paper addresses this gap by evaluating the impact of key modeling aspects (DC source, inverter model, power control, current/voltage control, and current limiting) on the response of protective relay elements both qualitatively and quantitatively. Both grid-following (GFL) and grid-forming (GFM) IBR models are comprehensively evaluated through a simplified real-world transmission network by varying the IBR modeling aspects, fault locations, and types. The insights and findings from this paper will benefit the power system protection community because this work provides modeling requirements and guidelines for IBR modeling so that correct IBR models will be used for protection scheme settings design.",
keywords = "grid-following inverter, grid-forming inverter, protective elements",
author = "Soham Chakraborty and Paulo Pinheiro and Romulo Bainy and Hangtian Lei and Brian Johnson and Scott Manson and Jing Wang and Rasel Mahmud and Andy Hoke and Cameron Kruse",
year = "2024",
language = "American English",
series = "Presented at the IEEE Energy Conversion Conference and Expo, 20-24 October 2024, Phoenix, Arizona",
publisher = "National Renewable Energy Laboratory (NREL)",
address = "United States",
type = "Other",
}