A Resilient Integrated Resource Planning Framework for Transmission Systems: Analysis and Optimization

This article presents a resilient Integrated Resource Planning (IRP) framework designed for transmission systems, with a specific focus on analyzing and optimizing responses to High-Impact Low-Probability (HILP) events. The framework aims to improve the resilience of transmission networks in the fac...

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Veröffentlicht in:	Sustainability 2024-03, Vol.16 (6), p.2449
Hauptverfasser:	Gautam, Mukesh, McJunkin, Timothy, Hruska, Ryan
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Sprache:	eng
Schlagworte:	Algorithms Blackouts Buses Case studies Decision making Electric power Electric power transmission Electric vehicles Electricity Electricity distribution Energy storage Innovations Linear programming Optimization Power supply Strategic planning Sustainable development Typhoons
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creator	Gautam, Mukesh McJunkin, Timothy Hruska, Ryan
description	This article presents a resilient Integrated Resource Planning (IRP) framework designed for transmission systems, with a specific focus on analyzing and optimizing responses to High-Impact Low-Probability (HILP) events. The framework aims to improve the resilience of transmission networks in the face of extreme events by prioritizing the assessment of events with significant consequences. Unlike traditional reliability-based planning methods that average the impact of various outage durations, this work adopts a metric based on the proximity of outage lines to generators to select HILP events. The system’s baseline resilience is evaluated by calculating load curtailment in different parts of the network resulting from HILP outage events. The transmission network is represented as an undirected graph. Graph-theoretic techniques are used to identify islands with or without generators, potentially forming segmented grids or microgrids. This article introduces Expected Load Curtailment (ELC) as a metric to quantify the system’s resilience. The framework allows for the re-evaluation of system resilience by integrating additional generating resources to achieve desired resilience levels. Optimization is performed in the re-evaluation stage to determine the optimal placement of distributed energy resources (DERs) for enhancing resilience, i.e., minimizing ELC. Case studies on the IEEE 24-bus system illustrate the effectiveness of the proposed framework. In the broader context, this resilient IRP framework aligns with energy sustainability goals by promoting robust and resilient transmission networks, as the optimal placement of DERs for resilience enhancement not only strengthens the system’s ability to withstand and recover from disruptions but also contributes to efficient resource utilization, advancing the overarching goal of energy sustainability.
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subjects	Algorithms Blackouts Buses Case studies Decision making Electric power Electric power transmission Electric vehicles Electricity Electricity distribution Energy storage Innovations Linear programming Optimization Power supply Strategic planning Sustainable development Typhoons
title	A Resilient Integrated Resource Planning Framework for Transmission Systems: Analysis and Optimization
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