System-level Testing of the Congestion Management Capability of a Hardware-Independent Optimal Power Flow Algorithm

The integration of distributed energy resources (DERs) into the electrical grid causes various challenges in the distribution grids. The complexity of smart grids as multi-domain energy systems requires innovative architectures and algorithms for system control. While these solutions are good on pap...

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Veröffentlicht in:	arXiv.org 2023-09
Hauptverfasser:	Schwierz, Thomas, Palaniappan, Rajkumar, Molodchyk, Oleksii, Rehtanz, Christian
Format:	Artikel
Sprache:	eng
Schlagworte:	Algorithms Congestion Control algorithms Distributed generation Electric potential Electric power grids Energy sources Hardware Power flow Smart grid Smart grid technology Voltage
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creator	Schwierz, Thomas Palaniappan, Rajkumar Molodchyk, Oleksii Rehtanz, Christian
description	The integration of distributed energy resources (DERs) into the electrical grid causes various challenges in the distribution grids. The complexity of smart grids as multi-domain energy systems requires innovative architectures and algorithms for system control. While these solutions are good on paper, several testing methods are required to test the applicability of components, functions and entire systems to the existing energy grids. In this paper, a full-scale low-voltage test setup in the Smart Grid Technology Lab (SGTL) at TU Dortmund University is used to evaluate the capability of an Optimal Power Flow Algorithm (OPF) to support voltage control, congestion management, and to provide redispatch to the higher grid levels. While conventional redispatch is commonly done preemptively, this paper analyses the possibility of providing redispatch to the higher voltage levels without taking the future grid state into consideration. The importance of this implementation is that the smart grid application used to execute the OPF is configured based on IEC 61850 data models, making the software independent of the hardware. Such standardised control algorithms are interoperable and can be implemented on any hardware that suits the requirements.
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subjects	Algorithms Congestion Control algorithms Distributed generation Electric potential Electric power grids Energy sources Hardware Power flow Smart grid Smart grid technology Voltage
title	System-level Testing of the Congestion Management Capability of a Hardware-Independent Optimal Power Flow Algorithm
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