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Bibliographic Details
Main Authors: Freytes, Julian, Rossé, Antoine, Costan, Valentin, Prime, Grégoire
Format: Preprint
Published: 2023
Subjects:
Online Access:https://arxiv.org/abs/2303.00391
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author Freytes, Julian
Rossé, Antoine
Costan, Valentin
Prime, Grégoire
author_facet Freytes, Julian
Rossé, Antoine
Costan, Valentin
Prime, Grégoire
contents Future power systems will include high shares of inverter-based generation. There is a general consensus that for allowing this transition, the Grid-Forming (GFM) control approach would be of great value. This article presents a GFM control strategy which is based on the concept of an Emulated Synchronous Condenser in parallel with a controlled current source with an explicit representation of the swing equation. The advantage of this control is that it can cope with challenging grid code requirements such as severe phase jumps, balanced and unbalanced Fault Ride-Through (FRT), main grid disconnection and black start. All these scenarios can be surpassed with a single control structure with no further logic involved (e.g. fault detection to turn on or off different control parts, freezes, etc.). The proposed strategy is evaluated via time-domain simulations of a 2-MW Battery Energy Storage System (BESS).
format Preprint
id arxiv_https___arxiv_org_abs_2303_00391
institution arXiv
publishDate 2023
record_format arxiv
spellingShingle Grid-Forming Control Based On Emulated Synchronous Condenser Strategy Compliant With Challenging Grid Code Requirements
Freytes, Julian
Rossé, Antoine
Costan, Valentin
Prime, Grégoire
Systems and Control
Future power systems will include high shares of inverter-based generation. There is a general consensus that for allowing this transition, the Grid-Forming (GFM) control approach would be of great value. This article presents a GFM control strategy which is based on the concept of an Emulated Synchronous Condenser in parallel with a controlled current source with an explicit representation of the swing equation. The advantage of this control is that it can cope with challenging grid code requirements such as severe phase jumps, balanced and unbalanced Fault Ride-Through (FRT), main grid disconnection and black start. All these scenarios can be surpassed with a single control structure with no further logic involved (e.g. fault detection to turn on or off different control parts, freezes, etc.). The proposed strategy is evaluated via time-domain simulations of a 2-MW Battery Energy Storage System (BESS).
title Grid-Forming Control Based On Emulated Synchronous Condenser Strategy Compliant With Challenging Grid Code Requirements
topic Systems and Control
url https://arxiv.org/abs/2303.00391