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Optimisation strategies to reduce renewables curtailment using transportable energy storage systems

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Optimisation strategies to reduce renewables curtailment using transportable energy storage systems. / Phurailatpam, Chitaranjan; Hu, Yiheng; Keyvani, Behzad et al.
Renewable Power Generation and Future Power Systems Conference 2023 (RPG 2023 UK). Vol. 2023 29. ed. IEEE, 2024. p. 75-80 (IET Conference Proceedings).

Research output: Contribution in Book/Report/Proceedings - With ISBN/ISSNConference contribution/Paperpeer-review

Harvard

Phurailatpam, C, Hu, Y, Keyvani, B, Zhao, N & Flynn, D 2024, Optimisation strategies to reduce renewables curtailment using transportable energy storage systems. in Renewable Power Generation and Future Power Systems Conference 2023 (RPG 2023 UK). 29 edn, vol. 2023, IET Conference Proceedings, IEEE, pp. 75-80. https://doi.org/10.1049/icp.2023.3153

APA

Phurailatpam, C., Hu, Y., Keyvani, B., Zhao, N., & Flynn, D. (2024). Optimisation strategies to reduce renewables curtailment using transportable energy storage systems. In Renewable Power Generation and Future Power Systems Conference 2023 (RPG 2023 UK) (29 ed., Vol. 2023, pp. 75-80). (IET Conference Proceedings). IEEE. https://doi.org/10.1049/icp.2023.3153

Vancouver

Phurailatpam C, Hu Y, Keyvani B, Zhao N, Flynn D. Optimisation strategies to reduce renewables curtailment using transportable energy storage systems. In Renewable Power Generation and Future Power Systems Conference 2023 (RPG 2023 UK). 29 ed. Vol. 2023. IEEE. 2024. p. 75-80. (IET Conference Proceedings). Epub 2023 Nov 15. doi: 10.1049/icp.2023.3153

Author

Phurailatpam, Chitaranjan ; Hu, Yiheng ; Keyvani, Behzad et al. / Optimisation strategies to reduce renewables curtailment using transportable energy storage systems. Renewable Power Generation and Future Power Systems Conference 2023 (RPG 2023 UK). Vol. 2023 29. ed. IEEE, 2024. pp. 75-80 (IET Conference Proceedings).

Bibtex

@inproceedings{534a207e35924210a093d91702a7670a,
title = "Optimisation strategies to reduce renewables curtailment using transportable energy storage systems",
abstract = "Increasing shares of renewable energy sources in power systems worldwide have led to increased renewable curtailment due to network and/or stability limitations. Energy storage systems, both stationary and mobile, are widely proposed as a promising solution for reducing such curtailment. The paper presents a detailed analysis of renewable energy curtailment, taking the case study of a future Irish grid scenario, to identify the prospects of transportable energy storage systems (TESS). A combined unit commitment optimal power flow formulation has been developed to evaluate the locational curtailment from all renewable sources. The study establishes a baseline understanding of the locations and durations of renewable curtailment, providing insights on short-Term/long-Term TESS relocation, along with short/long distance movement possibilities, paving the way for optimal sizing and management of TESS units.",
author = "Chitaranjan Phurailatpam and Yiheng Hu and Behzad Keyvani and Nan Zhao and Damian Flynn",
year = "2024",
month = mar,
day = "6",
doi = "10.1049/icp.2023.3153",
language = "English",
volume = "2023",
series = "IET Conference Proceedings",
publisher = "IEEE",
pages = "75--80",
booktitle = "Renewable Power Generation and Future Power Systems Conference 2023 (RPG 2023 UK)",
edition = "29",

}

RIS

TY - GEN

T1 - Optimisation strategies to reduce renewables curtailment using transportable energy storage systems

AU - Phurailatpam, Chitaranjan

AU - Hu, Yiheng

AU - Keyvani, Behzad

AU - Zhao, Nan

AU - Flynn, Damian

PY - 2024/3/6

Y1 - 2024/3/6

N2 - Increasing shares of renewable energy sources in power systems worldwide have led to increased renewable curtailment due to network and/or stability limitations. Energy storage systems, both stationary and mobile, are widely proposed as a promising solution for reducing such curtailment. The paper presents a detailed analysis of renewable energy curtailment, taking the case study of a future Irish grid scenario, to identify the prospects of transportable energy storage systems (TESS). A combined unit commitment optimal power flow formulation has been developed to evaluate the locational curtailment from all renewable sources. The study establishes a baseline understanding of the locations and durations of renewable curtailment, providing insights on short-Term/long-Term TESS relocation, along with short/long distance movement possibilities, paving the way for optimal sizing and management of TESS units.

AB - Increasing shares of renewable energy sources in power systems worldwide have led to increased renewable curtailment due to network and/or stability limitations. Energy storage systems, both stationary and mobile, are widely proposed as a promising solution for reducing such curtailment. The paper presents a detailed analysis of renewable energy curtailment, taking the case study of a future Irish grid scenario, to identify the prospects of transportable energy storage systems (TESS). A combined unit commitment optimal power flow formulation has been developed to evaluate the locational curtailment from all renewable sources. The study establishes a baseline understanding of the locations and durations of renewable curtailment, providing insights on short-Term/long-Term TESS relocation, along with short/long distance movement possibilities, paving the way for optimal sizing and management of TESS units.

U2 - 10.1049/icp.2023.3153

DO - 10.1049/icp.2023.3153

M3 - Conference contribution/Paper

VL - 2023

T3 - IET Conference Proceedings

SP - 75

EP - 80

BT - Renewable Power Generation and Future Power Systems Conference 2023 (RPG 2023 UK)

PB - IEEE

ER -