해상풍력발전단지의 최적 운영을 위한 기반 내부 전력망토폴로지 변경시스템

Min Jae Kim; Junho Bang; Deunchan Kim; Ji Won Kim; Soyeon Park; Hae Gweon Kang; Myeong Hoi Kwon

doi:10.5370/KIEE.2024.73.11.2045

해상풍력발전단지의 최적 운영을 위한 기반 내부 전력망토폴로지 변경시스템

Translated title of the contribution: AI-Based Internal Power Grid Topology Change System for Optimal Operation of Offshore Wind Farms

Min Jae Kim
, Junho Bang^*
, Deunchan Kim
, Ji Won Kim
, Soyeon Park
, Hae Gweon Kang
, Myeong Hoi Kwon

^*Corresponding author for this work

Research output: Contribution to journal › Journal article › peer-review

Abstract

Offshore wind power is gaining attraction as a sustainable energy solution, but optimizing topologies for changing environments remains a significant challenge. Existing algorithms design static topologies based on specific environmental conditions, which limits the flexibility of real-time adaptation. In this study, we propose a dynamic topology optimization technique using deep Q-networks (DQN) to address this problem. We model offshore wind farm topology optimization as a Markov decision process (MDP) and apply DQNs to solve it in real-time. Experiments are conducted through simulations using an offshore wind farm model with 40 wind turbines (5MW). DQN-based optimization achieved an annual energy production of 894.7 GWh and an average transmission loss rate of 4.80%, outperforming the fixed topology and random breaker switching methods. DQN showed high adaptability to seasonal wind direction changes and power demand fluctuations, maintaining stable performance throughout the year.

Translated title of the contribution	AI-Based Internal Power Grid Topology Change System for Optimal Operation of Offshore Wind Farms
Original language	Korean
Pages (from-to)	2045-2052
Number of pages	8
Journal	Transactions of the Korean Institute of Electrical Engineers
Volume	73
Issue number	11
DOIs	https://doi.org/10.5370/KIEE.2024.73.11.2045
State	Published - 2024.11

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

SDG 7 Affordable and Clean Energy

Keywords

DQN(Deep Q-Learning)
Energy Loss Optimization
Reinforce learning
Topology
Transmission Line Reconfiguration

Quacquarelli Symonds(QS) Subject Topics

Engineering - Electrical & Electronic
Engineering - Petroleum

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10.5370/KIEE.2024.73.11.2045

Cite this

@article{41bbc134190f40a9bfde21a2f3249d4b,

title = "해상풍력발전단지의 최적 운영을 위한 기반 내부 전력망토폴로지 변경시스템",

abstract = "Offshore wind power is gaining attraction as a sustainable energy solution, but optimizing topologies for changing environments remains a significant challenge. Existing algorithms design static topologies based on specific environmental conditions, which limits the flexibility of real-time adaptation. In this study, we propose a dynamic topology optimization technique using deep Q-networks (DQN) to address this problem. We model offshore wind farm topology optimization as a Markov decision process (MDP) and apply DQNs to solve it in real-time. Experiments are conducted through simulations using an offshore wind farm model with 40 wind turbines (5MW). DQN-based optimization achieved an annual energy production of 894.7 GWh and an average transmission loss rate of 4.80\%, outperforming the fixed topology and random breaker switching methods. DQN showed high adaptability to seasonal wind direction changes and power demand fluctuations, maintaining stable performance throughout the year.",

keywords = "DQN(Deep Q-Learning), Energy Loss Optimization, Reinforce learning, Topology, Transmission Line Reconfiguration",

author = "Kim, \{Min Jae\} and Junho Bang and Deunchan Kim and Kim, \{Ji Won\} and Soyeon Park and Kang, \{Hae Gweon\} and Kwon, \{Myeong Hoi\}",

note = "Publisher Copyright: Copyright {\textcopyright} The Korean Institute of Electrical Engineers.",

year = "2024",

month = nov,

doi = "10.5370/KIEE.2024.73.11.2045",

language = "Korean",

volume = "73",

pages = "2045--2052",

journal = "Transactions of the Korean Institute of Electrical Engineers",

issn = "1975-8359",

number = "11",

}

TY - JOUR

T1 - 해상풍력발전단지의 최적 운영을 위한 기반 내부 전력망토폴로지 변경시스템

AU - Kim, Min Jae

AU - Bang, Junho

AU - Kim, Deunchan

AU - Kim, Ji Won

AU - Park, Soyeon

AU - Kang, Hae Gweon

AU - Kwon, Myeong Hoi

PY - 2024/11

Y1 - 2024/11

N2 - Offshore wind power is gaining attraction as a sustainable energy solution, but optimizing topologies for changing environments remains a significant challenge. Existing algorithms design static topologies based on specific environmental conditions, which limits the flexibility of real-time adaptation. In this study, we propose a dynamic topology optimization technique using deep Q-networks (DQN) to address this problem. We model offshore wind farm topology optimization as a Markov decision process (MDP) and apply DQNs to solve it in real-time. Experiments are conducted through simulations using an offshore wind farm model with 40 wind turbines (5MW). DQN-based optimization achieved an annual energy production of 894.7 GWh and an average transmission loss rate of 4.80%, outperforming the fixed topology and random breaker switching methods. DQN showed high adaptability to seasonal wind direction changes and power demand fluctuations, maintaining stable performance throughout the year.

AB - Offshore wind power is gaining attraction as a sustainable energy solution, but optimizing topologies for changing environments remains a significant challenge. Existing algorithms design static topologies based on specific environmental conditions, which limits the flexibility of real-time adaptation. In this study, we propose a dynamic topology optimization technique using deep Q-networks (DQN) to address this problem. We model offshore wind farm topology optimization as a Markov decision process (MDP) and apply DQNs to solve it in real-time. Experiments are conducted through simulations using an offshore wind farm model with 40 wind turbines (5MW). DQN-based optimization achieved an annual energy production of 894.7 GWh and an average transmission loss rate of 4.80%, outperforming the fixed topology and random breaker switching methods. DQN showed high adaptability to seasonal wind direction changes and power demand fluctuations, maintaining stable performance throughout the year.

KW - DQN(Deep Q-Learning)

KW - Energy Loss Optimization

KW - Reinforce learning

KW - Topology

KW - Transmission Line Reconfiguration

UR - https://www.scopus.com/pages/publications/85209896139

U2 - 10.5370/KIEE.2024.73.11.2045

DO - 10.5370/KIEE.2024.73.11.2045

M3 - Journal article

AN - SCOPUS:85209896139

SN - 1975-8359

VL - 73

SP - 2045

EP - 2052

JO - Transactions of the Korean Institute of Electrical Engineers

JF - Transactions of the Korean Institute of Electrical Engineers

IS - 11

ER -

해상풍력발전단지의 최적 운영을 위한 기반 내부 전력망토폴로지 변경시스템

Abstract

UN SDGs

Keywords

Quacquarelli Symonds(QS) Subject Topics

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