TY - GEN
T1 - Data-Driven Quasi-Static Surrogate Models for Nuclear-Powered Integrated Energy Systems
AU - Gautam, Mukesh
AU - Poudel, Bikash
AU - Li, Binghui
N1 - Publisher Copyright:
© 2024 IEEE.
PY - 2024
Y1 - 2024
N2 - The integration of nuclear power into energy systems presents a promising avenue to address the growing global energy demands while minimizing greenhouse gas emissions. In this paper, we introduce a data-driven quasi-static surrogate model for nuclear-powered Integrated Energy Systems (IES) that comprises various components, including a small modular reactor (SMR), steam manifold, balance of plant (BOP), high-temperature steam electrolysis (HTSE), and district heating (DH) system. Traditional physics-based models for these components often entail significant computational resource and time con-sumption, necessitating the development of efficient surrogate models. The development of a complete surrogate model for the IES involves the creation of individual surrogate models for each component, leveraging machine learning techniques and simulated data. These isolated surrogate models are subsequently integrated, enabling a holistic view of the IES and reducing the computational burden associated with detailed physics-based simulations. This paper outlines the development process, validation, and the performance evaluation of the surrogate models. The exceptional performance, with low root-mean-squared errors and R-squared scores of at least 99.8% across all individual surrogate models, underscores their accuracy and practical applicability. These results demonstrate the potential of these models to expedite the analysis of nuclear-powered IES, offering insights that can shape future research and development efforts.
AB - The integration of nuclear power into energy systems presents a promising avenue to address the growing global energy demands while minimizing greenhouse gas emissions. In this paper, we introduce a data-driven quasi-static surrogate model for nuclear-powered Integrated Energy Systems (IES) that comprises various components, including a small modular reactor (SMR), steam manifold, balance of plant (BOP), high-temperature steam electrolysis (HTSE), and district heating (DH) system. Traditional physics-based models for these components often entail significant computational resource and time con-sumption, necessitating the development of efficient surrogate models. The development of a complete surrogate model for the IES involves the creation of individual surrogate models for each component, leveraging machine learning techniques and simulated data. These isolated surrogate models are subsequently integrated, enabling a holistic view of the IES and reducing the computational burden associated with detailed physics-based simulations. This paper outlines the development process, validation, and the performance evaluation of the surrogate models. The exceptional performance, with low root-mean-squared errors and R-squared scores of at least 99.8% across all individual surrogate models, underscores their accuracy and practical applicability. These results demonstrate the potential of these models to expedite the analysis of nuclear-powered IES, offering insights that can shape future research and development efforts.
KW - District heating
KW - integrated energy systems
KW - machine learning
KW - nuclear energy
KW - surrogate model
UR - http://www.scopus.com/inward/record.url?scp=85189928927&partnerID=8YFLogxK
U2 - 10.1109/TPEC60005.2024.10472286
DO - 10.1109/TPEC60005.2024.10472286
M3 - Conference contribution
AN - SCOPUS:85189928927
T3 - 2024 IEEE Texas Power and Energy Conference, TPEC 2024
BT - 2024 IEEE Texas Power and Energy Conference, TPEC 2024
PB - Institute of Electrical and Electronics Engineers Inc.
T2 - 2024 IEEE Texas Power and Energy Conference, TPEC 2024
Y2 - 12 February 2024 through 13 February 2024
ER -