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Autores principales: Dreze, Yann, Hao, Muting, di Mare, Luca
Formato: Preprint
Publicado: 2025
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Acceso en línea:https://arxiv.org/abs/2507.22613
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author Dreze, Yann
Hao, Muting
di Mare, Luca
author_facet Dreze, Yann
Hao, Muting
di Mare, Luca
contents This paper presents a multiscale methodology for efficient unsteady conjugate heat transfer simulations. The solid domain is modelled by coupling a global representation of the temperature field, based on the eigenfunctions of the unsteady heat conduction equation, with a local, fine-scale-resolving solution of the heat conduction equation at the conjugate interface. To address the disparate time scales and enhance convergence, the decoupled modal equations are leveraged to enable targeted acceleration of the longest thermal time scales. One-dimensional analyses validate the properties of the scheme, while scale-resolving simulations demonstrate its practical application for steady and unsteady problems. Notably, the method achieves up to a fourfold reduction in computational time to reach steady thermal conditions compared to conventional conjugate simulations, without introducing significant computational overhead or error, offering an accurate and accelerated framework for unsteady thermal analysis.
format Preprint
id arxiv_https___arxiv_org_abs_2507_22613
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Multiscale Unsteady Conjugate Transfer via Modal Projection
Dreze, Yann
Hao, Muting
di Mare, Luca
Computational Physics
This paper presents a multiscale methodology for efficient unsteady conjugate heat transfer simulations. The solid domain is modelled by coupling a global representation of the temperature field, based on the eigenfunctions of the unsteady heat conduction equation, with a local, fine-scale-resolving solution of the heat conduction equation at the conjugate interface. To address the disparate time scales and enhance convergence, the decoupled modal equations are leveraged to enable targeted acceleration of the longest thermal time scales. One-dimensional analyses validate the properties of the scheme, while scale-resolving simulations demonstrate its practical application for steady and unsteady problems. Notably, the method achieves up to a fourfold reduction in computational time to reach steady thermal conditions compared to conventional conjugate simulations, without introducing significant computational overhead or error, offering an accurate and accelerated framework for unsteady thermal analysis.
title Multiscale Unsteady Conjugate Transfer via Modal Projection
topic Computational Physics
url https://arxiv.org/abs/2507.22613