Numerical heat transfer model for swelling intumescent coatings during heating

Numerical heat transfer model for swelling intumescent coatings during heating

This research study presents a heat transfer model aimed at estimating the thermal and physical response of intumescent coatings. The numerical model is inspired by the outcomes of an experimental study focused on analysing the insulating effectiveness of a commercial intumescent coating for a range...

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Bibliographic Details
Published in:International journal of thermal sciences Vol. 184; p. 107922
Main Authors: Lucherini, Andrea, Hidalgo, Juan P., Torero, Jose L., Maluk, Cristian
Format: Journal Article
Language:English
Published: Elsevier Masson SAS 01-02-2023
Subjects:
Fire safety
Heat transfer
Intumescent coatings
Numerical model
Swelling
Swelling
Numerical model
Heat transfer
Intumescent coatings
Fire safety
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Summary:This research study presents a heat transfer model aimed at estimating the thermal and physical response of intumescent coatings. The numerical model is inspired by the outcomes of an experimental study focused on analysing the insulating effectiveness of a commercial intumescent coating for a range of heating conditions and initial coating thickness. The model solves the one-dimensional heat conduction problem using the finite-difference Crank-Nicolson method, and it assumes that the effectiveness of intumescent coatings is mainly dependent on their ability to develop swelled porous char. The coating swelling is implemented in the model by adopting an approach based on expanding the mesh representing the physical domain in proximity to the substrate-coating interface. The model described herein offers researchers and engineers a tool to estimate the heat transfer of swelling intumescent coatings (i.e. in-depth thermal gradient). Outcomes of the analysis shown herein demonstrate that the heat conduction within intumescent coatings is governed by the physical coating swelling and the thermal conditions at the coating-substrate interface. The numerical model shows that its accuracy is highly influenced by the coating thickness ahead of the reaction zone. Consequently, the coating swelling rate plays a key role, while the thermo-physical properties of the intumescent coating have a secondary effect. According to its assumptions, the model defines a quasi-steady-state thermal problem: it is more accurate for conditions close to steady-state (e.g. high heat fluxes), but it loses accuracy for cases characterised by transient phenomena (e.g. phases prior to the onset of swelling and low heat fluxes). [Display omitted] •Transient heat transfer model for swelling intumescent coatings.•Effectiveness of intumescent coatings based on ability to develop swelled char.•Swelling by expanding physical domain at the substrate-coating interface.•Correct prediction of the thermal gradient within swelling intumescent coatings.•Based on assumptions, quasi-steady-state thermal problem.
ISSN:1290-0729
1778-4166
DOI:10.1016/j.ijthermalsci.2022.107922