Heat transfer analysis using a Green's function approach for uniformly insulated steel members subjected to fire

Zhi Hua Wang; Siu Kui Au; Kang Hai Tan

doi:10.1016/j.engstruct.2005.05.005

Heat transfer analysis using a Green's function approach for uniformly insulated steel members subjected to fire

Zhi Hua Wang^*, Siu Kui Au, Kang Hai Tan

^*Corresponding author for this work

Nanyang Technological University

Research output: Contribution to journal › Article › peer-review

30 Citations (Scopus)

Abstract

An efficient numerical approach is developed in this paper for heat transfer analysis of insulated steel members exposed to fire, characterized by one-dimensional conduction through an insulation layer. The numerical schemes make use of Green's function solutions of diffusion equations, and consequently no spatial discretization is involved. Two types of time-varying boundary conditions, namely, the essential (Dirichlet) and the natural (Neumann), are treated individually. Computational models are developed for boundary conditions of each type, in which the choice of sampling time does not have the numerical stability requirement imposed. The numerical algorithm can be implemented in an Excel spreadsheet for engineering use.

Original language	English
Pages (from-to)	1551-1562
Number of pages	12
Journal	Engineering Structures
Volume	27
Issue number	10
DOIs	https://doi.org/10.1016/j.engstruct.2005.05.005
Publication status	Published - Aug 2005
Externally published	Yes

ASJC Scopus Subject Areas

Civil and Structural Engineering

Keywords

1D analysis
Fire
Green's function
Heat transfer
Insulation
Steel

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10.1016/j.engstruct.2005.05.005

Cite this

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title = "Heat transfer analysis using a Green's function approach for uniformly insulated steel members subjected to fire",

abstract = "An efficient numerical approach is developed in this paper for heat transfer analysis of insulated steel members exposed to fire, characterized by one-dimensional conduction through an insulation layer. The numerical schemes make use of Green's function solutions of diffusion equations, and consequently no spatial discretization is involved. Two types of time-varying boundary conditions, namely, the essential (Dirichlet) and the natural (Neumann), are treated individually. Computational models are developed for boundary conditions of each type, in which the choice of sampling time does not have the numerical stability requirement imposed. The numerical algorithm can be implemented in an Excel spreadsheet for engineering use.",

keywords = "1D analysis, Fire, Green's function, Heat transfer, Insulation, Steel",

author = "Wang, {Zhi Hua} and Au, {Siu Kui} and Tan, {Kang Hai}",

year = "2005",

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T1 - Heat transfer analysis using a Green's function approach for uniformly insulated steel members subjected to fire

AU - Wang, Zhi Hua

AU - Au, Siu Kui

AU - Tan, Kang Hai

PY - 2005/8

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N2 - An efficient numerical approach is developed in this paper for heat transfer analysis of insulated steel members exposed to fire, characterized by one-dimensional conduction through an insulation layer. The numerical schemes make use of Green's function solutions of diffusion equations, and consequently no spatial discretization is involved. Two types of time-varying boundary conditions, namely, the essential (Dirichlet) and the natural (Neumann), are treated individually. Computational models are developed for boundary conditions of each type, in which the choice of sampling time does not have the numerical stability requirement imposed. The numerical algorithm can be implemented in an Excel spreadsheet for engineering use.

AB - An efficient numerical approach is developed in this paper for heat transfer analysis of insulated steel members exposed to fire, characterized by one-dimensional conduction through an insulation layer. The numerical schemes make use of Green's function solutions of diffusion equations, and consequently no spatial discretization is involved. Two types of time-varying boundary conditions, namely, the essential (Dirichlet) and the natural (Neumann), are treated individually. Computational models are developed for boundary conditions of each type, in which the choice of sampling time does not have the numerical stability requirement imposed. The numerical algorithm can be implemented in an Excel spreadsheet for engineering use.

KW - 1D analysis

KW - Fire

KW - Green's function

KW - Heat transfer

KW - Insulation

KW - Steel

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JO - Engineering Structures

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ER -

Heat transfer analysis using a Green's function approach for uniformly insulated steel members subjected to fire

Abstract

ASJC Scopus Subject Areas

Keywords

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