J. A. Purkiss scite author profile

A system of coupled transient differential equations governing heat, mass transfer, and pore pressure built up in porous media ( concrete) , subjected to intensive heating, is derived. Water vapor and liquid water are considered separately in the mass transfer formulation. The primary unknowns are temperature, water vapor content, and pore pressure of the gaseous mixture. A nite element formulation and corresponding owchart of computat ions of all required data are presented. The numerical example solved represent s a cross section of a concrete column exposed to re. The domain and time distributions of temperature, pore pressure, water vapor, and liquid water content are presented. Computed pore pressure is higher than those usually reported by ot her analytical studies. The in uence of some initial parameters ( permeability, initial water content, and porosity) on maximum pore pressure is investigated.

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Stress–strain constitutive equations of concrete material at elevated temperatures

Purkiss

2005

Fire Safety Journal

170

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Assessment of fire damaged concrete using colour image analysis

Short

Purkiss

Guise

2001

Construction and Building Materials

149

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Fire Safety Engineering Design of Structures

Purkiss¹

2013

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J. A. Purkiss

Fire Safety Engineering Design of Structures

Finite Element Analysis of Coupled Heat and Moisture Transfer in Concrete Subjected to Fire

Stress–strain constitutive equations of concrete material at elevated temperatures

Assessment of fire damaged concrete using colour image analysis

Fire Safety Engineering Design of Structures

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