Simulation of fire resistance behaviour of pultruded GFRP columns

Abstract

This paper presents a numerical investigation on the fire resistance of pultruded GFRP columns with tubular cross-section, both unprotected and protected with a passive fire protection. Three-dimensional finite element models were developed and they considered the thermo-mechanical behaviour of GFRP material (temperature-dependent mechanical properties) and the temperature distributions previously obtained through heat transfer analyses and fluid dynamics inside the tube cavity. The numerical results presented include the time evolution of axial and flexural deformations of the GFRP columns, as well as the stress distributions in both longitudinal and transversal directions of the unprotected column under one-side fire exposure and axially compressed (designated as reference column). In comparison with this reference column, the paper focuses on the evaluation of the several effects, such as the use of fire protection system, the imposition of different fire exposure conditions and the application of distinct load levels. The Tsai-Hill criterion is used to identify the initial failure of GFRP columns and assess the evolution of failure index with fire exposure time, while the Hashin criterion is used to obtain an estimate of column strength and collapse mode. It is concluded that the proposed models are able to qualitatively capture the general trend of the experimental results, despite the quantitative differences not yet overcome. With the consideration of creep, delamination effects and fracture, the authors are confident that these models will soon correctly predict the complex mechanical behaviour and the fire resistance of GFRP columns.