Citation

Marti J, Idelsohn SR, Oñate E. Fire Technol. 2018; 54(6): 1783-1805.

Copyright

(Copyright © 2018, Holtzbrinck Springer Nature Publishing Group)

DOI

10.1007/s10694-018-0769-0

PMID

unavailable

Abstract

The tendency of the polymers to melt and drip when they are exposed to external heat source play a very important role in the ignition and the spread of fire. Numerical simulation is a promising methodology for predicting this behaviour. In this paper, a computational procedure that aims at analyzing the combustion, melting and flame spread of polymer is presented. The method models the polymer using a Lagrangian framework adopting the particle finite element method framework while the surrounding air is solved on a fixed Eulerian mesh. This approach allows to treat naturally the polymer shape deformations and to solve the thermo-mechanical problem in a staggered fashion. The problems are coupled using an embedded Dirichlet-Neumann scheme. A simple combustion model and a radiation modeling strategy are included in the air domain. With this strategy the burning of a polypropylene specimen under UL-94 vertical test conditions is simulated. Input parameters for the modelling (density, specific heat, conductivity and viscosity) and results for the validation of the numerical model has been obtained from different literature sources and by IMDEA burning a specimen of dimensions of 148×13×3.2mm3148×13×3.2mm3148 times 13 times 3.2,{mathrm {mm}}^3. Temperature measurements in the polymer have been recorder by means of three thermocouples exceeding the 1000 K. Simultaneously a digital camera was used to record the burning process. In addition, thermal decomposition of the material (Arrhenius coefficient A=7.14×1016min−1A=7.14×1016min−1{mathrm {A}}=7.14 times 10^{16},{mathrm {min}}^{-1} and activation energy E=240.67kJ/molE=240.67kJ/mol{mathrm {E}}=240.67,{mathrm {kJ/mol}}) as and changes in viscosity (

Keywords

Dripping; Melt flow; Particle finite element method (PFEM); UL-94 test