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Fire Technology
Published in: Fire Technology 3/2014

01-05-2014

Experimental and Numerical Study of the Interaction Between Water Mist and Fire in an Intermediate Test Tunnel

Authors: E. Blanchard, P. Boulet, P. Fromy, S. Desanghere, P. Carlotti, J. P. Vantelon, J. P. Garo

Published in: Fire Technology | Issue 3/2014

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Abstract

The paper deals with interaction between water mist and hot gases in a longitudinally ventilated tunnel. The work aims at understanding the interaction of mist, smoke and ventilation.The study is based on one intermediate tunnel test and an extensive use of the computational code Fire Dynamics Simulator (FDS, NIST). The approach consists first of reconstructing the test with the CFD code by defining the relevant numerical parameters to accurately model the involved water mist system. Then, it consists of handling from the local data the complicated flows generated by the water mist flooding on the one hand and by fire and ventilation on the other hand. The last stage consists in quantifying each mechanism involved in interaction between water mist and hot gases. There are three main results in this study. Firstly, the CFD code prediction is also evaluated in this configuration, with and without water mist. Before the mist system activation, the agreement is satisfactory for gas temperatures and heat flux. After the activation time, the CFD code predicts well the thermal environment and in particular its stratification. Secondly, water mist plays a strong thermal role since in the test studied, roughly half of the heat released by fire is absorbed by water droplets. Thirdly, heat transfer from gaseous phase to droplets is the main mechanism involved (73%). The remaining heat absorbed by droplets results from tunnel surface cooling which represents (9%) and radiative attenuation (18%).
previous article Towards Design Options and Trade-offs for Road Tunnels Incorporating Suppression Systems
next article Large-Scale Water Spray and Water Mist Fire Suppression System Tests for the Protection of Ro–Ro Cargo Decks on Ships

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Metadata
Title
Experimental and Numerical Study of the Interaction Between Water Mist and Fire in an Intermediate Test Tunnel
Authors
E. Blanchard
P. Boulet
P. Fromy
S. Desanghere
P. Carlotti
J. P. Vantelon
J. P. Garo
Publication date
01-05-2014
Publisher
Springer US
Published in
Fire Technology / Issue 3/2014
Print ISSN: 0015-2684
Electronic ISSN: 1572-8099
DOI
https://doi.org/10.1007/s10694-013-0323-z

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