4.6 Article

Similarity of energy balance in mechanically ventilated compartment fires: An insight into the conditions for reduced-scale fire experiments

Journal

NUCLEAR ENGINEERING AND TECHNOLOGY
Volume 54, Issue 8, Pages 2898-2914

Publisher

KOREAN NUCLEAR SOC
DOI: 10.1016/j.net.2022.02.013

Keywords

Compartment fire; Mechanical ventilation; Energy balance; Compartment geometry; Fire experiment; Similarity

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This paper proposes a method for setting the conditions for reduced-scale experiments of mechanically ventilated compartment fires, considering the similarity of energy balance. The evaluation of a small-scale fire experiment indicates that the energy balance variation can be assessed by the scaling factor F and the value of R-T reflects the effects of compartment geometry.
When evaluating energy balance and temperature in reduced-scale fire experiments, which are conducted as an alternative to full-scale fire experiments, it is important to consider the similarity in the scale among these experiments. In this paper, a method considering the similarity of energy balance is proposed for setting the conditions for reduced-scale experiments of mechanically ventilated compartment fires. A small-scale fire experiment consisting of various cases with different compartment geometries (aspect ratios between 0.2 and 4.7) and heights of vents and fire sources was conducted under mechanical ventilation, and the energy balance in the quasi-steady state was evaluated. The results indicate the following: (1) although the compartment geometry varies the energy balance in a mechanically ventilated compartment, the variation in the energy balance can be evaluated irrespective of the compartment size and geometry by considering scaling factor F (proportional to h(eff)A(w)R(T), where h(eff) is the effective heat transfer coefficient, A(w) is the total wall area, and R-T is the ratio of the spatial mean gas temperature to the exhaust temperature); (2) the value of R-T, which is a part of F, reflects the effects of the compartment geometry and corresponds to the distributions of the gas temperature and wall heat loss. (C) 2022 Korean Nuclear Society, Published by Elsevier Korea LLC.

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