Abstract
Statistics show that most fires occur in civil residential buildings. Most casualties are due to the inhalation of hot air loaded with smoke, leading to intoxication with substances harmful to the human body. This research aimed to develop a CFD model that relates the operation of the sprinkler system to the operation of the ventilation system through the air temperature in a specific point close to the sprinkler position. A real-scale experiment was carried out, and a CDF model was developed. Several parameters of the CFD model (thermal conductivity of the experimental test room walls, numerical grid elements’ dimensions, burner heat release rate variation) were imposed to the model, so that the resulting entire time variation of the temperature next to the sprinkler location corresponds to the real measured variation. Two other experiments were used to validate the numerical model. Besides the air temperature, at this point, other essential parameters were determined in the entire experimental space: indoor air temperature, visibility, oxygen concentration, and carbon dioxide concentration. We found that if the ventilation rate increases, the indoor temperatures in that specific point decrease, and the sprinkler is activated later or, in some cases, it might never be activated. However, this conclusion is not valid for the entire analyzed space, as the ventilation system alongside the natural air movement imposes specific air speed and specific temperature distribution inside the analyzed space.
Highlights
At this point, other essential parameters were determined in the entire experimental space: indoor air temperature, visibility, oxygen concentration, and carbon dioxide concentration
The purpose of this study is to experimentally develop a computational fluid dynamics (CFD) model that can be used to simulate the evolution of the fire indoors, as well as to analyze the relationship between the operation of the sprinkler system and ventilation system through the air temperature in a specific point close to the sprinkler position
The purpose study to understand the relationship between evolution purpose of of ourour study is toisunderstand the relationship between two two active systems for fire protection, the ventilation and sprinkler systems, and the active systems for fire protection, the ventilation and sprinkler systems, and howhow the opoperation of the ventilation system could influence the efficiency of the sprinkler system
Summary
To make a building safe, in the event of a fire, the main requirement is the capability to save the occupants [2]: maintaining optimal conditions for evacuating people is a priority. This can be achieved by ensuring low indoor temperatures, a good visibility, high oxygen concentrations, and low carbon dioxide concentrations, resulting from combustion, for a specified period. Other point located close to the sprinkler position (point S24) Besides this main parameter, other criteria are used for the modelling of this phenomenon. The model is determined on the measured data CALIB1 and tested on the experimental data from CALIB2 and CALIB3
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