Air Curtains Combined with Smoke Exhaust for Smoke Control in Case of Fire: Full-Size Experiments

This paper analyses the possibility of using air curtains to prevent smoke flow from fire compartments. Full size experiments have been carried out and several relevant conditions to assess smoke-tightness have been tested. The smoke temperature during the tests was ranging from 182°C to 351°C, the...

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Bibliographic Details
Published in:Fire technology 2019-01, Vol.55 (1), p.211-232
Main Authors: Viegas, João Carlos, Cruz, Hildebrando
Format: Article
Language:English
Subjects:
Air curtains
Characterization and Evaluation of Materials
Civil Engineering
Classical Mechanics
Engineering
Freezers
Nozzles
Performance prediction
Physics
Smoke
Supermarkets
Tightness
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Summary:This paper analyses the possibility of using air curtains to prevent smoke flow from fire compartments. Full size experiments have been carried out and several relevant conditions to assess smoke-tightness have been tested. The smoke temperature during the tests was ranging from 182°C to 351°C, the angle measured between the curtain axis and the vertical plane was ranging from 18° and 26°, the nozzle thickness was ranging from 0.017 m to 0.045 m and the velocity at the nozzle was ranging from 8.3 m/s to 19.9 m/s. During the tests, the air curtain’s nozzle was positioned horizontally at the top of a permanent opening (door). With this configuration, we obtained an approximately vertical downward jet through the used opening. This paper includes the final results of the tests and develops an analytical tool for predicting the performance of air curtains. It was concluded that it is possible to achieve smoke-tightness, provided that the adequate plane jet parameters and the compartment’s smoke exhaust are correctly adjusted. According to this analysis, the smoke-tightness limit corresponds to equation B = Δ P a / Δ P s = - 0.30 u a / u a _ m i n + 1.25 (with 1.30 ≤ u a / u a _ m i n ≤ 1.67 ).
ISSN:0015-2684
1572-8099
DOI:10.1007/s10694-018-0786-z