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Fire Technology

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11.07.2023

Revisiting Alpert’s Correlations: Numerical Exploration of Early-Stage Building Fire and Detection

verfasst von: Yanfu Zeng, Ho Yin Wong, Wojciech Węgrzyński, Xinyan Huang

Erschienen in: Fire Technology | Ausgabe 5/2023

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Abstract

Alpert’s correlations of fire ceiling jets have been widely used in the design of heat detectors and sprinklers since the 1970s. However, these correlations are primarily derived from large fire tests of 3.8–98 MW, high ceilings, and ideal liquid spraying flames. Thus, the feasibility of Alpert’s correlations for the smoke ceiling jet in early-stage fire detection with smaller fire sizes is still unclear. This study constructs a numerical model that is first validated by Alpert’s original ceiling temperature and velocity data of large fire powers. Then, the numerical model further explores the feasibility of Alpert’s correlations in predicting the gas temperature and velocity in steady-burning fires with 50–500 kW. Modelling confirms the accuracy of Alpert’s temperature correlations for the ceiling jet region, but suggests a large uncertainty of assuming a constant turning-region temperature for early-stage fires. Moreover, the modelled velocity pattern of smoke ceiling jet in the plume region is non-uniform, and its value in the ceiling jet region is significantly higher than Alpert’s fitting correlation. Finally, the response time of the heat detector and sprinkler in the ceiling jet region predicted by the numerical model is shorter than Alpert’s correlations, which suggests the conventional design based on Alpert’s correlations is sufficiently conservative.

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Titel: Revisiting Alpert’s Correlations: Numerical Exploration of Early-Stage Building Fire and Detection
verfasst von: Yanfu Zeng
Ho Yin Wong
Wojciech Węgrzyński
Xinyan Huang
Publikationsdatum: 11.07.2023
Verlag: Springer US
Erschienen in: Fire Technology / Ausgabe 5/2023
Print ISSN: 0015-2684
Elektronische ISSN: 1572-8099
DOI: https://doi.org/10.1007/s10694-023-01461-0

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