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Erschienen in:

01.08.2022

A Global Model for Heat Release Rate Prediction of Cable Burning on Vertical Cable Tray in Different Fire Scenarios

verfasst von: Xianjia Huang, Jinkai Wang, He Zhu, Chaoliang Xing, Chihonn Cheng, Wanki Chow, Katarzyna Kaczorek-Chrobak, Jadwiga Fangrat

Erschienen in: Fire Technology | Ausgabe 5/2022

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Abstract

Cable fire risk analysis is important for fire protection design in industrial as well as residential buildings. The vertical movement of the cable burning area along the vertical tray is one of the unique characteristics in vertical cable tray fire. Heat release rate (HRR) prediction is important for the fire hazard assessment. In this study, a model for estimating the HRR of the vertical cable tray fire in full scale was developed on the basis of a bench-scale cable burning test. For a given unit area of burning cable, a correlation was established between a cable fire on a vertical tray in full scale and a cable burning test in bench scale. Furthermore, the developed model takes into account the effects of the cable spacing, number of cable trays, and confined room on the cable fire behavior in full scale. Compared with the available experimental results in the literature, the local error of the predicted maximum HRR was less than 9.4%, which is significantly lower than previous model predictions in the literature. Evidently, the developed model can more accurately estimate the HRR of the vertical cable tray fire.

Vorheriger Artikel Evaluation of Fire Models by Using Local and Global Metrics and Experimental Uncertainty Estimates: Application to OECD/NEA Prisme Door Tests

Nächster Artikel A Novel Efficient Video Smoke Detection Algorithm Using Co-occurrence of Local Binary Pattern Variants

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Titel: A Global Model for Heat Release Rate Prediction of Cable Burning on Vertical Cable Tray in Different Fire Scenarios
verfasst von: Xianjia Huang
Jinkai Wang
He Zhu
Chaoliang Xing
Chihonn Cheng
Wanki Chow
Katarzyna Kaczorek-Chrobak
Jadwiga Fangrat
Publikationsdatum: 01.08.2022
Verlag: Springer US
Erschienen in: Fire Technology / Ausgabe 5/2022
Print ISSN: 0015-2684
Elektronische ISSN: 1572-8099
DOI: https://doi.org/10.1007/s10694-022-01304-4

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