Thermal buoyant smoke back-layering length in a naturally ventilated tunnel with vertical shafts

• Published in: Applied thermal engineering Vol. 93; pp. 947 - 957
• Main Authors: Wang, Yan Fu, Yan, Pei Na, Zhang, Biao, Jiang, Jun Cheng
• Format: Journal Article
• Language: English
• Published: Elsevier Ltd 25.01.2016
• Subjects: Back-layering length; Buoyancy; Computational fluid dynamics; Computer programs; Computer simulation; Dimensional analysis; Fires; Full-scale fire experiments; Mathematical models; Smoke; Software; Tunnel with vertical shafts; Tunnels (transportation); Tunnel with vertical shafts; Computational fluid dynamics; Back-layering length; Dimensional analysis; Full-scale fire experiments
• ISSN: 1359-4311
• DOI: 10.1016/j.applthermaleng.2015.10.053

•Smoke propagation are researched experimentally and numerically.•The effects of shaft dimension on back-layering length are researched.•Formula of back-layering length is deduced based on dimensional analysis. A series of full-scale experiments are carried out in tunnel with vertical shafts to research the effects of shaft on the smoke propagation in tunnel fires. Formulas for longitudinal propagation distance are fitted from experimental data using Origin software. Based on experimental data, Computational Fluid Dynamics model is built and validated. Thereafter, different scenarios are numerically studied using FLUENT software to simulate the effect of shaft on back-layering length. At last, a prediction formula for calculating back-layering length is deduced based on fire plume theory, dimensional analysis and the data from both experiments and simulations. In order to verify the validity of the proposed formula, the calculation results are compared with the experimental data. It shows that the proposed formulas agree well with the experimental data. So the proposed formulas can be used to predict the back-layering length of fire in tunnel with vertical shafts.