A platform for research: civil engineering, architecture and urbanism
A platform for research: civil engineering, architecture and urbanism
Research on the maximum fire smoke temperature beneath tunnel ceilings using longitudinal ventilation
The maximum fire smoke temperature beneath tunnel ceilings using longitudinal ventilation was studied by both small-scale experiments and numerical simulations for a small heat release rate (HRR) fire. And then, the accuracy of the numerical simulation is verified. A numerical simulation is subsequently employed to modify the Kurioka model for cases in large HRR. Then, the modified Kurioka model is verified by various on-site high HRR fire experimental results conducted by other authors.
Research on the maximum fire smoke temperature beneath tunnel ceilings using longitudinal ventilation
The maximum fire smoke temperature beneath tunnel ceilings using longitudinal ventilation was studied by both small-scale experiments and numerical simulations for a small heat release rate (HRR) fire. And then, the accuracy of the numerical simulation is verified. A numerical simulation is subsequently employed to modify the Kurioka model for cases in large HRR. Then, the modified Kurioka model is verified by various on-site high HRR fire experimental results conducted by other authors.
Research on the maximum fire smoke temperature beneath tunnel ceilings using longitudinal ventilation
Yang Hui (author) / Dong Bingyan (author) / Zhang Sijian (author) / Sun Dahui (author) / Lushin Kirill (author)
2018
Article (Journal)
Electronic Resource
Unknown
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Maximum temperature of smoke beneath ceiling in tunnel fire with vertical shafts
| British Library Online Contents | 2015
Maximum temperature of smoke beneath ceiling in tunnel fire with vertical shafts
| Online Contents | 2015
Maximum temperature of smoke beneath ceiling in tunnel fire with vertical shafts
| British Library Online Contents | 2015