Experimental and numerical investigation of flow distribution pattern at a T-shape roadway crossing under extreme storms

A major drainage systemwhich uses urban roadways as flood passages during extreme storm events has been proven to be effective and low-cost. However, to date, the amount of flow diverted at a bifurcating road crossing still could not be accurately assessed. Previous studies mainly focused on diversi...

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Published inEngineering applications of computational fluid mechanics Vol. 16; no. 1; pp. 2286 - 2300
Main Authors Feng, Wang, Shao, Zhiyu, Gong, Huafeng, Xu, Lei, Yost, Scott A., Ma, Haiyuan, Chai, Hongxiang
Format Journal Article
LanguageEnglish
Published Hong Kong Taylor & Francis 31.12.2022
Taylor & Francis Ltd
Taylor & Francis Group
Subjects
Boundary conditions
CFD
Computational fluid dynamics
Drainage systems
extreme storms
Factorial design
Flow distribution
major drainage system
Mathematical models
Numerical analysis
Numerical models
road crossing
Roads
Roads & highways
Storms
T shape
urban flooding
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Summary:A major drainage systemwhich uses urban roadways as flood passages during extreme storm events has been proven to be effective and low-cost. However, to date, the amount of flow diverted at a bifurcating road crossing still could not be accurately assessed. Previous studies mainly focused on diversion flat bottom channels with no turning radius. Results from these studies are not applicable to the road crossing due to the significant discrepancies between the two flow fields. In this study, the flow distribution pattern at a roadway crossing with a T-shape was studied experimentally and numerically. The three-dimensional computational fluid dynamics (CFD) model was constructed using FLUENT. The numerical model was validated using the experimental results and showed satisfying agreements. Results of the 2 k factorial design experiments show that the flow distribution ratio is sensitive to turning radius,  longitude slope,  flowrate and downstream boundary conditions. Detailed numerical studies were conducted to reveal the relationship between the flow distribution ratio and the individual impacting factor. Findings from this research could provide more accurate flowrate predictions  to  guide the design of the road crossings to improve the performance of the major drainage system during extreme storms.
ISSN:1994-2060
1997-003X
DOI:10.1080/19942060.2022.2141329