Abstract
Current research was not dedicated to investigate the mechanical behavior of a concrete drainage pipe under multiphysical coupling conditions of overburden pressure, traffic loads, groundwater, and pipe fluids. This study proposes a new numerical solution method for coupled stress, seepage, and flow fields based on a validated finite element model. The model was developed by ABAQUS and FLUENT and then solved simultaneously using the MpCCI (mesh-based parallel-code coupling interface) platform. Results show that the tensile stress at the springline and the radial displacement at the crown (or invert) of the bell under the effect of groundwater alone were reduced by 50.5% and 38.1%, respectively, compared to the effect of traffic load alone. Parametric analyses show that vehicle speed and fluid height have a slight impact on the pipes. The soil cover depth, wheel pressure, and gasket strength are directly proportional to the pipe stress and vertical displacement. Within the scope of their respective changes, the pipe stresses were increased by 34.4%, 36.7%, and 28.5%, and the vertical displacements were increased by 124%, 95.85%, and 87.7%. The bedding and backfill strengths are proportional to the pipe stress and inversely proportional to the vertical displacement. Within the scope of their respective changes, the pipe stresses were increased by 18.2% and 20.0%, and the vertical displacements were decreased by 11.4% and 10.4%. Sensitivity analyses show that soil cover depth has a greatest impact on the pipe, followed by traffic load.
Highlights
Drainage pipes are an important component of urban underground infrastructure, and they play an important role in the daily operation of a city
Scholars have studied the mechanical behavior of pipes buried in dry and nondry soils as well as the uid-structure interaction (FSI)
Based on the previous studies, this paper utilized the advanced FE model, numerical solution tools, and full-scale test to fully consider the coupled effects of stress field generated by overburden pressure and traffic load, FSI induced by fluid flow, and seepage field due to groundwater on concrete drainage pipe, and a parametric analysis was conducted for each parameter affecting the mechanical properties of the pipe
Summary
Drainage pipes are an important component of urban underground infrastructure, and they play an important role in the daily operation of a city. Rakitin and Xu [5] studied the effects of soil cover depth, traffic load location, and magnitude on bending moment of a large reinforced concrete pipe with a diameter of 1400 mm by the geotechnical centrifuge test. By numerically modeling geotechnical centrifuge tests, Xu et al [9] studied the mechanical responses (under static loading) of a large-diameter concrete pipe with bell-and-spigot joints under different loads, soil stiffness values, and loading locations. Based on the previous studies, this paper utilized the advanced FE model, numerical solution tools, and full-scale test to fully consider the coupled effects of stress field generated by overburden pressure and traffic load, FSI induced by fluid flow, and seepage field due to groundwater on concrete drainage pipe, and a parametric analysis was conducted for each parameter affecting the mechanical properties of the pipe.
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