Abstract
Frequent accidents caused by underground pipeline damage are a widespread societal concern. Trenchless rehabilitation methods, particularly cured-in-place pipe (CIPP) lining, are increasingly used for pipeline repair with great success. Existing research is mainly concerned with practical improvements in rehabilitation and evaluating the performance of rehabilitation. In this study, the model of corroded buried concrete pipeline that had been rehabilitated with CIPP was established using numerical methods, and the Mesh-based parallel-Code Coupling Interface (MpCCI) was used to investigate multifield coupling effects of soil pressure, traffic load, and fluid-structure interactions. Moreover, the influences of corrosion depth, corrosion width, traffic load, cover depth, and water quantity on CIPP wall thickness were compared and analyzed. The result shows that maximum principal stress and vertical displacement of pipeline markedly decreased after CIPP rehabilitation, and thus the new CIPP can carry loads in a deteriorated pipe. Stress and displacement of the composite pipe liner were positively correlated with corrosion depth and negatively correlated with corrosion width. Increase in traffic load rapidly increases von Mises stress of CIPP, and increase in cover depth rapidly increases maximum principal stress of pipeline. Water flow has little effect on the pipe liner, and flow capacity increases slightly after CIPP rehabilitation. CIPP wall thickness was positively correlated with corrosion depth, traffic load, cover depth, and water quantity and negatively correlated with corrosion width.
Highlights
Frequent accidents caused by underground pipeline damage are a widespread societal concern
cured-in-place pipe (CIPP) wall thickness was positively correlated with corrosion depth, traffic load, cover depth, and water quantity and negatively correlated with corrosion width
The Abaqus software, Fluent software, and Mesh-based parallel-Code Coupling Interface (MpCCI) software were used to establish a model of corroded concrete pipeline repaired by CIPP that was subjected to the multifield coupling of soil pressure, traffic load, and fluid-structure interactions. e influences of corrosion depth, corrosion width, traffic load, cover depth, and water quantity on the composite pipe liner were analyzed. e results of this study provide a strong basis for designing of CIPP wall thickness
Summary
E water inlet, water outlet, air inlet, air outlet, and wall of the fluid were set using boundary conditions. E no slip boundary condition was used at the wall-fluid interface, and roughness was set to 0.01. MpCCI was used to realize the coupling of the fluid model in Fluent and the structural model in Abaqus. Different strength theory models were used to determine the failure characteristics. Where σ1 is the maximum principal stress of the component at the yield point and σu is the ultimate tensile strength of the concrete, which was selected as 1.4 MPa in this study. According to the fourth strength theory, plastic yield of the CIPP is determined by the following equation:. 1732 43.50 25.20 20.71 22.90 14.70 where σ1, σ2, and σ3 are the three principal stresses at the yield point and σs is the yield limit of the material, which was selected as 21 MPa in this study
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