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AbstractPrevious research has produced valuable results on the transient dynamic response of tunnels buried in full-space. However, a half-space model is of more practical interest because tunnels normally have finite buried depths. In this paper, the dynamic response of a lined tunnel is studied where the surrounding soil is described using Biot's theory and the lining is described by the theory of elastodynamics. The half-space straight boundary is approximately represented by a convex arc of large radius. In accordance with Graff's addition theorem, the general solutions in a rectangular coordinate system are converted to ones in a polar coordinate system. The solutions for displacements and stresses of both the soil and the lining as well as the pore pressure of the soil in the Laplace transform domain are derived based on boundary conditions. Time domain solutions are then obtained by the use of inverse Laplace transform. Numerical results are presented showing the distributions of peak values of ground displacements, stresses and pore pressures of the soil.
HighlightsSolutions for Dynamic response of a tunnel in a saturated half space are derived.The half-space straight boundary is appr expressed by a convex arc with large radius.The displacement, the hoop stress and the pore pressure are analyzed.The displacement contour in saturated soil shows a heart shape.The hoop stress in the half-space is greater than that in full space.
AbstractPrevious research has produced valuable results on the transient dynamic response of tunnels buried in full-space. However, a half-space model is of more practical interest because tunnels normally have finite buried depths. In this paper, the dynamic response of a lined tunnel is studied where the surrounding soil is described using Biot's theory and the lining is described by the theory of elastodynamics. The half-space straight boundary is approximately represented by a convex arc of large radius. In accordance with Graff's addition theorem, the general solutions in a rectangular coordinate system are converted to ones in a polar coordinate system. The solutions for displacements and stresses of both the soil and the lining as well as the pore pressure of the soil in the Laplace transform domain are derived based on boundary conditions. Time domain solutions are then obtained by the use of inverse Laplace transform. Numerical results are presented showing the distributions of peak values of ground displacements, stresses and pore pressures of the soil.
HighlightsSolutions for Dynamic response of a tunnel in a saturated half space are derived.The half-space straight boundary is appr expressed by a convex arc with large radius.The displacement, the hoop stress and the pore pressure are analyzed.The displacement contour in saturated soil shows a heart shape.The hoop stress in the half-space is greater than that in full space.
Transient dynamic response of a shallow buried lined tunnel in saturated soil
Soil Dynamics and Earthquake Engineering ; 94 ; 13-17
2016-12-26
5 pages
Article (Journal)
Electronic Resource
English
Transient dynamic response of a shallow buried lined tunnel in saturated soil
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