This paper presents within the scope of the theory of static elasticity a derivation of soil spring constant in longitudinal direction of a buried pipeline in the seismic design. It is found that the spring constant depends on the shear modulus G of the soil deposits and the ratio lambda of the radius of zero displacement over the radius of a buried pipeline structure. When lambda increases, the soil spring constant decreases and the decreasing rate reduces remarkably when lambda is greater than about 10. The ratio of soil spring constant over G is 2.7 when lambda = 10. Furthermore, the dynamic effect of soil spring constants on buried pipeline structures is estimated analytically by the dynamic theory of elasticity. The soil spring constant that is derived, taking into account the boundary condition of ground surface, depends on the shear modulus G of the ground, nondimensional frequency omega b/V-s (omega = circular frequency; b = radius of buried pipeline; V-s = ground shear-wave velocity) and nondimensional depth d/b (d = depth of pipeline). [References: 14]
展开▼
机译:本文在静弹性理论的范围内,提出了抗震设计中地下管道纵向的土弹簧常数的推导。发现弹簧常数取决于土壤沉积物的剪切模量G和零位移半径与埋入式管道结构的半径之比λ。当lambda增大时,当lambda大于约10时,土壤弹簧常数减小,下降速度显着降低。当lambda = 10时,土壤弹簧常数与G的比值为2.7。此外,土壤弹簧常数对埋地管道的动态影响结构是通过动态力学理论进行分析估计的。考虑到地表的边界条件而得出的土壤弹簧常数取决于地面的剪切模量G,无量纲频率ωb / Vs(ω=圆形频率; b =地下管道的半径; Vs =地面横波速度)和无量纲深度d / b(d =管道深度)。 [参考:14]
展开▼
