Pore pressure development of freeze-thaw soft soil under cyclic loading
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摘要: 人工冻结法以其成本低、安全性高而广泛应用于地铁隧道工程中。软土经冻融作用后力学性质将发生改变,通过动三轴试验,对冻融软土在不同冻结温度和冻融围压(PF-T)下的轴向累积应变、刚度以及孔压发展情况进行研究,并在二次对数模型的基础上建立循环荷载作用下冻融软土的动孔压预测模型。基于核磁共振试验,研究PF-T对冻融土样孔隙分布的影响规律。研究结果表明:土样内部结构在PF-T的作用下达到平衡,且PF-T对土样变形的约束作用随PF-T增大而逐渐减小;冻结温度越低,土体受冻胀效应越明显;随着冻融围压的增加,土样的刚度软化程度逐渐减弱;土样在冻融过程中,PF-T的增大促使土体内部损伤骨架挤密作用更明显。经初次冻融后土体的力学性能衰减程度最大,2次、3次冻融后将加重已有的结构损伤区,同时带来新的结构损伤。冻融过程中,施加的PF-T越大,未冻水增加,冻胀作用减小,融土骨架结构越紧实。研究成果可为预测循环荷载作用下冻融软土的孔压发展提供理论依据。Abstract: Artificial freezing method is widely used in subway tunnel engineering because of its low cost and high safety. The mechanical properties of soft soil will change after freezing and thawing. The development of axial cumulative strain, stiffness and pore water pressure of frozen and thawed soft soil under different freezing temperatures and freezing and thawing confining pressure PF-T was studied through dynamic triaxial tests, and the dynamic pore water pressure prediction model of frozen and thawed soft soil under cyclic loading was established on the basis of quadratic logarithmic model. Based on the nuclear magnetic resonance test, the influence tf PF-T on the pore distribution of frozen-thawed soil samples was studied. The research results show that: the internal structure of the soil sample was balanced under the action of PF-T, and the restraining effect of PF-T on the deformation of the soil sample gradually decreases with the increase of PF-T; the lower the freezing temperature, the more obvious the frost heave effect of soil; with the increase of freezing and thawing confining pressure, the stiffness softening degree of soil samples gradually weakens; during the freezing and thawing process of soil samples, the increase of PF-T promotes the compaction of damaged skeleton in soil. After the first freeze-thaw, the mechanical properties of soil have the greatest attenuation, and after the second and third freeze-thaw, the existing structural damage area will be aggravated and new structural damage will be brought. In the process of freezing and thawing, the larger PF-T was applied, the more unfrozen water is, the less frost heaving is, and the more compact the skeleton structure is. The research results can provide theoretical basis for predicting the development of pore pressure of frozen-thawed soft soil under cyclic loading.
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表 1 试验方案
试样编号 T/℃ qs/kPa PF-T/kPa P/kPa f/Hz Ft N S-1 0 30 0 200 1 0 20000 S-2 −10 30 100 200 1 1~3 20000 S-3 −20 30 100 200 1 1~3 20000 S-4 −30 30 100 200 1 1~3 20000 S-5 −10 30 200 200 1 1~3 20000 S-6 −20 30 200 200 1 1~3 20000 S-7 −30 30 200 200 1 1~3 20000 S-8 −10 30 300 200 1 1~3 20000 S-9 −20 30 300 200 1 1~3 20000 S-10 −30 30 300 200 1 1~3 20000 S-11 −10 30 400 200 1 1~3 20000 S-12 −20 30 400 200 1 1~3 20000 S-13 −30 30 400 200 1 1~3 20000 
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表 2 拟合参数
T/℃ PF-T/kPa A B C 拟合度 −10 100 −0.0004 0.0173 0.4027 0.997 200 −0.0012 0.0283 −0.1711 0.986 300 −0.0014 0.0282 −1.999 0.980 400 −0.0011 0.0233 −0.0832 0.973 −20 100 −0.0012 0.0270 0.7515 0.992 200 −0.0015 0.0292 0.2936 0.991 300 −0.0007 0.0228 −0.0709 0.985 400 0.0004 0.0171 0.0733 0.997 −30 100 −0.0013 0.0287 0.7122 0.995 200 −0.0021 0.0443 −0.4566 0.990 300 −0.0015 0.0293 0.1407 0.990 400 −0.0007 0.0283 −0.2437 0.975
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