人工冻结竖井中冻土壁强度与变形分析*

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摘要在K0排水固结后再冻结(K0DCF)过程下，通过冻结兰州砂土和冻结兰州黄土的卸载剪切试验发现，不同围压下两种土质的应力-应变曲线均类似于理想刚塑性应力-应变曲线，但是K0固结段却表现出明显的差异。他们的屈服强度随围压的增大而线性增大，且黄土的屈服强度明显大于砂土；破坏变形随围压的增大也线性增大。他们的屈服强度均随温度的降低而增加，但黄土的强度值明显大于砂土；对破坏变形则存在两种不同的关系，对砂土，随温度的降低破坏变形降低；对黄土，随温度的降低破坏变形逐渐增大。

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关键词 ：关键词土力学, 人工冻结竖井, 冻土, 强度, 变形

Abstract：For frozen Lanzhou sandy soil and loess at the K0DCF test mode，it is found that the stress-strain curves are similar to ideal rigid plastic ones under unloading，but the stress-strain curves of sandy soil and loess are different in the sections of K0 consolidation. The yield strength increases linearly with increment of confining pressure and decrement of temperature. The yield strength of frozen loess is obviously larger than that of the frozen sandy soil. The failure strain also increases linearly with confining pressure. With decrement of temperature，for frozen sandy soil，the failure strain decreases，while for frozen loess，the failure strain increases gradually.

Key words： Keywords soil mechanics artificial frozen shaft frozen soil yield strength failure strain

收稿日期: 1900-01-01

引用本文:

马巍常小晓王大雁. 人工冻结竖井中冻土壁强度与变形分析*[J]. 岩石力学与工程学报, 2003, 22(S2): 2871-2874.
Mai Wei，Chang Xiaoxiao，Wang Dayan. BEHAVIORS OF STRENGTH AND DEFORMATION OF FROZEN SOIL WALL IN ARTIFICIALLY FROZEN SHAFT. , 2003, 22(S2): 2871-2874.

链接本文:

https://rockmech.whrsm.ac.cn/CN/ 或 https://rockmech.whrsm.ac.cn/CN/Y2003/V22/IS2/2871

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