Dynamic behavior of frozen soil under uniaxial strain and stress conditions 被引量：9

Dynamic behavior of frozen soil under uniaxial strain and stress conditions

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摘要 The split Hopkinson pressure bar （SHPB） method is used to investigate the dynamic behavior of the artificial frozen soil under the nearly uniaxial strain and uniaxial stress conditions. The tests are conducted at the temperatures of -3 ℃, -8 ℃, -13℃, -17℃, -23℃, and -28℃ and with the strain rates from 900 s^-1 to 1500 s^-1. The nearly uniaxial stress-strain curves exhibit an elastic-plastic behavior, whereas the uniaxial stress-strain curves show a brittle behavior. The compressive strength of the frozen soil exhibits the positive strain rate and negative temperature sensitivity, and the final strain of the frozen soil shows the positive strain under the nearly uniaxial strain is greater rate sensitivity. The strength of the frozen soil than that under the uniaxial stress. After the negative confinement tests, the specimens are compressed, and the visible cracks are not observed. However, the specimens are catastrophically damaged after the uniaxial SHPB tests. A phenomenological model with the thermal sensitivity is established to describe the dynamic behavior of the confined frozen soil. The split Hopkinson pressure bar （SHPB） method is used to investigate the dynamic behavior of the artificial frozen soil under the nearly uniaxial strain and uniaxial stress conditions. The tests are conducted at the temperatures of -3 ℃, -8 ℃, -13℃, -17℃, -23℃, and -28℃ and with the strain rates from 900 s^-1 to 1500 s^-1. The nearly uniaxial stress-strain curves exhibit an elastic-plastic behavior, whereas the uniaxial stress-strain curves show a brittle behavior. The compressive strength of the frozen soil exhibits the positive strain rate and negative temperature sensitivity, and the final strain of the frozen soil shows the positive strain under the nearly uniaxial strain is greater rate sensitivity. The strength of the frozen soil than that under the uniaxial stress. After the negative confinement tests, the specimens are compressed, and the visible cracks are not observed. However, the specimens are catastrophically damaged after the uniaxial SHPB tests. A phenomenological model with the thermal sensitivity is established to describe the dynamic behavior of the confined frozen soil.

作者张海东朱志武宋顺成康国政宁建国

机构地区 Traction Power State Key Laboratory State Key Laboratory of Frozen Soil Engineering State Key Laboratory of Explosion Science and Technology

出处《Applied Mathematics and Mechanics(English Edition)》 SCIE EI 2013年第2期229-238,共10页 应用数学和力学（英文版）

基金 supported by the National Natural Science Foundation of China (No.11172251) the Open Fund of State Key Laboratory of Frozen Soil Engineering (No.SKLFSE201001) the Fundamental Research Funds for the Central Universities (No.SWJTU09CX069)

关键词 frozen soil dynamic loading split Hopkinson pressure bar （SHPB） con-finement high strain rate frozen soil, dynamic loading, split Hopkinson pressure bar （SHPB）, con-finement, high strain rate

分类号 O344.1 [理学—固体力学]

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