Relation of Damage Variable and Gas Permeability Coefficient of Concrete under Stress

Relation of Damage Variable and Gas Permeability Coefficient of Concrete under Stress

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摘要 Compressive stress and tensile stress were applied to concrete specimens using test rigs designed by RILEM TC 246-TDC. Ultrasonic wave velocity and autoclam permeability system were used to characterize the damage variable and gas permeability coefficient of concrete, respectively. The experimental results show that the strain value of concrete increases with the increasing of stress level and loading time. The damage variable and gas permeability coefficient of concrete under compressive stress decrease at first and increase after a threshold value between 0 and 0.6. When the concrete is under tensile load, the damage variable and gas permeability coefficient increase with tensile stress, with a significant increase from 0.3 to 0.6 tensile stress. There is a strong linear relationship between the damage variable and the gas permeability coefficient, suggesting both as good indicators to characterize the damage of concrete under stress. Compressive stress and tensile stress were applied to concrete specimens using test rigs designed by RILEM TC 246-TDC. Ultrasonic wave velocity and autoclam permeability system were used to characterize the damage variable and gas permeability coefficient of concrete, respectively. The experimental results show that the strain value of concrete increases with the increasing of stress level and loading time. The damage variable and gas permeability coefficient of concrete under compressive stress decrease at first and increase after a threshold value between 0 and 0.6. When the concrete is under tensile load, the damage variable and gas permeability coefficient increase with tensile stress, with a significant increase from 0.3 to 0.6 tensile stress. There is a strong linear relationship between the damage variable and the gas permeability coefficient, suggesting both as good indicators to characterize the damage of concrete under stress.

作者 TANG Guanbao YAO Yan 唐官保;姚燕;WANG Ling;CUI Suping;CAO Yin

机构地区 College of Materials Science and Engineering State Key Laboratory of Green Building Materials

出处《Journal of Wuhan University of Technology(Materials Science)》 SCIE EI CAS 2018年第6期1481-1485,共5页 武汉理工大学学报（材料科学英文版）

基金 Funded by the National Natural Science Foundation of China(No.51320105016)

关键词 compression tension STRAIN damage variable gas permeability coefficient compression tension strain damage variable gas permeability coefficient

分类号 TB [一般工业技术]

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Journal of Wuhan University of Technology(Materials Science)

2018年第6期

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Relation of Damage Variable and Gas Permeability Coefficient of Concrete under Stress

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