真三轴加载条件下混凝土的力学特性

doi:10.13229/j.cnki.jdxbgxb201703012

摘要/Abstract

摘要： 采用真三轴设备对100 mm×100 mm×100 mm的立方体混凝土试块进行静态加载。首先,保持三个轴向的应力相同,施加应力到设计值p。然后,在保持最小主应力(Z轴)恒定并且X轴应变速率与Y轴应变速率之比也恒定的条件下,单调地增加Y轴应变。通过这种复杂加载试验,研究了混凝土的强度和体积特征。结果表明:在应力-应变混合路径加载的真三轴试验下,混凝土的抗压强度随着最小主应力的增大而增大,随着加载应变速率比的增大而线性递减,都大于单轴抗压强度,最高可达单轴抗压强度的3.4倍;混凝土试块在只经历静水压的加载历史时,初始剪切模量不受影响,不同组剪应力-剪应变关系曲线初始段都存在重合现象。峰值体积应变随着最小主应力和应变速率比的增大而增大,体积先减小后增大,出现扩容现象; 当最小主应力为10 MPa时,混凝土的峰值强度和峰值体积压应变几乎同时出现,并随着最小主应力的增大,两者出现的时间间隔增大,峰值体应变滞后。

关键词: 土木建筑工程, 复合材料, 混凝土, 应力-应变混合路径, 真三轴, 体积应变

Abstract: The mechanical behavior of concrete specimens (cube, L=100 mm) subjected to a mixed path of stress and strain loading was investigated. The specimens were statically loaded into a true triaxial apparatus. First, the stresses in all three directions were simultaneously increased to a specified value p. Then, the strain in Y axis was increased monotonically while maintaining a constant Z-axial stress and a constant strain rate ratio between Y and X axes. The experimental results show that the compressive strengths of the concrete increase with the minimum principal stress, and decrease linearly with the increase in the strain rate ratio, which are higher than uniaxial compressive strength, and the maximum value is 3.4 times of the uniaxial compressive strength. The hydrostatic pressure does not affect the initial shear modulus when the concrete specimens experience only monotonic increase in hydrostatic pressure, and a coinciding part is found in the curves of shear stress versus shear strsin for different experimental groups. The peak value of volumetric strain increases with the minimum principal stress and the strain rate ratio. The volume of the concrete specimen decreases first and then increases, volumetric dilatancy phenomenon occurs. The peak strength and peak volumetric strain appear at the same time when the minimum principal stress is 10 MPa. Then as the minimum principal stress increases the time interval between the peak strength and peak volumetric strain increases, and the peak volumetric strain appears latter.

Key words: civil engineering, composite material, concrete, mixed load path of both stress and strain, true triaxial, volumetric strain

中图分类号:

TU528

李静, 王哲. 真三轴加载条件下混凝土的力学特性[J]. 吉林大学学报(工学版), 2017, 47(3): 771-777.

LI Jing, WANG Zhe. Mechanical characteristics of concrete under true triaxial loading condition[J]. 吉林大学学报(工学版), 2017, 47(3): 771-777.

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