玄武岩纤维混凝土孔隙结构表征及劈裂拉伸试验研究

doi:10.19936/j.cnki.2096-8000.20221028.010

摘要/Abstract

摘要： 基于试验研究不同长度(0 mm、6 mm、12 mm、18 mm)玄武岩纤维混凝土内部孔隙结构表征及在不同应变率下劈裂拉伸力学特性,采用核磁共振(nuclear magnetic resonance)及电镜扫描(scanning electron microscope)技术,分析试件T₂谱分布、孔径分布、孔隙率及纤维与混凝土间的黏结情况,并利用万能试验机与分离式霍普金森压杆(split Hopkinson pressure bar)对不同长度玄武岩纤维混凝土试件开展不同应变率下的劈裂拉伸试验,分析纤维长度、应变率对混凝土劈裂拉伸力学性能的影响。结果表明:玄武岩纤维混凝土的T₂谱曲线为双峰型,素混凝土试件T₂谱峰值最大,孔隙率最大,纤维的掺入能有效降低试件孔隙率,长度为6 mm时效果最佳;试件内部孔隙以微孔、小孔为主,纤维的掺入使试件微孔占比增大,小孔占比降低;随着应变率的增大,试件表现出应变率强化效应,动态增强因子(dynamic increase factor)与应变率间呈良好对数相关;纤维的掺入能有效增强试件拉伸强度,减小其极限应变,纤维长度为18 mm时效果最佳;SEM结果表明玄武岩纤维与混凝土材料间黏结作用能有效承担荷载,减小裂隙扩展,增强试件抵抗受力变形能力。

关键词: 玄武岩纤维, 混凝土, 核磁共振, 电镜扫描, SHPB, 劈裂拉伸强度, 极限应变

Abstract: Based on the experimental study of the internal pore structure characterization of basalt fiber concrete with different lengths (0 mm, 6 mm, 12 mm, 18 mm) and the mechanical properties of splitting tension under different strain rates, the techniques of nuclear magnetic resonance and scanning electron microscope were used to analyze the T₂ spectrum distribution, pore size distribution, porosity and the bond between fiber and concrete. Dynamic splitting tests were carried out on basalt fiber concrete specimens of different lengths at different strain rates by using universal testing machine and split Hopkinson pressure bar, and the effects of fiber length and strain rate on the splitting tensile properties of concrete were analyzed. The results show that the T₂ spectrum curve of basalt fiber concrete is bimodal. The T₂ spectrum peak value and porosity of plain concrete specimen are the largest. The incorporation of fiber can effectively reduce the porosity of the specimen, and the effect is best when the length is 6 mm. The internal pores of the specimen are mainly micropores and small holes. The incorporation of fiber increases the proportion of micropores in the specimen, while the proportion of small holes decreases. As the strain rate increases, the specimen exhibits a strain rate strengthening effect, and the dynamic increase factor has a good logarithmic correlation with strain rate. The incorporation of fiber can effectively enhance the tensile strength of the specimen and reduce its ultimate strain. The effect is best when the fiber length is 18 mm. SEM result shows that the bond between basalt fiber and concrete material can effectively bear the load, reduce the crack expansion and enhance the resistance of the specimen to deformation.

Key words: basalt fiber, concrete, nuclear magnetic resonance, scanning electron microscope, SHPB, split tensile strength, ultimate strain

中图分类号:

TB332

贾静恩, 张彬. 玄武岩纤维混凝土孔隙结构表征及劈裂拉伸试验研究[J]. 复合材料科学与工程, 2022, 0(10): 63-69.

JIA Jing-en, ZHANG Bin. Study on characterization of pore structure of basalt fiber concrete and split tensile test[J]. COMPOSITES SCIENCE AND ENGINEERING, 2022, 0(10): 63-69.

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