Experimental Study on Common and Steel Fiber Reinforced Concrete Under Dynamic Tensile Stress 被引量：2

Experimental Study on Common and Steel Fiber Reinforced Concrete Under Dynamic Tensile Stress

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摘要 Split Hopkinson technique has been developed to test the strength of common concrete and steel fiber reinforced concrete under dynamic tensile stress. Two types of test methods are considered, the splitting tensile test and a modified spalling test in which a specimen is loaded under uniaxial stress. The result shows that the dynamic strength enhancement of concrete is remarkable by using the reinforcing fiber. But for the common concrete, the base of compressive strength seems to show little effect on the tensile strength under dynamic loading. The experimental results also show that the resistance to tensile fracture of the steel fiber reinforced concrete for C100-mix is higher than those of C40-mix.. Split Hopkinson technique has been developed to test the strength of common concrete and steel fiber reinforced concrete under dynamic tensile stress. Two types of test methods are considered, the splitting tensile test and a modified spalling test in which a specimen is loaded under uniaxial stress. The result shows that the dynamic strength enhancement of concrete is remarkable by using the reinforcing fiber. But for the common concrete, the base of compressive strength seems to show little effect on the tensile strength under dynamic loading. The experimental results also show that the resistance to tensile fracture of the steel fiber reinforced concrete for C100-mix is higher than those of C40-mix..

作者董新龙陈江瑛高培正祁振林王永忠王永刚王礼立

机构地区 Mechanics and Materials Science Research Center Research Institute of Engineering Design

出处《Journal of Beijing Institute of Technology》 EI CAS 2004年第3期254-259,共6页 北京理工大学学报（英文版）

基金 SponsoredbytheMinisterialLevelFoundation( 5 780 2 0 1QT190 1)

关键词 CONCRETE dynamic test tensile strength SPALLING concrete dynamic test tensile strength spalling

分类号 O347 [理学—固体力学]

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参考文献5

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Experimental Study on Common and Steel Fiber Reinforced Concrete Under Dynamic Tensile Stress 被引量：2

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