Journal of South China University of Technology(Natural Science Edition)

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Microscopic Mechanical Analysis of Interface Deformation during Pull-out of Single Polypropylene Fiber

BI Yujie1  MAO Lingtao1,2  LIU Haizhou3  LIU Jiaojiao1  LIU Yifan4   

  1. 1. School of Mechanics and Civil Engineering, China University of Mining and Technology, Beijing 100083,China;

    2. Shenzhen Institute of Advanced Technology,Chinese Academy of Sciences,Shenzhen 518055,Guangdong, China;

    3. State Key Laboratory for Fine Exploration and Intelligent Development of Coal Resources, China University of Mining and Technology, Beijing 100083, China;

    4. China Construction Seventh Engineering Division Co., Ltd.,Zhengzhou 450000, Henan, China

  • Published:2025-02-28

Abstract:

To investigate the bonding mechanical properties between polypropylene fiber and concrete interface, the debonding process of the interface was studied through single fiber pull-out microscopic mechanical experiments and numerical simulations. An in-situ scanning observation system was established using micro CT and a self-developed single fiber drawing device to observe the process of pulling out a single polypropylene fiber with indentation from the mortar matrix. By employing mechanically regularized global digital volume correlation, the deformation fields of the interface between fiber and matrix was obtained, and the interface debonding was quantified by calculating the relative displacement of the shared nodes between the fiber and the matrix. A 3D microscopic numerical model reflecting the true shape of fibers and matrix was established based on CT images, and the single fiber drawing process was simulated and analyzed. The results show that the force-displacement curves displayed multi-peak fluctuations corresponding to the fiber geometry after the peak. The strain fields at interfaces measured by digital volume correlation and numerical simulation showed a strain concentration phenomenon related to the geometric shape of the indentation fiber, indicating that the periodic indentation of the fiber increases mechanical interlocking and friction forces between the fiber and the matrix during pullout. The relative displacement at the interface was maximum at the embedded initiation and decreases along the fiber toward the embedded end. In the plane perpendicular to the fiber direction, the variation of relative displacement was correlated with the geometric shape of the fiber. The relative displacement along the fiber direction reflected that the fiber and matrix have completely debonded before the pullout force reaches the peak load.

Key words: polypropylene fiber reinforced concrete, interface debonding, digital volume correlation method, measurement of three-dimensional deformation field