Abstract
Composite materials are becoming more popular in technological applications due to the significant weight savings and strength these materials offer compared to metallic materials. In many of these practical situations, the structures suffer from drop impact loads. Materials and structures significantly change their behavior when submitted to impact loading conditions as compared to quasi-static loading. The present work is devoted to investigating the elastic strain wave in Carbon-Fiber-Reinforced Polymers (CFRP) when subjected to a drop test. A novel drop weight impact test experimental method evaluates parameters specific to 3D composite materials during the study. A strain gauge rosette is employed to record the kinematic on the composites' surface. Experimental results were validated through numerical analysis by FDM Numerical Simulations in Matlab® and Ansys Explicit Dynamic Module. A MATLAB® code was developed to solve wave equation in a 2-D polar coordinate system by discretizing through a Forward-Time Central-Space (FTCS) Finite Difference Method (FDM). Another FEA analysis was performed in ANSYS® Workbench Explicit Dynamics module to simulate the elastic waves produced during the DWIT. The study demonstrates that the elastic waves generated upon impact with a 33 g steel ball from a height of 1 m in a quasi-isotropic CFRP sheet give a strain wave frequency of 205 Hz and finish in almost 0.015 s due to a significant damping effect. Numerical simulations were in good agreement with the experimental findings.
Highlights
Materials are the fundamental elements of all-natural and man-made structures
This study aims to investigate the strain waves produced on surface of Carbon-Fiber-Reinforced Polymers (CFRP) material when it is impacted
Dynamic strain reflects the behavior of CFRP under drop impact for in-plane measurement
Summary
Materials are the fundamental elements of all-natural and man-made structures. Usually, new materials emerge due to the necessity to improve structural efficiency and performance. Strain Wave Analysis in Carbon-Fiber-Reinforced Composites subjected to. Composites are generally used because they have the required properties that cannot be achieved by any constituent materials acting alone. The most common example is the fibrous composite consisting of reinforcing fibers embedded in a binder or matrix material. Fibers are the principal load-bearing members, while the surrounding matrix keeps them in their allocated position, and orientation acts as a load transfer medium between them and protects them from environmental damages due to chemical corrosion and humidity [1,2,3,4]. Carbon fibers reinforced polymers offer a combination of strength and modulus comparable to or better than many traditional metallic materials. Despite many superior properties of composites over metals, they are susceptible to damages caused by low-velocity impact during service, reducing their performance to a great extent [5,6,7,8]
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