Performance of delaminated CFRP composite under pure bending using two-dimensional digital image correlation

IF 0.9 Q4 ENGINEERING, CIVIL

Australian Journal of Structural Engineering Pub Date : 2023-11-08 DOI:10.1080/13287982.2023.2275807

Kopparthi Phaneendra Kumar, Srikar Gemaraju, Bhaskara Rao Pathakokila, Suresh Gamini

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Abstract

ABSTRACTDelamination is an interlaminar damage which may be pre-existing in multilayered fibre reinforced polymer composite parts due to manufacturing imperfections or generated by out of plane loading during service life. Its existence leads to significant reduction of structural integrity, strength and stiffness of the material. Hence, to study the effect of induced delamination on the performance of a composite under pure bending, a circular polytetrafluoroethylene (PTFE) film was introduced between the second and third plies of a sixteen layered carbon/epoxy laminate during fabrication. The bending tests were conducted in displacement control mode. The displacements and strains were measured through the thickness of the composite using two-dimensional digital image correlation. The damage modes were captured using CCD camera and the causes were explained. The flexural strength and modulus of composite were 329.74 MPa and 104.58 GPa respectively. The delaminated composite behaved as a single member without any crack within the elastic range. The existence of PTFE drastically reduced flexural stiffness of composite beyond the stress at 75.81% of its ultimate strength. The ± 45º plies offered low mechanical performance against the induced off axis loading. Hence, in these plies fibre breakage was higher. In the portion of PTFE, the strains were higher due to larger outward displacements produced by local buckling.KEYWORDS: Carbon fibreartificial delaminationflexural strengthdigital image correlation (DIC)damagelocal buckling AcknowledgmentsAuthors are grateful to Dr. Ramji Manoharan, Professor & Head, Department of Mechanical and Aerospace Engineering, Indian Institute of Technology, Hyderabad, India for the permission given to work in composites laboratory. Authors are also thankful to Dr. Gangadharan Raju, Associate Professor, Department of Mechanical and Aerospace Engineering, Indian Institute of Technology, Hyderabad, India for the suggestions given to carry out this work. They are grateful to Mr. Lala Bahadur Andraju and Mr. M. Seshadri, Former Research Scholars, Department of Mechanical and Aerospace Engineering, Indian Institute of Technology, Hyderabad, India for their advice given to conduct experiments.Disclosure statementNo potential conflict of interest was reported by the author(s).Additional informationFundingThis study was not funded by any organization.

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基于二维数字图像相关的分层CFRP复合材料纯弯曲性能研究

摘要脱层是多层纤维增强聚合物复合材料零件由于制造缺陷或在使用寿命中受到面外载荷而产生的层间损伤。它的存在导致材料的结构完整性、强度和刚度显著降低。因此，为了研究诱导脱层对纯弯曲复合材料性能的影响，在制造过程中，在16层碳/环氧复合材料的第二层和第三层之间引入了圆形聚四氟乙烯(PTFE)薄膜。弯曲试验在位移控制模式下进行。利用二维数字图像相关技术通过复合材料的厚度测量位移和应变。利用CCD相机捕捉了其损伤模式，并对损伤原因进行了分析。复合材料的抗弯强度和模量分别为329.74 MPa和104.58 GPa。分层复合材料在弹性范围内表现为单一构件，无裂纹。PTFE的存在使复合材料的抗弯刚度大大降低，达到极限强度的75.81%。±45º层对诱导离轴载荷的机械性能较低。因此，在这些层中，纤维断裂率较高。在PTFE部分，由于局部屈曲产生较大的向外位移，应变较高。致谢致谢致谢致谢致谢致谢致谢致谢致谢致谢致谢致谢致谢致谢致谢致谢致谢致谢致谢致谢致谢致谢致谢致谢致谢致谢致谢致谢致谢致谢致谢致谢致谢致谢致谢作者还感谢印度海得拉巴印度理工学院机械与航空航天工程系副教授Gangadharan Raju博士为开展这项工作提出的建议。他们感谢印度海得拉巴印度理工学院机械和航空航天工程系前研究学者Lala Bahadur Andraju先生和M. Seshadri先生为进行实验提供的建议。披露声明作者未报告潜在的利益冲突。本研究没有得到任何组织的资助。

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来源期刊

Australian Journal of Structural Engineering ENGINEERING, CIVIL-

CiteScore

2.50

自引率

0.00%

发文量

期刊介绍： The Australian Journal of Structural Engineering (AJSE) is published under the auspices of the Structural College Board of Engineers Australia. It fulfils part of the Board''s mission for Continuing Professional Development. The journal also offers a means for exchange and interaction of scientific and professional issues and technical developments. The journal is open to members and non-members of Engineers Australia. Original papers on research and development (Technical Papers) and professional matters and achievements (Professional Papers) in all areas relevant to the science, art and practice of structural engineering are considered for possible publication. All papers and technical notes are peer-reviewed. The fundamental criterion for acceptance for publication is the intellectual and professional value of the contribution. Occasionally, papers previously published in essentially the same form elsewhere may be considered for publication. In this case acknowledgement to prior publication must be included in a footnote on page one of the manuscript. These papers are peer-reviewed as new submissions. The length of acceptable contributions typically should not exceed 4,000 to 5,000 word equivalents. Longer manuscripts may be considered at the discretion of the Editor. Technical Notes typically should not exceed about 1,000 word equivalents. Discussions on a Paper or Note published in the AJSE are welcomed. Discussions must address significant matters related to the content of a Paper or Technical Note and may include supplementary and critical comments and questions regarding content.