The Effect of Expansion Deformation on the Damage of Hole Wall and Fatigue Performance of Carbon Fiber Reinforced Composite Materials

doi:10.3901/JME.2025.07.134

Abstract

Abstract: Carbon fiber reinforced polymer (CFRP) is a widely used structural material in advanced aircraft, and its components are often used in important load-bearing areas through bolted joint. These structures need to withstand complex alternating loads during service, which puts high demands on their fatigue performance. However, The structural holes in CFRP components are easily subjected to bolt compression during mechanical connection. This will cause fatigue failure of these components, affecting the long-term service performance of the aircraft. To address the above problems, this work proposes a CFRP hole expansion strengthening process. The influence of expansion deformation on the damage of CFRP hole walls and fatigue performance was studied through a combination of simulation and experiment, and the gain mechanism of hole expansion process on the fatigue life of CFRP/Ti connectors was explained. The results indicate that as the expansion deformation increases, the expansion force continuously increases. The damage to CFRP holes is also more severe. When the expansion deformation exceeds 4%, serious damage occurs to the hole wall. The main forms of damage are fiber compression fracture in the 0 ° layer, fiber compression bending fracture in the 90 ° layer, and matrix compression fracture damage in each layer. The bushing pressed into the hole during the expansion process can reduce the compression effect of the bolt on the CFRP hole during the loading process of the CFRP/Ti connector. It can avoid stress concentration and prevent premature fatigue failure caused by CFRP crushing. When the expansion deformation is 3%, the fatigue life of the specimen is 3.5 times that of the ordinary specimen, and the gain is the most significant. Excessive initial damage will suppress the fatigue life gain of CFRP when the expansion deformation is too large.

Key words: composite materials, hole expansion, deformation, damage, fatigue performance

CLC Number:

TG54

WANG Chenguang, WANG Haihang, YANG Jie, FAN Zhilei, ZHOU Entao, GE Ende, AN Qinglong, CHEN Ming. The Effect of Expansion Deformation on the Damage of Hole Wall and Fatigue Performance of Carbon Fiber Reinforced Composite Materials[J]. Journal of Mechanical Engineering, 2025, 61(7): 134-143.

References

[1] 陈勇，吴光辉，钟科林，等. 复合材料在大飞机上的应用现状[J]. 现代交通与冶金材料，2024，4(2)：1-7. CHEN Yong，WU Guanghui，ZHONG Kelin，et al. Application of composite materials in large aircrafts[J]. Modern Transportation and Metallurgical Materials，2024，4(2)：1-7.
[2] LI Y，JIAO F，ZHANG Z，et al. A prediction model for drilling temperature of CFRP/Ti stacks and green cooling strategy considering chip ejection process[J]. Journal of Materials Processing Technology，2024，329：0924-1036.
[3] WEI Z，ZHANG K，WANG Z et al. Experimental and numerical investigation of wear behavior at overlapping area in CFRP/Ti laminated single-lap bolted joint[J]. Engineering Failure Analysis，2024，159：1350-6307.
[4] MCCARTHY M，LAWLOR V，STANLEY W. Bolt-hole clearance effects and strength criteria in single-bolt，single-lap，composite bolted joints[J]. Composites Science and Technology，2002，62(10)：1415-1431.
[5] CAO Y，CAO Z，ZUO Y，et al. Numerical and experimental investigation of fitting tolerance effects on damage and failure of CFRP/Ti double-lap single-bolt joints[J]. Aerospace Science and Technology，2018，78：461-470.
[6] SONG D，LI Y，ZHANG K，et al. Stress distribution modeling for interference-fit area of each individual layer around composite laminates joint[J]. Composites Part B：Engineering，2015，78：469-479.
[7] PRADHAN B，RAMESH B. Assessment of beneficial effects of interference-fit in pin-loaded FRP composites[J]. Journal of reinforced plastics and composites，2007，26(8)：771-788.
[8] 张岐良，曹增强. 复合材料螺接性能的影响因素研究[J]. 航空学报，2012，33(4)：755-762. ZHANG Qiliang，CAO Zengqiang. Research on the influencing factors of the bolt joint performance of composite materials[J]. Acta Aeronautica et Astronautica Sinica，2012，33(4)：755-762.
[9] 张俊琪，刘龙权，陈昆昆，等. 干涉配合对复合材料机械连接结构承载能力的影响[J]. 上海交通大学学报，2013，47(11)：1795-1800. ZHANG Junqi，LIU Longquan，CHEN Kunkun，et al. Influence of bolt-hole interference fit conditions on load capacity in composite mechanical joints[J]. Journal of Shanghai Jiao Tong University，2013，47(11)：1795-1800.
[10] 葛恩德. 碳纤维复合材料及其叠层连接结构孔挤压强化技术研究[D]. 南京：南京航空航天大学，2015. GE Ende. Research on hole expansion strengthing technology of composites and their stacks joint structures[D]. Nanjing：Nanjing University of Aeronautics and Astronautics，2015.
[11] 刘一兵，孟仲伟. 复合材料层板衬套强化孔的疲劳寿命增益分析[J]. 航空学报，1998，19(5)：585-587. LIU Yibing，MENG Zhongwei. Analysis of increment for the fatigue life of bushing intensified hole on composite laminate plate[J]. Acta Aeronautica et Astronautica Sinica，1998，19(5)：585-587.
[12] CHENG Y，SU H，FU Y，et al. Numerical simulation on stress distribution and failure of composites holes with cold expansion[J]. Advanced Materials Manufacturing Science and Technology XV，2014，770：221-225.
[13] TROMBINI M，ENEA M，AEEUDA M，et al. 1D higher-order theories for quasi-static progressive failure analysis of composites based on a full 3D Hashin orthotropic damage model[J]. Composites Part B：Engineering，2024，270：1359-8368.
[14] ZOU F，DANG J，CHEN T. Evaluation of typical hole-making strategies on mechanical behavior of CFRP/Ti single-lap bolted joints[J]. Composite Structures，2023，305：116511.
[15] 左杨杰. 复合材料/钛合金结构干涉配合螺栓连接动静态损伤及失效研究[D]. 西安：西北工业大学，2018. ZUO Yangjie. Quasi-static and dynamic damage and failure investigation of CFRP/Ti interference fit bolted structures[D]. Xi’an：Northwestern Polytechnical University，2018.