The influence of hole quality on mechanical behavior and strain distribution of open‐hole CFRP laminates subject to different machining processes

Machining process is generally required for cutting composite material of structural components prior to final assembly in aerospace industry. This study aimed to investigate surface quality and mechanical behavior of open‐hole composite laminates following different machining processes including ab...

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Bibliographic Details
Published in:Polymer composites 2022-12, Vol.43 (12), p.9218-9230
Main Authors: Li, Maojun, Jiang, Xiaoyang, Su, Ting
Format: Article
Language:English
Subjects:
Abrasive cutting
Abrasive machining
Aerospace industry
CFRP laminate
Composite materials
Digital imaging
Fiber lasers
Geometric accuracy
geometrical accuracy
Hydraulic jet cutting
Laminates
Laser machining
machining
mechanical behavior
Mechanical properties
Shear strain
Strain distribution
Surface properties
Ultraviolet lasers
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Summary:Machining process is generally required for cutting composite material of structural components prior to final assembly in aerospace industry. This study aimed to investigate surface quality and mechanical behavior of open‐hole composite laminates following different machining processes including abrasive waterjet cutting, high power fiber laser machining, conventional drilling and ultraviolet laser machining. Hole quality was quantified for further understanding the correlation between surface damage and mechanical behavior. Experimental results demonstrated that the hole geometrical accuracy and mechanical property were highly dependent on the machining methods. Digital image correlation technique was implemented to capture the strain distribution and strain evolution around open holes during tensile loading. Machining methods exhibited significant impact on εyy, εxx, and εxy strain levels around hole edges, while limited influence on strain distribution patterns. εyy and εxx concentrated in the regions consisting of fibers perpendicular to and along the loading direction respectively, and shear strain εxy featured with X shape around hole edge.
ISSN:0272-8397
1548-0569
DOI:10.1002/pc.27099