Review on the Fatigue of Composite Hybrid Joints Used in Aircraft Structures

Nabil Chowdhury; Wing Kong Chiu; John Wang

doi:10.4028/www.scientific.net/AMR.891-892.1591

Paper Titles

Modeling Reliability of Critical Infrastructures with Application to Port Oil Transportation System
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Optimizing Reliability of Critical Infrastructures with Application to Port Oil Piping Transportation System
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Postponing Crack Nucleation in 2024 Aluminium Alloy by Dynamic Precipitation from the Supersaturated State
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Specimens for Simultaneous Mode II, III and II+III Fatigue Crack Propagation: Elasto-Plastic Solution of Crack Tip Stress-Strain Field
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Review on the Fatigue of Composite Hybrid Joints Used in Aircraft Structures
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A Review of Damage Tolerant Design, Certification and Repair in Metals Compared to Composite Materials
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Low-Cycle Fatigue Behavior of TWIP Steel - Effect of Grain Size
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Crystal Plasticity Finite Element Simulations of Polycrystalline Aluminium Alloy under Cyclic Loading
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Modelling the Effect of Particle Size Distribution in Multiphase Flows with Computational Fluid Dynamics and Physical Erosion Experiments
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HomeAdvanced Materials ResearchAdvanced Materials Research Vols. 891-892Review on the Fatigue of Composite Hybrid Joints...

Review on the Fatigue of Composite Hybrid Joints Used in Aircraft Structures

Abstract:

The use of composite materials as a replacement for commonly used metals such as aluminium and steel are increasing in the engineering industry, particularly in the aerospace sector. The move towards light weight and high stiffness structures that have good fatigue durability and corrosion resistance has led to the rapid move from metal to composites. This change allows for further flexibility in design and fabrication of various components and joints. There are three main categories of joints used in composite materials – mechanically fastened joints, adhesively bonded joints and the combination of the two called hybrid joints. In order to adequately understand the effectiveness of these joints, substantial testing and validation is required, particularly in the use of hybrid joints for real life applications. Static testing, load distribution and parametric studies of hybrid joints have been investigated by various researchers; however further work is still required in understanding the durability and fatigue of hybrid joints and ensuring that both the adhesive and mechanical fasteners can work together effectively in producing an optimum joint. Mechanical fastening alone in composite laminates is not a preferred joining method as they create high stress concentrations around the fastener holes. Adhesive bonding although has numerous benefits it is difficult to detect the bond defect particularly in cases where weak bonds can occur during applications and it is sensitive towards the environmental conditions. Thus hybrid joints are seen arguably as being more effective in joining composite components together and offer greater residual strength. Hence the performance, strength and long-term durability of these joints need to be further investigated and be applied to practical situations whilst assisting in repair certification.