Abstract
Curved laminates in aero-structures, such as the L-angle sections where webs and flanges meet, are prone to delamination due to high interlaminar stresses in these regions. Some efforts to investigate delamination in these structures can be found in the literature but commonly structures are limited to unidirectional layups or modelling approaches are constrained to the cohesive element based methods. In this work, multi-directional L-angle laminates were manufactured using unidirectional prepregs and tested under four-point bending load conditions to examine the interface damage. Acoustic emission technique was used to assist the capture of damage initiation and propagation. Three interface modelling strategies for predicting delamination, namely cohesive element, cohesive surface and perfectly bonded interface were used in the numerical study. The interface damage behaviour was successfully predicted by the simulation methods and differences among the strategies were compared.
Highlights
Composite materials have increasingly been used to meet the growing need for lightweight structures, primarily in aerospace, wind energy, automotive and construction sectors, due to their high specific stiffness and strength along with high energy absorption
The large volume usage of fibre reinforced composites in recent aircraft such as Airbus A350, A320 and Boeing B787 has demonstrated the maturity and acceptance of these advanced materials. Due to their absence of through thickness reinforcement, laminated composite materials are prone to delamination, which reduces the material properties and is considered as one of the most catastrophic failure mechanisms for composite structures [1]
Different interface modelling strategies for delamination modelling will be investigated and compared. This includes the use of the cohesive element method and the cohesive surface method to predict the progressive interface damage behaviour as well as using a perfectly bonded interface to predict delamination initiation
Summary
Composite materials have increasingly been used to meet the growing need for lightweight structures, primarily in aerospace, wind energy, automotive and construction sectors, due to their high specific stiffness and strength along with high energy absorption. Keywords Delamination, Curved laminate, Cohesive zone model, Damage initiation
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