Journal
INTERNATIONAL JOURNAL OF SOLIDS AND STRUCTURES
Volume 233, Issue -, Pages -Publisher
PERGAMON-ELSEVIER SCIENCE LTD
DOI: 10.1016/j.ijsolstr.2021.111150
Keywords
DCB; Snap-back instability; Delamination; Bridging; Crack trapping
Categories
Funding
- King Abdullah University of Science and Technology (KAUST) [BAS/1/1315-01-01]
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This study focuses on the use of bridging mechanisms to toughen the interface of laminated composites, exploring the theoretical analysis of fracture resistance enhancement through bridging in a composite double cantilever beam (DCB). The research reveals crack trapping, snap-back instability, and the overall toughness contributions, providing insights into the physics related to the structural response of DCB with discrete toughening elements. A dimensionless quantity for evaluating snap-back instability intensity and the role of geometrical properties in macroscopic fracture toughness are also discussed.
Adhesive bonding community shows a continued interest in using bridging mechanisms to toughen the interface of secondary bonded joints, especially in the case of laminated composites. Due to snap-back instability that occurs during fracture, confusions may exist when identifying the toughening effect experimentally. The true toughening effect may be overestimated by lumping all energy contributions (kinetic energy included) in an overall effective toughness. Here, fundamentals for bridging to enhance fracture resistance are explored through the theoretical analysis of the delamination of a composite dou-ble cantilever beam (DCB) with bridging. Specifically, we establish a theoretical framework on the basis of Timoshenko beam theory and linear elastic fracture mechanics to solve the fracture response of DCB in the presence of discrete bridging phases. We elucidate the crack trapping and the snap-back instability in structural response during the crack propagation. We identify the contribution to the overall toughness observed numerically/experimentally of both the physical fracture energy and other types of dissipation. The associated toughening mechanisms are then unveiled. Furthermore, we study the effects of property of the bridging phases on the snap-back instability, based on which, we propose a dimensionless quantity that can be deployed as an indicator of the intensity of snap-back instability. Finally, we identify the role of geometrical properties, i.e. the substrate thickness and the arrangement spacing of the bridging phases, in the snap-back instability and the macroscopic fracture toughness of a DCB. This work provides, from a theoretical point of view, an essential insight into the physics related to the structural response of DCB with discrete toughening elements. (c) 2021 Elsevier Ltd. All rights reserved.
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