An asymptotic method-based composite plate model considering imperfect interfaces

Jaehun Lee, Jun Sik Kim, Maenghyo Cho

Research output: Contribution to journalArticlepeer-review

6 Scopus citations

Abstract

This paper presents an asymptotic method-based analysis of composite laminates having interfacial imperfections. In general, imperfect interfaces are simply modeled by introducing a linear, spring-layer model, which empirically assumes that the displacement jumps that occur at the weakened interface are proportional to the transverse shear stresses of interface positions. In this study, we propose a composite plate model derived by using asymptotic expansion that does not make any assumptions, other than the scaling of coordinate systems. Within the framework of the asymptotic analysis, the spring-layer model is introduced to describe the effect of weakened interfaces, which is realized by the separation of domains in the through-the-thickness direction, and the integration of piecewise continuous warping functions. As a result, we newly define a spring parameter that is exactly the same as the stiffness of a spring. Therefore, a set of spring elements are added to the through-the-thickness modeling of the microscopic analysis, and the plate equations derived in the macroscopic problem are the same as those of the perfectly bonded laminates. As a consequence, we also derive the proposed plate model with the mathematical rigor that the previous asymptotic models contain. We provide some numerical results verifying that the proposed method shows good agreement with the elasticity and 3D FEM solutions.

Original languageEnglish
Pages (from-to)258-270
Number of pages13
JournalInternational Journal of Solids and Structures
Volume190
DOIs
StatePublished - 1 May 2020

Keywords

  • Asymptotic method
  • Composite laminates
  • Imperfect interface
  • Interlayer slip
  • Spring layer model

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