Cracks in laminates subjected to concentrated forces and moments

Research output: Contribution to journalArticlepeer-review


The crack problems are important not only in macromechanics but also in micromechanics. Because of its importance a lot of analytical, numerical and experimental studies have been published in journals and books. Among them, the study of Green's function attracts many researchers' attention because analytically it may provide solutions for arbitrary loading through superposition and numerically it can be employed as the fundamental solutions for boundary element method and as the kernel functions of integral equations to consider crack interaction problems. Although a lot of Green's functions have been presented in the literature, due to mathematical infeasibility most of them are restricted to two-dimensional problems and very few of them consider possible coupled stretching-bending analysis which may occur for general unsymmetric composite laminates subjected inplane and/or out-of-plane forces and moments. In this paper we consider an infinite composite laminate containing a traction-free crack subjected to concentrated forces and moments at an arbitrary point of the laminate. By employing Stroh-like formalism for the coupled stretching-bending analysis, recently the Green's functions for the infinite laminates (without holes) were obtained in closed-form. Based upon the non-hole Green's functions, through the use of analytical continuation method the Green's functions for cracks 'are now obtained in explicit closed-form and are valid for the full fields. By proper differentiation, the associated stress intensity factors are also solved explicitly.

Original languageEnglish
Pages (from-to)1-6
Number of pages6
JournalKey Engineering Materials
Volume306-308 I
Publication statusPublished - 2006 Jan 1

All Science Journal Classification (ASJC) codes

  • Materials Science(all)
  • Mechanics of Materials
  • Mechanical Engineering


Dive into the research topics of 'Cracks in laminates subjected to concentrated forces and moments'. Together they form a unique fingerprint.

Cite this