Adhesively bonded disk under compressive diametrical load

A closed-form full-field solution is presented for stresses and displacement in a circular disk containing a diametrical adhesive thin layer induced by two opposite compressive loads acting along an arbitrary diametrical direction. For the sake of simplicity, the adhesive layer is treated as a tange...

Full description

Saved in:
Bibliographic Details
Published inInternational journal of solids and structures Vol. 152-153; pp. 51 - 65
Main Authors Radi, E., Dragoni, E., Spaggiari, A.
Format Journal Article
LanguageEnglish
Published New York Elsevier Ltd 01.11.2018
Elsevier BV
Subjects
Adhesive bonding
Adhesive strength
Airy stress function
Bipolar coordinates
Boundary conditions
Closed form solutions
Collocation method
Collocation methods
Differential equations
Digital imaging
Displacement
Elasticity
Exact solutions
Fredholm equations
Integral equations
Mode mixity
Parameters
Perturbation analysis
Perturbation methods
Plane elasticity
Power series
Series expansion
Shear modulus
Shear stiffness
Shear stress
Singular integral equation
Stress concentration
Stress distribution
Stress functions
Symmetry
Trigonometric functions
Perturbation analysis
Mode mixity
Plane elasticity
Singular integral equation
Adhesive bonding
Bipolar coordinates
Collocation method
Airy stress function
Online AccessGet full text

Cover

More Information
Summary:A closed-form full-field solution is presented for stresses and displacement in a circular disk containing a diametrical adhesive thin layer induced by two opposite compressive loads acting along an arbitrary diametrical direction. For the sake of simplicity, the adhesive layer is treated as a tangential displacement discontinuity between the two disk halves. The problem is split into symmetric and skew-symmetric loading conditions. No contribution is expected from the adhesive layer for the symmetric problem. For the skew-symmetric loading condition, a general integral solution in bipolar coordinates has been assumed for the Airy stress function in the form of a Fourier sine transform. The imposition of the boundary conditions then allows us to reduce the problem to a Fredholm integral equation of the first kind defined on the half-line or equivalently to a singular integro-differential equation defined on a bounded interval. A preliminary asymptotic analysis of the stress and displacement fields at the edges of the adhesive thin layer shows that the stress field is finite therein, but the rotation displays a logarithmic singularity. A numerical solution of the singular integro-differential equation is then provided by assuming a power series expansion for the shear stress, whose coefficients are determined by using a collocation method. An approximate closed-form solution is also derived by exploiting a perturbation method that assumes the ratio between the shear modulus of the disk material and the shear stiffness of the adhesive thin layer as small parameter. The shear stress distribution along the thin layer turns out to be more and more uniform as the adhesive shear stiffness decreases. In order to validate the analytical results, FE investigations and also experimental results obtained by using Digital Image Correlation (DIC) techniques are presented for varying loading orientation and material parameters.
ISSN:0020-7683
1879-2146
DOI:10.1016/j.ijsolstr.2018.05.021