Material characterization of structural adhesives in the bulk and bonded forms is discussed. Constitutive relations used for describing stress–strain data are reviewed. The difficulties associated with adhesive characterization in the bonded form are cited. Common testing procedures for adhesive characterization in the bulk and bonded forms are reviewed. In presenting the constitutive relations used in material characterization of structural adhesives, deformation theories introduced by Hencky are reviewed first. The modifications made in this theory to render it rate dependent and bilinear are discussed and applications to adhesive characterization are cited. Application of linear viscoelasticity, mechanical model characterization, and its use in describing the dependence of adhesive and cohesive strengths on rate, temperature, and bond thickness are presented. The time–temperature superposition principle and three-dimensional stress–strain relations in integral and differential operator forms are reviewed. Frequent assumptions for dilatation and distortion operations are presented. Procedures for describing nonlinear viscoelastic behavior are reviewed. It is pointed out that the extent of nonlinearity is dependent on both the stress level and the time scale. The use of nonlinear spring and dashpot elements, nonlinear differential operators, and perturbation of elastic and viscous coefficients are cited. Prandtl’s incremental theory of plasticity and its extension in the form of over-stress theory is presented. The incorporation of this over-stress idea into the viscoelastic mechanical model characterization is discussed. The modified Bingham model and the Chase–Goldsmith model developed in this fashion and their application to adhesive material characterization are presented. The use of empirical relations for the description of creep behavior is discussed. Prediction of shear behavior based on bulk tensile data is demonstrated. It is suggested that characterization of adhesive behavior in the bonded form should include the application of stress analysis, fracture mechanics, polymer chemistry and surface analysis techniques. In testing bonded samples the use of thick adherend symmetric single lap geometry or napkin ring test geometry is advised and it is suggested that the specimens should be prepared with the same surface preparation and cure techniques.
Skip Nav Destination
Article navigation
October 1987
Review Articles
Constitutive Behavior and Testing of Structural Adhesives
Erol Sancaktar
Erol Sancaktar
Department of Mechanical and Industrial Engineering, Clarkson University, Potsdam NY 13676
Search for other works by this author on:
Erol Sancaktar
Department of Mechanical and Industrial Engineering, Clarkson University, Potsdam NY 13676
Appl. Mech. Rev. Oct 1987, 40(10): 1393-1402 (10 pages)
Published Online: October 1, 1987
Article history
Online:
June 3, 2009
Citation
Sancaktar, E. (October 1, 1987). "Constitutive Behavior and Testing of Structural Adhesives." ASME. Appl. Mech. Rev. October 1987; 40(10): 1393–1402. https://doi.org/10.1115/1.3149541
Download citation file:
Get Email Alerts
Cited By
Related Articles
Development of the Damage State Variable for a Unified Creep Plasticity Damage Constitutive Model of the 95.5Sn–3.9Ag–0.6Cu Lead-Free Solder
J. Electron. Packag (March,2008)
Nonlinear Visco-Poroelasticity of Gels With Different Rheological Parts
J. Appl. Mech (July,2020)
Simple Shear Testing of Parallel-Fibered Planar Soft Tissues
J Biomech Eng (April,2001)
Viscoelastic–Viscoplastic Cyclic Deformation of Polycarbonate Polymer: Experiment and Constitutive Model
J. Appl. Mech (April,2016)
Related Proceedings Papers
Related Chapters
Analysis of Components: Strain- and Deformation-Controlled Limits
Design & Analysis of ASME Boiler and Pressure Vessel Components in the Creep Range
Microstructure Evolution and Physics-Based Modeling
Ultrasonic Welding of Lithium-Ion Batteries
Analysis of Components Strain and Deformation-Controlled Limits
Analysis of ASME Boiler, Pressure Vessel, and Nuclear Components in the Creep Range