Modification and evaluation of a FRF-based model updating method for identification of viscoelastic constitutive models for a nonlinear polyurethane adhesive in a bonded joint

• Published in: International journal of adhesion and adhesives Vol. 74; pp. 181 - 193
• Main Authors: Najib, Mehdi F., Nobari, Ali S., Nikbin, Kamran
• Format: Journal Article
• Language: English
• Published: Kidlington Elsevier Ltd 01.04.2017; Elsevier BV
• Subjects: Adhesion tests; Adhesive bonding; Adhesive joints; Adhesives; Bonded joints; Constitutive models; Dynamic mechanical properties; Elastic modulus (D); Finite element method; Frequency response functions; High frequencies; Loss modulus; Mathematical models; Mechanical properties; Mechanical properties of adhesives (D); Model updating; Polyurethane; Polyurethane (A); Polyurethane resins; Random excitation; Sensitivity analysis; Stiffness; Storage modulus; Viscoelasticity; Viscoelasticity (D); ACC; Mechanical properties of adhesives (D); FRAC; IEM; Elastic modulus (D); SCC; OELF; Viscoelasticity (D); EMA; RFM; FRF; SLS; Polyurethane (A); FE
• ISSN: 0143-7496; 1879-0127
• DOI: 10.1016/j.ijadhadh.2017.01.013

In this study, a Frequency Response Function (FRF) -based model updating method, was modified for the purpose of the identification of viscoelastic constitutive models. A steel beam, bonded to a heavy rigid steel block by a layer of Sikaflex-252 polyurethane adhesive, was employed as the test setup. Using the concept of Optimum Equivalent Linear FRF (OELF), accelerance FRFs were measured at different random excitation levels which demonstrated the nonlinear behavior of the adhesive. Using a finite element model, the sensitivity analysis showed that the selected FRFs are more sensitive to the storage and loss moduli of the adhesive near the resonances. Therefore, firstly, both of the storage and loss moduli were identified near each resonance separately and the results have been compared with the results based on Inverse Eigen-sensitivity Method (IEM). In continuation, five viscoelastic constitutive models were utilized and identified to characterize the dynamic mechanical properties of the adhesive at different excitation levels. Applying the identified models, the correlation between the FRFs of the FE models and the experimental ones were tested. The results show that amongst the identified models, The Standard Linear Solid (SLS) model in parallel with a viscous or constant structural damper (stiffness proportional) results in better correlation with experiments. Increasing the excitation level, the storage modulus of the adhesive decreases, whereas the loss modulus increases, especially at high frequencies.