Vibration Response of Tubular Joints Using a Simplified Mass-Spring Model

  • Shaalan A. Alqarni 
  • Khalid H. Almitani 
  • Ramzi Othman 


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Submitted Nov 8, 2019
Published Dec 6, 2019
10.24018/ejeng.2019.4.12.1628

Abstract viewed = 377 times

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Using adhesives for joining tubular structures has been widely used to replace the traditional joining methods of welding, brazing, soldering, etc. The unique features associated with adhesives include low manufacturing cost, long components’ life, and lightweight. The goal of this study is to investigate the vibration response of the tubular joints when they are subjected to a harmonic axial load considering that the shear stress is linear through the thickness. A simplified mass-spring model is applied to study the response of the problem analytically. Finite element method (FEM) using ANSYS is then availed to validate and compare results obtained in the analytical approach. Additionally, some parameters such as overlap length and adherent material will be changed to examine their influence on the frequency response. Results and findings achieved analytically and numerically showed that the natural frequencies increase as the adherent wave velocity increases, whereas they decrease as the overlap length increases.

Keywords: Adherent Properties Analytical Solution Natural Frequency Tubular Joint

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References

  1. E. Selahi, Elasticity solution of adhesive tubular joints in laminated composites with axial symmetry, Archive of Mechanical Engineering, (2018).
     Google Scholar
  2. A. Carpinteri, J. Boaretto, G. Fortese, F. Giordani, I. Iturrioz, C. Ronchei, D. Scorza, S. Vantadori, Fatigue life estimation of fillet-welded tubular T-joints subjected to multiaxial loading, International Journal of Fatigue, (2017) 263-270.
     Google Scholar
  3. C. Qiu, C. Ding, X. He, L. Zhang, Y. Bai, Axial performance of steel splice connection for tubular FRP column members, Composite Structures, (2018) 498-509.
     Google Scholar
  4. N. Arnaud, R. Créac'Hcadec, J. Cognard, A tension/compression–torsion test suited to analyze the mechanical behaviour of adhesives under non-proportional loadings, International Journal of Adhesion and Adhesives, (2014) 3-14.
     Google Scholar
  5. H. Li, S. Tu, Y. Liu, X. Lu, X. Zhu, Mechanical Properties of L-joint with composite sandwich structure, Composite Structures, (2019).
     Google Scholar
  6. O, Volkersen, "Die Nietkraftverteilung in zugbeanspruchten Nietverbindungenmit konstanten Laschenquerscnitten", Luftfahrtforschung, vol. 20, pp.41-47, 1938.
     Google Scholar
  7. S. Kumar, M. Khan, An elastic solution for adhesive stresses in multi-material cylindrical joints, International Journal of Adhesion and Adhesives (2016) 142-152. -123.
     Google Scholar
  8. N. Stein, H. Mardani, W. Becker, An efficient analysis model for functionally graded adhesive single lap joints, International Journal of Adhesion and Adhesives, (2016) 117-125.
     Google Scholar
  9. A. Abouel-Kasem, I. M. Hassab-Allah, M. M. Nemat-Alla, Analysis and Design of Viscoelastic Adhesively Bonded Tubular Joint, Journal of Engineering and Applied Sciences, (2014) 217-219.
     Google Scholar
  10. S. V. Nimje, S. K. Panigrahi, Stress and Failure Analyses of Functionally Graded Adhesively Bonded Joints of Laminated FRP Composite Plates and Tubes: A Critical Progress in Adhesion and Adhesives, (2018) 155-184.
     Google Scholar