How to cite this paper
Khorasani, R., Kordkheili, S & Parviz, H. (2021). An analytical and experimental study on dampening material effects on the dynamic behavior of free-free aluminum sheets.Engineering Solid Mechanics, 9(2), 111-122.
Refrences
Jones, D. I. (2001). Handbook of viscoelastic vibration damping. John Wiley & Sons.
Nashif, A. D., Jones, D. I., & Henderson, J. P. (1985). Vibration damping. John Wiley & Sons.
Tso-Liang, T., Cho-Chung, L., & Ching-Cho, L. (1996). Optimal design of a dynamic absorber using polymer-laminated steel sheets. Computers & structures, 60(6), 981-988.
Ren, Z., Atalla, N., & Ghinet, S. (2011). Optimization based identification of the dynamic properties of linearly viscoelastic materials using vibrating beam technique. Journal of vibration and acoustics, 133(4).
Lewandowski, R., & Baum, M. (2015). Dynamic characteristics of multilayered beams with viscoelastic layers described by the fractional Zener model. Archive of Applied Mechanics, 85(12), 1793-1814.
Park, S. W. (2001). Analytical modeling of viscoelastic dampers for structural and vibration control. International Journal of Solids and structures, 38(44-45), 8065-8092.
Ovaert, T. C., Kim, B. R., & Wang, J. (2003). Multi-parameter models of the viscoelastic/plastic mechanical properties of coatings via combined nanoindentation and non-linear finite element modeling. Progress in Organic Coatings, 47(3-4), 312-323.
Kurano, S. (2005). Experimental study on effects of elastomer coating on the vibration-damping property of steel and CFRP plates for ship's hull. Nippon Kikai Gakkai Ronbunshu A Hen(Transactions of the Japan Society of Mechanical Engineers Part A)(Japan), 17(6), 982.
Ghayesh, M. H., & Moradian, N. (2011). Nonlinear dynamic response of axially moving, stretched viscoelastic strings. Archive of Applied Mechanics, 81(6), 781-799.
Rossikhin, Y. A., & Shitikova, M. V. (2008). Free damped vibrations of a viscoelastic oscillator based on Rabotnov’s model. Mechanics of Time-Dependent Materials, 12(2), 129-149.
Fan, R., Meng, G., Yang, J., & He, C. (2009). Experimental study of the effect of viscoelastic damping materials on noise and vibration reduction within railway vehicles. Journal of Sound and Vibration, 319(1-2), 58-76.
Kumar, N., & Singh, S. P. (2010). Experimental study on vibration and damping of curved panel treated with constrained viscoelastic layer. Composite structures, 92(2), 233-243.
Saidi, I., Gad, E. F., Wilson, J. L., & Haritos, N. (2011). Development of passive viscoelastic damper to attenuate excessive floor vibrations. Engineering structures, 33(12), 3317-3328.
Zhou, X. Q., Yu, D. Y., Shao, X. Y., Zhang, S. Q., & Wang, S. (2016). Research and applications of viscoelastic vibration damping materials: A review. Composite Structures, 136, 460-480.
Sheng, M., Guo, Z., Qin, Q., & He, Y. (2018). Vibration characteristics of a sandwich plate with viscoelastic periodic cores. Composite Structures, 206, 54-69.
Biswal, D. K., & Mohanty, S. C. (2019). Free vibration study of multilayer sandwich spherical shell panels with viscoelastic core and isotropic/laminated face layers. Composites Part B: Engineering, 159, 72-85.
Claude, B., Duigou, L., Girault, G., & Cadou, J. M. (2019). Study of damped vibrations of a vibroacoustic interior problem with viscoelastic sandwich structure using a High Order Newton solver. Journal of Sound and Vibration, 462, 114947.
Kordkheili, S. H., & Khorasani, R. (2019). On the geometrically nonlinear analysis of sandwich shells with viscoelastic core: A layerwise dynamic finite element formulation. Composite Structures, 230, 111388.
Zhang, Y., Jin, G., Chen, M., Ye, T., Yang, C., & Yin, Y. (2020). Free vibration and damping analysis of porous functionally graded sandwich plates with a viscoelastic core. Composite Structures, 112298.
Rouleau, L., Legay, A., & Deü, J. F. (2018). Interface finite elements for the modelling of constrained viscoelastic layers. Composite Structures, 204, 847-854.
Biswal, D. K., & Mohanty, S. C. (2018). Free vibration and damping characteristics study of doubly curved sandwich shell panels with viscoelastic core and isotropic/laminated constraining layer. European Journal of Mechanics-A/Solids, 72, 424-439.
Zarraga, O., Sarría, I., García-Barruetabeña, J., & Cortés, F. (2020). Homogenised formulation for plates with thick constrained viscoelastic core. Computers & Structures, 229, 106185.
Gupta, A., Reddy, R. S., Panda, S., & Kumar, N. (2020). Damping treatment of beam with unconstrained/constrained 1-3 smart viscoelastic composite layer. Materials Today: Proceedings.
D’Ottavio, M., Krasnobrizha, A., Valot, E., Polit, O., Vescovini, R., & Dozio, L. (2020). Dynamic response of viscoelastic multiple-core sandwich structures. Journal of Sound and Vibration, 491, 115753.
Standard, A. S. T. M. (2010). E756-05. Standard test method for measuring vibration-damping properties of materials.
Fu, Z. F., & He, J. (2001). Modal analysis. Elsevier.
Nashif, A. D., Jones, D. I., & Henderson, J. P. (1985). Vibration damping. John Wiley & Sons.
Tso-Liang, T., Cho-Chung, L., & Ching-Cho, L. (1996). Optimal design of a dynamic absorber using polymer-laminated steel sheets. Computers & structures, 60(6), 981-988.
Ren, Z., Atalla, N., & Ghinet, S. (2011). Optimization based identification of the dynamic properties of linearly viscoelastic materials using vibrating beam technique. Journal of vibration and acoustics, 133(4).
Lewandowski, R., & Baum, M. (2015). Dynamic characteristics of multilayered beams with viscoelastic layers described by the fractional Zener model. Archive of Applied Mechanics, 85(12), 1793-1814.
Park, S. W. (2001). Analytical modeling of viscoelastic dampers for structural and vibration control. International Journal of Solids and structures, 38(44-45), 8065-8092.
Ovaert, T. C., Kim, B. R., & Wang, J. (2003). Multi-parameter models of the viscoelastic/plastic mechanical properties of coatings via combined nanoindentation and non-linear finite element modeling. Progress in Organic Coatings, 47(3-4), 312-323.
Kurano, S. (2005). Experimental study on effects of elastomer coating on the vibration-damping property of steel and CFRP plates for ship's hull. Nippon Kikai Gakkai Ronbunshu A Hen(Transactions of the Japan Society of Mechanical Engineers Part A)(Japan), 17(6), 982.
Ghayesh, M. H., & Moradian, N. (2011). Nonlinear dynamic response of axially moving, stretched viscoelastic strings. Archive of Applied Mechanics, 81(6), 781-799.
Rossikhin, Y. A., & Shitikova, M. V. (2008). Free damped vibrations of a viscoelastic oscillator based on Rabotnov’s model. Mechanics of Time-Dependent Materials, 12(2), 129-149.
Fan, R., Meng, G., Yang, J., & He, C. (2009). Experimental study of the effect of viscoelastic damping materials on noise and vibration reduction within railway vehicles. Journal of Sound and Vibration, 319(1-2), 58-76.
Kumar, N., & Singh, S. P. (2010). Experimental study on vibration and damping of curved panel treated with constrained viscoelastic layer. Composite structures, 92(2), 233-243.
Saidi, I., Gad, E. F., Wilson, J. L., & Haritos, N. (2011). Development of passive viscoelastic damper to attenuate excessive floor vibrations. Engineering structures, 33(12), 3317-3328.
Zhou, X. Q., Yu, D. Y., Shao, X. Y., Zhang, S. Q., & Wang, S. (2016). Research and applications of viscoelastic vibration damping materials: A review. Composite Structures, 136, 460-480.
Sheng, M., Guo, Z., Qin, Q., & He, Y. (2018). Vibration characteristics of a sandwich plate with viscoelastic periodic cores. Composite Structures, 206, 54-69.
Biswal, D. K., & Mohanty, S. C. (2019). Free vibration study of multilayer sandwich spherical shell panels with viscoelastic core and isotropic/laminated face layers. Composites Part B: Engineering, 159, 72-85.
Claude, B., Duigou, L., Girault, G., & Cadou, J. M. (2019). Study of damped vibrations of a vibroacoustic interior problem with viscoelastic sandwich structure using a High Order Newton solver. Journal of Sound and Vibration, 462, 114947.
Kordkheili, S. H., & Khorasani, R. (2019). On the geometrically nonlinear analysis of sandwich shells with viscoelastic core: A layerwise dynamic finite element formulation. Composite Structures, 230, 111388.
Zhang, Y., Jin, G., Chen, M., Ye, T., Yang, C., & Yin, Y. (2020). Free vibration and damping analysis of porous functionally graded sandwich plates with a viscoelastic core. Composite Structures, 112298.
Rouleau, L., Legay, A., & Deü, J. F. (2018). Interface finite elements for the modelling of constrained viscoelastic layers. Composite Structures, 204, 847-854.
Biswal, D. K., & Mohanty, S. C. (2018). Free vibration and damping characteristics study of doubly curved sandwich shell panels with viscoelastic core and isotropic/laminated constraining layer. European Journal of Mechanics-A/Solids, 72, 424-439.
Zarraga, O., Sarría, I., García-Barruetabeña, J., & Cortés, F. (2020). Homogenised formulation for plates with thick constrained viscoelastic core. Computers & Structures, 229, 106185.
Gupta, A., Reddy, R. S., Panda, S., & Kumar, N. (2020). Damping treatment of beam with unconstrained/constrained 1-3 smart viscoelastic composite layer. Materials Today: Proceedings.
D’Ottavio, M., Krasnobrizha, A., Valot, E., Polit, O., Vescovini, R., & Dozio, L. (2020). Dynamic response of viscoelastic multiple-core sandwich structures. Journal of Sound and Vibration, 491, 115753.
Standard, A. S. T. M. (2010). E756-05. Standard test method for measuring vibration-damping properties of materials.
Fu, Z. F., & He, J. (2001). Modal analysis. Elsevier.