The trapezoidal finite element in absolute coordinates for dynamic modeling of automotive tire and air spring bellows. Part II: verification

• Autorzy: Pogorelov Dmitry , Rodikov Alexander

Identyfikatory

DOI

10.21307/tp-2021-037

• Języki publikacji: EN

Abstrakty

EN

The second part of the paper includes numerical tests verifying equations of motion of flexible bodies in absolute coordinates with rectangle and isosceles trapezoid finite elements. The equations are formulated in the first part of the paper. The verification is based on three types of problems: calculation of natural frequencies and modes, evaluation of buckling, and computation of large static and dynamic deflections of flexible bodies. Tests show good agreement with the theoretical results and the results obtained by other authors.

Słowa kluczowe

EN

absolute nodal coordinates; dynamic tire; model; finite elements

PL

bezwzględne współrzędne węzłowe; opona dynamiczna; model; elementy skończone

• Wydawca: Wydawnictwo Politechniki Śląskiej
• Czasopismo: Transport Problems
• Rocznik: 2021
• Tom: T. 16, z. 3
• Strony: 5--16
• Opis fizyczny: Bibliogr. 8 poz.

Twórcy

autor

Pogorelov Dmitry

• Bryansk State Technical University, Laboratory of Computational Mechanics, bulv. 50 let Oktyabrya 7, Bryansk, 241035, Russia

autor

Rodikov Alexander

• Bryansk State Technical University, Laboratory of Computational Mechanics, bulv. 50 let Oktyabrya 7, Bryansk, 241035, Russia

Bibliografia

• 1. Pogorelov, D.Y. & Rodikov, A.N. The trapezoidal finite element in absolute coordinates for dynamic modeling of automotive tire and air spring bellows. Part 1: Equations of motion. Transport Problems. 2021. Vol. 16. No. 2. P. P. 141-152.
• 2. Zhou, Z.H. & Wong, K.W. & Xu, X.S. & et al. Natural vibration of circular and annular thin plates by Hamiltonian approach. Journal of Sound and Vibration. 2011. No. 330. P. 1005-1017.
• 3. Bardell, N.S. & Dunsdon, J.M. & Langley, R.S. Free vibration of thin, isotropic, open conical panels. Journal of Sound and Vibration. 1998. No. 217. P. 297-320.
• 4. Gere, J.M. & Timoshenko, S.P. Mechanics of Materials. 3rd Edition. Springer US. 1991. 827 p.
• 5. Levy, S. Square plate with clamped edges under normal pressure producing large deflections. Report No. 740. Washington, D.C.: National Advisory Committee for Aeronautics. 1941. 14 p.
• 6. Dumir, P.C. & Nath, Y. & Gandhi, M.L. Non-linear axisymmetric static analysis of orthotropic thin annular plates. International Journal of Non-Linear Mechanics. 1984. Vol. 19(3). P. 255-272.
• 7. Yoo, W.S. & Lee, J.H. & Park S.J. & et al. Large deflection analysis of a thin plate: Computer Simulations and Experiments. Multibody System Dynamics. 2004. Vol. 11. P. 185-208.
• 8. Биргер, И.А & Пановко, Я.Г. Прочность, устойчивость, колебания. Справочник в трех томах. Том 3. Москва: Машиностроение. 1968.