Асимптотические оценки и оценки сходимости функциональных рядов, описывающих нестационарные колебания оболочек

Autor

  • Леонид Борисович Лерман Институт химии поверхности им. А.А. Чуйко НАН Украины ул. Генерала Наумова, 17, г. Киев, Украина, 1703164, Ukraine

DOI:

https://doi.org/10.15587/2313-8416.2015.39198

Słowa kluczowe:

теория оболочек, нестационарные решения, асимптотические оценки, функциональные ряды

Abstrakt

Установлены свойства решений нестационарных задач для систем дифференциальных уравнений теории оболочек. Решения построены в виде разложений по собственным формам колебаний оболочки. С использованием полученных функциональных рядов найдены асимптотические оценки решений для малых и больших (относительно основного периода собственных колебаний) промежутков времени. Получены общие оценки сходимости функциональных рядов

Biogram autora

Леонид Борисович Лерман, Институт химии поверхности им. А.А. Чуйко НАН Украины ул. Генерала Наумова, 17, г. Киев, Украина, 1703164

Кандидат техн.наук, ст.н.сот.

Отдел № 14: теории наноструктурных систем

Bibliografia

Lerman, L. B. (2000). On solution of problems of dynamics of plates and shells with local structure heterogeneities. Int. Appl. Mechanics, 35 (10), 1014–1020.

Zarutsky, V. A., Lerman, L. B. (1999). The realization of modal superposition method in shell dynamic problems with constructive heterogeneities. Zeszyty naukove politchniki Rrzeszowskie, Nr. 174, Mechanica, z. 52, Problemy dynamiki konstrukcji: Rzeszow, 127–132.

Lerman, L. B. (2001). About some properties of solutions of non-classic Eigen value problem for vibrations’ shell equations. Bulletin of University of Kyiv, Series: Physics & Mathematics, Part 3, 52–56.

Lerman, L. B. (2000). On determination of stationary states for systems of thin-walled elements at propagation of harmonic disturbances. Acoustic bulletin, 3 (1), 61–72.

Lerman, L. B. (2000). On solution of problems of dynamics of thin-walled elements of construction with inhomogeneous dynamics boundary conditions. Int. Appl. Mechanics, 36 (8), 97–103.

Gus’, A. N. (Ed.) (1980). Methods of shell design. In five volumes. Kyiv: Nauk. Dumka.

Bazhenov, V. A., Dacshenko, L. V., Kolomiez, L. V. (2005). Numerical method in mechanics. Odessa: Standard, 563.

Slepyan, L. I. (1972). Nonsteady elastic waves. Lviv: Shipbuilding, 376.

Gylin, P. A. (2006). Applied Mechanics rudiments of shell theory. Saint-Petersburg: Leningrad Polytechnic, 166.

Altenbach, H., Veremeyev, V. A. (2001). On the shell theory on nanoscale with surface stresses. International Journal of Engineering Science, 49 (12), 1294–1301. doi: 10.1016/j.ijengsci.2011.03.011

Ergin, A., Ugurlu, B. (2009). Linear vibration analysis of cantilever plates partially submerged in fluid. Journal of Fluids and Structures, 17 (7), 927–939. doi: 10.1016/s0889-9746(03)00050-1

Moffal, S., He, L. (2005). On decoupled and fully-coupled methods for lade curved cylindrical plates with variable thickness. Journal of Fluids and Structures, 20, 217–234. doi: 10.1016/j.jfluidstructs.2004.10.012

Zabegaev, A. I. (2002). Dynamical model of composite shell construction for calculation loads in conditions of intensive shearing actions. First Utkin reading. Math. All-Russian scientific and technical conference Saint-Petersburg, 2, 138–140.

Ivanco, T. G., Keller, D. F. (2012). Investigations of ground-wind loads for launch vehicles. Journal of Spacecraft and Rockets, 49 (4), 574–585. doi: 10.2514/1.59457

Alijant, F., Amabili, M. (2014). Non-linear vibrations of shells: A literature review from 2003 to 2013. International Journal of Non-Linear Mechanics, 58 (2064), 233–257. doi: 10.1016/j.ijnonlinmec.2013.09.012

Qatu, M. S., Sullivan, R. W., Wang, W. (2010). Recent research advances of the dynamic analysis of composite shells: 2000-2009. Composite Structure, 93 (1), 14–31. doi: 10.1016/j.compstruct.2010.05.014

Abel, J. F., Cooke, J. R. (Eds.) (2008). Proceeding of the 6th International Conference on Computation of Shell and Spatial Structures IASS-IACM 2008: Spanning Nano to Mega. Cornell University, Ithaca, NY, USA.

Naimark, M. A. (1969). Linear differential operators. Moscow: Nauka, 528.

Berezansky, Yu. M. (1965). Expansion by eigenfunctions of self-adjoint operators. Kyiv: Nauk. Dumka, 779.

Levitan, B. M., Sargsyan, I. S. (1970). Introduction in spectral theory (self-adjoint ordinary differential operators). Moscow: Nauka, 671.

##submission.downloads##

Opublikowane

2015-03-24

Numer

Tom 3 Nr 2 (8) (2015)

Dział

Technical Sciences

Licencja

Copyright (c) 2015 Леонид Борисович Лерман

Creative Commons License

Utwór dostępny jest na licencji Creative Commons Uznanie autorstwa 4.0 Międzynarodowe.

Our journal abides by the Creative Commons CC BY copyright rights and permissions for open access journals.

Authors, who are published in this journal, agree to the following conditions:

1. The authors reserve the right to authorship of the work and pass the first publication right of this work to the journal under the terms of a Creative Commons CC BY, which allows others to freely distribute the published research with the obligatory reference to the authors of the original work and the first publication of the work in this journal.

 2. The authors have the right to conclude separate supplement agreements that relate to non-exclusive work distribution in the form in which it has been published by the journal (for example, to upload the work to the online storage of the journal or publish it as part of a monograph), provided that the reference to the first publication of the work in this journal is included.