Identyfikatory
Warianty tytułu
Modelowanie i analiza stanu naprężenie-odkształcenie systemów robotycznych
Języki publikacji
Abstrakty
The paper considers the methodology for modeling and analyzing the performance of a robotic system: multi-stage semi-natural simulation stand designed to simulate the flight characteristics of guidance systems in ground conditions. The results of the calculation showed that the use of a composite material gives advantages over the traditionally used materials for the manufacture of such stands: magnesium alloys, due to the high specific strength of the composite material.
W artykule rozważono metodykę modelowania i analizy działania systemu robotycznego: wieloetapowe półnaturalne stanowisko symulacyjne przeznaczone do symulacji charakterystyk lotu systemów naprowadzania w warunkach naziemnych. Wyniki obliczeń wykazały, że zastosowanie materiału kompozytowego daje przewagę nad tradycyjnie stosowanymi materiałami do produkcji takich stojaków: stopami magnezu, ze względu na wysoką wytrzymałość właściwą materiału kompozytowego.
Wydawca
Czasopismo
Rocznik
Tom
Strony
66--69
Opis fizyczny
Bibliogr. 19 poz., rys.
Twórcy
autor
- Moscow Aviation Institute (National Research University), Volokolamskoe Highway, 4, Moscow, Russia
Bibliografia
- [1] Obraztsov I.F., Volmir A.S., Khayrnasov K.Z. Toroidal shells: delayed catastrophes at dynamic loading. Reports of the USSR Academy of Sciences, 266 (1982), No. 6, 1344-1346.
- [2] Bakulin V.N., Obraztsov I.F., Potopakhin V.A. Dynamical problems of the nonlinear theory of multilayer shells The action of intense thermal power loads, concentrated energy flows. Moscow: Nauka (1988).
- [3] Bakulin V.N., Khairnasov K.Z. Oscillations of layered prestressed cylindrical shells. Proceedings of the All-Union Scientific and Technical Seminar “Application of polymer composite materials in mechanical engineering. Voroshilovograd”, (1987), 36-40.
- [4] Khayrnasov K.Z. The methodology of static and dynamic analysis and optimization of layout schemes of multi-stage dynamic stands for semi-natural modeling. Proceedings of the International Scientific Conference “Architecture of shells and strength analysis of thin-walled building and engineering structures of complex form”, 1 (2001), 28-35.
- [5] Khayrnasov K.Z. A methodology for optimizing layout schemes of multi-stage dynamic stands for semi-natural modeling. Bulletin of the Peoples' Friendship University of Russia. Series: Engineering Research, 1 (2002), 37-41.
- [6] Khairnasov K.Z. Development of a methodology for the design, calculation and analysis of multi-stage dynamic stands for semi-natural modeling from composite materials. Materials of the International Conference CAD / CAM / PDM – 2002 Systems of design, technological preparation of production and management of the stages of the life cycle of an industrial product, Moscow. 1, (2002), 383-390.
- [7] Aleksandrov A.Ya., Kurshin L.M. Three-layer plates and shells Strength, stability, vibrations. Moscow: Mechanical Engineering (1968).
- [8] Vasiliev V.V., Protasov V.D., Bolotin V.V. Composite materials Moscow: Mechanical engineering (1990).
- [9] Obraztsov I.F., Vasiliev V.V., Bunakov V.A. Optimum reinforcement for composite shells Moscow: Mechanical engineering 1977.
- [10] Bolotin V.V., Novichkov Yu.P. Mechanics of multilayer structures. Moscow: Mechanical engineering (1980).
- [11] Kamanyu P., Lambert L. Methodology for designing mechanically bonded compounds in layered composite materials. Composite Science Technology, 66 (2006), 3004- 3020.
- [12] Roos R., Kress G., Ermanni P. A post-processing method for interlaminar normal stresses in doubly curved laminates. Composite Structures, 81 (2007), 463-470.
- [13] Zienkiewicz O.C., Taylor R.L., Zhu J.Z. The finite element method: its basis and foundation. Oxford: Butterworth- Heinemann (2013).
- [14] Moaveni S. Theory of finite element analysis and application with ANSYS. London: Pearson Education (2015).
- [15] Kutromanos I. Applied fundamentals of finite element analysis. Linear finite element analysis. New York: John Wiley & Sons (2018).
- [16] Bate K.J. Finite Element Procedures. New York: Pearson Education (2006).
- [17] Jones R.M. The mechanics of composite materials. London: Taylor and Francis (2014).
- [18] Reddy J.N. The Mechanics of Multilayer Composite Plates and Shells: Theory and Analysis, Second Edition. London: Taylor & Francis (2003).
- [19] Grover N., Singh B.N., Maiti D.K. Analytical and finite element modeling of multilayer composite and three-layer plates: Evaluation of a new theory of shear deformation for a free vibration response. International Journal of Mechanical Sciences, 67 (2013), 89-99.
Uwagi
Opracowanie rekordu ze środków MNiSW, umowa Nr 461252 w ramach programu "Społeczna odpowiedzialność nauki" - moduł: Popularyzacja nauki i promocja sportu (2021).
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-1b17e742-c383-4f11-812b-5b68d6ce07de