Calculus of Long Rectangle Plate Articulated on Both Long Sides Charged with a Linear Load Uniformly Distributed on a Line Parallel to the Long Borders through the Transfer-Matrix Method

Mihaela SUCIU

doi:10.59573/emsj.8(6).2024.12

Authors

Mihaela SUCIU

DOI:

https://doi.org/10.59573/emsj.8(6).2024.12

Keywords:

long rectangle plate, unit beam, charge density, Dirac’s and Heaviside’s functions and operators, state vector, Transfer-Matrix

Abstract

The Transfer-Matrix Method is very special and interesting for a lot of industrial fields. This paper presents a study for an application of rectangular long plate articulated at the two long borders and charged with an uniform linear load, that act on a line parallel to the long sides. The long rectangular plate is discretized in unit beams, a beam has width equal to the unit, thickness equal to the plate thickness and length equal to the plate width. The study is made for the unit beam in two cases: the first case, in which the load acts in a certain section x₀ and the second case, a particularization of the first case, that is: the concentrated vertical force acts in the middle of the beam opening. All the elements for all state vectors for all the sections of the beam can be calculated and the stresses and the deformations in all sections of the beam too. By extension, the stresses and strains are calculated for the long rectangular plate articulated on both long borders. This work is original and very interesting for a lot of industrial fields.

References

Ahanova, A. S., Yessenbayeva, G. A., & Tursyngaliev, N. K. (2016). On the calculation of plates by the series representation of the deflection function. Bulletin of Karaganda University, Mathematics Series, 82(2), 15-22.

Altenbach, H. (2009). Analysis of homogeneous and non-homogeneous plates. In R. de Borst & T. Sadowski (Eds.), Lecture Notes on Composite Materials. Solid Mechanics And Its Applications (Vol. 154, pp. 1-36). Springer, Dordrecht. https://doi.org/10.1007/978-1-4020-8772-1_1

Bhavikatti, S. S. (2024). Theory of plates and shells. New Age International Limited Publishers, New Delhi, Bangalore, Chennai, Cochin, Guwahati, Hyderabad, Kolkata, Lucknow, Mumbai, ISBN (13): 978-81-224-3492-7. www.newagepublishers.com.

Codrea, L., Tripa, M.-S., Opruta, D., Gyorbiro, R. & Suciu, M. (2023). Transfer-Matrix Method for Calculus of Long Cylinder Tube with Industrial Applications. Mathematics, 11(17), 3756. https://doi.org/10.3390/math11173756.

Cojocariu-Oltean, O., Tripa, M.-S., Baraian, I., Rotaru, D.-I. & Suciu, M. (2024). About Calculus Through the Transfer Matrix Method of a Beam with Intermediate Support with Applications in Dental Restorations. Mathematics, 12(23), 386. https://doi.org/10.3390/math12233861.

Cretu, N., Pop, M.-I. & Andia Prado, H. S. (2022). Some Theoretical and Experimental Extensions Based on the Properties of the Intrinsic Transfer Matrix. Materials, 15(2), 519. https://doi.org/10.3390/ma15020519.

Delyavskyy, M., Sobczak-Piastka, J., Rosinski, K., Buchaniec, D. & Famulyak, Y. (2023). Solution of thin rectangular plates with various boundary conditions. In AIP Conference Proceedings (Vol. 2949, No. 1). AIP Publishing.

Delyavs’kyi, M. V., Zdolbits’ka, N. V., Onyshko, L. I. & Zdolbits’kyi, A. P. (2015). Determination of the stress-strain state in thin orthotropic plates on Winkler’s elastic foundations. Materials Science, 50, 782-791.

Fertis, D., & Lee, C. (1990). Equivalent systems for the analysis of rectangular plates of varying thickness. Developments in theoretical and applied mechanics, 15, 627-637.

Fetea, M. S. (2018). Theoretical and comparative study regarding the mechanical response under the static loading for different rectangular plates. Annals of the University of Oradea, Fascicle: Environmental Protection, XXXI, 141-146.

Gery, P.-M. & Calgaro, J.-A. (1987). Les Matrices-Transfert dans le calcul des structures. Editions Eyrolles, Paris, France.

Grigorenko, Y. M. & Rozhok, L. S. (2002). Stress–strain analysis of rectangular plates with a variable thickness and constant weight. International Applied Mechanics, 38(2), 167-173.

Imrak, C. E. & Gerdemeli, I. (2007). An exact solution for the deflection of a clamped rectangular plate under uniform load. Applied mathematical sciences, 1(43), 2129-2137.

Kuliyev, S. (2003). Stress state of compound polygonal plate. Mechanics Research Communications, 30(6), 519-530.

Kutsenko, A., Kutsenko, O. & Yaremenko, V. V. (2021). On some aspects of implementation of boundary elements method in plate theory. Machinery & Energetic, 12(3), 107-111.

Lu, Z., Tao, D. & Qijian, L. (2021). Buckling of Piles in Layered Soils by Transfer-Matrix Method. International Journal of Structural Stability and Dynamics, 21(8), 2150109. https://doi.org/10.1142/S0219455421501091.

Matrosov, A. V. & Suratov, V. A. (2018). Stress-strain state in the corner points of a clamped plate under uniformly distributed normal load. Materials Physics and Mechanics, 36(1), 124-146.

Meleshko, V.V. & Gomilko, A. M. (1994). On the bending of clamped rectangular plates. Mechanics research communications, 21(1), 19-24.

Moubayed, N., Wahab, A., Bernard, M., El-Khatib, H., Sayegh, A., Alsaleh, F., Moubayed, A., Wahab, M., Bernard, H., El-Khatib, A., Sayegh, F., Alsaleh, Y., Dachouwaly, N. & Chehadeh, N. (2014). Static analysis of an orthotropic plate. Physics Procedia, 55, 367-372. https://doi.org/10.1016/j.phpro.2014.07.053.

Nikoloc Stanojevic, V., Dolicanin, Ć. & Radojkovic, M. (2010). Application of Numerical methods in Solving a Phenomenon of the Theory of thin Plates. Sci. Tech. Rev, 60(1), 61-65.

Niyonyungu, F. & Karangwa, J. (2019). Convergence analysis of finite element approach to classical approach for analysis of plates in bending. Advances in Science and Technology. Research Journal, 13(4), 170-180.

Ohga, M., Shigematsu, T. & Kohigashi, S. (1991). Analysis of folded plate structures by a combined boundary element-transfer matrix method. Computers & structures, 41(4), 739-744.

Orynyak, I. & Danylenko, K. (2024). Method of matched sections as a beam-like approach for plate analysis. Finite Elements in Analysis and Design, 230, 104103.

Papanikolaou, V. K. & Doudoumis, I. N. (2001). Elastic analysis and application tables of rectangular plates with unilateral contact support conditions. Computers & Structures, 79(29-30), 2559-2578.

Revenko, V. (2018). Development of two-dimensional theory of thick plates bending on the basis of general solution of Lamé equations. Scientific Journal of the Ternopil National Technical University, (1), 33-39.

Revenko, V. P. & Revenko, A. V. (2017). Determination of Plane Stress-Strain States of the Plates on the Basis of the Three-Dimensional Theory of Elasticity. Materials Science, 52, 811-818.

Sprintu, I. & Fuiorea, I. (2013). Analytical solutions of the mechanical answer of thin orthotropic plates. Proceedings of the Romanian Academy, Series A, 14(4), 343–350.

Suciu, M. (2023), About an approach by Transfer-Matrix Method (TMM) for mandible body bone calculus. Mathematics, 11(2), 450. https://doi.org/10.3390/math11173756.

Suciu, M. & Tripa, M.-S. (2021). Strength of Materials. UT Press Cluj-Napoca, Romania.

Sun, J.-p. & Li, Q.-n. (2011). Precise Transfer-Matrix Method for elastic-buckling analysis of compression bar. [J] Engineering Mechanics, 28(7), 26-030.

Surianinov, M. & Shyliaiev, O. (2018). Calculation of plate-beam systems by method of boundary elements. International Journal of Engineering and Technology, 7(2), 238-241.

Vijayakumar, K. (2014). Review of a few selected theories of plates in bending. International Scholarly Research Notices, (1), 291478.

Volokh, K. Y. (1994). On the classical theory of plates. Journal of Applied Mathematics and Mechanics, 58(6), 1101-1110.

Warren, C. Y. (1989). ROARC’S-Formulas for Stress & Strain (6-ème Edition). McGraw-Hill Book Company, New York, NY, SUA.

Yessenbayeva, G. A., Yesbayeva, D. N. & Makazhanova, T. K. (2018). On the calculation of the rectangular finite element of the plate. Bul. of the Karaganda Univ. – Mechanics, 2. https://doi.org/10.31489/2018m2/150-156.

Yessenbayeva, G. A., Yesbayeva, D. N. & Syzdykova, N. K. (2019). On the finite element method for calculation of rectangular plates. Bul. of the Karaganda Univ. - Mathematics, 95(3). https://doi.org/10.31489/2019m2/128-135.

Yuhong, B. (2000). Bending of rectangular plate with each edges arbitrary a point supported under a concentrated load. Applied Mathematics and Mechanics, 21, 591-596.

Zveryayev, Y. M. (2003). Analysis of the hypotheses used when constructing the theory of beams and plates. Journal of Applied Mathematics and Mechanics, 67(3), 425-434.