Study of the dynamic process in a nonlinear mathematical model of the transverse oscillations of a moving beam under perturbed boundary conditions

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dc.citation.epage49
dc.citation.issue11
dc.citation.journalTitleМатематичне моделювання та комп'ютинг
dc.citation.spage37
dc.citation.volume1
dc.contributor.affiliationНаціональний університет «Львівська політехніка»
dc.contributor.affiliationLviv Polytechnic National University
dc.contributor.authorСліпчук, А. М.
dc.contributor.authorПукач, П. Я.
dc.contributor.authorВовк, М. І.
dc.contributor.authorСлюсарчук, О. З.
dc.contributor.authorSlipchuk, A. M.
dc.contributor.authorPukach, P. Ya.
dc.contributor.authorVovk, M. I.
dc.contributor.authorSlyusarchuk, O. Z.
dc.coverage.placenameЛьвів
dc.coverage.placenameLviv
dc.date.accessioned2025-10-20T07:44:26Z
dc.date.created2024-02-24
dc.date.issued2024-02-24
dc.description.abstractВивчення поперечних коливань систем, що рухаються вздовж своєї осі, є дуже складним, але водночас і дуже важливим завданням. У цій роботі аналізуються математичні моделі нелінійних поперечних коливань балки, що рухається вздовж своєї осі, як для нерезонансного, так і для резонансного випадків. Завдання стає ще складнішим, якщо додатково врахувати спосіб кріплення кінців балки або збурення на її кінцях. Отримані залежності, які можуть бути використані в будівництві, транспорті, промисловості, машинобудуванні та інших галузях техніки, що забезпечують стійкість і безпеку експлуатації таких механічних систем. Отримані математичні моделі для інженерів-конструкторів для визначення амплітудно-частотної характеристики відповідних конструкцій. Ці математичні моделі є ключовими для дослідження динаміки рухомих середовищ. Отримані результати дозволяють враховувати не тільки вплив кінематичних та фізико-механічних параметрів на амплітудно-частотну характеристику середовища, але й спосіб кріплення. Крім того, отримані в роботі кореляції дозволяють вивчати не лише вплив параметрів рухомого середовища на характер змін частоти та амплітуди коливань, але й враховувати рух у точках опори середовища. А саме, ще на етапі проектування трубопроводу для рідини, що тече з певною швидкістю, можна враховувати вплив коливань опор або способу їх кріплення на динаміку коливального процесу. Отримані залежності дозволяють конструкторам з високим рівнем точності враховувати вплив наведених у роботі характеристик та прогнозувати динамічні явища в них. В інженерних розрахунках різних механічних систем отримані залежності можуть бути використані для оптимізації параметрів, щоб уникнути негативних руйнівних явищ під час експлуатації.
dc.description.abstractThe study of transverse oscillations of systems moving along their axis is a very difficult, but at the same time a very important task. Mathematical models of nonlinear transverse oscillations of a beam moving along its axis are analyzed in this paper work, both for non-resonant and resonant cases. The task becomes even more complicated if we additionally take into account the method of fastening the ends of the beam or the perturbation at its ends. We have obtained dependencies that can be used in construction, transport, industry, mechanical engineering and other domains of technology, ensuring the stability and safety of the operation of such mechanical systems. Mathematical models have been obtained for structural engineers to determine the amplitude–frequency response of relevant structures. These mathematical models are key to researching the dynamics of moving media. The obtained results allow considering not only the influence of kinematic and physical-mechanical parameters on the amplitude–amplitude frequency response of the medium, but also the fastening method. In addition, the correlations obtained in the paper make it possible to study not only the influence of the moving medium parameters on the nature of changes in the frequency and amplitude of oscillations, but also to consider the movement at the points of support of the medium. Namely, even at the stage of designing a pipeline for a liquid flowing at a certain speed, it is possible to consider the influence of the oscillation of the supports or their fastening method on the dynamics of the oscillatory process. The resulting dependencies allow designers to consider the influence of the characteristics given in the paper with a high level of accuracy and predict dynamic phenomena in them. In engineering calculations of various mechanical systems, the resulting dependencies can be used to optimize parameters to avoid negative destructive phenomena during operation.
dc.format.extent37-49
dc.format.pages13
dc.identifier.citationStudy of the dynamic process in a nonlinear mathematical model of the transverse oscillations of a moving beam under perturbed boundary conditions / A. M. Slipchuk, P. Ya. Pukach, M. I. Vovk, O. Z. Slyusarchuk // Mathematical Modeling and Computing. — Lviv : Lviv Politechnic Publishing House, 2024. — Vol 1. — No 11. — P. 37–49.
dc.identifier.citationenStudy of the dynamic process in a nonlinear mathematical model of the transverse oscillations of a moving beam under perturbed boundary conditions / A. M. Slipchuk, P. Ya. Pukach, M. I. Vovk, O. Z. Slyusarchuk // Mathematical Modeling and Computing. — Lviv : Lviv Politechnic Publishing House, 2024. — Vol 1. — No 11. — P. 37–49.
dc.identifier.doi10.23939/mmc2024.01.037
dc.identifier.urihttps://ena.lpnu.ua/handle/ntb/113796
dc.language.isoen
dc.publisherВидавництво Львівської політехніки
dc.publisherLviv Politechnic Publishing House
dc.relation.ispartofМатематичне моделювання та комп'ютинг, 11 (1), 2024
dc.relation.ispartofMathematical Modeling and Computing, 11 (1), 2024
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dc.relation.references[27] Slipchuk A., Pukach P., Vovk M. Asymptotic Study of Longitudinal Velocity Influence and Nonlinear Elastic Characteristics of the Oscillating Moving Beam. Mathematics. 11 (2), 322 (2023).
dc.relation.references[28] Raj S. K., Sahoo B., Nayak A. R., Panda L. N. Nonlinear dynamics of traveling beam with longitudinally varying axial tension and variable velocity under parametric and internal resonances. Nonlinear Dynamics. 111 (4), 3113–3147 (2023).
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dc.relation.references[31] Fereidoon A., Kordani N., Rostamiyan Y., Ganji D. D. Analytical solution to determine displacement of nonlinear oscillations with parametric excitation by differential transformation method. Mathematical and Computational Applications. 15 (5), 810–815 (2010).
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dc.relation.referencesen[1] Ogundele A. D., Agboola O. A., Sinha S. C. Mathematical modeling and simulation of nonlinear spacecraft rendezvous and formation flying problems via averaging method. Communications in Nonlinear Science and Numerical Simulation. 95, 105668 (2021).
dc.relation.referencesen[2] Lv H.-W., Li L., Li Y.-H. Non-linearly parametric resonances of an axially moving viscoelastic sandwich beam with time-dependent velocity. Applied Mathematical Modelling. 53, 83–105 (2018).
dc.relation.referencesen[3] Yan W., Shi L., He H., Chen Y. Analytic solution of dynamic characteristics of non-uniform elastically supported beam with arbitrary added masses. Engineering Mechanics. 33 (1), 47–57 (2016).
dc.relation.referencesen[4] Ai Z. Y., Wang X. M., Ye Z., Yang J. J. Dynamic analysis of an infinite beam resting on layered transversely isotropic saturated media subjected to moving harmonic loads. International Journal for Numerical and Analytical Methods in Geomechanics. 47 (10), 1721–1741 (2023).
dc.relation.referencesen[5] Lamarque C.-H., Ture Savadkoohi A. Algebraic techniques and perturbation methods to approach amplitude frequency response curves. International Journal of Non-Linear Mechanics. 144, 104096 (2022).
dc.relation.referencesen[6] A¸sik M. Z., Dural E., Yetmez M., Uzhan T. A mathematical model for the behavior of laminated uniformly curved glass beams. Composites Part B: Engineering. 58, 593–604 (2014).
dc.relation.referencesen[7] Liu M., Zheng L., Zhou P., Xiao H. Stability and dynamics analysis of in-plane parametric vibration of stay cables in a cable-stayed bridge with superlong spans subjected to axial excitation. Journal of Aerospace Engineering. 33 (1), 04019106 (2020).
dc.relation.referencesen[8] Ali S., Hawwa M. A. Dynamic Characteristics of a Small-Size Beam Mounted on an Accelerating Structure. Micromachines. 14 (4), 780 (2023).
dc.relation.referencesen[9] Wong Y., Liu L., Lee B. Frequency and amplitude prediction of limit cycle oscillations of an airfoil containing concentrated structural nonlinearities. 19th AIAA Applied Aerodynamics Conference. 1293 (2001).
dc.relation.referencesen[10] Cheng Y., Wu Y., Guo B.-Z. Absolute boundary stabilization for an axially moving Kirchhoff beam. Automatica. 129, 109667 (2021).
dc.relation.referencesen[11] Wang Y., Ding H., Chen L.-Q. Asymptotic solutions of coupled equations of supercritically axially moving beam. Nonlinear Dynamics. 87, 25–36 (2017).
dc.relation.referencesen[12] Wang Y., Zhu W. Nonlinear transverse vibration of a hyperelastic beam under harmonic axial loading in the subcritical buckling regime. Applied Mathematical Modelling. 94, 597–618 (2021).
dc.relation.referencesen[13] Gusu D. M., Danu M. Existence of solutions of boundary value problem for nonlinear one-dimensional wave equations by fixed point method. Mathematical Problems in Engineering. 2022, 5099060 (2022).
dc.relation.referencesen[14] Erba¸s B., Kaplunov J., Elishakoff I. Asymptotic derivation of a refined equation for an elastic beam resting on a Winkler foundation. Mathematics and Mechanics of Solids. 27 (9), 1638–1648 (2022).
dc.relation.referencesen[15] Sokil B. I., Pukach P. Ya., Sokil M. B., Vovk M. I. Advanced asymptotic approaches and perturbation theory methods in the study of the mathematical model of single-frequency oscillations of a nonlinear elastic body. Mathematical Modeling and Computing. 7 (2), 269–277 (2020).
dc.relation.referencesen[16] Sorokin V. S., Thomsen J. J., Brøns M. Coupled longitudinal and transverse vibrations of tensioned Euler-Bernoulli beams with general linear boundary conditions. Mechanical Systems and Signal Processing. 150, 107244. (2021).
dc.relation.referencesen[17] Ali S. Nonlinear dynamic and stability of a small size moving beam under thermal conditions. Mathematical Methods in the Applied Sciences. 46 (6), 7201–7214 (2023).
dc.relation.referencesen[18] Raj S. K., Sahoo B., Nayak A. R., Panda L. N. Nonlinear Analysis of a Viscoelastic Beam Moving with Variable Axial Tension and Time-Dependent Speed. Iranian Journal of Science and Technology, Transactions of Mechanical Engineering. 1–24 (2023).
dc.relation.referencesen[19] Chen L., Tang Y.-Q., Liu S., Zhou Y., Liu X.-G. Nonlinear phenomena in axially moving beams with speeddependent tension and tension-dependent speed. International Journal of Bifurcation and Chaos. 31 (03), 2150037 (2021).
dc.relation.referencesen[20] Bouquain J., Meheust Y., Davy P. Horizontal pre-asymptotic solute transport in a plane fracture with significant density contrasts. Journal of contaminant hydrology. 120, 184–197 (2011).
dc.relation.referencesen[21] Quyen V. T. B., Tien D. N. Nonlinear Dynamic Analysis of Truss with Initial Member Length Imperfection Subjected to Impulsive Load Using Mixed Finite Element Method. Proceedings of FORM 2021: Construction The Formation of Living Environment. 249–258 (2022).
dc.relation.referencesen[22] Huzyk N., Pukach P. Ya., Sokil B., Sokil M., Vovk M. On the external and internal resonance phenomena of the elastic bodies with the complex oscillations. Mathematical Modeling and Computing. 9 (1), 152–158 (2022).
dc.relation.referencesen[23] Limarchenko O., Nefedov A. Resonant modes of the motion of a cylindrical reservoir on a movable pendulum suspension with a free-surface liquid. Mathematical Modeling and Computing. 5 (2), 178–183 (2018).
dc.relation.referencesen[24] Abel L. A., Walterfang M., Stainer M. J., Bowman E. A., Velakoulis D. Longitudinal assessment of reflexive and volitional saccades in Niemann–Pick Type C disease during treatment with miglustat. Orphanet Journal of Rare Diseases. 10 (1), 160 (2015).
dc.relation.referencesen[25] Sheng G. G., Han Y., Zhang Z., Zhao L. Control of nonlinear vibration of beams subjected to moving loads using tuned mass dampers. Acta Mechanica. 234 (7), 3019–3036 (2023).
dc.relation.referencesen[26] Slipchuk A., Pukach P., Vovk M., Slyusarchuk O. Advancing asymptotic approaches to studying the longitudinal and torsional oscillations of a moving beam. Eastern-European Journal of Enterprise Technologies. 3 (7), 31–39 (2022).
dc.relation.referencesen[27] Slipchuk A., Pukach P., Vovk M. Asymptotic Study of Longitudinal Velocity Influence and Nonlinear Elastic Characteristics of the Oscillating Moving Beam. Mathematics. 11 (2), 322 (2023).
dc.relation.referencesen[28] Raj S. K., Sahoo B., Nayak A. R., Panda L. N. Nonlinear dynamics of traveling beam with longitudinally varying axial tension and variable velocity under parametric and internal resonances. Nonlinear Dynamics. 111 (4), 3113–3147 (2023).
dc.relation.referencesen[29] Wang B. Asymptotic analysis on weakly forced vibration of axially moving viscoelastic beam constituted by standard linear solid model. Applied Mathematics and Mechanics. 33 (6), 817–828 (2012).
dc.relation.referencesen[30] Raj S. K., Sahoo B., Nayak A. R., Panda L. N. Nonlinear Analysis of a Viscoelastic Beam Moving with Variable Axial Tension and Time-Dependent Speed. Iranian Journal of Science and Technology, Transactions of Mechanical Engineering. 1–24 (2023).
dc.relation.referencesen[31] Fereidoon A., Kordani N., Rostamiyan Y., Ganji D. D. Analytical solution to determine displacement of nonlinear oscillations with parametric excitation by differential transformation method. Mathematical and Computational Applications. 15 (5), 810–815 (2010).
dc.relation.referencesen[32] Kauderer H. Nichtlineare Mechanik. Springer-Verlag (2013).
dc.rights.holder© Національний університет “Львівська політехніка”, 2024
dc.subjectпоперечні коливання
dc.subjectматематична модель
dc.subjectграничні умови
dc.subjectнелінійні коливання
dc.subjectасимптотичний метод
dc.subjectпружна балка
dc.subjectрезонанс
dc.subjectспосіб кріплення
dc.subjecttransverse oscillations
dc.subjectmathematical model
dc.subjectboundary conditions
dc.subjectnonlinear oscillations
dc.subjectasymptotic method
dc.subjectelastic beam
dc.subjectresonance
dc.subjectfastening method
dc.titleStudy of the dynamic process in a nonlinear mathematical model of the transverse oscillations of a moving beam under perturbed boundary conditions
dc.title.alternativeДослідження динамічного процесу в нелінійній математичній моделі поперечних коливань рухомої балки за збурених граничних умов
dc.typeArticle

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Mathematical Modeling And Computing. – 2024. – Vol. 11, No. 1