Мақаланы E-mail арқылы жіберу 
Formulas for Fundamental Natural Frequency of Plane Periodic Truss
- Авторлар: Kirsanov M.N.1
-
Мекемелер:
- National Research University “MPEI”
- Шығарылым: Том 19, № 6 (2023)
- Беттер: 551-559
- Бөлім: Analysis and design of building structures
- URL: https://journals.rcsi.science/1815-5235/article/view/325819
- DOI: https://doi.org/10.22363/1815-5235-2023-19-6-551-559
- EDN: https://elibrary.ru/GIHHVG
- ID: 325819
Дәйексөз келтіру
Толық мәтін
Аннотация
This study considers a plane statically determinate truss with double lattice structure and without a lower chord. Well-known versions of this design are Fink and Bollman trusses. Two methods are used to derive the analytical relationship of the lower limit of the fundamental frequency with the number of panels in the periodic structure. It is assumed that mass of the truss is concentrated at its joints (nodes). The nodes vibrate vertically, and the number of degrees of freedom coincides with the number of nodes. The stiffness analysis of the truss is performed using the Maxwell - Mohr method. The forces in the elastic elements and the reactions of the roller and pin supports are calculated by the method of joints depending on the size of the truss and its order of periodicity. The system of linear equations is solved using the inverse matrix method. The Dunkerley method of partial frequencies is used to calculate the lower limit of the fundamental frequency. For a series of solutions obtained for trusses with different number of panels, the common term in the sequence of solution formulas is found by induction using Maple software. The solution coefficients have polynomial form in the number of panels of order not higher than the fifth. The solution is compared with an approximate version of the Dunkerley method, in which the sum of the terms corresponding to partial frequencies is calculated using the mean value theorem. The closeness of the frequency obtained by the two analytical methods to the numerical frequency spectrum solution is shown by particular examples. An approximate version of the Dunkerley method has a simpler form and an accuracy comparable to the original Dunkerley method.
Авторлар туралы
Mikhail Kirsanov
National Research University “MPEI”
Хат алмасуға жауапты Автор.
Email: c216@ya.ru
ORCID iD: 0000-0002-8588-3871
Doctor of Physical and Mathematical Sciences, Professor of the Department of Robotics, Mechatronics, Dynamics and Strength of Machines
Moscow, Russian FederationӘдебиет тізімі
- Kobielak S., Zamiar Z. Oval concrete domes // Archives of Civil and Mechanical Engineering. 2017. Vol. 17. No. 3. P. 486–501. https://doi.org/10.1016/J.ACME.2016.11.009
- Rezaiee-Pajand M., Rajabzadeh-Safaei N. Exact post-buckling analysis of planar and space trusses // Engineering Structures. 2020. Vol. 223. https://doi.org/10.1016/J.ENGSTRUCT.2020.111146
- Macareno L.M., Agirrebeitia J., Angulo C., Avilés R. FEM Subsystem Replacement Techniques for Strength Problems in Variable Geometry Trusses // Finite Elements in Analysis and Design. 2008. Vol. 44. P. 346–357. https://doi.org/10.1016/j.finel.2007.12.003
- Белянкин Н.А., Бойко А.Ю. Формулы для прогиба балочной фермы с произвольным числом панелей при равномерном загружении // Строительная механика и конструкции. 2019. № 1 (20). С. 21–29. EDN: YZOZGH
- Ткачук Г.Н. Формула зависимости прогиба несимметрично нагруженной плоской фермы с усиленными раскосами от числа панелей // Строительная механика и конструкции. 2019. № 2 (21). С. 32–39. EDN: JKKMFY
- Бойко А.Ю., Ткачук Г.Н. Вывод формул зависимости прогиба плоской шарнирно-стержневой рамы от числа панелей в системе Maple // Строительная механика и конструкции. 2019. № 4 (23). С. 15–25. EDN: ZJDBGW
- Кирсанов М.Н. Напряженное состояние и деформации прямоугольного пространственного стержневого покрытия // Научный вестник Воронежского государственного архитектурно-строительного университета. Строительство и архитектура. 2016. № 1 (41). С. 93–100. EDN: VNXUON
- Бука-Вайваде К., Кирсанов М.Н., Сердюк Д.О. Calculation of deformations of a cantilever-frame planar truss model with an arbitrary number of panels // Вестник МГСУ. 2020. Т. 15. Вып. 4. С. 510–517. https://doi.org/10.22227/1997-0935.2020.4.510-517
- Кирсанов М.Н. Оценка прогиба и устойчивости пространственной балочной фермы // Строительная механика и расчет сооружений. 2016. № 5 (268). С. 19–22. EDN: WWUGZJ
- Ларичев С.А. Индуктивный анализ влияния строительного подъема на жесткость пространственной балочной фермы // Trends in Applied Mechanics and Mechatronics. М.: Инфра-М, 2015. Т. 1. С. 4–8. EDN: AZKRYX
- Hutchinson R.G., Fleck N.A. Microarchitectured cellular solids — the hunt for statically determinate periodic trusses // ZAMM — Journal of Applied Mathematics and Mechanics. 2005. Vol. 85. Issue 9. P. 607–617. https://doi.org/10.1002/zamm.200410208
- Hutchinson R.G., Fleck N.A. The structural performance of the periodic truss // Journal of the Mechanics and Physics of Solids. 2006. Vol. 54. №. 4. P. 756–782. https://doi.org/10.1016/j.jmps.2005.10.008
- Zok F.W., Latture R.M., Begley M.R. Periodic trus s structures // Journal of the Mechanics and Physics of Solids. 2016. Vol. 96. P. 184–203. https://doi.org/10.1016/j.jmps.2016.07.007
- Kaveh A., Rahami H., Shojaei I. Swift Analysis of Civil Engineering Structures Using Graph Theory Methods. 2020. Vol. 290. https://doi.org/10.1007/978-3-030-45549-1
- Kaveh A., Hosseini S.M., Zaerreza A. Size, Layout, and Topology Optimization of Skeletal Structures Using Plasma Generation Optimization // Iranian Journal of Science and Technology. Transactions of Civil Engineering. 2020. Vol. 45. No. 2. P. 513–543. https://doi.org/10.1007/S40996-020-00527-1
- Goloskokov D.P., Matrosov A.V. A Superposition Method in the Analysis of an Isotropic Rectangle // Applied Mathematical Sciences. 2016. Vol. 10. No. 54. P. 2647–2660. https://doi.org/10.12988/ams.2016.67211
- Goloskokov D.P., Matrosov A.V. Approximate analytical solutions in the analysis of thin elastic plates. AIP Conference Proceedings. 2018. Vol. 1959. Issue 1. https://doi.org/10.1063/1.5034687
- Kirsanov M.N. Trussed Frames and Arches: Schemes and Formulas. Cambridge Scholars Publ., 2020.186 p. ISBN: 978-1-5275-5976-9
- Kirsanov M.N. Planar Trusses: Schemes and Formulas. Cambridge Scholars Publ., 2019. 206 p. ISBN: 978-1-52753531-2
- Щиголь Е.Д. Формула для нижней оценки собственных колебаний плоской регулярной балочной фермы с прямолинейным верхним поясом // Строительная механика и конструкции. 2023. № 2 (37). С. 46–53. https://doi.org/10.36622/VSTU.2023.37.2.005.
- Манукало А.С. Анализ значения первой частоты собственных колебаний плоской шпренгельной фермы // Строительная механика и конструкции. 2023. № 2 (37). С. 54–60. https://doi.org/10.36622/VSTU.2023.37.2.006
- Kirsanov M. Simplified Dunkerley method for estimating the first oscillation frequency of a regular truss // Construction of Unique Buildings and Structures. 2023. Vol. 108. https://doi.org/10.4123/CUBS.108.1
- Скулова П.А. Оценка частоты собственных колебаний фермы Больмана // Механизация и автоматизация строительства: сборник статей. Самарский государственный технический университет. Самара, 2020. С. 102–107. EDN: PJJVTX
- Петриченко Е.А. Нижняя граница частоты собственных колебаний фермы Финка // Строительная механика и конструкции. 2020. № 3 (26). C. 21–29. EDN: PINHFN
- Rutenberg A. A Lower Bound for Dunkerley’s Formula in Continuous Elastic Systems // Journal of Sound and Vibration, Academic Press. 1976. Vol. 45. P. 249–252. https://doi.org/10.1016/0022-460X(76)90599-X
- Low K.H. A Modified Dunkerley Formula for Eigenfrequencies of Beams Carrying Concentrated Masses // International Journal of Mechanical Sciences, Pergamon. 2000. Vol. 42. P. 1287–1305. https://doi.org/10.1016/S0020-7403(99)00049-1
Қосымша файлдар
