Розрахунки сталевих баштових споруд на витривалість з врахуванням впливу вітрового вихрового збудження

Заголовок (англійською): 
Steel tower structures fatigue analysis taking into account the influence of wind vortex shedding
Автор(и): 
Нужний В.В.
Автор(и) (англ): 
Nuzhnyj V.V.
Ключові слова (укр): 
вихрове збудження, баштові споруди, витривалість, вітрове навантаження, власна частота, форма коливань
Ключові слова (англ): 
vortex shedding, tower structures, fatigue, wind load, natural frequency, oscillation mode
Анотація (укр): 
Робота присвячена питанням впливу вихрового збудження на сталеві баштові споруди суцільного перерізу, що широко застосовуються в сучасній інфраструктурі. Визначений характер впливу вихрового збудження на споруди, визначена усереднена кількість коливальних циклів на рік та розроблені рекомендації щодо розрахунку споруд на витривалість.
Анотація (англ): 
The work is devoted to the issues of the influence of vortex shedding on steel tower structures of solid section, which are widely used in modern infrastructure. The nature of the influence of vortex excitation on structures was determined, the average number of oscillation cycles per year was determined, and recommendations were developed for calculating the fatigue of structures.
Публікатор: 
Київський національний університет будівництва і архітектури
Назва журналу, номер, рік випуску (укр): 
Опір матеріалів і теорія споруд, 2024, номер 113
Назва журналу, номер, рік випуску (англ): 
Strength of Materials and Theory of Structures, 2024, number 113
Мова статті: 
Українська
Формат документа: 
application/pdf
Документ: 
29.pdf
Дата публікації: 
26 December 2024
Номер збірника: 
113
Університет автора: 
Київський національний університет будівництва і архітектури
Литература: 
 
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  2. Simiu E., Scanlan R.H. Wind Effects on Structures: Fundamentals and Applications to Design. New York: John Wiley, 1996, 704 p.
  3. Giosan, I. and Eng, P. (2007) Vortex Shedding Induced Loads on Free Standing Structures, Structural Vortex Shedding Response Estimation Methodology and Finite Element Estimation. https://citeseerx.ist.psu.edu/viewdoc/summary?doi=10.1.1.582.3179
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  20. Архів погоди https://meteopost.com/
  
References: 
 
  1. Davenport, A. G. The Application of Statistical Concepts to the Wind Loading of  Structures. Proceedings of the Institution of Civil Engineers, 1961.  –Vol.19 – p.449-472.
  2. Simiu E., Scanlan R.H. Wind Effects on Structures: Fundamentals  and Applications to Design. New York: John Wiley, 1996, 704 p.
  3. Giosan, I. and Eng, P. (2007) Vortex Shedding Induced Loads on Free Standing Structures, Structural Vortex Shedding Response Estimation Methodology and Finite Element Estimation. https://citeseerx.ist.psu.edu/viewdoc/summary?doi=10.1.1.582.3179
  4. Scruton, C.: An Introduction to Wind Effects on Structures – Oxford University Press, Oxford, UK, 1981
  5. Galemann, T., Ruscheweyh, H.: Untersuchung winderregter Schwingungen an Stahlschornsteinen. Forschungsbericht Projekt 163 - Lehrstuhl für Stahlbau, RWTH Aachen, 1992.
  6. Holmes, J.D.: Response of cylindrical structures to vortex shedding in the natural wind - 13th Australian Fluid Mechanics Conference Monash University, Melbourne, Australia, 13-18 December 1998.
  7. Verboom, V.K., van Koten, H.: Vortex excitation: Three design rules tested on 13 industrial chimneys - Journal of Wind Engineering and Industrial Aerodynamics, 98 (2010), pp. 145-154.
  8. Piccardo, G., Solari, G. – Closed Form Prediction of 3D Wind-excited response of slender structures. Journal of Wind Engineering in Industrial Aerodynamics, 1998; 74-76: 697-708.
  9. Solari, G. – The role of analytical methods for evaluating the wind-induced response of structures, Journal of Wind Engineering in Industrial Aerodynamics, 90, 1453-1477, 2002.
  10. Rukovodstvo po raschetu zdanij y sooruzhenij na deistvije vetra (Guide to calculating buildings and structures for wind exposure.). – M., Strojizdat, 1978 – 216s. (in Russian).
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  12. Priyan Mendis, Shiromal Fernando, John Holmes, Tharaka Gunawardena, Yousef Abu-Zidan, Priyan Dias. Wind induced fatigue analysis of Lotus Tower Mast. Nineteenth Australasian Wind Engineering Society Workshop, April 4-6, 2018, Torquay, Victoria.
  13. Vieira, D., Barros, R.C. Tubular steel lattice telecommunication towers, subjected to wind loading and vortex shedding (2017) COMPDYN 2017 - Proceedings of the 6th International Conference on Computational. Methods in Structural Dynamics and Earthquake Engineering, 2, pp. 3154-3162  https://doi.org/10.1007/978-981-19-2886-4_6
  14. Rakočević, M., Popović, S.: Calculation procedure for determining wind action from vortex-induced vibration with verification of fatigue strength of steel structures, GRAĐEVINAR, 70 (2018) 9, pp. 793-809, https://doi.org/10.14256/JCE.2125.2017
  15. Wang, D., Zhao, Z., Liu, Y., Ma, Y., Liu, H., Chen, M. Study on vortex induced resonance mechanism between tower and blade of large wind turbine  (2023) Taiyangneng Xuebao/Acta Energiae Solaris Sinica, 44 (10), pp. 306-312. http://doi.org/10.19912/j.0254-0096.tynxb.2022-084.
  16. Krishnappa, L., Sander, A., Thoben, K.-D. Aerodynamic Devices to Reduce/Suppress Vortex Induced Vibrations on a Wind Turbine Tower: A Review. (2022) Journal of Physics: Conference Series, 2265 (3), art. No. 032053 https://doi.org/10.1088/1742-6596/2265/3/032053
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  19. Nuzhnyj, V., & Bilyk, S. (2024). Revealing the influence of wind vortex shedding on the stressed-strained state of steel tower structures with solid cross-section. Eastern-European Journal of Enterprise Technologies, 3(1 (129), 69–79. https://doi.org/10.15587/1729-4061.2024.306181
  20. Weather archive https://meteopost.com/