NONLINEAR DYNAMIC ANALYSIS OF WIND ACTIONS ON A CABLE-STAYED GLASS FAÇADE SYSTEM

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Oleg Goryachevsky
Alexander Belostotsky

Abstract

This paper presents the results of a nonlinear dynamic analysis of wind actions on a cable-stayed glass façade. The wind impact was determined by a transient eddy-resolving numerical simulation using a hybrid RANS-LES model SBES. The revealed dynamic response of the façade system confirms the relevance of dynamic calculations compared to simplified static approaches.

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How to Cite
Goryachevsky, O., & Belostotsky, A. (2024). NONLINEAR DYNAMIC ANALYSIS OF WIND ACTIONS ON A CABLE-STAYED GLASS FAÇADE SYSTEM. International Journal for Computational Civil and Structural Engineering, 20(3), 56-68. https://doi.org/10.22337/2587-9618-2024-20-3-56-68
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References

Blocken B. 50 years of computational wind engineering: past, present and future // J. Wind Eng. Wind Eng. Ind. Aerodyn., 2014, V. 129, pp. 69-102.

Belostotsky A.M., Akimov P.A., Afanasyeva I.N.. Vychislitel'naya aerodinamika v zadachah stroitel'stva, Moscow: Izdatel'stvo ASV, 2017, 720 p. (in Russian).

Cochran L., Derickson R. A physical modeller's view of computational wind engineering // J. Wind Eng. Wind Eng. Ind. Aerodyn., 2011, V. 99, Issue 4, pp. 139-153.

Meroney R.N., Derickson R. Virtual reality in wind engineering: the windy world within the computer // J. Wind Eng. Wind Eng., 2014, V. 11, pp. 11-26.

Thordal, M.S., Bennetsen, J.C., Capra, S., Koss, H.H.H.. Towards a standard CFD setup for wind load assessment of high-rise buildings: Part 1 - Benchmark of the CAARC building // Journal of Wind Engineering and Industrial Aerodynamics, 2020, V. 205, P. 104283.

Bruno L. et al. Codes and standards on computational wind engineering for structural design: State of art and recent trends // Wind and Structures, 2023, V., No. 2, pp. 37, No. 2, pp. 133-151.

CNR DT 207 R1/2018 Istruzioni per la valutazione delle azioni e degli effetti del vento sulle costruzioni, 2019. (in Italian)

ASCE/SEI 7-22 Minimum Design Loads and Associated Criteria for Building and other Structures, 2022.

Matematicheskoe (chislennoe)" modelirovanie vetrovyh nagruzok i vozdejstvii. Metodicheskoe posobie. Moscow: FAU "FCS", 2020, 61 p.

STO 02066523-089-1-2024 Numerical modelling of wind and snow actions, 2024

Feng R.-q., Zhang L.-l., Wu Y., Shen S.-z. Dynamic performance of cable net facades // Journal of Constructional Steel Research, 2009, V. 65, № 12. pp. 2217-2227.

Feng R.-q., Ye J.-h., Wu Y., Shen S.-z. Nonlinear response spectra of cable net facades // Soil Dynamics and Earthquake Engineering, 2012, V. 32, pp. 71-86.

Feng R.-q., Ye J.-h., Wu Y., Shen S.-z. Mechanical Behaviour of Glass Panels Supported by Clamping Joints in Cable Net Facades // Journal of Constructional Steel Research, 2012, V. 12, № 1. pp. 15-24.

Amadio C., Bedon C. Elastoplastic dissipative devices for the mitigation of blast resisting cable-supported glazing façades // Engineering Structures, 2012, V. 39, pp. 103-115.

Bedon C., Amadio C. Exploratory numerical analysis of two-way straight cable-net façades subjected to air blast loads // Engineering Structures, 2014, V. 79, pp. 276-289

Yussof, M.M. Cable-net supported glass façade systems. A thesis submitted in partial fulfilment for the degree of Doctor of Philosophy. United Kingdom, University of Surrey, 2015. P. 249

Wang Y. et al. Experimental and numerical studies on the static and the dynamic behaviours of embedded cable support (ECS) glass facade system // Engineering Structures, 2019 V. 178, pp. 521-533.

Xiang Y. et al. Effect of the primary structure on the seismic response of the cable-net façade // Engineering Structures, 2020, V. 220, pp. 110989.

Rizzo F., Bedon C. Performance of cable-supported glass façades under time-depending wind action // Glass Structures & Engineering, 2023, V. 8, No. 1, pp. 81-98.

Zhou Q. et al. Frequency calculation method and wind-induced dynamic response of cable net façades considering the façade stiffness // Structures, 2023, V., V. 55, pp. 718-726.

Menter F.R.. Review of the shear-stress transport turbulence model experience from an industrial perspective // J. Wind Eng. Wind Eng. Ind. Aerodyn., 2009, V. 23, pp. 305-316.

Menter F., Hüppe A., Matyushenko A., Kolmogorov D. An overview of hybrid RANS-LES models developed for industrial CFD // Appl. Sci., 2021, V. 11, p. 2459, 2021.

Nicoud F., Ducros F. Subgrid-scale stress modelling based on the square of the velocity gradient tensor // Flow, Turbulence and Combustion, 1999, V., No. 62, no. 62, №. 3, pp. 183-200.

Menter F.R.. Best Practice: Scale-Resolving Simulations in ANSYS CFD. Version 2.00. Technical paper. ANSYS, 2015, 47 p.

Goryachevsky O.S. Numerical modelling of wind loads on windows // International Journal for Computational Civil and Structural Engineering, 2023, V. 19, No. 3, pp. 19, No. 3, pp. 114-129

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