Finite Element Modeling of Stress-Strain State of Manufacturing Site Metal Structure Under Dynamic Load

Purpose: The aim of this work is to calculate the admissible allocation of new technological equipment with reliable metal frame in reinforced-concrete area with cast-in-situ walls and foundation slab on earth foundation.

Methodology/approach: The stress-strain state of structures and earth foundation of the manufacturing site is performed by the finite element method using the verified software package Ing+ 2021 MicroFe and proposed finite element model. Static analysis of loads, dynamic analysis of the vibratory screen, joint analysis of static and dynamic loads.

Research findings: It is found that under new dynamic load from the vibratory screen, FEM is performed with consideration of damping properties of the structural materials and soil as well as dynamic properties of the latter. It is shown that strength/stability and rigidity of metal structures is ensured for the frame at the installation of the vibratory screen.

1. Zolina T.V., Tusnin A.R. Extending of Operation Life of Industrial Building. Vestnik MGSU. 2015; (6): 41–49. (In Russian)

2. Zolina T.V. Examination Procedure for Building Residual Operation Life. Vestnik MGSU. 2014; (11): 98–108. (In Russian)

3. Borovskiy D.S. Strength Analysis of Rod Elements of Steel Structures under Multiparameter Loading. Vestnik grazhdanskikh inzhenerov. 2021; 2 (85): 36–41. (In Russian)

4. Gukova M.I., Iskendirov V.G., Farfel M.I. Design, Manufacturing and Installation Errors Leading to Emergency Condition of Industrial Buildings. Promyshlennoe i grazhdanskoe stroitel'stvo. 2013; (10): 25–28. (In Russian)

5. Eremin K.A., Matveyushkin S.A. Risk analysis of Bearing Structures of Steel Frame Coverings of One-Storey Industrial Buildings. Promyshlennoe i grazhdanskoe stroitel'stvo. 2011; (3): 16–18. (In Russian)

6. Eremin K.A., Matveyushkin S.A. Strength Analysis of Bearing Structures of Steel Frame Coverings of One-Storey Industrial Buildings. Promyshlennoe i grazhdanskoe stroitel'stvo. 2010; (10): 19–21. (In Russian)

7. Shashkin K.G. Stress-Strain State Analysis of Building Foundations with Regard to their Interaction. Rekonstruktsiya gorodov i geotekhnicheskoe stroitel'stvo. 2001; (4): 6. (In Russian)

8. Alekseev S.I., Kamaev V.S. Stiffness Parameters of Buildings in Strength Analysis of Foundations. Vestnik of Tomsk State University of Architecture and Building. 2007; (3): 165–172. (In Russian)

9. Mikhailov V.S., Teplykh A.V. Allowing for Characteristics of Various Design Models in Calculating Mutual Influence of Buildings on pile-Raft Foundation in SCAD Software. In: Proc. 6th Int. Sci. Symp. ‘Relevant Computer Modeling Problems of Structures’. Vladivostok. 2016. Pp. 133–134. (In Russian)

10. Tsytovich N.A. Soil Mechanics. Moscow: Vysshaya shkola, 1983, 288 p. (In Russian)

11. Ishihara K. Soil Behavior in Earthquakes: Saint-Petersburg: NPO “Georeconstruction-Fundament-Project”, 2006. 384 p. (Russian translation)

12. Volgin G.A., Rozhkov A.F., Inzhutov I.S., Goncharov Yu.M. Experimental and Numerical Analysis of Dynamic Parameters of Large-Panel Building. Vestnik of Tomsk State University of Architecture and Building. 2016; (3): 111–120. (In Russian)

13. Khoroshavin E.A. Dynamic Tests of Administrative Building “Krasnoyarskgrazhdanproekt” in Krasnoyarsk. Vestnik MGSU. 2021; 16 (2): 128–143. (In Russian)

14. Kumpyak O.G., Galyautdinov Z.R., Odnokopylov G.I., Pakhmurin O.R. Diagnostics of Loaded Foundations of Gas Compressor Station Without Process Shutdown. Vestnik of Tomsk State University of Architecture and Building. 2017; (1): 114–121. (In Russian)

15. Kopanitsa D.G., Kaparulin S.L., Savchenko V.I., Koshtunkov V.G., Plyaskin A.S. Beating of Spatial Framework of Concentrating Plant Under Periodic Loads. Vestnik of Tomsk State University of Architecture and Building. 2007; (2): 139–143. (In Russian)

16. Plevkov V.S., Sarkisov D.Yu., Baldin S.V. Analysis of Vibrational Process Parameters of LoadBearing Frame of Industrial Building. Teoriya inzhenernykh sooruzhenii. Stroitel'nye konstruktsii. 2017; 72 (4): 47–56. (In Russian)

17. Yushchube S.V., Podshivalov I.I., Larionov A.S. Safety of Building Constructed on Hillside Slope. Vestnik Tomskogo gosudarstvennogo arkhitekturno-stroitel'nogo universiteta – Journal of Construction and Architecture. 2021; 23 (1): 126–139. (In Russian)