Application of the Finite Element Method (FEM) through GFAS Software to the study of a tunnel

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Publicado: 2021-05-30
DOI: https://doi.org/10.53313/gwj41006
Palabras clave:
tunnels; stresses; FEM; GFAS

Referencias

1. Chilleri, J.; He, Y.; Bedrov, D.; Kirby, R.M. Optimal allocation of computational resources based on Gaussian process: Application to molecular dynamics simulations. Comput. Mater. Sci. 2021, 188, 110178.

2. Yu, D.; Liu, X.; Ren, G. Application of the Computer Graphic Design Color Language in the Food Packaging Design. In Frontier Computing; Hung, J.C., Yen, N.Y., Chang, J.-W., Eds.; Springer Singapore: Singapore, 2020; pp. 1677–1682.

3. Hayashi, Y.; Nakajima, Y.; Sugiyama, H. Computational screening of cryoprotective agents for regenerative medical products using quantum chemistry and molecular dynamics simulations. Cryobiology 2021.

4. Vo, D.-V.; Hong, K.H.; Lee, J.; Park, H. Synthesis, in vitro evaluation, and computational simulations studies of 1,2,3-triazole analogues as DPP-4 inhibitors. Bioorg. Med. Chem. 2021, 29, 115861.

5. Weizmann, M.; Amir, O.; Grobman, Y.J. The effect of block geometry on structural behavior of topological interlocking assemblies. Autom. Constr. 2021, 128, 103717.

6. Sun, T.; Qin, L.; Fu, Y.; Liu, C.; Shi, R. Mathematical modeling of cutting layer geometry and cutting force in orthogonal turn-milling. J. Mater. Process. Technol. 2021, 290, 116992.

7. Yatskul, A.; Lemiere, J.-P.; Cointault, F. Influence of the divider head functioning conditions and geometry on the seed's distribution accuracy of the air-seeder. Biosyst. Eng. 2017, 161, 120–134.

8. Cai, Y.; Chen, J.; Wang, N. A Nitsche extended finite element method for the biharmonic interface problem. Comput. Methods Appl. Mech. Eng. 2021, 382, 113880.

9. Guo, L.; Bi, C. Adaptive finite element method for nonmonotone quasi-linear elliptic problems. Comput. Math. with Appl. 2021, 93, 94–105.

10. Ye, X.; Zhang, S. A stabilizer free weak Galerkin finite element method on polytopal mesh: Part II. J. Comput. Appl. Math. 2021, 394, 113525.

11. Wang, L.-F.; Zhou, X.-P. A field-enriched finite element method for simulating the failure process of rocks with different defects. Comput. Struct. 2021, 250, 106539.

12. Courant, R. Variational methods for the solution of problems of equilibrium and vibrations. Lect. notes pure Appl. Math. 1994, 1.

13. Gunawardena, Y.; Aslani, F. Finite element modelling of concrete-filled spiral-welded mild-steel and stainless-steel tubes in flexure. Structures 2021, 32, 792–816.

14. Swoboda, G.; Marence, M.; Mader, I. Finite element modelling of tunnel excavation. Int. J. Eng. Model. 1994, 6, 51–63.

15. Chisena, R.S.; Chen, L.; Shih, A.J. Finite element composite simplification modeling and design of the material extrusion wave infill for thin-walled structures. Int. J. Mech. Sci. 2021, 196, 106276.

16. Obert, L.; Duvall, W.I.; Merrill, R.H. Design of underground openings in competent rock. United States Government Printing Office, 1960.

17. Fawaz, G.; Murcia-Delso, J. Three-dimensional finite element modeling of RC columns subjected to cyclic lateral loading. Eng. Struct. 2021, 239, 112291.

18. Zolfagharian, A.; Durran, L.; Gharaie, S.; Rolfe, B.; Kaynak, A.; Bodaghi, M. 4D printing soft robots guided by machine learning and finite element models. Sensors Actuators A Phys. 2021, 328, 112774.

19. Mango, E.J. Safety Characteristics in System Application Software for Human Rated Exploration Missions. J. Sp. Saf. Eng. 2016, 3, 104–110.

20. Marques, T.V.R.; Cabral, A.A. Influence of the heating rates on the correlation between glass-forming ability (GFA) and glass stability (GS) parameters. J. Non. Cryst. Solids 2014, 390, 70–76.

21. Wu, S.J.; Liu, Z.Q.; Qu, R.T.; Zhang, Z.F. Designing metallic glasses with optimal combinations of glass-forming ability and mechanical properties. J. Mater. Sci. Technol. 2021, 67, 254–264.

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Maurizio Ponte
University of Calabria image/svg+xml
Filippo Catanzariti
Software provider for structural and geotechnical engineering, Geostru SC Engsoft S.r.l., Cluj-Napoca, Romania
Gloria Campilongo
University of Calabria image/svg+xml

Resumen

Computational simulation is widely used in companies to perform analysis and improve the quality of products and projects. Most of these analyses are carried out using software that uses the Finite Element Method, which allows to obtain answers to numerous engineering problems. In this study, two examples of application to the study of tunnels of the Finite Element Method using the Geostru Software "GFAS - Geotechnical F.E.M. Analysis System" are proposed. The case of a tunnel excavated inside a granite rock massif was analyzed, first determining the state of stresses in the cavity contour through a theoretical method and comparing these results with those obtained in the software. Then, by means of finite element modeling, the settlements induced by the excavation were determined. Finally, the problem of tunnel excavation in a viscoplastic rock mass is presented and the authors propose a comparison of the analytical and numerical method.

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Número

Vol. 4 Núm. 01 (2021): Agua y Biodiversidad: Claves para el Equilibrio de los Ecosistemas

Sección

Artículos

Cómo citar

Ponte, M., Catanzariti, F., & Campilongo, G. (2021). Application of the Finite Element Method (FEM) through GFAS Software to the study of a tunnel. Green World Journal, 4(01). https://doi.org/10.53313/gwj41006

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