Numerical algorithm based on implicit finite-difference schemes for analysis of dynamic processes in blocky media
-
Vladimir M. Sadovskii
and
Oxana V. Sadovskaya
Abstract
Dynamic processes in block-structured media are described within the framework of a mathematical model where elastic blocks interact with each other through pliable interlayers possessing complex mechanical properties. The case of elastic interaction is considered, the effects of plasticity and viscoelastic shear in block interlayers are taken into account. We use the model of porous fluid-saturated material in interlayers in which pores collapse during sudden or prolonged application of compressive stresses. An implicit difference scheme is constructed for numerical implementation of the model based on principles for construction of Ivanov’s schemes with controlled energy dissipation. Using MPI (Message Passing Interface), we developed parallel software for modelling wave motion in a two-dimensional formulation. The results of numerical analysis are presented for the waves initiated by rotation of blocks, which indicates a strong anisotropy of the blocky medium.
References
[1] N. I. Aleksandrova, A. G. Chernikov, and E. N. Sher, Experimental Investigation Into the one-dimensional calculated model of wave propagation in block medium. J. Min. Sci. 41 (2005), No. 3, 232–239.10.1007/s10913-005-0088-ySearch in Google Scholar
[2] S. V. Astaforov, E. V. Shilko, and S. G. Psakhie, Influence of constrained conditions on the character of deformation and fracture of block media under shear loads. Phys. Mesomech. 13 (2010), No. 3–4, 164–172.10.1016/j.physme.2010.07.008Search in Google Scholar
[3] J. Azevedo, G. Sincraian, and J. V. Lemos, Seismic behaviour of blocky masonry structures. Earthq. Spectra16 (2000), No. 2, 337–365.10.1193/1.1586116Search in Google Scholar
[4] V. G. Bazhenov, S. A. Kapustin, V. V. Toropov, and G. V. Turovtsev, Modelling of the deformation and failure processes in structural masonry. In: Applied Problems of Strength and Plasticity, No. 56, KMK Sci. Press Ltd, Moscow, 1997, pp. 56–61 (in Russian).Search in Google Scholar
[5] M. A. Biot, Theory of propagation of elastic waves in a fluid-saturated porous solid, I. Low-frequency range. J. Acoust. Soc. Amer. 28 (1956), No. 2, 168–178.10.1121/1.1908239Search in Google Scholar
[6] I. A. Garagash, Model of dynamics of fragmented media with movable blocks. Phys. Mesomech. 5 (2002), No. 5–6, 45–51.Search in Google Scholar
[7] E. F. Grekova, Nonlinear isotropic elastic reduced Cosserat continuum as a possible model for geomedium and geomaterials. Spherical prestressed state in the semilinear material. J. Seismol. 16 (2012), No. 4, 695–707.10.1007/s10950-012-9299-2Search in Google Scholar
[8] V. I. Erofeyev, Wave Processes in Solids with Microstructure. Ser. on Stability, Vibration and Control of Systems, Vol. 8. World Sci. Publ., New Jersey–London–Singapore–Hong Kong–Bangalore–Taipei, 2003.10.1142/5157Search in Google Scholar
[9] G. V. Ivanov, Yu. M. Volchkov, I. O. Bogulskii, S. A. Anisimov, and V. D. Kurguzov, Numerical Solution of Dynamic Elastic–Plastic Problems of Deformable Solids. Sib. Univ. Izd., Novosibirsk, 2002 (in Russian).Search in Google Scholar
[10] G. I. Marchuk, Splitting Methods. Nauka, Moscow, 1988 (in Russian).Search in Google Scholar
[11] L. A. Molotkov, On an effective model of an elastic block medium with slide contacts on the interfaces. J. Math. Sci. 86 (1997), No. 3, 2721–2734.10.1007/BF02355163Search in Google Scholar
[12] E. Pasternak and A. Dyskin, Measuring of Cosserat effects and reconstruction of moduli using dispersive waves. In: Mechanics of Generalized Continua: One Hundred Years After the Cosserat (Eds. G. A. Maugin and A. V. Metrikine), Ser. Advanced in Mechanics and Mathematics, Vol. 21, pp. 71–78. Springer, Heidelberg–New York–Dordrecht–London, 2010.10.1007/978-1-4419-5695-8_8Search in Google Scholar
[13] E. Pasternak and A. V. Dyskin, On a possibility of reconstruction of Cosserat moduli in particulate materials using long waves. Acta Mech. 225 (2014), No. 8, 2409–2422.10.1007/s00707-014-1132-2Search in Google Scholar
[14] G. W. Postma, Wave propagation in a stratified medium. Geophysics20 (1955), No. 4, 780–806.10.1190/1.1438187Search in Google Scholar
[15] O. V. Sadovskaya and V. M. Sadovskii, Analysis of rotational motion of material microstructure particles by equations of the Cosserat elasticity theory. Acoust. Phys. 56 (2010), No. 6, 942–950.10.1134/S1063771010060199Search in Google Scholar
[16] O. Sadovskaya and V. Sadovskii, Mathematical Modelling in Mechanics of Granular Materials. Ser. Advanced Structured Materials, vol. 21. Springer, Heidelberg–New York–Dordrecht–London, 2012.10.1007/978-3-642-29053-4Search in Google Scholar
[17] V. M. Sadovskii and O. V. Sadovskaya, Modelling of elastic waves in a blocky medium based on equations of the Cosserat continuum. Wave Motion52 (2015), 138–150.10.1016/j.wavemoti.2014.09.008Search in Google Scholar
[18] V. M. Sadovskii, O. V. Sadovskaya, and A. A. Lukyanov, Modelling of wave processes in blocky media with porous and fluid-saturated interlayers. J. Comp. Phys. 345 (2017), 834–855.10.1016/j.jcp.2017.06.001Search in Google Scholar
[19] V. M. Sadovskii, O. V. Sadovskaya, and E. P. Chentsov, Parallel program system for numerical modelling of the dynamic processes in the multi-blocky media on cluster systems (2Dyn_Blocks_MPI). Certificate of state registration of the computer program No. 2016615178 from 17.05.2016. RU OBPBT6 (116). FIPS, Moscow, 2016.Search in Google Scholar
[20] V. A. Saraikin, A. G. Chernikov, and E. N. Sher, Wave propagation in two-dimensional block media with viscoelastic layers (Theory and experiment). J. Appl. Mech. Tech. Phys. 56 (2015), No. 4, 688–697.10.1134/S0021894415040161Search in Google Scholar
[21] M. P. Varygina, M. A. Pokhabova, O. V. Sadovskaya, and V. M. Sadovskii, Numerical algorithms for the analysis of elastic waves in block media with thin interlayers. Numer. Methods Program. 12 (2011), No. 2, 435–442.Search in Google Scholar
© 2018 Walter de Gruyter GmbH, Berlin/Boston
Articles in the same Issue
- Frontmatter
- Preface
- The formulation and study of some variational assimilation problems and inverse problems in ionosphere
- New homogenization method for diffusion equations
- A splitting method for free surface flows over partially submerged obstacles
- Numerical algorithm based on implicit finite-difference schemes for analysis of dynamic processes in blocky media
- Semi-Lagrangian difference approximations with different stability requirements
- Adjoint equations in variational data assimilation problems
Articles in the same Issue
- Frontmatter
- Preface
- The formulation and study of some variational assimilation problems and inverse problems in ionosphere
- New homogenization method for diffusion equations
- A splitting method for free surface flows over partially submerged obstacles
- Numerical algorithm based on implicit finite-difference schemes for analysis of dynamic processes in blocky media
- Semi-Lagrangian difference approximations with different stability requirements
- Adjoint equations in variational data assimilation problems
