Mechanics of Solids
A Journal of Russian Academy of Sciences

Founded
in January 1966
Issued 6 times a year
Print ISSN 0025-6544
Online ISSN 1934-7936

Russian

English

About Journal | Issues | Guidelines | Editorial Board | Contact Us

About Journal
Issues
- Latest Issue
- Archive of Issues
  - 2012-1
    - pp.95-102
- Online First
- Search for Articles
Guidelines
- Submit Article
Editorial Board
Contact Us

Issues > Archive of Issues > 2012-1 > pp.95-102

Archive of Issues

Total articles in the database:		12804
In Russian (Изв. РАН. МТТ):		8044
In English (Mech. Solids):		4760

<< Previous article | Volume 47, Issue 1 / 2012 | Next article >>

A.V. Radchenko and P.A. Radchenko, "Behavior of Brittle Anisotropic Materials with Different Orientation of Mechanical Properties at the Edge of Piercing," Mech. Solids. 47 (1), 95-102 (2012)

Year

2012

Volume

Number

Pages

95-102

DOI

10.3103/S0025654412010098

Title

Behavior of Brittle Anisotropic Materials with Different Orientation of Mechanical Properties at the Edge of Piercing

Author(s)

A.V. Radchenko (Tomsk State University of Architecture and Civil Engineering, Solyanaya pl. 2, Tomsk, 634003 Russia, andrey-radchenko@live.ru)
P.A. Radchenko (Institute of Strength Physics and Materials Science, Siberian Branch of Russian Academy of Sciences, Akademicheskii pr-t 2/4, Tomsk, 634021 Russia, radchenko@live.ru)

Abstract

The problem of normal interaction between a compact steel isotropic cylindrical projectile and an orthotropic plate at the edge of piercing in the range of impact velocity from 50 m/s to 400 m/s. The obstacle is made of an organoplastic material with some initial orientation of its mechanical properties or the same material whose properties are obtained by a 90° rotation of the initial material about the axis OY. The destruction of obstacles is studied and the efficiency of their protective properties is comparatively analyzed depending on the orientation of the elastic and strength properties of the anisotropic material. The problem is solved numerically by the finite element method in the three-dimensional statement. The behavior of the projectile material is described by an elastoplastic model, while the response of the obstacle anisotropic material is described in the framework of the elastic-brittle model with different tensile and compressive strengths.

Keywords

anisotropy, strength, fracture, elasticity, plasticity, composite materials, dynamic loads

References

1.	A. V. Radchenko and S. V. Kobenko, "Effect of Oriented Elastic and Strength Characteristics on the Impact Fracture of Anisotropic Materials," Dokl. Ross. Akad. Nauk 373 (4), 479-482 (2000) [Dokl. Phys. (Engl. Transl.) 45 (8), 397-400 (2000)].
2.	V. A. Gorel'skii, A. V. Radchenko, and I. E. Khorev, "Kinetic Mechanisms of the Process of Punching of Two-Layer Plates," Izv. Akad. Nauk SSSR. Mekh. Tverd. Tela, No. 6, 185-189 (1988) [Mech. Solids (Engl. Transl.)].
3.	M. L. Wilkins, "Calculation of Elastic-Plastic Flows," in Numerical Methods in Hydrodynamics, (Mir, Moscow, 1967), pp. 212-263 [in Russian].
4.	A. V. Radchenko, V. E. Fortov, and I. E. Khorev, "Physical Features of High-Velocity Interaction of Elongated Technogenic Fragments with Constructions," Dokl. Ross. Akad. Nauk 389 (1), 49-54 (2003) [Dokl. Phys. (Engl. Transl.) 48 (3), 126-130 (2003)].
5.	E. M. Wu, "Phenomenological Failure Criteria for Anisotropic Media," in Composite Materials, Vol. 2: Mechanics of Composite Materials (Mir, Moscow, 1978), pp. 401-492 [in Russian].
6.	E. K. Ashkenazi and E. V. Ganov, Anisotropy of Structural Materials. Reference Book (Mashinostroenie, Leningrad, 1980) [in Russian].
7.	A. V. Radchenko, S. V. Kobenko, I. N. Marcenuk, et al., "Research of Features of Behavior of Isotropic and Anisotropic Materials under Impact," Int. J. Impact. Engng 23, 745-756 (1999).
8.	M. N. Krivosheina, A. V. Radchenko, and S. V. Kobenko, "Fracture of Orthotropic and Isotropic Spherical Bodies under the Action of a Pulse of Uniform Compression," Mekh. Komp..Mater. Konstr. 7 (1), 95-102 (1992) [J. Comp. Mech. Design (Engl. Transl.)].
9.	E. A. Kozlov, "Shock Adiabat Features, Phase Transition Macrokinetics and Spall Fracture of Iron in Different Phase States," High Pressure Res. 10, 541-582 (1992).
10.	E. A. Kozlov, "Experimental Verification of E. I. Zababakhin Hypothesis Concerning Limitation of Energy Cumulation in the Spherically Converging Shock-Wave Front in Medium with Phase Transitions," in Shock Compression of Condensed Matter (1991), pp. 169-176.
11.	N. N. Belov, A. A. Konyaev, V. G. Simonenko, et al., "Effect of Polymorphous Phase Transformations on Explosive Compression of Steel Spheres," Fiz. Goreniya Vzryva 33 (5), 128-136 (1997) [Comb. Expl. Shock Waves (Engl. Transl.) 33 (5), 619-625 (1997)].

Received

19 October 2010

Link to Fulltext

http://www.springerlink.com/content/f51637145157q43v/

<< Previous article | Volume 47, Issue 1 / 2012 | Next article >>

If you find a misprint on a webpage, please help us correct it promptly - just highlight and press Ctrl+Enter

101 Vernadsky Avenue, Bldg 1, Room 246, 119526 Moscow, Russia • (+7 495) 434-3538 • mechsol@ipmnet.ru • https://mtt.ipmnet.ru
Founders: Russian Academy of Sciences, Ishlinsky Institute for Problems in Mechanics RAS