Geodesic
Analytical and experimental determination of the specific penetration resistance.
Journal of Samara State Technical University, Ser. Physical and Mathematical Sciences, Tome 23 (2019) no. 1, pp. 49-68.

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In the present paper, the main force parameter is estimated under the static tests. This parameter is the specific penetration resistance and it is generally believed that the parameter is a constant in case of static penetration. However, a number of experimental and analytical data illustrate varying the specific penetration resistance according to the current depth of penetration. It is noted that the weakening free-surface effect decreases the specific penetration resistance near the facial or rear edge. Consequently, the relevance of the topic is emphasized by the influence of the facial and rear weakening free-surface effect on the penetration parameters detected in the experimental studies and engineering calculations. The refined approximation of the specific penetration resistance presented in this paper is taking account of the penetration of the sharp indenter into the plate of middle thickness within the framework of the viscous crater formation and the facial and rear weakening free-surface effect. Also this article contains data processing technique. For carrying out the tests a number of experimental samples were made. It is plates of different thicknesses, it must be emphasized that test sample materials are technical plasticine, plumbum and Wood's metal. It should also be noted that for the static tests three cone-nose indenters were made. Indenter sizes: the diameter of the cylindrical part is 7 mm in all cases and the lengths of the conical nose are 3.2 mm, 5.6 mm, and 8.4 mm. The test were carryed out on a testing machine Zwick/Roell Z-250. The key parameters derived from the experiment are the specific penetration resistance of the deep layers, the friction coefficient and the parameters of the weakening free-surface effect. The results obtained in the experiment lead to the approximation of the resistance force from more general parameters. These parameters are the specific penetration resistance of the deep layers and the friction coefficient of a sample, geometric parameters of indenter and plate. An approximation error does not exceed 25 % for the technical plasticine, 16 % for the Wood's metal, and 25 % for the plumbum. These errors are given for “sharp” (the length of the cone-nose is 8.4 mm) and “middle” (the length of the cone-nose is 5.6 mm) indenter because of a problem has been in depth considered in the investigation. This problem is that penetration of the “blunt” indenter is not follow to condition of viscous crater formation. Therefore, different versions should be used to describe the penetration process (for example, plugging mechanism). It is proposed in penetration models for the estimation of the penetration resistance force of sharp indenters into the plate of middle thickness.
Keywords: static penetration test, technical plasticine, Wood's metal, specific penetration resistance, weakening free-surface effect. 
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V. N. Aptukov; A. R. Khasanov; A. F. Merzlyakov. Analytical and experimental determination of the specific penetration resistance.. Journal of Samara State Technical University, Ser. Physical and Mathematical Sciences, Tome 23 (2019) no. 1, pp. 49-68. http://geodesic.mathdoc.fr/item/VSGTU_2019_23_1_a3/

[1] Vitman F. F., Stepanov V. A., “Effect of the strain rate on the resistance of metals to deformation at impact velocities of 100–1000 m/sec”, Nekotorye problemy prochnosti tverdogo tela [Some problems of the strength of solids], USSR Academy of Sciences, Moscow, Leningrad, 1959, 207–221 (In Russian)

[2] Aptukov V. N., “Penetration: Mechanical aspects and mathematical modeling (review)”, Strength of Materials, 22:2 (1990), 230–240 | DOI

[3] Ben-Dor G., Dubinsky A., Elperin T., “Ballistic impact: recent advances in analytical modeling of plate penetration dynamics – A Review”, Appl. Mech. Rev., 58 (2005), 355–371 | DOI

[4] Ben-Dor G., Dubinsky A., Elperin T., “Analytical engineering models of high speed normal impact by hard projectiles on metal shields”, Cent. Eur. J. Eng., 3:3 (2013), 349–373 | DOI

[5] Ben-Dor G., Dubinsky A., Elperin T., “Empirical models for predicting protective properties of concrete shields against high-speed impact”, J. Mech. Mater. Struct., 8:2-4 (2013), 199–232 | DOI

[6] Ben-Dor G., Dubinsky A., Elperin T., “Engineering models of high speed penetration into geological shields”, Cent. Eur. J. Eng., 4:1 (2014), 1–19 | DOI

[7] Ben-Dor G., Dubinsky A., Elperin T., Applied High-Speed Plate Penetration Dynamics, Solid Mechanics and its Applications, 132, Springer, Dordrecht, 2006, 364 pp. | DOI | Zbl

[8] Ben-Dor G., Dubinsky A., Elperin T., High-speed penetration dynamics: Engineering models and methods, World Scientific Publishing, Singapore, 2013, 680 pp | DOI

[9] Vitman F. F., Zlatin N. A., Ioffe B. S., “Deformation resistance of metals at rates of $10^{-6}$–$10^{2}$ m/sec”, Zh. Tekhn. Fiz., 19:3 (1949), 123–128 (In Russian)

[10] Zukas J. A., Nicholas T., Swift H. F., Greszczuk L. B., Curran D. R., Impact Dynamics, Wiley and Sons, New York, 1982, 452 pp.

[11] Aptukov V. N., Gladkovsky V. A., Lesnichenko Yu. Yu., “Interaction of the impactor with a shield of a finite thickness”, Uprugoe i viazkouprugoe povedenie materialov i konstruktsii [Elastic and viscoelastic behavior of materials and structures], Ural Scientific Center of the USSR Academy of Sciences, Sverdlovsk, 1981, 68–73 (In Russian)

[12] Boldenkov V. V., Drokin P. A., Method of determining dynamical hardness of materials, RU Patent 2258211, Int. Cl. 7 G 01 N 3/48. Proprietor(s) Minatom RF (RU), FGUP “RFJaTs-VNIIEF” (RU). Appl. No. 2004109856/28. Filed 31.03.2004 and issued 10.08.2004. Bull. 22 (In Russian)

[13] Goryk A., Kovalchuk S., Shulyansky G., “Determination of elastoplastic coefficient of shock interaction of spherical indenter with deformable halfspace”, Eastern-European Journal of Enterprise Technologies, 1:7 (61) (2013), 56–59 (In Russian)

[14] Rudnitsky V. A., Kren A. P., Lantsman G. A., “Investigation of the ratio between the dynamic and static hardness of metals”, Vestsi Natsyianal'nai Akademii Navuk Belarusi. Ser. Fizika-Tekhnichnykh Navuk, 2016, no. 4, 16–22 (In Russian)

[15] Markovets M. P., Opredelenie mekhanicheskikh svoistv metallov po tverdosti [Determination of the Mechanical Properties of Metals on the Basis of Hardness], Mashinostroenie, Moscow, 1979, 191 pp. (In Russian)

[16] Stoev P. I., Moschenok V. I., “Definition of mechanical properties of metals and alloys on hardness”, Visnik Kharkivs'kogo Natsional'nogo Universitetu im. V. N. Karazina, 601:2 (22) (2003), 106–112 (In Russian)

[17] Sapozhnikov S. B., Ignatova A. V., “Mechanical properties of technical plasticine under static and dynamic loadings”, PNRPU Mechanics Bulletin, 2014, no. 2, 200–219 (In Russian) | DOI

[18] Wang X., Zhang D., Gu C., Shen Z., Liu H., “Research on the micro sheet stamping process using plasticine as soft punch”, Materials, 7:6 (2014), 4118–4131 | DOI

[19] Wojcik L., Lis K., Pater Z., “Plastometric tests for plasticine as physical modelling material”, Open Engineering, 6:1 (2016), 653–659 | DOI

[20] Veldanov V. A., Markov V. A., Pusev V. I., Ruchko A. M., Sotskii M. Y., Fedorov S. V., “Computation of nondeformable striker penetration into low-strength obstacles using piezoelectric accelerometry data”, Tech. Phys., 56:7 (2011), 992–1002 | DOI

[21] Dolganina N. Yu., “Evaluation of ballistic limit and multilayer fabric plate deflection under indenter impact”, Bulletin of the South Ural State University, Series: Mechanical Engineering Industry, 15:10 (186) (2010), 17–23 (In Russian)

[22] NIJ Standard–0101.04. Ballistic Resistance of Personal Body Armor, National Institute of Justice Office of Science and Technology, Washington, 2010, 67 pp.

[23] NIJ Standard–0115.00. Stab Resistance of Personal Body Armor, National Institute of Justice Office of Science and Technology, Washington, 2010, 46 pp.

[24] Aptukov V. N., “Expansion of a spherical cavity in a compressible elastoplastic medium. Report 1. Effect of mechanical characteristics, free surface, and lamination”, Strength of Materials, 23:12 (1991), 1262–1268 | DOI

[25] Aptukov V. N., Khasanov A. R., “Optimization of parameters of layered plates during dynamic hard indenter penetration with friction and weakining effect of free surfaces”, PNRPU Mechanics Bulletin, 2014, no. 2, 48–75 (In Russian) | DOI