Author
B. D. Chukhin
Bio: B. D. Chukhin is an academic researcher. The author has contributed to research in topics: Viscosity & Deformation (engineering). The author has an hindex of 1, co-authored 1 publications receiving 10 citations.
Papers
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TL;DR: In this article, the impact compressibility of different aluminum alloys in the test pressure range is weakly dependent on chemical composition, treatment process, and material strength, and the boundary for a marked effect of strain rate on its resistance moves into the region of higher rates.
Abstract: 1.
Within the limits of experimental error, the impact compressibility of different aluminum alloys in the test pressure range is weakly dependent on chemical composition, treatment process, and material strength.
2.
Resistance to deformation in the high strain rate region increases with increasing strain rate, and the boundary for a marked effect of strain rate on its resistance moves into the region of higher rates.
3.
In the case of the absence of a correlation between strength properties with uniaxial stress and uniaxial strain states, their sensitivity to loading rate may be connected with a single viscosity factor.
11 citations
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TL;DR: In this paper, the results of mechanical tensile and shear tests of steels of different strength levels with plastic strain rates of 3·10−3−105 sec−1 were presented.
Abstract: The results are presented of mechanical tensile and shear tests of steels of different strength levels with plastic strain rates of 3·10−3–105 sec−1. The changes in the characteristics of strength, plasticity, and microstructure are analyzed in relation to the strength level of the steel and loading rate. For steels of different structural classes at high deformation rates (approximately up to 105 sec−1) a significant increase in the characteristics of strength and plasticity is observed.
9 citations
TL;DR: In this article, the penetration and perforation of plates of two aluminium alloys by a cylindrical steel projectile were examined experimentally and simulated numerically, and the influence of the impact velocity upon the penetration depth and the deformation and perfusion modes were investigated.
6 citations
TL;DR: In this paper, a comprehensive technique of studying and predicting the behavior of materials under conditions of dynamic tension is presented, in which a possibility of increasing the strength properties of materials by severe plastic deformation (SPD) in a wide range of varying parameters of external loads and the fi-xation of these changes in the framework of the proposed technique is demonstrated using Al-Mg and Al-Cu-mg aluminum alloys as examples.
Abstract: An increase in the velocities of automobile and aerospace transport and, simultaneously, the necessary of decreasing their masses increase the requirements to the operating reliability of used materials and constructions. In this case, the operation of a material under dynamic impact loads remains in nonnormative ranges. This work presents a comprehensive technique of studying and predicting the behavior of materials under conditions of dynamic tension. A possibility of increasing the strength properties of materials by severe plastic deformation (SPD) in a wide range of varying parameters of external loads and the fi-xation of these changes in the framework of the proposed technique is demonstrated using Al–Mg and Al‒Cu–Mg aluminum alloys as examples.
6 citations
6 citations
TL;DR: In this paper, a number of low-carbon steels in uniaxial tension and compression in the strain rate range 10−3−4·103 sec−1 and at temperatures of 293−573 K were tested.
Abstract: Results are given for mechanical tests on a number of low-carbon steels in uniaxial tension and compression in the strain rate range 10−3–4·103 sec−1 and at temperatures of 293–573 K. An increase is confirmed for strength and ductility characteristics with an increase in strain rate. It is shown that the sensitivity of metals to strain rate depends on the specific temperature and rate conditions of loading. On the basis of experimental data obtained analytical dependences are suggested for the resistance of materials to deformation on the degree and rate of deformation, and also on temperature.
3 citations