Resistance to deformation and fracture of aluminum AD1 under shock-wave loading at temperatures of 20 and 600°C

被引:0
|
作者
G. V. Garkushin
G. I. Kanel’
S. V. Razorenov
机构
[1] Russian Academy of Sciences,Institute of Problems of Chemical Physics
[2] Russian Academy of Sciences,Scientific Association for High Temperatures
来源
Physics of the Solid State | 2010年 / 52卷
关键词
Shock Wave; High Strain Rate; Wave Profile; Spall Strength; Shock Wave Loading;
D O I
暂无
中图分类号
学科分类号
摘要
The results of measurements of the dynamic elastic limit and spall strength under shock-wave loading of aluminum samples AD1 of thicknesses between 0.5 and 10.0 mm at room temperature and at temperature increased up to 600°C are presented. The anomalous thermal hardening of aluminum under high strain rate has been confirmed. An analysis of the decay of precursors at temperatures of 20 and 600°C has shown that the change in the main mechanism of drag of dislocations occurs at a strain rate equal approximately to 5 × 103 s−1, which agrees with the results of measurements by the Hopkinson split bar method. The results of measurements of the spall strength in a wide range of strain rates add the previously obtained data and agree with them.
引用
收藏
页码:2369 / 2375
页数:6
相关论文
共 50 条
  • [31] THE FRACTURE OF EI787 AND EP410U STEELS UNDER SHOCK-WAVE LOADING
    GOLUBEV, VK
    NELIN, SS
    SOBOLEV, YS
    UTYUGOV, YV
    SOVIET MATERIALS SCIENCE, 1990, 26 (05): : 607 - 609
  • [32] The Formation of Elastoplastic Fronts and Spall Fracture in AMg6 Alloy under Shock-Wave Loading
    Saveleva, N. V.
    Bayandin, Yu. V.
    Savinykh, A. S.
    Garkushin, G. V.
    Razorenov, S. V.
    Naimark, O. B.
    TECHNICAL PHYSICS LETTERS, 2018, 44 (09) : 823 - 826
  • [33] On the fracture behavior of uranium subjected to shock-wave loading in the temperature range -196 to 800 degrees C
    Golubev, VK
    Sobolev, YS
    Yukina, NA
    RUSSIAN METALLURGY, 1997, (02): : 103 - 105
  • [34] High strain rate deformation and fracture of the magnesium alloy Ma2-1 under shock wave loading
    G. V. Garkushin
    G. I. Kanel’
    S. V. Razorenov
    Physics of the Solid State, 2012, 54 : 1079 - 1085
  • [35] High strain rate deformation and fracture of the magnesium alloy Ma2-1 under shock wave loading
    Garkushin, G. V.
    Kanel', G. I.
    Razorenov, S. V.
    PHYSICS OF THE SOLID STATE, 2012, 54 (05) : 1079 - 1085
  • [36] On the manifestation of reversible deformation under shock-wave loading of nitrogenous Cr-Mn-Ni austenitic steel
    Sagaradze, V. V.
    Kataeva, N., V
    Kabanova, I. G.
    Afanasyev, S., V
    Pavlenko, A., V
    LETTERS ON MATERIALS, 2021, 11 (04): : 403 - 408
  • [37] Strength Properties of Aluminum-Oxide Ceramics Prepared by the Additive Manufacturing Method under Shock-Wave Loading
    Promakhov, V. V.
    Savinykh, A. S.
    Dubkova, Ya. A.
    Schulz, N. A.
    Grunt, N. V.
    Razorenov, S. V.
    TECHNICAL PHYSICS LETTERS, 2018, 44 (10) : 898 - 901
  • [38] Strength Properties of Aluminum-Oxide Ceramics Prepared by the Additive Manufacturing Method under Shock-Wave Loading
    V. V. Promakhov
    A. S. Savinykh
    Ya. A. Dubkova
    N. A. Schulz
    N. V. Grunt
    S. V. Razorenov
    Technical Physics Letters, 2018, 44 : 898 - 901
  • [39] Smooth particle hydrodynamics method for modeling cavitation-induced fracture of a fluid under shock-wave loading
    Davydov, M. N.
    Kedrinskii, V. K.
    JOURNAL OF APPLIED MECHANICS AND TECHNICAL PHYSICS, 2013, 54 (06) : 877 - 884
  • [40] Smooth particle hydrodynamics method for modeling cavitation-induced fracture of a fluid under shock-wave loading
    M. N. Davydov
    V. K. Kedrinskii
    Journal of Applied Mechanics and Technical Physics, 2013, 54 : 877 - 884
12345