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Влияние структурного состояния на упругие и микропластические свойства алюминиевого сплава AД1
Summary
This Russian-language study examined how different processing methods affecting the crystal grain structure of aluminum alloy AD1 influence its elastic and 'microplastic' deformation properties. 'Microplastic' here refers to microscopic metal deformation — this is a materials engineering study unrelated to plastic particle pollution.
The results of a study of aluminum alloy AD1 in four structural states before and after severe plastic deformation are presented. Both the initial coarse-grained state (supply state) and three fine-grained states, which differ from each other in the method of obtaining, are considered. Elastic and microplastic properties (modulus of elasticity, decrement of elastic vibrations, microplastic deformation) were determined by the acoustic method of a composite vibrator. It is shown that the modulus of elasticity changes to a large extent under the influence of the evolution of internal stresses; the attenuation of ultrasound after severe plastic deformation increases due to an increase in the area of grain boundaries. Key words: AD1 aluminum, modulus of elasticity, microcrystalline aluminum, decrement of elastic vibrations, microplastic deformation.
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