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HomeKey Engineering MaterialsKey Engineering Materials Vol. 684Isothermal Backward Extrusion of Thick-Walled...

Isothermal Backward Extrusion of Thick-Walled Anisotropic Pipe Blanks in Mode of Short-Time Creeping

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Abstract:

Provided here is a mathematical model of the operation of backward extrusion in the mode of short-time creeping of thick-walled pipe blanks made out of orthotropic material with cylindrical anisotropy of the mechanical properties. Carried out was theoretical research of the operation of isothermal axisymmetric backward extrusion of thick-walled pipe blanks made out of anisotropic materials by conic point-tool in the mode of short-time creeping. Established were regularities regarding the change of material flow kinematics, regarding the stressed and strained condition of the blank, regarding force modes and limit possibilities of deformation depending on the technological parameters, on friction conditions on the contact surfaces of the operating tools and of the blank, regarding the geometrical dimensions of the blank and of the manufactured part, and of the anisotropy of the mechanical properties of the blank material, that on the basis of the developed mathematical model of isothermal non-radial flow of anisotropic material under conditions of axisymmetric stressed and strained conditions in the mode of short-time creeping. Experimental operations were carried out for isothermal backward extrusion of thick-walled pipe blanks made out of АМг6 aluminum and ВТ6С titanium alloys. Comparing the results of theoretical and experimental data for force modes of the operation of isothermal backward extrusion of thick-walled pipe blanks points to their satisfactory similarity (difference not exceeding 5% - 10%).

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Periodical:

Key Engineering Materials (Volume 684)

Pages:

143-151

DOI:

https://doi.org/10.4028/www.scientific.net/KEM.684.143

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Online since:

February 2016

Authors:

Sergey Sergeevich Yakovlev, Aleksey Alekseevich Perepelkin, Andrey Aleksandrovich Pasynkov

Keywords:

Anisotropic Material, Backward Extrusion, Damage Rate, Destruction, Force, Mathematical Model, Short-Time Creep, Strain, Stress

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© 2016 Trans Tech Publications Ltd. All Rights Reserved

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