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METAL PROCESSING
Название Technological regimes of expansion with heating of pipelines’ elements
DOI 10.17580/tsm.2024.02.08
Автор Platonov V. I., Chudin V. N.
Информация об авторе

Tula State University, Tula, Russia

V. I. Platonov, Associate Professor of Department of Mechanics and Processes of Plastic Forming, e-mail: pvi_1@rambler.ru

 

Russian University of Transport (MIIT), Moscow, Russia

V. N. Chudin, Professor of Department of Materials Resistance and Construction Mechanics

Реферат

The paper proposes relations for calculating the deformation and force regimes of the expansion process with heating of pipeline elements under conditions of viscoplastic deformation. The calculation of the expansion operation was carried out for billets made from the light and strong alloys based on aluminum and titanium. Technological processes of expansion are used to increase the diametrical size of the end part of a tube cylindrical billet. Products made of high-strength materials can be used as adapters for the pipeline systems with the different diameters, the fuel tank elements, the various containers, the casings in the aerospace, chemical and other branches of technics, where it is necessary to ensure the operability of constructions at the extreme temperatures and pressures, at the vibration and force loads in the aggressive environments. The observance of special conditions, regulating the temperature and velocity parameters of shaping, allows plastically to treat billets from the high-strength alloys with the high degrees of deformation and forecast mechanical characteristics. The use of heating technology only for the part of the pipe billet, undergoing plastic deformation, leads to significant savings in energy resources and the timerequir ed to raise the temperature. The material of the billets is assumed to be anisotropic, viscoplastic and relaxation under specified temperature and speed deformation conditions. The energy method of calculation, based on the kinematics of deformation, is used. The relations for calculating the pressure value and the loss of continuity of the initial billet’s material on the degree of shape changing of the billet, the velocity of operation and the anisotropy of mechanical properties are given. It is shown that the velocity of deformation has a significant influence on the magnitude of deformations, pressure and damage of billet’s material, i.e. on the product’s quality. The calculated results and product samples are presented.

Ключевые слова Viscoplasticity, anisotropy, kinematics, velocity, power, pressure, material continuity
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