Summary. The mathematical model of kinematics of a plastic shaping at the sinking of a thin-walled precision pipe applied to calibration of the ends of the unified elements of the pipeline of aircraft from titanic alloys and corrosion-resistant steel before assembly to the route by means of automatic argon-arc welding of ring joints is developed. For modeling, the power criterion of stability with use of kinematic possible fields of speeds is applied to receiving the top assessment of effort of deformation. The developed model of kinematics of a plastic current allows to receive power parameters of the main condition of process of calibration by sinking and can be used for the solution of a task on stability of process of deformation by results of comparison of power (power) parameters for the main (steady) and indignant states. Modeling is made in cylindrical system of coordinates by comparison of options of kinematic possible fields of the speeds of a current meeting a condition of incompressibility and kinematic regional conditions. The result of the modeling was selected discontinuous field of high-speed, in which the decrease outer radius (R) occurs only by increasing the thickness of the pipe wall (t). For this option the size of pressure of sinking had the smallest value, therefore the chosen field of speeds closely to the valid. It is established that with increase in a step of giving 1 at calibration by the multisector tool the demanded pressure of sinking of q decreases. At an identical step of giving 1 pipe with the smaller relative thickness of (t/r) needs to be calibrated the smaller pressure of sinking. With increase of a limit of fluidity at shift of material of pipe preparation pressure of sinking of (q) increases.

mathematical model, reduction, pressure, thin-wall pipe, stability, velocity field

1. Zakharchenko N. D., Salakhetdinov Z. Kh. Rukovodiashchii tekhnicheskii material RTM 1.4.1638 – 86. Konstruktivno-tekhnologicheskaia otrabotka truboprovodnykh kommunikatsii, izgotovlenie i kontrol’ trub i patrubkov [The leading technical material LТМ 1.4.1638 – 86. Structurally – technological optimization of pipeline communications, production and control of pipes and branch pipes], Мoscow, NIАТ, 1988. 576 p. (In Russ.).

2. Golub V. V., Egorov V. G., Zakharchenko N. D. Rotary drawing of thin-walled cases of filter holders. KShP. Obrabotka materialov davleniem. [Press-forging production. Processing of materials by pressure], 1998, no. 3, pp.16-20. (In Russ.).

3. Chumadin A. S. Zo Hein Win Calculation of power parameters at rotational compression of pipes. Nauch. tr. MATI-RGTU. [Scientific work МАТI-RSТU], 2013, no.20, pp.182-185. (In Russ.).

4. Sosenushkin E. N., Tret’iakova E.I. Eksperimental’noe issledovanie ustoichivosti trubnoi zagotovki pri kombinirovanii operatsii obzhima i razdachi [Field research of stability of pipe preparation at a combination of operations of pressing and expansion]. Мoscow, Ross. Assots. proizvoditelei stankoinstrum. produktsii “Stankoinstrument”, 2010. pp. 313-318. (In Russ.).