Numerical simulation of the preforming process of a thick-walled coupling made of shape memory alloys
Аuthors
PJSC UAC Sukhoi Design Bureau, 23A, Polikarpova str., Moscow, 125284, Russia
e-mail: aleksej-sharunov@yandex.ru
Abstract
The work deals with the numerical modeling of the pre-deformation process (distribution – increase in the inner radius) of a thick-walled cylindrical coupling made of shape memory alloy (SMA) with the constant pressure in the process of direct thermoelastic phase transformation. The process of elastic, phase and structural deformations accumulation while the SMA coupling cooling through the temperature range of direct martensitic transformation was considered within the framework of the problem.
As part of the work, the process of model integrating of the nonlinear deformation during phase and structural transformations into the finite element complex Simulia AbaQus was performed through the procedure for creating custom material using UMAT technology and explicitly determining the tangent stiffness matrix. The pre-deformation process of a thick-walled cylindrical coupling made of SMA is being considered in a once-cohesive thermomechanical formulation, with account for the effect of the acting stress on the of phase transition temperature values.
The article demonstrates the effect of accounting for the structural transition in the process of a direct thermoelastic phase transition for two types of boundary conditions. Fidelity of the results of the work is confirmed by the validation of the developed software modules based on the results of field tests of elementary samples based on the Ni-Ti system and verification employing known analytical solutions to the boundary value problems of the SMA mechanics.
The results presented in the article may be employed in the design of thermomechanical joint couplings from the SMA.
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