Design of a disk-mandrel assembly for achieving rotational autofrettage in the disk

Kamal, Seikh Mustafa; Dixit, US

doi:10.1177/0954406220954890

Cited by 2 publications

(1 citation statement)

References 28 publications

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“…Of course in actual practice, the rotation of the cylinder about its axis with free surfaces is impossible and the cylinder must be coupled mechanically. Kamal and Dixit 17 presented the numerical simulation of a practical case of rotational autofrettage of a disc mounted on a mandrel. To ensure that a continuous contact is maintained between the mandrel and the inner wall, the disc was shrink-fitted on the mandrel.…”

Section: Fem Model Of Rotational Autofrettagementioning

confidence: 99%

Effect of length in rotational autofrettage of long cylinders with free ends

Shufen¹,

Dixit

2021

Proceedings of the Institution of Mechanical Engineers, Part C:

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Thick-walled cylindrical and spherical pressure vessels are often subjected to autofrettage, a process in which the vessel is loaded at the inner wall to cause a partial or complete plastic deformation emanating from the inner wall, followed by unloading. This introduces the beneficial compressive residual stresses in the vicinity of the inner wall. Depending on the type of the loading, there are five different types of autofrettage processes— hydraulic, swage, explosive, thermal and rotational. This article analyzes the rotational autofrettage, in which the cylinder to be autofrettaged is loaded by rotating it about its longitudinal axis. The centrifugal forces cause the required plastic deformation in the cylinder. Hence, when the cylinder is unloaded by bringing it to rest, compressive hoop residual stresses are introduced in the vicinity of its inner wall. When long cylinders are rotated about their axes, the distribution of axial stress changes with length of the cylinder and affects the generation of the residual stresses in the autofrettaged cylinder. This effect is investigated here by a finite element method (FEM) analysis of rotational autofrettage of cylinder made up of A723 gun steel. The FEM analysis using ABAQUS® package reveals the presence of tensile axial residual stresses in the vicinity of the inner wall of the cylinder, which increase with length. The tensile residual stresses can be mitigated by constraining the ends of the cylinder during the rotational autofrettage.

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Section: Fem Model Of Rotational Autofrettagementioning

confidence: 99%