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Abstract

Abrasive flow machining (AFM) is a non-conventional finishing process that provides a high level of surface finish and close tolerances with an economically acceptable rate of surface generation for a wide range of industrial components. AFM deburrs and polishes by forcing an abrasive laden media (elastic/viscoelastic polymer) across the workpiece surface. Abrasion occurs only where the media flow is restricted; other areas remain unaffected. One serious limitation of AFM processes is a low material removal rate. An effort has been made towards the performance improvement of this process by applying centrifugal force on the abrasive media using a rotating rod introduced in the workpiece passage. This variant of AFM, called centrifugal force assisted abrasive flow machining (CFAAFM), has been developed. This paper presents finite element modelling (FEM) of a polymer-based non-Newtonian viscoelastic fluid used in the CFAAFM process and the same is used to evaluate the resultant pressure, velocity, and radial stresses during a working cycle. All FEM analyses were performed using a commercial finite element package ANSYS. The results are compared with the data available in the literature, and close agreement has been found between the two.

Keywords

CFAAFM CFG rod finite element modelling ANSYS viscoelastic fluid

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Finite element analysis of media used in the centrifugal force assisted abrasive flow machining process

Abstract

Abstract

Keywords

References