Abstract
Surface roughness plays an important role in product quality, particularly in situations such as precision fits and high-strength applications. Magnetic abrasive finishing (MAF) is an advanced finishing process in which the cutting force is controlled by magnetic field. This process is capable of giving nanometer-scale surface finish. This paper describes modeling, simulation and analysis of the profiles of the surface obtained after MAF. The real-life surface profile is so complicated that a single parameter can not give a full description of surface quality. However, in the present work, the height of the surface profile distribution before MAF is considered to be Gaussian. The surface roughness model is developed which computes center-line average (R a ) surface roughness. The validity of this model is checked by comparison with the experimental results. A series of numerical experiments are performed using finite-element methods and surface roughness models of the process, to study the effect of flux density, height of working gap, size of magnetic abrasive particles and rotational speed of magnetic pole on the surface quality. Based upon the results, we concluded that R a values of the finished workpiece surface decrease with increase in magnetic flux density, size of magnetic abrasive particles and rotational speed of flexible magnetic abrasive brush. On the other hand, the surface roughness values increase with increase in the working gap.
Keywords:
- Axisymmetric
- Center-line average (CLA)
- Finite difference method
- Finite-element method (FEM)
- Flexible magnetic abrasive brush (FMAB)
- Intensity of magnetic field
- Magnetic potential
- Magnetic abrasive finishing (MAF)
- Magnetic abrasive particle (MAP)
- Modeling
- Nanometer (nm) finish
- Non-uniform surface profile
- Non-conventional finishing
- Parametric analysis
- Roughness model
- Simulation
- Surface roughness
ACKNOWLEDGMENTS
The financial support by the Department of Science and Technology, Government of India, through project number SR/S3/RM/25/2003, for this work is acknowledged. The authors acknowledge the suggestions of Prof. M. Sachchidanand of Electrical Engineering Department, Prof. Deepak Gupta of Materials and Metallurgical Engineering Department and Prof. A. K. Mazumdar of Physics Department, Indian Institute of Technology, Kanpur, during the modeling of the process. The authors acknowledge the help of Ms. Reena Gupta, Mechanical Engineering Department, Indian Institute of Technology, Kanpur, in the preparation of this manuscript.