Study on the Performances of the Ferromagnetic Poles Based on the Curved Surface Magnetic Abrasive Finishing

Yan Hong Ding; Xin Gai Yao; Xing Xiang Wang; Shi Chun Yang

doi:10.4028/www.scientific.net/KEM.359-360.365

Paper Titles

Research on Micro-Mechanism of Nanocomposite Ceramic in Two-Dimensional Ultrasound Grinding
p.344

Experimental Study on the Ultraprecision Lapping Technology of the Copper Substrates for Alloy Films
p.349

Influences of Ultrasonic Assistance in High Speed Lapping of Nano ZTA Engineering Ceramic on the Surface Machining Quality
p.355

Electrochemical Grinding for Unclosed Internal Cylinder Surface
p.360

Study on the Performances of the Ferromagnetic Poles Based on the Curved Surface Magnetic Abrasive Finishing
p.365

Basic Experimental Research on the NC-Contour Evolution Ultrasonic Assisted Grinding Ceramic Blade Surface
p.369

Experimental Research on Small Holes by Electrical Discharge Machining Combined with Ultrasonic Vibration and Assisted Inwall Polish with the Ultrasonic Vibrating
p.374

Experimental Study on Lapping Force Characteristics of Hard-Brittle Materials in Ultrasonic Vibration Lapping
p.379

A Mechanistic Model of Material Removal in Magnetorheological Finishing (MRF)
p.384

HomeKey Engineering MaterialsKey Engineering Materials Vols. 359-360Study on the Performances of the Ferromagnetic...

Study on the Performances of the Ferromagnetic Poles Based on the Curved Surface Magnetic Abrasive Finishing

Abstract:

Magnetic abrasive finishing (MAF) is a kind of method for polishing the surfaces and the edges. The investigation for the technique of MAF and the development of the ferromagnetic poles lay a theoretical foundation for developing a new method for finishing the curved surfaces automatically under the numerical control. In the paper, the performance parameters of the developed magneto poles, which are used for finishing the plane surfaces and the curved ones, have been tested. The curvature of the finished surface, the sloping angle of the machined surface and the rotation speed of the poles, which affect the surface roughness, are studied theoretically. What mentioned above supply references to the practical uses of the MAF, especially in the mould manufacturing.

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Periodical:

Key Engineering Materials (Volumes 359-360)

Pages:

365-368

DOI:

https://doi.org/10.4028/www.scientific.net/KEM.359-360.365

Citation:

Cite this paper

Online since:

November 2007

Authors:

Yan Hong Ding, Xin Gai Yao, Xing Xiang Wang, Shi Chun Yang

Keywords:

Curved Surfaces, Ferromagnetic Pole, Magnetic Abrasive Finishing (MAF), Roughness

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[2] 2. 5 0 55 110 165 Finishing Time T(min) Roughness Ra(µm).

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