Magnetic Abrasive Deburring Technology for Blanks

Yuri Mikhailovich Baron

doi:10.4028/www.scientific.net/JERA.25.1

Paper Titles

Magnetic Abrasive Deburring Technology for Blanks
p.1

Optimizing the Friction Welding Process Parameter to Obtain the Maximum Tensile Strength in AA 2024 Grade High Strength Aluminum Alloy Joints
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A Review of Research Processes in the Vortex Pump
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Experimental Analysis of Telescopic Catalytic Converter in a Petrol Engine to Reduce Cold Start Emission
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Selection of a Waste Heat Recovery System for a Marine Diesel Engine Based on Exergy Analysis
p.36

Investigation into Electrical Conductivity of the Multicomponent System of Trackbed
p.52

Effect of Variable Heat Source/Sink on Chemically Reacting 3D Slip Flow Caused by a Slendering Stretching Sheet
p.58

High Frequency Fields of the PEMC Elliptical Reflector Placed in Chiral Medium Using Maslov’s Method
p.70

Analytical Modeling and Optimization of a Solar Chimney Power Plant
p.78

HomeInternational Journal of Engineering Research in...International Journal of Engineering Research in...Magnetic Abrasive Deburring Technology for Blanks

Magnetic Abrasive Deburring Technology for Blanks

Abstract:

Blanks made from sheet steel or other materials have burrs on their edges. The burrs are formed on the blanks at cutting down or processing of them by cutting tools. Removing of the burrs requires a lot of manual work. Frequently the blanks have small rigidity, and it especially complicates removal of the burrs. This article describes intensification of the magnetic abrasive finishing method (MAF) with a goal to eliminate the manual deburring and to raise productivity of deburring on the flexible blanks. The study goal was achieved by optimization of MAF conditions and a of the work area geometrical form.

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International Journal of Engineering Research in Africa (Volume 25)

Pages:

1-10

DOI:

https://doi.org/10.4028/www.scientific.net/JERA.25.1

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Online since:

August 2016

Authors:

Yuri Mikhailovich Baron*

Keywords:

Allowance, Blank, Deburring, Experiment Noncorrosive Steel, Flux Density, High Productivity, Magnetic Abrasive Finishing, Magnetic Abrasive Powder, Movement Speeds, Removing, Work Area Form

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References

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