A novel media properties-based material removal rate model for magnetic field-assisted finishing

Page view(s)
13
Checked on Nov 30, 2022
A novel media properties-based material removal rate model for magnetic field-assisted finishing
Title:
A novel media properties-based material removal rate model for magnetic field-assisted finishing
Other Titles:
International Journal of Mechanical Sciences
Publication Date:
04 April 2018
Citation:
Chun Wai Kum, Takashi Sato, Jiang Guo, Kui Liu, David Butler, A novel media properties-based material removal rate model for magnetic field-assisted finishing, International Journal of Mechanical Sciences, Volume 141, 2018, Pages 189-197, ISSN 0020-7403, https://doi.org/10.1016/j.ijmecsci.2018.04.006.
Abstract:
Magnetic field assisted finishing (MFAF) is a category of non-conventional finishing processes that use magnetic field to manipulate finishing media typically consisting of magnetic particles and non-magnetic abrasives suspended in a carrier fluid. In order to better control the process, an improved understanding of the actual removal process is needed. This paper introduces a new material removal rate model for magnetic field-assisted finishing (MFAF) that aims to do so. The model considers the complexity of finishing media used in MFAF processes, where two different types of particles are present and interact with each other. The proposed material removal rate expression is based on contact mechanics and is a function of number of active magnetic particles, number of active abrasives, force per magnetic particle, and force per abrasive. Expressions for particle numbers were developed by considering an ideal face-centred cubic configuration for the magnetic particle network, while expressions for forces were developed based on a proposed framework for the particle interactions. The model was verified experimentally for a double-magnet MFAF process by varying the abrasive size and abrasive concentration. When the abrasive size was increased from 0.6 μm to 15 μm, the material removal rate decreased, consistent with the theoretical trend given by the model. Then, when abrasive concentration, given by the abrasives-to-carbonyl-iron volumetric ratio, was increased from 0 to 0.768, the material removal rate initially increased and then reached a maximum when the volume ratio is 0.259 before decreasing with further increase of the volume ratio. This is also in agreement with the theoretical trend given by the model.
License type:
http://creativecommons.org/licenses/by-nc-nd/4.0/
Funding Info:
Description:
ISSN:
0020-7403
Files uploaded:

File Size Format Action
manuscript-v024-cw-afterreview.pdf 1,000.58 KB PDF Open