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http://dx.doi.org/10.12989/amr.2015.4.4.215

Roughness and micro pit defects on surface of SUS 430 stainless steel strip in cold rolling process  

Li, Changsheng (State Key Laboratory of Rolling and Automation, Northeastern University)
Zhu, Tao (State Key Laboratory of Rolling and Automation, Northeastern University)
Fu, Bo (Baosteel Stainless Steel Co. Ltd.)
Li, Youyuan (Baosteel Stainless Steel Co. Ltd.)
Publication Information
Advances in materials Research / v.4, no.4, 2015 , pp. 215-226 More about this Journal
Abstract
Experiment on roughness and micro pit defects of SUS 430 ferrite stainless steel was investigated in laboratory. The relation between roughness and glossiness with reduction in height, roll surface roughness, emulsion parameters was analyzed. The surface morphology of micro pit defects was observed by SEM, and the effects of micro pit defects on rolling reduction, roll surface roughness, emulsion parameters, lubrication oil in deformation zone and work roll diameter were discussed. With the increasing of reduction ratio strip surface roughness Ra(s), Rp(s) and Rv(s) were decreasing along rolling and width direction, the drop value in rolling direction was faster than that in width direction. The roughness and glossiness were obtained under emulsion concentration 3% and 6%, temperature $55^{\circ}C$ and $63^{\circ}C$, roll surface roughness $Ra(r)=0.5{\mu}m$, $Ra(r)=0.7{\mu}m$ and $Ra(r)=1.0{\mu}m$. The glossiness was declined rapidly when the micro defects ratio was above 23%. With the pass number increasing, the micro pit defects were reduced, uneven peak was decreased and gently along rolling direction. The micro pit defects were increased with the roll surface roughness increase. The defects ratio was declined with larger gradient at pass number 1 to 3, but gentle slope at pass number 4 to 5. When work roll diameter was small, bite angle was increasing, lubrication oil in micro pit of deformation zone was decreased, micro defects were decreased, and glossiness value on the surface of strip was increased.
Keywords
stainless steel; cold rolling; lubrication; roughness; micro pit defects;
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