Your search keyword '"edge effect factor"' showing total 2 results

1. Edge effect factor affecting the tribological properties in water of protrusion surface textures on stainless steel

Author

Xingyang Wu, Zhou Ge, Haozhi Niu, Jingjie Ruan, and Jianhua Zhang

Subjects

stress analysis, stainless steel, lubricants, surface texture, wear, sliding friction, lubrication, mechanical contact, edge profiling, edge effect factor, tribological properties, protrusion surface textures, normally textured patterns, stress concentration, nonconformal contacting pairs, protrusion-type textures, stainless steel discs, protrusions, friction tests, wedge contact, normally textured pairs, friction reduction effect, area ratios, area ratio, sliding, lubricant supply, contact interfaces, Biotechnology, TP248.13-248.65, Biochemistry, QD415-436

Abstract

Surface textures have been demonstrated to have a positive effect on the friction reduction. However, sharp edges of the normally textured patterns usually cause stress concentration and severe wear during sliding, especially for non-conformal contacting pairs. In this study, protrusion-type textures were fabricated at different area ratios on stainless steel discs and edge profiling was performed for the protrusions, and friction tests were conducted in water to investigate the tribological properties. The results show that the friction was reduced markedly by edge profiling due to the formation of wedge contact and improvement of lubricant supply to the contact interfaces under low load. Under high load, severe wear destroyed the wedge contact resulting in high friction as those of the normally textured pairs. High area ratio exhibited better friction reduction effect. The stress analysis via ANSYS indicated that much high stress concentrated at the edges of the protrusions and could be reduced significantly by edge profiling.

Published

2018

2. Edge effect factor affecting the tribological properties in water of protrusion surface textures on stainless steel

Author

Zhou Ge, Xingyang Wu, Niu Haozhi, Jingjie Ruan, and Zhang Jianhua

Subjects

business.product_category, sliding, 02 engineering and technology, Surface finish, contact interfaces, surface texture, 0203 mechanical engineering, lcsh:QD415-436, Lubricant, Composite material, protrusion-type textures, lubrication, Stress concentration, friction tests, protrusions, 021001 nanoscience & nanotechnology, Wedge (mechanical device), Surfaces, Coatings and Films, 020303 mechanical engineering & transports, Lubrication, stress analysis, edge profiling, 0210 nano-technology, wear, Materials science, lcsh:Biotechnology, Biomedical Engineering, Biophysics, Edge (geometry), friction reduction effect, lcsh:Biochemistry, Biomaterials, Stress (mechanics), sliding friction, normally textured pairs, area ratios, lcsh:TP248.13-248.65, stainless steel discs, stainless steel, stress concentration, mechanical contact, protrusion surface textures, Mechanical Engineering, tribological properties, lubricant supply, normally textured patterns, area ratio, Tribology, lubricants, edge effect factor, wedge contact, nonconformal contacting pairs, business, human activities

Abstract

Surface textures have been demonstrated to have a positive effect on the friction reduction. However, sharp edges of the normally textured patterns usually cause stress concentration and severe wear during sliding, especially for non-conformal contacting pairs. In this study, protrusion-type textures were fabricated at different area ratios on stainless steel discs and edge profiling was performed for the protrusions, and friction tests were conducted in water to investigate the tribological properties. The results show that the friction was reduced markedly by edge profiling due to the formation of wedge contact and improvement of lubricant supply to the contact interfaces under low load. Under high load, severe wear destroyed the wedge contact resulting in high friction as those of the normally textured pairs. High area ratio exhibited better friction reduction effect. The stress analysis via ANSYS indicated that much high stress concentrated at the edges of the protrusions and could be reduced significantly by edge profiling.

Published

2018