Effects of Physicochemical Properties of Different Base Oils on Friction Coefficient and Surface Roughness in MQL Milling AISI 1045

• Published in: International Journal of Precision Engineering and Manufacturing-Green Technology, 8(6) Vol. 8; no. 6; pp. 1629 - 1647
• Main Authors: Yin, Qingan, Li, Changhe, Dong, Lan, Bai, Xiufang, Zhang, Yanbin, Yang, Min, Jia, Dongzhou, Li, Runze, Liu, Zhanqiang
• Format: Journal Article
• Language: English
• Published: Seoul Korean Society for Precision Engineering 01.11.2021; Springer Nature B.V; 한국정밀공학회
• Subjects: Atomizing; Biodegradability; Biodegradation; Coefficient of friction; Contact angle; Cooling; Energy Efficiency; Engineering; Experiments; Fatty acids; Friction; Industrial and Production Engineering; Lubricants; Lubricating oils; Manufacturing; Milling (machining); Mineral oils; Molecular structure; Palm oil; Peanut oil; Physicochemical properties; Physiochemistry; Regular Paper; Soybeans; Steel; Surface roughness; Surface tension; Sustainable Development; Vegetable oils; Viscosity; Workpieces; 기계공학; Minimum quantity lubrication; Sustainable machining; Different base oil; Physicochemical property; Milling
• ISSN: 2288-6206; 2198-0810
• DOI: 10.1007/s40684-021-00318-7

Minimum quantity lubrication (MQL) is an emerging green and resource-saving machining technique jetting minute amount lubricants and gas after mixing and atomization. However, MQL development is restricted to mineral oils because of its undegradability and threat to the environment and human health. Vegetable oils can replace mineral oils as base oil for MQL benefitting from its biodegradability and renewable property. Nevertheless, the lubrication mechanism at the tool-workpiece interface of different vegetable oils with various physicochemical properties has not been revealed systematically. In order to verify the interfacial lubrication characteristics of different vegetable oils, MQL milling experiments of AISI 1045 based on five vegetable oils (cottonseed, palm, castor, soybean, and peanut oils) were carried out. The experimental results showed that, palm oil obtained the lowest milling force ( F x  = 312 N, F y  = 156 N), friction coefficient (0.78), and surface roughness values ( Ra  = 0.431 μm, RSm  = 0.252 mm) and the smoothest surface of workpiece. Furthermore, the physiochemical properties (composition, molecular structure, viscosity, surface tension, and contact angle) of vegetable oil were analyzed. Palm oil with high content of saturated fatty acid, high viscosity and small contact angle can form the lubricating oil film with the highest strength and the largest spreading area at the tool-workpiece interface. Therefore, palm oil can achieve the optimal lubrication effect.