Investigation of Surface Integrity of 304 Stainless Steel in Turning Process with Nanofluid Minimum-Quantity Lubrication Using h-BN Nanoparticles

Metals Pub Date : 2024-05-16 DOI:10.3390/met14050583
Min Fu, G. Xiao, Hui Chen, Jingjie Zhang, M. Yi, Zhaoqiang Chen, Chonghai Xu
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Abstract

This paper investigates the influence of the concentration and particle size of h-BN nanoparticles in a nanofluid on the surface integrity of 304 austenitic stainless steel during turning, focusing on the cutting force, friction coefficient, cutting temperature, surface roughness, surface residual stress, work hardening capacity, and 3D surface topography. The results show that, compared to dry cutting, the addition of 3 wt.% h-BN nanofluid can reduce the friction coefficient on the rake face by 38.9%, lower the cutting temperature by 43.5%, decrease the surface roughness by 53.8%, decrease the surface residual stress by 61.6%, and reduce the work hardening degree by 27.5%. Two-dimensional profiles and the 3D surface topography display a more balanced peak–valley distribution. Furthermore, by studying the effect of different h-BN particle sizes in nanofluids on the surface integrity of the machined workpiece, it was found that nanoscale particles have a greater tendency to penetrate the tool–chip interface than submicron particles. Moreover, the h-BN particles in the nanofluid play a “rolling effect” and “microsphere” effect, and the sesame oil will also form a lubricating oil film in the knife-chip contact area, thereby reducing the friction coefficient, reducing the cutting force, and improving the machining surface quality.
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使用 h-BN 纳米粒子的纳米流体最小量润滑车削过程中 304 不锈钢表面完整性的研究
本文研究了纳米流体中 h-BN 纳米粒子的浓度和粒度对 304 奥氏体不锈钢车削过程中表面完整性的影响,重点关注切削力、摩擦系数、切削温度、表面粗糙度、表面残余应力、加工硬化能力和三维表面形貌。结果表明,与干切削相比,添加 3 wt.% 的 h-BN 纳米流体可使前刀面摩擦系数降低 38.9%,切削温度降低 43.5%,表面粗糙度降低 53.8%,表面残余应力降低 61.6%,加工硬化程度降低 27.5%。二维剖面和三维表面形貌显示出更均衡的峰谷分布。此外,通过研究纳米流体中不同大小的 h-BN 颗粒对加工工件表面完整性的影响,发现纳米级颗粒比亚微米级颗粒更容易穿透工具-芯片界面。此外,纳米流体中的 h-BN 颗粒起到了 "滚动效应 "和 "微球效应",芝麻油也会在刀片接触区形成润滑油膜,从而降低摩擦系数,减少切削力,提高加工表面质量。
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