Characterisation of the wear properties of a single-aggregated cubic boron nitride grain during Ti–6Al–4V alloy grinding

• Published in: Wear Vol. 452-453; p. 203296
• Main Authors: Zhao, Biao, Jiang, Guohua, Ding, Wenfeng, Xiao, Guodong, Huan, Haixiang, Wang, Yang, Su, Honghua
• Format: Journal Article
• Language: English
• Published: Amsterdam Elsevier B.V 15.07.2020; Elsevier Science Ltd
• Subjects: Aggregated cubic boron nitride grains; Cubic boron nitride; Grinding wheels; Grooves; Self-sharpening; Sharpening; Steady wear stage; Three-dimensional reconstruction; Titanium base alloys; Wear rate; Wear volume; Steady wear stage; Self-sharpening; Wear volume; Aggregated cubic boron nitride grains; Three-dimensional reconstruction
• ISSN: 0043-1648; 1873-2577
• DOI: 10.1016/j.wear.2020.203296

Single-grain grinding the Ti–6Al–4V alloys is performed to investigate the wear characteristics and material removal mechanism of aggregated cubic boron nitride (AcBN) grains fabricated by multiple monocrystalline cBN grains. An innovative approach entailing the tracking of grains and scratches by using the 3D reconstruction is proposed to investigate accurately the wear characteristics and material removal ability of such grains. Grain wear, which is affected by grinding wheel speed vs and undeformed chip thickness agmax, is characterised. The variations in grinding force and grinding force ratio, volumetric pile-up ratio and volumetric groove removal rate are also studied. Results show that the as-sintered AcBN grains have better self-sharpening ability, higher grinding ratio, and more stable grain wear rate than the McBN grains. In addition, the wear rate of AcBN grains is more sensible in determining the effect of vs compared with the use of agmax. The AcBN grains attained a higher wear volume (nearly thrice the value), a more stable wear rate and a more stable grinding force ratio when vs increases to 120 m/s as opposed to the other smaller vs values regardless of the agmax values. •Vacuum sintering method is applied to fabricate AcBN grains by utilising McBN grains and inter-abrasive metallic phase.•AcBN grains features a steady micro-wear and multi-wear region attributing to improve the grinding performance.•Wear volume of the AcBN grains at 120 m/s is nearly thrice of that of other smaller grinding wheel speeds.•Grinding efficiency of the AcBN grains evaluated based on the volumetric pile-up ratio appears as a parabola-like curve.