It is often desired to increase the machining rate while maintaining the desired surface and subsurface integrity during fabricating high-quality optical glass components. This paper proposed a high-speed high-efficiency low-damage grinding technology for machining brittle optical materials, which consists of three grinding processes: rough grinding, semi-finishing grinding and finishing grinding. Grinding characteristics is investigated with respect to grinding forces, specific cutting energy, surface roughness, ground surface quality, subsurface damage, and material removal mechanisms in grinding of fused silica optical glasses with this technology at the grinding speeds of up to 150 m/s. These indications are thoroughly discussed by contacting the undeformed chip thickness. The results indicate that the level of these indications are significantly improved with an increase in the wheel speed due to the decrease of the undeformed chip thickness. It is also found that the improvement of ground surface quality is limited when the wheel speed from 120 m/s increases to 150 m/s may be due to the influence of vibration caused by the higher wheel speed. For different grinding processes, these results are also substantially improved with the change of grinding conditions. It is found that the material removal mechanism is dominated by brittle fracture at rough and semi-finishing grinding processes, while ductile flow mode can be observed at the finishing grinding process. There are some differences between the experimental results and the previous predicted model of subsurface damage depth.
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机译:在制造高质量的光学玻璃组件的过程中,经常需要在保持所需的表面和亚表面完整性的同时提高加工速度。本文提出了一种用于加工脆性光学材料的高速高效低损伤磨削技术,该技术包括粗磨,半精磨和精磨三种磨削工艺。在以高达150 m / s的磨削速度磨削熔融石英光学玻璃的过程中,研究了磨削特性,涉及磨削力,比切削能,表面粗糙度,地面质量,亚表面损伤以及材料去除机理。通过接触未变形的切屑厚度来彻底讨论这些指示。结果表明,由于未变形切屑厚度的减小,随着轮速的增加,这些指示的水平得到了显着改善。还发现,当车轮速度从120 m / s增加到150 m / s时,地表质量的改善受到限制,这可能是由于较高车轮速度引起的振动的影响。对于不同的研磨工艺,随着研磨条件的改变,这些结果也得到了显着改善。发现在粗磨和半精磨过程中,材料的去除机理主要是脆性断裂,而在精磨过程中可以观察到韧性流动模式。实验结果与以前的地下破坏深度预测模型之间存在一些差异。
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