Optimizing rock breaking performance: The influence of chamfer on polycrystalline diamond compact (PDC) cutters

Advances in Production Engineering & Management Pub Date : 2023-12-28 DOI:10.14743/apem2023.4.482

P. Ju

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Abstract

Research on the rock-breaking performance of the Polycrystalline Diamond Compact (PDC) cutter has primarily focused on sharp cutters, often overlooking the influence of chamfer. Notably, the design of chamfer parameters has been largely unreported. In this study, we established a theoretical model of cutting force that takes chamfer into account. We analysed the primary and secondary relationships of four factors – back rake angle, depth of cut, chamfer angle, and chamfer length – on the force of the PDC cutter. This was done through a pseudo-level orthogonal level test. A numerical simulation, based on the Smooth Particle Hydrodynamic (SPH) method, was conducted to analyse the rock-breaking force and stress distribution characteristics of PDC cutters with different chamfer angles. Combined with a drop hammer impact test, we provided an optimized design of chamfer parameters. Our findings revealed that while the chamfer had a relatively minor influence on the force of the PDC cutter, it contributed to the optimal distribution of stress on the PDC cutter. This effectively protected the cutting edge and prevented early cracks and spalls of the cutter. When the chamfer angle was less than or equal to the back rake angle, the resultant force of the PDC cutter increased with the increase of the chamfer angle. However, when the chamfer angle was greater than the back rake angle, the resultant force of the PDC cutter first increased and then slightly decreased with the increase of the chamfer angle. Additionally, the resultant force of the PDC cutter increased approximately linearly with the increase of chamfer length. When the chamfer angle of the PDC cutter was between 30° and 45°, the fluctuation of the cutting force was relatively smooth, the rock-breaking process was stable, and the cutter’s impact resistance energy was relatively higher. These findings will provide valuable guidelines for the design of chamfered PDC cutters.

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优化岩石破碎性能：倒角对聚晶金刚石铣刀（PDC）的影响

有关聚晶金刚石（PDC）铣刀破岩性能的研究主要集中在锋利的铣刀上，往往忽略了倒角的影响。值得注意的是，倒角参数的设计在很大程度上未见报道。在这项研究中，我们建立了一个将倒角考虑在内的切削力理论模型。我们分析了后倾角、切削深度、倒角角度和倒角长度这四个因素对 PDC 切削力的主次关系。这是通过伪水平正交水平测试完成的。基于平滑粒子流体力学（SPH）方法进行了数值模拟，分析了不同倒角的 PDC 刀盘的破岩力和应力分布特征。结合落锤冲击试验，我们对倒角参数进行了优化设计。我们的研究结果表明，虽然倒角对 PDC 刀盘力的影响相对较小，但它有助于优化 PDC 刀盘的应力分布。这有效地保护了切削刃，防止了切削刃出现早期裂纹和剥落。当倒角小于或等于后倾角时，随着倒角的增大，PDC 切割器的作用力也随之增大。然而，当倒角大于后倾角时，随着倒角的增大，PDC 切割器的作用力先是增大，然后略有减小。此外，PDC 切割器的结果力随着倒角长度的增加而近似线性增加。当 PDC 切割器的倒角在 30° 至 45° 之间时，切割力的波动相对平稳，岩石破碎过程稳定，切割器的抗冲击能量相对较高。这些发现将为倒角 PDC 刀盘的设计提供有价值的指导。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Advances in Production Engineering & Management

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