Improving the wear resistance of 3D printed spur gears through a free-form tooth flank optimization process

Christos Kalligeros, Christos Papalexis, Dimitrios Georgiou, Dimitrios Krifos, Christos Vakouftsis, Klearchos Terpos, Konstantinos Goudas, Panagiotis Balis, Theodoros Kontaris, Georgios Kaisarlis, Antonios Tsolakis, Pavlos Zalimidis, Nickolas Sapidis, Christopher G. Provatidis, Vasilios Spitas
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Abstract

Involute gears have traditionally been the preferred choice for gear transmission systems due to their simplicity and interchangeability. However, there are applications where they do not provide the most durable and efficient solution. While the cost of implementing optimized non-involute gears in most applications often outweighs their comparative advantages, the advent of additive manufacturing has opened up possibilities for designers to explore alternative gear tooth profiles. This is particularly relevant in the realm of plastic gears, where optimized non-involute gears produced through 3D printing can address their primary drawbacks, such as surface durability and wear resistance. In this study, a comprehensive free-form optimization process was conducted to determine the optimal tooth profile that minimizes wear on 3D printed spur gears during operation. The tooth flank geometry was represented using a 4th order B-spline curve, and a genetic algorithm was employed to determine the optimum positions of the control points aiming to minimize wear depth across the tooth flanks. The spur gears were manufactured using Fused Deposition Modeling (FDM) with PLA material. The parameters of the additive manufacturing process were experimentally fine-tuned to achieve the best possible accuracy. To evaluate the performance of the optimized free-form gears, two case studies were implemented, demonstrating that the optimized gears achieved a remarkable reduction of average wear depth by more than 50% and a reduction of maximum wear depth by more than 69% compared to standard involute gears. To further validate the effectiveness of the optimization method, experiments were carried out using an FZG test rig. The profiles of the tooth flanks were measured on a Coordinate Measuring Machine (CMM) before and after the experiments to compare the wear depth against the standard involute gears. The results revealed a significant improvement in the wear resistance of the tooth flanks, with a reduction of wear depth of 44.1%.
通过自由齿面优化工艺提高3D打印直齿齿轮的耐磨性
渐开线齿轮传统上是齿轮传动系统的首选,因为它们的简单性和互换性。然而,在某些应用程序中,它们不能提供最持久和最有效的解决方案。虽然在大多数应用中实施优化的非渐开线齿轮的成本通常超过其相对优势,但增材制造的出现为设计人员探索替代齿轮齿形开辟了可能性。这在塑料齿轮领域尤其重要,通过3D打印生产的优化非渐开线齿轮可以解决其主要缺点,例如表面耐久性和耐磨性。在这项研究中,进行了一个全面的自由形状优化过程,以确定最佳的齿形,以最大限度地减少3D打印正齿轮在运行过程中的磨损。采用4阶b样条曲线表示齿面几何形状,并采用遗传算法确定控制点的最佳位置,以最小化齿面磨损深度。采用聚乳酸(PLA)材料的熔融沉积建模(FDM)技术制造正齿轮。通过实验对增材制造工艺参数进行微调,以达到最佳精度。为了评估优化后的自由形齿轮的性能,实施了两个案例研究,表明优化后的齿轮与标准渐开线齿轮相比,平均磨损深度降低了50%以上,最大磨损深度降低了69%以上。为了进一步验证优化方法的有效性,在FZG试验台上进行了实验。实验前后在三坐标测量机上测量齿侧轮廓,与标准渐开线齿轮的磨损深度进行比较。结果表明,齿侧的耐磨性得到了显著提高,磨损深度降低了44.1%。
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来源期刊
自引率
0.00%
发文量
342
审稿时长
6 weeks
期刊介绍: MATEC Web of Conferences is an Open Access publication series dedicated to archiving conference proceedings dealing with all fundamental and applied research aspects related to Materials science, Engineering and Chemistry. All engineering disciplines are covered by the aims and scope of the journal: civil, naval, mechanical, chemical, and electrical engineering as well as nanotechnology and metrology. The journal concerns also all materials in regard to their physical-chemical characterization, implementation, resistance in their environment… Other subdisciples of chemistry, such as analytical chemistry, petrochemistry, organic chemistry…, and even pharmacology, are also welcome. MATEC Web of Conferences offers a wide range of services from the organization of the submission of conference proceedings to the worldwide dissemination of the conference papers. It provides an efficient archiving solution, ensuring maximum exposure and wide indexing of scientific conference proceedings. Proceedings are published under the scientific responsibility of the conference editors.
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