增材制造高传动比同轴齿轮箱的概念研究

IF 0.8 Q4 ROBOTICS
Philipp Eisele, Sajid Nisar, Franz Haas
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引用次数: 0

摘要

这项研究介绍了新颖的 "Kraken-Gear "机构,强调了增材聚合物三维打印技术在轻型机器人应用(如手术器械)的高传动比齿轮箱系统中的优势。创新的运动学解决方案提供了高扭转系统刚度、大齿轮比和无间隙传动。利用 "热光刻 "快速成型制造方法,可确保齿轮箱部件精确无翘曲。齿轮箱以医疗技术为目标,满足了严格的要求:无间隙、振动小、精度高、扭矩大、重量轻,符合人体工程学的舒适性和减轻疲劳。计算模拟对力和应力进行了评估,凸显了增材制造在成本效益和功能效率方面的潜力。尽管如此,为实现最佳功能,尤其是在要求苛刻的医疗应用中,谨慎选择材料仍是当务之急。总之,这项研究强调了一种很有前景的齿轮箱制造方法,强调了材料选择和基于模拟的评估对实现最佳性能的关键作用。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
A conceptual examination of an additive manufactured high-ratio coaxial gearbox

This research introduces the novel “Kraken-Gear” mechanism, emphasizing the advantages of additive polymer 3D printing in high-ratio gearbox systems for lightweight robotic applications, such as surgical instruments. The innovative kinematic solution provides high torsional system stiffness, substantial gear ratios, and backlash-free transmission. Leveraging the “hot lithography” additive manufacturing method ensures precise and warp-free gearbox components. Targeting medical technology, the gearbox meets stringent requirements: backlash-free, minimal vibration, high precision, and torque, with minimized weight for ergonomic comfort and fatigue mitigation. Computational simulations assess forces and stresses, highlighting the potential of additive manufacturing for cost-effective and functionally efficient gearbox fabrication. Nevertheless, careful material selection remains imperative for optimal functionality, especially in demanding medical applications. In summary, this research underscores a promising approach to gearbox fabrication, emphasizing the critical role of material selection and simulation-based assessments for optimal performance.

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来源期刊
CiteScore
2.00
自引率
22.20%
发文量
101
期刊介绍: Artificial Life and Robotics is an international journal publishing original technical papers and authoritative state-of-the-art reviews on the development of new technologies concerning artificial life and robotics, especially computer-based simulation and hardware for the twenty-first century. This journal covers a broad multidisciplinary field, including areas such as artificial brain research, artificial intelligence, artificial life, artificial living, artificial mind research, brain science, chaos, cognitive science, complexity, computer graphics, evolutionary computations, fuzzy control, genetic algorithms, innovative computations, intelligent control and modelling, micromachines, micro-robot world cup soccer tournament, mobile vehicles, neural networks, neurocomputers, neurocomputing technologies and applications, robotics, robus virtual engineering, and virtual reality. Hardware-oriented submissions are particularly welcome. Publishing body: International Symposium on Artificial Life and RoboticsEditor-in-Chiei: Hiroshi Tanaka Hatanaka R Apartment 101, Hatanaka 8-7A, Ooaza-Hatanaka, Oita city, Oita, Japan 870-0856 ©International Symposium on Artificial Life and Robotics
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