Investigation of Moving Load Distribution with the Effect of LDR and LSR on Three-dimensional Fatigue Fracture Behavior of Spur Gear Drive

IF 1.9 4区 工程技术 Q2 Engineering International Journal of Precision Engineering and Manufacturing Pub Date : 2024-07-26 DOI:10.1007/s12541-024-00983-z
N. Gnanasekar, Rama Thirumurugan, M. Jayaraj, N. Manikandan, N. Nagaprasad, Krishnaraj Ramaswamy
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Abstract

The tooth fracture failure modes in the spur gear tooth root are mainly influenced by the magnitude and positions of bending fatigue load along the gear face width. Numerous studies in the literature used 3D finite element (FE) models to analyze crack propagation, but they did not take into account the effect of the load distribution ratio (LDR) throughout the gear face width, either in a moving load model or a uniform load model. In this study, an effort is made to investigate the impact of LDR and Load Sharing Ratio (LSR) in the modeling of moving loads for various loading positions and measure the actual crack propagation behavior of a spur gear with a root fracture using the 3D FE technique. Further, the influences of FE spur gear models on the variation of Actual Load Distribution with the effect of LSR, Stress Intensity Factors (SIFs), and crack propagation paths are also studied. A 3D FE crack propagation modeling procedure is validated with the experimental results of the SAEJ1619 fatigue test procedure. The experimental investigation using standard SAEJ1619 fatigue test procedure shows that the symmetric crack propagation failure at the crack front of the spur gear tooth was observed for a given uniform bending fatigue load. The results show that the mode I SIFs (KI) and mode II SIFs (KII) are dominant at the crack opening displacement for the positions of moving load between the Highest Point of Single Tooth Contact (HPSTC) and Highest Point of Tooth Contact (HPTC) lines. But, the KII is highly influenced by KI for further crack growth when the load is moved to the HPSTC line than the HPTC line. This study provides the guidelines to predict the actual crack propagation path failure behavior for various positions of moving load for various gear drive systems with root crack.

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研究移动载荷分布与 LDR 和 LSR 对正齿轮传动装置三维疲劳断裂行为的影响
正齿轮齿根的断齿失效模式主要受沿齿面宽度的弯曲疲劳载荷大小和位置的影响。大量文献研究使用三维有限元(FE)模型分析裂纹扩展,但无论是在移动载荷模型还是均匀载荷模型中,都没有考虑整个齿轮面宽度上载荷分配比例(LDR)的影响。在本研究中,我们努力研究 LDR 和负载分担比 (LSR) 在不同加载位置的移动负载模型中的影响,并使用三维 FE 技术测量具有根部断裂的直齿轮的实际裂纹扩展行为。此外,还研究了 FE 正齿轮模型对实际载荷分布变化的影响,以及 LSR、应力强度因子 (SIF) 和裂纹扩展路径的影响。三维 FE 裂纹扩展建模程序与 SAEJ1619 疲劳测试程序的实验结果进行了验证。使用标准 SAEJ1619 疲劳测试程序进行的实验研究表明,在给定的均匀弯曲疲劳载荷下,在正齿轮齿的裂纹前端观察到了对称裂纹扩展失效。结果表明,在单齿接触最高点(HPSTC)和齿接触最高点(HPTC)线之间的移动载荷位置,模式 I SIF(KI)和模式 II SIF(KII)在裂纹开口位移处占主导地位。但是,当载荷移动到 HPSTC 线比 HPTC 线时,KII 受 KI 的影响较大,从而影响裂纹的进一步增长。这项研究为预测带有根部裂纹的各种齿轮传动系统在不同移动载荷位置下的实际裂纹扩展路径失效行为提供了指导。
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来源期刊
CiteScore
4.10
自引率
10.50%
发文量
115
审稿时长
3-6 weeks
期刊介绍: The International Journal of Precision Engineering and Manufacturing accepts original contributions on all aspects of precision engineering and manufacturing. The journal specific focus areas include, but are not limited to: - Precision Machining Processes - Manufacturing Systems - Robotics and Automation - Machine Tools - Design and Materials - Biomechanical Engineering - Nano/Micro Technology - Rapid Prototyping and Manufacturing - Measurements and Control Surveys and reviews will also be planned in consultation with the Editorial Board.
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