Influence of 3D modification on dynamic characteristics of herringbone gearbox system and vibration reduction design

Li, Zhibin; Wang, Sanmin; Li, Fei; Li, Linlin; Liu, Linlin; Zou, Haoran

doi:10.1177/14644193221107483

Cited by 2 publications

(1 citation statement)

References 26 publications

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“…According to the actual working conditions and bearing capacity, the tooth surface of herringbone gear can be modified to achieve 3D modification (tooth profile and axial) from a micro perspective. 28 Through the 3D modification, the impact and vibration caused by the STE can be reduced. It also can avoid partial load, improve bearing capacity, lubrication state of tooth surface when meshing and anti-gluing ability, and reduce relative sliding rate of tooth surface.…”

Section: Tooth Surface Modification Methodsmentioning

confidence: 99%

Study on nonlinear dynamic characteristics of power six-branch herringbone gear transmission system with 3D modification

Wang

2023

Proceedings of the Institution of Mechanical Engineers, Part K:

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The power six-branch herringbone gear transmission system has the advantages of large power transmission and transmission ratio. Because of its multi-way transmission and over-constraint structure, to prevent loaded tooth interference, there are large backlashes between teeth. The system shows complex nonlinear dynamic characteristics under the influence of backlashes, which seriously affects meshing performance. The modification technology can effectively improve gear meshing performance. Hence, on the basis of optimizing meshing performance of the active pair of the six-branch herringbone gear transmission system, this article will combine 3D modification with system nonlinear vibration characteristics and propose an analysis method of the system nonlinear vibration characteristics under 3D modification to reduce vibration and noise. First, the 3D modified tooth surface equation is determined by forming grinding, the loaded transmission error (LTE) of the system's active pair is obtained by tooth contact analysis (TCA) and loaded tooth contact analysis (LTCA) technology, and the optimal modification parameters are obtained by Ant Lion Optimizer (ALO) with the minimum error amplitude as optimization objective. Then, the time-varying meshing stiffness of system under the optimal modification is calculated, and the pure torsional nonlinear dynamic model with backlashes, meshing stiffness, and static transmission error (STE) is established. Finally, the global vibration characteristics in parameter field are studied through time domain and bifurcation diagram of system. Results show that the 3D modification can eliminate edge contact of tooth and improve tooth contact performance. With the increase of input power, the root mean square (RMS) values of acceleration increase and the RMS values and jump decrease after 3D modification. With the increase of input speed, the RMS curves appear multiple resonance peaks and jumps at low input speed. After 3D modification, the RMS, jump, and resonance peak values decrease. Compared with level І, the backlashes and STEs of level II and phase difference ϛsII have great influence on system dynamic characteristics and easily make system in chaotic motion, while the 3D modification reduces their influence and makes system motion periodic.

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Section: Tooth Surface Modification Methodsmentioning

confidence: 99%

Study on nonlinear dynamic characteristics of power six-branch herringbone gear transmission system with 3D modification

Wang

2023

Proceedings of the Institution of Mechanical Engineers, Part K:

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Optimization Design of Phononic Crystals Based on BPNN‐MPA in Applied Mathematical Analysis

2024

Journal of Applied Mathematics

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Traditional finite element analysis methods have the problem of expensive and unstable band structure diagram calculation when generating phononic crystals. Therefore, this study combines back propagation neural networks with ocean predator algorithms to optimize the geometric structure of phononic crystals. The results show that the coefficient of determination for the predicted bandgap width and lower bound of Model 3 is 1.00, which is better than the comparison model. However, Models 2 and 5 have poor predictive performance for bandgap width due to overfitting during actual training. Therefore, after using the ocean predator algorithm for hyperparameter adjustment, it is found that the maximum number of failures in the validation set of Model 5 is 30, the number of hidden layer nodes is 30, and after 500 experiments, the average error of the bandgap width is 5.26%, and the average error of the lower bound of the bandgap is 1.33%. The average error of the bandgap width after hyperparameter adjustment is 4.89%, and the average error of the lower bound of the bandgap is 1.21%, both of which are effectively reduced and better than the comparison model. Overall, the combination model has high computational efficiency and stability in phononic crystal optimization and can be practically applied in the design and optimization of phononic crystal geometric structures.

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Influence of 3D modification on dynamic characteristics of herringbone gearbox system and vibration reduction design

Cited by 2 publications

References 26 publications

Study on nonlinear dynamic characteristics of power six-branch herringbone gear transmission system with 3D modification

Study on nonlinear dynamic characteristics of power six-branch herringbone gear transmission system with 3D modification

Optimization Design of Phononic Crystals Based on BPNN‐MPA in Applied Mathematical Analysis

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