Parameterized High‐Precision Finite Element Modelling Method of 3D Helical Gears with Contact Zone Refinement

Liu, Yan-Ping; Zhao, Yixuan; Liu, Ming; Sun, Xiaoshuai

doi:10.1155/2019/5809164

Cited by 9 publications

(6 citation statements)

References 28 publications

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“…Hex-dominant is used for model meshing [24], with refinement in specific areas defined as the contact area. Some bearings are involved in the design and will be represented by revolute joints.…”

Section: Finite Element Analysismentioning

confidence: 99%

Evaluating the Gear Stress of Novel Reverse Rotation Bit Manual Screwdriver Design for Miniscrew Implants

Umas

Supriadi²,

Whulanza³

et al. 2021

JMechE

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One of the problems faced by the screwdrivers used for craniomaxillofacial implant fixation is that the maximum torque required for implant removal is significantly higher than the maximum torque needed for inserting implants. Another problem is that the hand torque produced by a right-handed person is lower in the counterclockwise direction, which is the removal direction for miniscrews. The novel design presented here of a manual screwdriver equipped with an epicyclic gear will produce a reverse bit rotation and provide the mechanical advantage of higher torque output. In this study, simulations were conducted by varying the torque input within the range of 0-1000 Nmm with an applied load in each simulation to be adapted based on the epicyclic gear set. The materials used in this study are AISI 316L and Ti6Al4V. The maximum Von Mises stress value was observed in the sun gear from the second gear set at 522.59 MPa (AISI 316L) and 430.76 MPa (Ti6Al4V) for the maximum torque input, which was followed by the planetary and ring gear from the second gear set and then the planetary gear, ring gear, and sun gear from the first gear set. The total deformation also showed the difference between the two materials; the deformation when using AISI 316L as the material was lower than when using Ti6Al4V

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Section: Finite Element Analysismentioning

confidence: 99%

Evaluating the Gear Stress of Novel Reverse Rotation Bit Manual Screwdriver Design for Miniscrew Implants

Umas

Supriadi²,

Whulanza³

et al. 2021

JMechE

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show abstract

“…Another parameterized approach to establish a high precision three-dimension finite element model of involute helical gears is proposed by Liu et.al. [10]. In that study, a refinement methodology of the elements has been developed to improve the mesh quality and accuracy.…”

Section: Introductionmentioning

confidence: 99%

A Modified Approach to the Rack Generation of Beveloid Gears

Şentürk,

Fetvacı

2024

sv-jme

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The purpose of this paper is to present an easier and more efficient method for the determination of the geometry of a bevelled gear tooth. Based on a method that provides an easier way for the rack generation of involute helical gears, the mathematical model of a beveloid gear is studied. The mathematical procedure for developing two-dimensional cross-sections has been extended to three-dimensional gear models. A computer programme is developed to obtain generating and generated surfaces. The proposed algorithm is compared with the previous studies for verification and validation. The results demonstrate that the coordinates obtained from the given method are nearly the same on the start and end points of the main gear parts, such as the involute and root fillets regions. Also, between the limits, the values can be considered acceptable. A coordinate deviation of the gear profile has been observed in the mathematical model, because of the profile shift. Modifications have been developed in the equations to eliminate these cases. The main advantage of the proposed method is to obtain mathematical models without carrying out some of the calculation steps used in previous studies. Eventually, this feature will provide an easier and faster method to develop computer-aided models of the beveloid gear types.

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“…Barbieri et al [33] proposed an adaptive mesh refinement method, which improves the accuracy of threedimensional contact simulation by increasing the local mesh density in the contact area. Similarly, Liu et al [34] proposed a parameterized approach to establish high-precision FE model of a helical gear and then calculated the TVMS and contact stress based on quasistatic analysis. Song et al [35] utilized the FE method to analyze TVMS with varying center distances.…”

Section: Introductionmentioning

confidence: 99%

Analysis of Dynamic Mesh Stiffness and Dynamic Response of Helical Gear Based on Sparse Polynomial Chaos Expansion

et al. 2023

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This paper presents an efficient method for obtaining the dynamic mesh stiffness and dynamic response of a helical gear pair. Unlike the traditional dynamic model that utilizes a time-dependent sequence, the mesh stiffness using the presented method is updated according to the gear displacement vector at each sub-step of the numerical calculation. Three-dimensional loaded tooth contact analysis (3D LTCA) is used to determine the mesh stiffness, and a surrogate model based on sparse polynomial chaos expansion (SPCE) is proposed to improve the computational efficiency, which is achieved by reducing the number of coefficients in the polynomial chaos expansion (PCE) model though a quantum genetic algorithm. During the calculation, the gear displacement vector at each sub-step is converted into the changes in center distance, misalignment angle, and mesh force, which are then introduced into the SPCE model to update the mesh stiffness for subsequent calculations. The results suggest that the SPCE model exhibits high accuracy and can significantly improve the computational efficiency of the PCE model, making it suitable for dynamic calculations. Upon updating the mesh stiffness during the dynamic calculation, the mesh stiffness declines, the dynamic transmission error (DTE) increases, and the frequency components of the responses change significantly.

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Parameterized High‐Precision Finite Element Modelling Method of 3D Helical Gears with Contact Zone Refinement

Cited by 9 publications

References 28 publications

Evaluating the Gear Stress of Novel Reverse Rotation Bit Manual Screwdriver Design for Miniscrew Implants

Evaluating the Gear Stress of Novel Reverse Rotation Bit Manual Screwdriver Design for Miniscrew Implants

A Modified Approach to the Rack Generation of Beveloid Gears

Analysis of Dynamic Mesh Stiffness and Dynamic Response of Helical Gear Based on Sparse Polynomial Chaos Expansion

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