Gear transmission rattle: Assessment of meshing forces under hydrodynamic lubrication

Rincón, Alfonso Fernández del; Diez-Ibarbia, A.; Theodossiades, Stephanos

doi:10.1016/j.apacoust.2017.04.001

Cited by 28 publications

(10 citation statements)

References 27 publications

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“…Within this framework, the lubricant role is still to be understood, specifically under non-stationary conditions, since only few studies deal with this issue [1,6,7,26,27,28], being this the main goal of the present work, as well as the novelty with respect to the preliminary hydrodynamic force analysis under gear rattle conditions performed in [11]. In this regard, in previous analysis of the authors [11], six hydrodynamic formulations found in literature [29,30,31,32], which consider both squeeze and entraining fluid effects to model the fluid contact in HDL conditions, were implemented in the model developed by the authors [9,12,13] to simulate gear rattle under stationary conditions. Specifically, several mean input velocities were considered in that analysis, obtaining the dynamic response under several torque cases, concluding that, when constant input speed was considered, the wedge term overcomes the squeeze term effect on the dynamic response.…”

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confidence: 99%

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Gear rattle dynamics under non-stationary conditions: The lubricant role

Diez-Ibarbia

Rincón

García

et al. 2020

Mechanism and Machine Theory

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confidence: 99%

“…In order to avoid repetitions with the aforementioned analysis [10,11], only a summary of the lubrication concepts and the dynamic model is described in sections 2 and 3, highlighting the required information for this specific study. Then, the tests set-up and results are discussed in sections 4 and 5 whilst the conclusions are exposed in section 6.…”

mentioning

confidence: 99%

Gear rattle dynamics under non-stationary conditions: The lubricant role

Diez-Ibarbia

Rincón

García

et al. 2020

Mechanism and Machine Theory

Self Cite

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“…Spur gear has been extensively implemented in vehicles, ships, aviation and other fields with its advantages of accurate and stable transmission and high efficiency (Dai et al, 2021;Liu et al, 2020;Mo et al, 2019Mo et al, , 2020a. The state of the tooth surface is one of the key factors that determine lubrication characteristics, load capacity and service life of the gear (Fernandez-Del-Rincon et al, 2019;Lorenz et al, 2021;Simon, 2019;Wang and Zhu, 2021). Generally, gear tooth surface roughness is of the same order of magnitude as the minimum film thickness.…”

Section: Introductionmentioning

confidence: 99%

Effect of micro-textures on lubrication characteristics of spur gears under 3D line-contact EHL model

Zhao

Zhou

et al. 2021

ILT

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Purpose The purpose of this paper is to use a combination of numerical simulation and experiment to evaluate the performance of laser surface texturing (LST) in the field of gear lubrication, and to more accurately predict the lubrication characteristics of different surfaces. Design/methodology/approach The method used in this paper is developed on the basis of the deterministic solution of the three-dimensional (3D) mixed elasto-hydrodynamic lubrication (EHL) model and the model parameters are corrected by friction test. The film pressure, film thickness and friction coefficient of different micro-textured tooth surfaces are predicted on the basis of accurate 3D mixed EHL models. Findings The results demonstrate that the micro-texture structure of the tooth surface can increase the local film thickness and enhance the lubricating performance of the tooth surface without drastically reducing the contact fatigue life. The stress distribution and friction characteristics of the tooth surface can be optimized by adjusting the micro-texture arrangement and the size of the micro-textures. Originality/value A new evaluation method using a 3D hybrid EHL model and friction test to predict the lubrication characteristics of LST is proposed, which can effectively improve the processing economy and save time. Peer review The peer review history for this article is available at: https://publons.com/publon/10.1108/ILT-11-2020-0423

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“…According to the literature reviewed, there are two kinds of noise emitted from the automotive gearbox, namely, gear rattle noise and gear whine noise. Gear rattle noise is generally caused by fluctuations in the engine torque and speed [1][2][3][4], which usually lead to contact loss and impacts between lightly loaded mating gears. Gear rattle noise also has a close relationship with lubricant conditions [5][6][7].…”

Section: Introductionmentioning

confidence: 99%

Classifying, Predicting, and Reducing Strategies of the Mesh Excitations of Gear Whine Noise: A Survey

Sun

Liu

et al. 2020

Shock and Vibration

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Gear whine noise has attracted increasing attention from researchers in both the academe and the industry over the past two decades. The wide range of research topics demonstrates that there is a huge technical challenge in understanding the source-path-receiver mechanisms deeply and predicting the gear whine noise precisely. Thoroughly understanding the sources of gear whine noise is the first step to solving this issue. In this paper, the authors summarize a certain number of published articles regarding the sources of gear whine noise. The excitations of gear whine noise are classified into three groups: transmission error along the line of action direction, frictional excitations along the off-line of action direction, and shuttling excitation along the axial direction. The mechanisms, characteristics, predicting approaches, measuring methods, and decreasing strategies for these excitations are summarized. Current research characteristics and future research recommendations are presented at the end.

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Gear transmission rattle: Assessment of meshing forces under hydrodynamic lubrication

Cited by 28 publications

References 27 publications

Gear rattle dynamics under non-stationary conditions: The lubricant role

Gear rattle dynamics under non-stationary conditions: The lubricant role

Effect of micro-textures on lubrication characteristics of spur gears under 3D line-contact EHL model

Classifying, Predicting, and Reducing Strategies of the Mesh Excitations of Gear Whine Noise: A Survey

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