A Method to Derive Friction and Rolling Power Loss Formulae for Mixed Elastohydrodynamic Lubrication

Li, Sheng; Kahraman, Ahmet

doi:10.1299/jamdsm.5.252

Cited by 39 publications

(11 citation statements)

References 17 publications

(37 reference statements)

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“…The changes in the normal load were captured via a gear load distribution model while the changes in rolling and sliding velocities were calculated by using the involute geometry. As this method is rather computationally demanding, an alternate method of developing closed-form friction formulae up front by regression of a larger number of EHL analyses covering proper ranges of contact parameter for gears (Xu et al (2007), Li and Kahraman (2011)). The same approach was used by Talbot and Kahraman (2014) which was shown to agree with their earlier experiments (Talbot et al (2012)) well.…”

Section: Mechanical Power Loss Models 241 Gear Mesh Mechanical Powementioning

confidence: 99%

“…Here κλ μ is the sliding friction coefficient defined for a typical automatic transmission fluid in the manner of Li and Kahraman (2011) …”

Section: Mechanical Power Loss Models 241 Gear Mesh Mechanical Powementioning

confidence: 99%

“…Here, such a power flow formulation will be combined with EHL based power loss models of gear meshes and planet bearings to predict mechanical losses of planetary gear trains of automatic transmissions Mechanical power loss models for gears and gear trains can be divided into two distinct categories, the first addresses the power losses in simple gear systems like a pair of gears in mesh or a single planetary gear stage. These models may utilize an empirical friction coefficient as reviewed in Martin (1978) or utilize physics-based models to calculate power losses (Xu et al (2007), Li and Kahraman (2010), Li and Kahraman (2011)). The second category of studies utilize a kinematics argument to obtain the power loss or efficiency in complex gear trains by utilizing an assumed gear mesh efficiency value for the individual meshes (Pennestri andFreudenstein (1993), del Castillo (2002), Chen and Angeles (2011)).…”

Section: Introductionmentioning

confidence: 99%

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Modelling of steady-state mechanical power losses in planetary gear trains of automatic transmissions

Janakiraman

Kahraman

Talbot

2017

JAMDSM

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In this study, steady-state mechanical power loss model of an automatic transmission gear train consisting of multiple stages of planetary gear sets is developed. Load dependent (mechanical) power losses at the internal (ring-planet) and external (sun-planet) gear meshes and planet bearing interfaces are included through elastohydrodynamic lubrication (EHL) based power loss formulations. At the end, efficiency of an 8-speed automatic transmission is studied under representative operating conditions to quantify the contribution of various loss mechanisms to the total loss under variable speed, load and temperature conditions. Impact of gear surface roughness amplitudes on the resultant power losses is also described. Keywords

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Section: Mechanical Power Loss Models 241 Gear Mesh Mechanical Powementioning

confidence: 99%

“…Here κλ μ is the sliding friction coefficient defined for a typical automatic transmission fluid in the manner of Li and Kahraman (2011) …”

Section: Mechanical Power Loss Models 241 Gear Mesh Mechanical Powementioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Modelling of steady-state mechanical power losses in planetary gear trains of automatic transmissions

Janakiraman

Kahraman

Talbot

2017

JAMDSM

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“…In addition, the lubricants used are not representative of a wind turbine gearbox lubricant. The VG for the oils used in previous studies is too low (less than 120 mm 2 /s and less than 27.6 mm 2 /s at 40°C, respectively, for the automotive and aerospace lubricants) to allow film‐forming capabilities at the Hertzian region of the rolling‐sliding contacts in wind turbine gearboxes. In fact, He et al recently presented friction test data for a gear oil Mobil 600 XP 68 whose dynamic viscosity at oil temperature of 40°C 0.0597 Pa·s is similar to that of SAE 75W90.…”

Section: Introductionmentioning

confidence: 99%

“…For example, the prediction of mechanical power loss of a gear pair using a numerical EHD model will require several hundreds of EHD analyses of the defined gear pair. To circumvent this issue, Xu et al 17 and Li and Kahraman 34 have used smooth contact and mixed EHD lubrication theory to derive friction coefficient formulae for automotive (SAE 75W90) and aerospace (Mil-L23699) lubricants, respectively. Recently, Masjedi and Khonsari 35 used a line-contact EHD methodology to derive a curve fit formula for predicting friction coefficients in a rough EHD line-contact lubricated with a nondetergent SAE 30.…”

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confidence: 99%

An experimental characterization of the friction coefficient of a wind turbine gearbox lubricant

2019

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In this study, a method to predict the contact friction coefficients at the rolling‐sliding contacts of isotropic superfinished and axially ground gear and bearing surfaces in wind turbine gearboxes is proposed. A two‐disc test rig was used to measure friction coefficient values within a slide‐to‐roll ratio range of −0.8 to 0.8, rolling velocities of 2 to 12 m/s, at oil temperatures of 50°C, 70°C, and 100°C and Hertzian contact pressures of 1.2, 1.6, and 2.0 GPa. A polyalphaolefin (PAO) International Standards Organization (ISO) viscosity grade (VG) 320 was the lubricant. Data from 90 individual friction coefficient tests were combined to develop two closed‐form friction coefficient formulae. A multivariable linear regression analysis was used to derive the regressed formulae. Using the developed regressed formulae, the predicted friction values follow the trend of measured values at all of the operating conditions. The results show that the regressed formulae are close to experimental friction coefficient values. The friction coefficient predictions confirm that the regressed formulae are capable of simulating contact friction values for the lubricated contact conditions considered.

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Lubrication mechanisms of rubbing interface in internal meshing teeth with small clearance

Ren

Zhang

Yang

et al. 2020

Lubrication Science

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Internal gears with small tooth number difference are widely used as core component in robotics, medical, and other fields. The clearance between the entire meshing teeth is much smaller compared with other gear transmissions, indicating that the entire tooth profile can significantly affect the mixed elastohydrodynamic lubrication (EHL) state of a certain meshing point. Thereby, available lubrication analysis is limited with the assumption of effective radius at each meshing point. In the present study, the entire tooth profile with gear flank modification is studied to improve lubricating characteristics. A mixed EHL model for predicting the film, pressure, power loss, and subsurface stress is presented with consideration of the entire tooth geometry. We find that the tooth geometry away from the meshing location shows a remarkable influence on the film and pressure distribution as well as power loss of tooth rubbing interface, which is commonly unrecognised in previous study. Optimization of modification parameters is observed under different operating conditions, highlighting the critical role of entire tooth geometry in mixed EHL behaviour for internal gears with small tooth number difference.

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A Method to Derive Friction and Rolling Power Loss Formulae for Mixed Elastohydrodynamic Lubrication

Cited by 39 publications

References 17 publications

Modelling of steady-state mechanical power losses in planetary gear trains of automatic transmissions

Modelling of steady-state mechanical power losses in planetary gear trains of automatic transmissions

An experimental characterization of the friction coefficient of a wind turbine gearbox lubricant

Lubrication mechanisms of rubbing interface in internal meshing teeth with small clearance

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