Constructing fast and representative analytical  models of wind turbine main bearings

Stirling, James; Hart, Edward; Amiri, Abbas Kazemi

doi:10.5194/wes-6-15-2021

Cited by 8 publications

(11 citation statements)

References 15 publications

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“…These studies all considered only the case of a non-moment reacting support at the main-bearing, a condition that generally holds for a double-row spherical roller bearing (SRB) in a three-point mounting configuration but does not hold for paired tapered roller bearings (TRBs) which, as a unit, provide a combination of force and moment reactions to applied loads. Stirling et al (2021) proposed an extension of the preceding analytical main-bearing representations that accounts for moment reactions via inclusion of rotational springs.…”

Section: Main-bearing Modelling and Load Characteristicsmentioning

confidence: 99%

Impacts of wind field characteristics and non-steady deterministic wind events on time varying main-bearing loads

Hart¹,

Stock²,

Elderfield³

et al. 2022

Preprint

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Abstract. This work considers the characteristics and drivers of the loads experienced by wind turbine main-bearings. Simplified load response models of two different hub and main-bearing configurations are presented, representative of both inverting direct-drive and four-point mounted geared drivetrains. The influences of deterministic wind field characteristics, such as wind speed, shear, yaw offset and veer, on the bearing load patterns are then investigated for similarity scaled 5, 7.5 and 10 MW reference wind turbine models. Main-bearing load response in cases of deterministic gusts and extreme changes in wind direction are also considered for the 5 MW model. Perhaps surprisingly, veer is identified as an important driver of main-bearing load fluctuations. Upscaling results indicate that similar behaviour holds as turbines become larger, but with mean loads and load fluctuation levels increasing at least cubically with the turbine rotor radius. Strong links between turbine control and main-bearing load response are also observed.

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Section: Main-bearing Modelling and Load Characteristicsmentioning

confidence: 99%

Impacts of wind field characteristics and non-steady deterministic wind events on time varying main-bearing loads

Hart¹,

Stock²,

Elderfield³

et al. 2022

Preprint

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“…Bearing fatigue life standards are reaching their limit for calculating main bearing rating life due to low operational speeds, high axial loads, and lubrication characteristics, especially as tall land-based and offshore turbines continue to increase in size. These types of failures can be better understood through both accelerated benchtop as well as full-scale investigations supported by modeling (Sethuraman, Guo, and Sheng 2015;Stirling, Hart, and Kazemi Amiri 2021;Guo et al 2021). The aim of this work should be to help identify root causes and make better-informed initial design and maintenance decisions .…”

Section: Main Bearing Wearmentioning

confidence: 99%

Wind Turbine Drivetrain Reliability and Wind Plant Operations and Maintenance Research and Development Opportunities

Keller

Sheng

Guo

et al. 2021

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“…This was done using the statically determinate single main-bearing model previously used in Hart et al (2019); Hart (2020); Stirling et al (2021) and discussed in Section 2. As described earlier, evaluation of main-bearing applied loading involves a static load balance at each timestep.…”

Section: Generating the "Contact Conditions Dataset"mentioning

confidence: 99%

“…Main-bearing research to-date has mainly focused on load modelling (Kock et al, 2019;Hart, 2020;Wang et al, 2020;Zheng et al, 2020a;Stirling et al, 2021), load characteristics (Cardaun et al, 2019;Hart et al, 2019;Hart, 2020;Guo et al, 2021) and implications for fatigue damage (Zheng et al, 2020b;Loriemi et al, 2021). Lubrication conditions within the main-bearing are generally not considered.…”

Section: Introductionmentioning

confidence: 99%

“…Applied loads at the turbine hub are obtained from simulations (described below) and the radial loads at the main-bearing are resolved independently in horizontal and vertical planes. In Stirling et al (2021) it was shown that, for the single main-bearing configuration, this simplified drivetrain representation is able to accurately recreate the radial response at the main-bearing seen in a higher fidelity, but still relatively simple, 3D finite element model. All thrust is assumed to be reacted by the main-bearing for the single main-bearing configuration (equivalently, "three point suspension") studied here.…”

Section: Introductionmentioning

confidence: 99%

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Wind turbine main-bearing lubrication – Part 2: Simulation based results for a double-row spherical roller main-bearing in a 1.5 MW wind turbine

Hart

Mello

Dwyer-Joyce

2021

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Abstract. This paper is the second in a two-part study on lubrication in wind turbine main-bearings. Where “Part 1” provided an introductory review of elastohydrodynamic lubrication theory, this paper will apply those ideas to investigate lubrication in the double-row spherical roller main-bearing of a 1.5 MW wind turbine. Lubrication is investigated across a “contact conditions dataset” generated by inputting processed loads, obtained from aeroelastic simulations, into a Hertzian contact model of the main-bearing. From the Hertzian model is extracted values of roller load and contact patch dimensions, along with the time rate-of-change of contact patch dimensions. Also included in the dataset are additional environmental and operational variable values (e.g. wind speeds and shaft rotational speeds). A suitable formula for estimating film thickness within this particular bearing is then identified. Using lubricant properties of a commercially available wind turbine grease, specifically marketed for use in main-bearings, an analysis of film thickness across the generated dataset is undertaken. The analysis includes consideration of effects relating to starvation, grease thickener interactions and possible dynamic EHL effects. Results show that the modelled main-bearing would be expected to operate under mixed lubrication conditions for a non-negligible proportion of its operational life, indicating that further work is required to better understand lubrication in this context and implications for main-bearing damage and operational lifetimes. Key sensitivities and uncertainties within the analysis are discussed, along with recommendations for future work.

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Constructing fast and representative analytical models of wind turbine main bearings

Cited by 8 publications

References 15 publications

Impacts of wind field characteristics and non-steady deterministic wind events on time varying main-bearing loads

Impacts of wind field characteristics and non-steady deterministic wind events on time varying main-bearing loads

Wind Turbine Drivetrain Reliability and Wind Plant Operations and Maintenance Research and Development Opportunities

Wind turbine main-bearing lubrication – Part 2: Simulation based results for a double-row spherical roller main-bearing in a 1.5 MW wind turbine

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