Intracycle angular velocity control of cross-flow turbines

Strom, Benjamin; Brunton, Steven L.; Polagye, Brian

doi:10.1038/nenergy.2017.103

Cited by 56 publications

(66 citation statements)

References 42 publications

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“…Estimating the structure of a flow field from limited and noisy measurements is an important challenge in many engineering applications. For example, accurate estimation is central to active flow control [1,2,3,4], which has the potential to advance next-generation technology, ranging from fuel-efficient, low-drag automobiles [5] to high-efficiency turbines [6] and internal combustion engines [7]. The ability to reconstruct important flow features from restricted observations is also critical in applications as diverse as cardiac bloodflow modeling [8,9], ship wake identification [10], and climate science [11].…”

Section: Introductionmentioning

confidence: 99%

Robust flow reconstruction from limited measurements via sparse representation

Callaham¹,

Maeda²,

Brunton³

2019

Phys. Rev. Fluids

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140

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In many applications it is important to estimate a fluid flow field from limited and possibly corrupt measurements. Current methods in flow estimation often use least squares regression to reconstruct the flow field, finding the minimum-energy solution that is consistent with the measured data. However, this approach may be prone to overfitting and sensitive to noise. To address these challenges we instead seek a sparse representation of the data in a library of examples. Sparse representation has been widely used for image recognition and reconstruction, and it is well-suited to structured data with limited, corrupt measurements. We explore sparse representation for flow reconstruction on a variety of fluid data sets with a wide range of complexity, including vortex shedding past a cylinder at low Reynolds number, a mixing layer, and two geophysical flows. In addition, we compare several measurement strategies and consider various types of noise and corruption over a range of intensities. We find that sparse representation has considerably improved estimation accuracy and robustness to noise and corruption compared with least squares methods. We also introduce a sparse estimation procedure on local spatial patches for complex multiscale flows that preclude a global sparse representation. Based on these results, sparse representation is a promising framework for extracting useful information from complex flow fields with realistic measurements.

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Section: Introductionmentioning

confidence: 99%

Robust flow reconstruction from limited measurements via sparse representation

Callaham¹,

Maeda²,

Brunton³

2019

Phys. Rev. Fluids

Self Cite

140

View full text Add to dashboard Cite

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“…of 18, 23, 27 and 32×10 3 , where ν is the kinematic viscosity. Losses due to drag on the mounting structures were estimated by performing the same tip-speed ratio sweeps with the mounting structures alone, after the method of Bachant et al 16 .…”

Section: Methodsmentioning

confidence: 99%

“…Despite historical concerns of low performance and structural failure due to fatigue, lift-based cross-flow turbines have experienced a resurgence of research and commercial interest in recent years and hold promise for urban 1 and offshore 2 wind applications. Modern experimental and computational techniques have enabled substantial increases in power performance 3 and suggestions that optimized arrays may be able to extract more power per area than arrays of axial-flow turbines 4 . Drag-based cross-flow turbines are also an area of active research 5 , but are not the focus of this investigation and recent developments (e.g., Plourde et al 6 ) are not discussed here.…”

Section: Introductionmentioning

confidence: 99%

Impact of blade mounting structures on cross-flow turbine performance

Strom

Johnson

Polagye

2018

Journal of Renewable and Sustainable Energy

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Cross-flow or vertical-axis turbines are flow energy conversion devices in which lift forces cause blades to rotate around an axis perpendicular to the flow. In marine currents, rivers, and some wind energy applications, cross-flow turbines are a promising alternative to more conventional axial-flow turbines. The performance implications of the choice of structure used to mount turbine blades to the central shaft is examined experimentally in a recirculating water flume. Turbine performance is found to be strongly dependent on choice of mounting structure. Power loss due to rotational drag on these structures is estimated experimentally by rotating the mounting structure without blades. Through a perturbation-theory approach, interactions between turbine blades and mounting structures are examined. Analytical models for the power loss due to mounting structure drag are introduced and shown to be consistent with experiments. To provide guidance for cross-flow turbine design, the models are re-formulated in terms of non-dimensional turbine design and operational parameters. Mounting blades solely at their mid-span is shown to decrease performance through multiple fluid effects. Using foil cross-section struts located at the turbine blade tips is found to result in the highest turbine performance.

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“…Some researches in stall regulated wind turbines to output power controls have recently been conducted (Bourlis, 2011;Maheswari & Tamilvendhan, 2012;Pereira, Bussel, & Timmer, 2014). Pitch control and fixed pitch mechanisms have also been the subjects of investigations (Boorsma & Schepers, 2016;Farouk & Gawad, 2013;Leroy et al, 2016;Neammanee, Sirisumrannukul, & Chatratana, 2010;Strom, Brunton, & Polagye, 2016;Vijae, 2011). Modified design of wind turbines have also been investigated (Abdulhadi, 2012;Baldacchino et al, 2016;Elfarra, 2011;Lutz & Wagner, 2000;Lynch, 2011;Maniaci et al, 2016;Perfilev, 2013;Rahimi, Hartvelt, Peinke, & Schepers, 2016;Schubel & Crossley, 2012).…”

Section: Output Control and Modified Design In Wind Turbinesmentioning

confidence: 99%

Performances and Stall Delays of Three Dimensional Wind Turbine Blade Plate-Models with Helicopter-Like Propeller Blade Tips

Sutrisno

Deendarlianto

Indarto

et al. 2017

MAS

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The research on three dimensional (3-D) wind turbine blades has been introduced (Sutrisno, Prajitno, Purnomo, & B.W. Setyawan, 2016). In the current experiment, the 3-D wind turbine blades would be fitted with helicopter-like blade tips and additional fins to the blade hubs to demonstrate some laminarizing features.It was found that additional helicopter-like blade tip to the turbine blade creates strong laminar flows over the surface of the blade tips. Supplementary, finned hub, fitted to the blade body, creates rolled-up vortex flows, weakens the blade stall growth development, especially for blades at high-speed wind. A proposed mathematical form of modified lifting line model has been developed to pursue further 3-d blade development study of 3-d wind turbine blade.Rolled up vortex effects, developed by finned of the base hub, has been acknowledged could demolish the turbulent region, as well as laminarize the stall domain to intensify the induced wind turbine blade lift.

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Intracycle angular velocity control of cross-flow turbines

Cited by 56 publications

References 42 publications

Robust flow reconstruction from limited measurements via sparse representation

Robust flow reconstruction from limited measurements via sparse representation

Impact of blade mounting structures on cross-flow turbine performance

Performances and Stall Delays of Three Dimensional Wind Turbine Blade Plate-Models with Helicopter-Like Propeller Blade Tips

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