Influence of turbulence on the wake of a marine current turbine simulator

Blackmore, Tom; Batten, W.M.J.; Bahaj, A.S.

doi:10.1098/rspa.2014.0331

Cited by 46 publications

(56 citation statements)

References 25 publications

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“…On the other hand, large scale turbulence interacts directly with the body itself and the wake as a whole. Similar effects have been found using porous disc rotor simulators [10], and the interaction of turbulence scale with the wake observed using Large Eddy Simulations with actuator discs [11]. It was found that small scale turbulence reduced the velocity deficit in the wake of the actuator disc, but did not significantly affect the wake expansion or wake recovery.…”

Section: Discussion Of Resultssupporting

confidence: 64%

“…Previous investigations have shown how the thrust coefficient, or mean (time averaged) thrust force, of a porous disc rotor simulator can vary by over 20% in turbulent flows with different turbulence characteristics [10]. Further, numerical simulations have shown how turbulence affects the wake recovery behind an actuator disc turbine representation [11]. Studies using model turbine rotors have also shown significant variations when operated in flows with different turbulence intensities [12]- [14].…”

Section: Introductionmentioning

confidence: 91%

“…For example, it is possible to have 2 different flows with turbulence intensities of 10%, but one has large scale, low frequency turbulent structures, and the other with small scale, high frequency structures. Previous investigations have found the integral length scale to be an important parameter resulting in significant variations in thrust and wake recovery [10], [11].…”

Section: Turbulence Intensitymentioning

confidence: 99%

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Effects of turbulence on tidal turbines: Implications to performance, blade loads, and condition monitoring

Blackmore

Myers

Bahaj

2016

International Journal of Marine Energy

126

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Laboratory scale testing of tidal turbines has generated valuable datasets to support optimised turbine design and numerical model validation. However, tidal sites are highly turbulent with a broad range of length scales and turbulence intensities that are site specific. In this work we describe an experimental campaign using static grids to generate turbulence and investigate its impact on a model tidal turbine in a circulating water flume. Length scales, energy spectra and turbulence dissipation rates are first considered for centre point measurements before full flow characterisation of the ambient conditions across the turbine rotor area. Six different cases were chosen to observe the performance of a 1/20 th scale 0.8m diameter turbine subjected to these flows. The rotor thrust and torque, and flapwise and edgewise blade root bending moments were measured. It was found that the thrust and power coefficients were sensitive to the estimate of ambient velocity. In the most extreme case the Betz limit could be 'exceeded' depending on which estimate of ambient velocity was used. Overall variations in the peak power coefficient of over 10% were observed, demonstrating the significance turbulence has on turbine performance. It was also found that there is a strong correlation between fluctuations in blade root bending moments and the rotor loads. As a result we proposed that fatigue loads acting on the blades may be estimated from the fluctuations in power output of the turbine. Therefore maintenance operations maybe optimised from real-time fatigue monitoring of blade loads without the need to install additional instrumentation on the turbine blades. Under this proposed regime the cost of energy will be reduced due to reductions in turbine costs and following optimisation of the maintenance requirements and operational costs. This could also improve turbine reliability which would have significant implications for large multi turbine arrays.

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Section: Discussion Of Resultssupporting

confidence: 64%

Section: Introductionmentioning

confidence: 91%

Section: Turbulence Intensitymentioning

confidence: 99%

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Effects of turbulence on tidal turbines: Implications to performance, blade loads, and condition monitoring

Blackmore

Myers

Bahaj

2016

International Journal of Marine Energy

126

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“…Furthermore, Singh et al [29] pointed out that wind turbines reduce the intermittency and asymmetry in the wake by breaking and deflecting the large-scale flow structures; the non-local transfer between large and small scales is strongly attenuated, resulting in the more homogenized velocity structure as compared to the base flow. Numerical simulations by Blackmore et al [30] showed that the increase in Λ u of the incoming flow might speed up the wake recovery and increase the wake span.…”

Section: Introductionmentioning

confidence: 99%

On the Evolution of the Integral Time Scale within Wind Farms

et al. 2018

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A wind-tunnel investigation was carried out to characterize the spatial distribution of the integral time scale (T u ) within, and in the vicinity of, two model wind farms. The turbine arrays were placed over a rough wall and operated under high turbulence. The two layouts consisted of aligned units distinguished only by the streamwise spacing (∆x T ) between the devices, set at five and ten rotor diameters d T (or S x = ∆x T /d T = 5 and 10). They shared the same spanwise spacing between turbines of 2.5d T ; this resulted in arrays of 8 × 3 and 5 × 3 horizontal-axis turbines. Hotwire anemometry was used to characterize the instantaneous velocity at various vertical and transverse locations along the central column of the wind farms. Results show that T u was modulated by the wind farm layout. It was significantly reduced within the wind farms and right above them, where the internal boundary layer develops. The undisturbed levels above the wind farms were recovered only at ≈d T /2 above the top tip. This quantity appeared to reach adjusted values starting the fifth row of turbines in the S x = 5 wind farm, and earlier in the S x = 10 counterpart. Within the adjusted zone, the distribution of T u at hub height exhibited a negligible growth in the S x = 5 case; whereas it underwent a mild growth in the S x = 10 wind farm. In addition, the flow impinging the inner turbines exhibited T u /T u inc < 1, where T u inc is the integral time scale of the overall incoming flow. Specifically, T u → βT u inc at z = z hub , where β < 1 within standard layouts of wind farms, in particular β ≈ 0.5 and 0.7 for S x = 5 and 10.

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“…1,2 Several marine current power research projects are underway world-wide, commercial as well as academic. 3,4 Much work has been or is being done on scale-model experiments and numerical modeling, [5][6][7][8] and investigations have been and are being performed outside the laboratories as well. 9,10 The water flow speed at a potential marine current power site is an important factor in determining the possible energy yield from the site.…”

mentioning

confidence: 99%

Experimental demonstration of performance of a vertical axis marine current turbine in a river

Lundin

Forslund

Goude

et al. 2016

Journal of Renewable and Sustainable Energy

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An experimental station for marine current power has been installed in a river. The station comprises a vertical axis turbine with a direct-driven permanent magnet synchronous generator. In measurements of steady-state operation in varying flow conditions, performance comparable to that of turbines designed for significantly higher flow speeds is achieved, demonstrating the viability of electricity generation in low speed (below 1.5 m/s) marine currents.

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Influence of turbulence on the wake of a marine current turbine simulator

Cited by 46 publications

References 25 publications

Effects of turbulence on tidal turbines: Implications to performance, blade loads, and condition monitoring

Effects of turbulence on tidal turbines: Implications to performance, blade loads, and condition monitoring

On the Evolution of the Integral Time Scale within Wind Farms

Experimental demonstration of performance of a vertical axis marine current turbine in a river

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