Tidal turbine array optimisation using the adjoint approach

Funke, Simon W.; Farrell, Patrick E.; Piggott, Matthew D.

doi:10.1016/j.renene.2013.09.031

Cited by 164 publications

(206 citation statements)

References 36 publications

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“…These approaches benefit from high-fidelity CFD and leverage the power of adjoint optimization but have only been applied for fixed layouts. Finally, Funke et al (2014) performed an adjoint optimization of ocean turbine layouts using an analysis based on the shallow water equations, with ocean turbines represented by increased bottom friction.…”

Section: Approaches To Wind Plant Optimizationmentioning

confidence: 99%

Optimization of wind plant layouts using an adjoint approach

et al. 2017

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Abstract. Using adjoint optimization and three-dimensional steady-state Reynolds-averaged Navier-Stokes (RANS) simulations, we present a new gradient-based approach for optimally siting wind turbines within utilityscale wind plants. By solving the adjoint equations of the flow model, the gradients needed for optimization are found at a cost that is independent of the number of control variables, thereby permitting optimization of large wind plants with many turbine locations. Moreover, compared to the common approach of superimposing prescribed wake deficits onto linearized flow models, the computational efficiency of the adjoint approach allows the use of higher-fidelity RANS flow models which can capture nonlinear turbulent flow physics within a wind plant. The steady-state RANS flow model is implemented in the Python finite-element package FEniCS and the derivation and solution of the discrete adjoint equations are automated within the dolfin-adjoint framework. Gradient-based optimization of wind turbine locations is demonstrated for idealized test cases that reveal new optimization heuristics such as rotational symmetry, local speedups, and nonlinear wake curvature effects. Layout optimization is also demonstrated on more complex wind rose shapes, including a full annual energy production (AEP) layout optimization over 36 inflow directions and 5 wind speed bins.

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Section: Approaches To Wind Plant Optimizationmentioning

confidence: 99%

Optimization of wind plant layouts using an adjoint approach

et al. 2017

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“…The force is distributed evenly over the area of the grid cell. A final approach uses increased bed roughness to simulate the drag induced by energy extraction on the flow (e.g., [19,20,30,31]). Disadvantages of this approach are that it cannot account for the dimensions or performance characteristics of the turbine and energy is always captured from the flow regardless of the flow direction; this is unrealistic in the case of horizontal axis turbines whose orientation is typically fixed.…”

Section: Numerical Approach To Representation Of Turbinesmentioning

confidence: 99%

“…This allows the flows around individual turbines and interactions between adjacent turbines in an array to be resolved. This approach is similar to those of [19,20] who also use selective high resolution around turbines in 2D, depth-averaged, far-field models to capture the hydrodynamic interactions between adjacent turbines in arrays, with a view to optimising array layouts. Reference [19] used an irregular mesh to obtain the higher resolution while reference [20] used a regularly-spaced adaptive mesh.…”

Section: Introductionmentioning

confidence: 99%

“…This approach is similar to those of [19,20] who also use selective high resolution around turbines in 2D, depth-averaged, far-field models to capture the hydrodynamic interactions between adjacent turbines in arrays, with a view to optimising array layouts. Reference [19] used an irregular mesh to obtain the higher resolution while reference [20] used a regularly-spaced adaptive mesh. In the present model, the optimisation of array layouts is not conducted directly during the simulation; rather a number of simulations of single and twin turbine deployments are used to investigate turbine interactions with regard to power capture and the results are used to inform the optimum placement and spacing of turbines in a multi-row array.…”

Section: Introductionmentioning

confidence: 99%

“…The model of [20] is also incapable of directly conducting optimisation of layouts and is used to compare the energy capture from arrays of different layouts. By comparison, reference [19] combined a gradient-based optimisation algorithm with a shallow water flow model to carry out optimisation in a single simulation whereby turbines are repositioned and flows recalculated in an iterative manner. The authors are currently working to develop such optimising functionality within our model.…”

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Towards a Low-Cost Modelling System for Optimising the Layout of Tidal Turbine Arrays

Olbert

Hartnett

2015

Energies

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Abstract:In the long-term, tidal turbines will most likely be deployed in farms/arrays where energy extraction by one turbine may significantly affect the energy available to another turbine. Given the prohibitive cost of experimental and/or field investigations of such turbine interactions, numerical models can play a significant role in determining the optimum layout of tidal turbine arrays with respect to energy capture. In the present research, a low-cost modelling solution for optimising turbine array layouts is presented and assessed. Nesting is used in a far-field model to telescope spatial resolution down to the scale of the turbines within the turbine array, allowing simulation of the interactions between adjacent turbines as well as the hydrodynamic impacts of individual turbines. The turbines are incorporated as momentum sinks. The results show that the model can compute turbine wakes with similar far-field spatial extents and velocity deficits to those measured in published experimental studies. The results show that optimum spacings for multi-row arrays with regard to power yield are 3-4 rotor diameters (RD) across-stream and 1-4 RD along-stream, and that turbines in downstream rows should be staggered to avoid wake effects of upstream turbines and to make use of the accelerated flows induced by adjacent upstream turbines.

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On Goal Oriented Time Adaptivity using Local Error Estimates

Meisrimel¹,

Birken

2017

Proc Appl Math and Mech

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We consider adaptive time discretization methods for ordinary differential equations where one aims to control the error in a quantity of interest of the form J(u) = te t 0 j(u(t)) dt, with j : R d → R. In this setting we propose a new timestep controller based on local error estimates of the quantity of interest. The new method converges when the tolerance goes to zero.We experimentally compare the new scheme with the classic norm-based time-adaptivity based on local error estimates as well as the dual-weighted residual (DWR) method. The results show significantly lower efficiency for the DWR method. The local error based schemes are similarly efficient, with the new scheme showing significant improvement in some cases.

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Tidal turbine array optimisation using the adjoint approach

Cited by 164 publications

References 36 publications

Optimization of wind plant layouts using an adjoint approach

Optimization of wind plant layouts using an adjoint approach

Towards a Low-Cost Modelling System for Optimising the Layout of Tidal Turbine Arrays

On Goal Oriented Time Adaptivity using Local Error Estimates

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