Tidal Turbine Benchmarking Project: Stage I - Steady Flow Blind Predictions: Preprint

R. H. J. Willden; X. Chen; S. W. Harvey; H. Edwards; C. Vogel; K. Bhavsar; T. Allsop; J. Gilbert; H. Mullings; M. Ghobrial; P. Ouro; D. Apsley; T. Stallard; I. Benson; A. Young; P. Schmitt; F. Zilic de Arcos; M.-A. Dufour; C. Choma Bex; G. Pinon; A. Evans; M. Togneri; I. Masters; L. da Silva Ignacio; C. A. R. Duarte; F. Souza; S. Gambuzza; Y. Liu; I. Viola; M. Rentschler; T. Gomes; G. Vaz; R. Azcueta; H. Ward; F. Salvatore; Z. Sarichloo; D. Calcagni; Thanh Toan Tran; Hannah Ross; M. Oliveira; R. Puraca; B. Carmo

Tidal Turbine Benchmarking Project: Stage I - Steady Flow Blind Predictions: Preprint

R. H. J. Willden, X. Chen, S. W. Harvey, H. Edwards, C. Vogel, K. Bhavsar, T. Allsop, J. Gilbert, H. Mullings, M. Ghobrial, P. Ouro, D. Apsley, T. Stallard, I. Benson, A. Young, P. Schmitt, F. Zilic de Arcos, M.-A. Dufour, C. Choma Bex, G. PinonA. Evans, M. Togneri, I. Masters, L. da Silva Ignacio, C. A. R. Duarte, F. Souza, S. Gambuzza, Y. Liu, I. Viola, M. Rentschler, T. Gomes, G. Vaz, R. Azcueta, H. Ward, F. Salvatore, Z. Sarichloo, D. Calcagni, Thanh Toan Tran, Hannah Ross, M. Oliveira, R. Puraca, B. Carmo

Center for Energy Conversion and Storage Systems

Research output: Contribution to conference › Paper

Abstract

This paper presents the first blind prediction stage of the Tidal Turbine Benchmarking Project being conducted and funded by the UK's EPSRC and Supergen ORE Hub. In this first stage, only steady flow conditions, at low and elevated turbulence (3.1%) levels, were considered. Prior to the blind prediction stage, a large laboratory scale experiment was conducted in which a highly instrumented 1.6m diameter tidal rotor was towed through a large towing tank in well-defined flow conditions with and without an upstream turbulence grid. Details of the test campaign and rotor design were released as part of this community blind prediction exercise. Participants were invited to use a range of engineering modelling approaches to simulate the performance and loads of the turbine. 26 submissions were received from 12 groups from across academia and industry using solution techniques ranging from blade resolved computational fluid dynamics through actuator line, boundary integral element methods, vortex methods to engineering Blade Element Momentum methods. The comparisons between experiments and blind predictions were extremely positive helping to provide validation and uncertainty estimates for the models, but also validating the experimental tests themselves. The exercise demonstrated that the experimental turbine data provides a robust data set against which researchers and design engineers can test their models and implementations to ensure robustness in their processes, helping to reduce uncertainty and provide increased confidence in engineering processes. Furthermore, the data set provides the basis by which modellers can evaluate and refine approaches.

Original language	American English
Number of pages	13
State	Published - 2023
Event	European Wave and Tidal Energy Conference - Bilbao, Spain Duration: 3 Sep 2023 → 7 Sep 2023

Conference

Conference	European Wave and Tidal Energy Conference
City	Bilbao, Spain
Period	3/09/23 → 7/09/23

NREL Publication Number

NREL/CP-5700-86715

Keywords

benchmarking
blind prediction
tidal turbine

Access to Document

https://www.nrel.gov/docs/fy23osti/86715.pdf

Cite this

Willden, R. H. J., Chen, X., Harvey, S. W., Edwards, H., Vogel, C., Bhavsar, K., Allsop, T., Gilbert, J., Mullings, H., Ghobrial, M., Ouro, P., Apsley, D., Stallard, T., Benson, I., Young, A., Schmitt, P., Zilic de Arcos, F., Dufour, M.-A., Choma Bex, C., ... Carmo, B. (2023). Tidal Turbine Benchmarking Project: Stage I - Steady Flow Blind Predictions: Preprint. Paper presented at European Wave and Tidal Energy Conference, Bilbao, Spain. https://www.nrel.gov/docs/fy23osti/86715.pdf

@conference{20156fa723ae47c685e9ff93da72e650,

title = "Tidal Turbine Benchmarking Project: Stage I - Steady Flow Blind Predictions: Preprint",

abstract = "This paper presents the first blind prediction stage of the Tidal Turbine Benchmarking Project being conducted and funded by the UK's EPSRC and Supergen ORE Hub. In this first stage, only steady flow conditions, at low and elevated turbulence (3.1%) levels, were considered. Prior to the blind prediction stage, a large laboratory scale experiment was conducted in which a highly instrumented 1.6m diameter tidal rotor was towed through a large towing tank in well-defined flow conditions with and without an upstream turbulence grid. Details of the test campaign and rotor design were released as part of this community blind prediction exercise. Participants were invited to use a range of engineering modelling approaches to simulate the performance and loads of the turbine. 26 submissions were received from 12 groups from across academia and industry using solution techniques ranging from blade resolved computational fluid dynamics through actuator line, boundary integral element methods, vortex methods to engineering Blade Element Momentum methods. The comparisons between experiments and blind predictions were extremely positive helping to provide validation and uncertainty estimates for the models, but also validating the experimental tests themselves. The exercise demonstrated that the experimental turbine data provides a robust data set against which researchers and design engineers can test their models and implementations to ensure robustness in their processes, helping to reduce uncertainty and provide increased confidence in engineering processes. Furthermore, the data set provides the basis by which modellers can evaluate and refine approaches.",

keywords = "benchmarking, blind prediction, tidal turbine",

author = "Willden, {R. H. J.} and X. Chen and Harvey, {S. W.} and H. Edwards and C. Vogel and K. Bhavsar and T. Allsop and J. Gilbert and H. Mullings and M. Ghobrial and P. Ouro and D. Apsley and T. Stallard and I. Benson and A. Young and P. Schmitt and {Zilic de Arcos}, F. and M.-A. Dufour and {Choma Bex}, C. and G. Pinon and A. Evans and M. Togneri and I. Masters and {da Silva Ignacio}, L. and Duarte, {C. A. R.} and F. Souza and S. Gambuzza and Y. Liu and I. Viola and M. Rentschler and T. Gomes and G. Vaz and R. Azcueta and H. Ward and F. Salvatore and Z. Sarichloo and D. Calcagni and Tran, {Thanh Toan} and Hannah Ross and M. Oliveira and R. Puraca and B. Carmo",

year = "2023",

language = "American English",

note = "European Wave and Tidal Energy Conference ; Conference date: 03-09-2023 Through 07-09-2023",

}

Willden, RHJ, Chen, X, Harvey, SW, Edwards, H, Vogel, C, Bhavsar, K, Allsop, T, Gilbert, J, Mullings, H, Ghobrial, M, Ouro, P, Apsley, D, Stallard, T, Benson, I, Young, A, Schmitt, P, Zilic de Arcos, F, Dufour, M-A, Choma Bex, C, Pinon, G, Evans, A, Togneri, M, Masters, I, da Silva Ignacio, L, Duarte, CAR, Souza, F, Gambuzza, S, Liu, Y, Viola, I, Rentschler, M, Gomes, T, Vaz, G, Azcueta, R, Ward, H, Salvatore, F, Sarichloo, Z, Calcagni, D, Tran, TT , Ross, H, Oliveira, M, Puraca, R & Carmo, B 2023, 'Tidal Turbine Benchmarking Project: Stage I - Steady Flow Blind Predictions: Preprint', Paper presented at European Wave and Tidal Energy Conference, Bilbao, Spain, 3/09/23 - 7/09/23. <https://www.nrel.gov/docs/fy23osti/86715.pdf>

TY - CONF

T1 - Tidal Turbine Benchmarking Project: Stage I - Steady Flow Blind Predictions: Preprint

AU - Willden, R. H. J.

AU - Chen, X.

AU - Harvey, S. W.

AU - Edwards, H.

AU - Vogel, C.

AU - Bhavsar, K.

AU - Allsop, T.

AU - Gilbert, J.

AU - Mullings, H.

AU - Ghobrial, M.

AU - Ouro, P.

AU - Apsley, D.

AU - Stallard, T.

AU - Benson, I.

AU - Young, A.

AU - Schmitt, P.

AU - Zilic de Arcos, F.

AU - Dufour, M.-A.

AU - Choma Bex, C.

AU - Pinon, G.

AU - Evans, A.

AU - Togneri, M.

AU - Masters, I.

AU - da Silva Ignacio, L.

AU - Duarte, C. A. R.

AU - Souza, F.

AU - Gambuzza, S.

AU - Liu, Y.

AU - Viola, I.

AU - Rentschler, M.

AU - Gomes, T.

AU - Vaz, G.

AU - Azcueta, R.

AU - Ward, H.

AU - Salvatore, F.

AU - Sarichloo, Z.

AU - Calcagni, D.

AU - Tran, Thanh Toan

AU - Ross, Hannah

AU - Oliveira, M.

AU - Puraca, R.

AU - Carmo, B.

PY - 2023

Y1 - 2023

N2 - This paper presents the first blind prediction stage of the Tidal Turbine Benchmarking Project being conducted and funded by the UK's EPSRC and Supergen ORE Hub. In this first stage, only steady flow conditions, at low and elevated turbulence (3.1%) levels, were considered. Prior to the blind prediction stage, a large laboratory scale experiment was conducted in which a highly instrumented 1.6m diameter tidal rotor was towed through a large towing tank in well-defined flow conditions with and without an upstream turbulence grid. Details of the test campaign and rotor design were released as part of this community blind prediction exercise. Participants were invited to use a range of engineering modelling approaches to simulate the performance and loads of the turbine. 26 submissions were received from 12 groups from across academia and industry using solution techniques ranging from blade resolved computational fluid dynamics through actuator line, boundary integral element methods, vortex methods to engineering Blade Element Momentum methods. The comparisons between experiments and blind predictions were extremely positive helping to provide validation and uncertainty estimates for the models, but also validating the experimental tests themselves. The exercise demonstrated that the experimental turbine data provides a robust data set against which researchers and design engineers can test their models and implementations to ensure robustness in their processes, helping to reduce uncertainty and provide increased confidence in engineering processes. Furthermore, the data set provides the basis by which modellers can evaluate and refine approaches.

AB - This paper presents the first blind prediction stage of the Tidal Turbine Benchmarking Project being conducted and funded by the UK's EPSRC and Supergen ORE Hub. In this first stage, only steady flow conditions, at low and elevated turbulence (3.1%) levels, were considered. Prior to the blind prediction stage, a large laboratory scale experiment was conducted in which a highly instrumented 1.6m diameter tidal rotor was towed through a large towing tank in well-defined flow conditions with and without an upstream turbulence grid. Details of the test campaign and rotor design were released as part of this community blind prediction exercise. Participants were invited to use a range of engineering modelling approaches to simulate the performance and loads of the turbine. 26 submissions were received from 12 groups from across academia and industry using solution techniques ranging from blade resolved computational fluid dynamics through actuator line, boundary integral element methods, vortex methods to engineering Blade Element Momentum methods. The comparisons between experiments and blind predictions were extremely positive helping to provide validation and uncertainty estimates for the models, but also validating the experimental tests themselves. The exercise demonstrated that the experimental turbine data provides a robust data set against which researchers and design engineers can test their models and implementations to ensure robustness in their processes, helping to reduce uncertainty and provide increased confidence in engineering processes. Furthermore, the data set provides the basis by which modellers can evaluate and refine approaches.

KW - benchmarking

KW - blind prediction

KW - tidal turbine

M3 - Paper

T2 - European Wave and Tidal Energy Conference

Y2 - 3 September 2023 through 7 September 2023

ER -

Tidal Turbine Benchmarking Project: Stage I - Steady Flow Blind Predictions: Preprint

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NREL Publication Number

Keywords

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