Resultado final
The deliverable includes the implementation of the common pre- and post-processor and a user manual, which describes how the tools can be used by all participants and the interface definition. Software and user manual will be uploaded to the public web site.
Description of the reference and the control-oriented wind farm modelsThe deliverable includes the implementation of the reference wind farms in SOWFA and a user manual, which describes how the simulations can be repeated by all participants. Software and user manual will be uploaded to the public web site. In addition, the deliverable includes the implementation of the different control-oriented wind farm models and a user manual, which describes how the models can be used by all participants. Software and user manual will be uploaded to the public web site.
A power curtailment strategy that minimizes the wind farm loading.
Optimized farm layoutSimWindFarm (Engineering wind farm simulator) is used to produce an average model of wakes and turbulence. A two dimensional distribution of wind velocity and direction is used to calculate tower loads, drive train loads, and power production resulting in an assessment of layout options.
Cost-Benefit AnalysisA report on the economics of the new control technology on the scale of a Life Cycle (Cost) Assessment giving guidance on the dominating effects and potential for optimization when implementing the technology in existing and future wind farms.
Documentation of test campaignsWind tunnel tests of the combined controllers for individual wind turbines and wind farms are accomplished, and all relevant experimental results are available. Wake deflection as a function of operational parameters (misalignment and environmental conditions) is characterized and the relevant test data is available.
Report Communication Plan and clustering with other projects (first version)Communication Plan and educational program, M14, revision M18. It will include visual identity and communication material. Relation of activities to reinforce project messages through networking.
Hardware and infrastructure conditions for energy capture and fatigue improvementsThe report will describe how the proposed wind farm control affects the operations of existing wind farms in terms of energy capture, hardware, and communication infrastructure and power system compliance. The report will identify which of the developed techniques are applicable to existing wind farms.
Final validation reportThis will include a comparison of simulations against scaled tests in wind tunnel and the calibration of model parameters such as to obtain best match between simulations and wind tunnel experiments. In addition, a comparison of simulations against full scale field testing, with the calibration of model parameters such as to obtain best match between simulations and field tests. Finally, analysed data coming from open loop filed tests and if available, documentation of results from closed-loop wake deflection algorithms in field tests.
Feasibility by re-designA report detailing the new redesigned wind turbine and the new wind farm, both designed taking into account the wind farm control algorithms. The guidelines for wind turbine and wind farm redesign will also be included. This report will also analyze the KPIs for wind turbine, in terms of loads, and also for the wind farm.
Operation and maintenance cost modellingA report on the developed O&M cost model including the results of implemented probabilistic cost scenarios. The scenarios include a baseline formulation in offshore and onshore conditions, documentation of updated reliability values due to introduced new control technology and presentation of improvement potential in O&M strategies. The parameterized model is used to determine the O&M costs needed for Task 4.5.1.
Control methodology for induction based control and for wake redirection controlAn induction based feedforward-feedback controller design methodology that finds the optimal control settings. A yaw based feedforward + feedback controller design methodology that finds the optimal yaw control settings.
Report Communication Plan and clustering with other projects (revision)Communication Plan and educational program, M6, revision M18. It will include visual identity and communication material. Relation of activities to reinforce project messages through networking.
Demonstration of combined turbine / farm level controls by simulationsControllers that operate at the combined wind-turbine/wind-farm level are demonstrated in a simulation environment.
Minimal loading wind turbine de-rating strategy and active yaw controllersAn optimal derating strategy will be described and a WT controller for the reference machines defined in WP 1 will be provided, so it can be used by Partners for induction based control. In addition, an active yaw controller for the reference machines defined in WP1 will be developed, and provided to Partners for wake redirection control. This controller will be integrated with the controller of subtask 2.1.1, so that it can be used in task 2.4.
Classification of control-oriented models for wind farm control applicationsThe developed control-oriented models of task 1.2 will be classified with respect to their capabilities. The descriptions include conditions under which the developed models can be used for the various applications in WP 2.
Definition of reference wind farms and simulation scenariosThe defined reference wind farm layouts with wind turbines and corresponding baseline reference controllers will be described and specified simulations scenarios for wind farm control will be introduced to enable a classification of the developed models and a comparison for the different technologies developed in WP 2.
Assessment of controller key performance indicators & Guidelines on controller application for the management of existing wind farmsA complete report containing the comparison of the KPIs analyzed in task 4.1.1 and 4.1.2. The assessment of component loading on the individual wind turbine level is used to derive wind farm level implications in task 4.2 and formulation of reliability levels in task 4.4. A complete report containing the comparison of the KPIs analyzed in task 4.1.1 and 4.1.2. The assessment of component loading on the individual wind turbine level is used to derive wind farm level implications in task 4.2 and formulation of reliability levels in task 4.4.
Report feasibility analysis, business models, and business plan industrial partners and large Engineering firms and Value PropositionIdentification of best business models for each partner in the proposal and Business Plan for EGP, GE, RAMBOLL and GARRAD HASSAN.
Final Project ConferenceOrganization of a final conference in Spain to present the project results and potential impacts M36.
Review on Standards and GuidelinesA report detailing the missing link between new technology and existing standards in the area of safety and protection systems, grid code compliance and design load cases. Recommendations are derived to be used as input to new Standards.
Definition of field-testing conditionsThe operating conditions for field testing are defined in terms of all relevant parameters. This also leads to the definition of the configuration of all supporting equipment.
Demonstration of wind turbine controllers and supporting technologies by simulationsControllers for individual wind turbines are demonstrated in a simulation environment. Also supporting technologies that operate at the level of single wind turbines, as for example wind observers, are similarly demonstrated.
Methodology for active load controlAn event-triggered IPC algorithm will be developed, and integrated with the WT controller for the reference machines defined in WP1, so it can be used in task 2.4. An overview of alternative wake control methodologies using advanced flow actuators.
Training sessionsTwo training sessions, one day duration, tentatively organized in Spain and Netherlands.
Process Handbook and documents templatesProcess Handbook including rules for reports writing, project image, revision rules, etc.
Testing in the wind tunnel of wind turbines controllersWind tunnel tests of the controllers for individual wind turbines are accomplished, and all relevant experimental results are available.
Integrated wind farm controllersIn this deliverable wind farm control technologies from deliverables 2.1, 2.2 and 2.3 will be combined and further assessed. As the usual assumptions for the validity of the aeroelastic tools is exceeded in the advanced control concepts more advanced tools will be used to evaluate certain critical conditions like e.g. stability issues for various technologies.
Definition of wind tunnel testing conditionsThe operating conditions for wind tunnel testing are defined in terms of all relevant parameters. This also leads to the definition of the testing matrix, and to an exact schedule of all wind tunnel experiments.
Project management through a dedicated Platform based on Emdesk or similar in parallel to the Web site.
Publicaciones
Autores:
E. Bossanyi
Publicado en:
Proc. Torque from Wind conference, 2018
Editor:
Politecnico di Milano
Autores:
S. Boersma, B.M. Doekemeijer, P.M.O. Gebraad, P.A. Fleming, J. Annoni, A.K. Scholbrock, J.A. Frederik, J-W. van Wingerden
Publicado en:
2017 American Control Conference (ACC), 2017, Página(s) 1-18, ISBN 978-1-5090-5992-8
Editor:
IEEE
DOI:
10.23919/acc.2017.7962923
Autores:
E. Bossanyi
Publicado en:
Proc. Wind Energy Science conference, 2017
Editor:
Technical University of Denmark
Autores:
Steffen Raach, Jan-Willem van Wingerden, Sjoerd Boersma, David Schlipf, Po Wen Cheng
Publicado en:
2017 American Control Conference (ACC), 2017, Página(s) 703-708, ISBN 978-1-5090-5992-8
Editor:
IEEE
DOI:
10.23919/ACC.2017.7963035
Autores:
Daan van der Hoek ; Stoyan Kanev ; Wouter Engels
Publicado en:
2018
Editor:
Daan van der Hoek ; Stoyan Kanev ; Wouter Engels
Autores:
B. M. Doekemeijer ; S. Boersma ; L. Y. Pao ; J. W. van Wingerden
Publicado en:
2018
Editor:
B. M. Doekemeijer ; S. Boersma ; L. Y. Pao ; J. W. van Wingerden
Autores:
Doekemeijer, Bart M; Fleming, Paul A; van Wingerden, Jan-Willem
Publicado en:
Edición 1, 2018
Editor:
IEEE Conference Proceedings
DOI:
10.5281/zenodo.2556497
Autores:
Schreiber, Johannes; Bottasso, Carlo Luigi
Publicado en:
Edición 4, 2018
Editor:
Proceedings of the American Control Conference 2018
DOI:
10.5281/zenodo.2593200
Autores:
B. M. Doekemeijer, S. Boersma, L. Y. Pao, J. W. van Wingerden
Publicado en:
2017 American Control Conference (ACC), 2017, Página(s) 19-24, ISBN 978-1-5090-5992-8
Editor:
IEEE
DOI:
10.23919/ACC.2017.7962924
Autores:
Doekemeijer, Bart M; Boersma, Sjoerd; Pao, Lucy Y; van Wingerden, Jan-Willem
Publicado en:
Edición 2, 2018
Editor:
IOP Conf. Series: Journal of Physics: Conf. Series 1037 (2018) 032013
DOI:
10.5281/zenodo.2556512
Autores:
Rott, Andreas; Doekemeijer, Bart; Seifert, Janna Kristina; Wingerden, Jan-Willem; Kühn, Martin
Publicado en:
eISSN: 2366-7451, Edición 3, 2018
Editor:
Wind Energ. Sci., 3, 869–882, 2018
DOI:
10.5281/zenodo.2556507
Autores:
B.M. Doekemeijer, S. Boersma, J.W. van Wingerden, L .Y.Pao
Publicado en:
2018
Editor:
Journal of Physics: Conference Series (JPCS).
Autores:
Ervin Bossanyi
Publicado en:
2018
Editor:
Journal of Physics: Conference Series (JPCS)
Autores:
Iker Elorza, Carlos Calleja and Aron Pujana-Arrese
Publicado en:
2018
Editor:
Journal of Physics: Conference Series (JPCS)
Autores:
E Bossanyi
Publicado en:
2017
Editor:
Proc. Wind Energy Science conference
Autores:
Renzo Ruisi & Ervin Bossanyi
Publicado en:
2019
Editor:
Bilbao (IOP Journal of Physics Conference Series)
Autores:
E Bossanyi
Publicado en:
2019
Editor:
Proc. WindEurope Conference
Autores:
Bossanyi, Ervin; Ruisi, Renzo; Potenza, Giancarlo; Calabretta, Fabio
Publicado en:
Edición 2, 2018
Editor:
London
DOI:
10.5281/zenodo.3475157
Autores:
Daan van der Hoek, Stoyan Kanev, Wouter Engels
Publicado en:
2018 Annual American Control Conference (ACC), 2018, Página(s) 3116-3121, ISBN 978-1-5386-5428-6
Editor:
IEEE
DOI:
10.23919/acc.2018.8431162
Autores:
Doekemeijer, Bart; Bossanyi, Ervin; Kanev,Stoyan; Bot, E.T.G.; Elorza, Iker; Campagnolo, Filippo; Fortes‐Plaza, A; Schreiber, J; Eguinoa‐Erdozain, Irene; Gomez‐Iradi, Sugoi; Astrain‐Juangarcia, David; Cantero‐Nouqueret, Elena; Irigoyen‐Martinez, Uxue; Fernandes‐ Correia, Pedro; Benito-Cia, Pablo; Kern, Stefan; Kim, Y; Raach, Steffen; Knudsen, Torben; Schito, Paolo
Publicado en:
Edición 2, 2018
Editor:
Consortium
DOI:
10.5281/zenodo.3462440
Autores:
Irigoyen, Uxue
Publicado en:
Edición 1, 2017
Editor:
Consortium
DOI:
10.5281/zenodo.3462384
Autores:
Raach,Steffen; Campagnolo, Filippo; Ramamurthy, Bharath Kodiyala; Kern,Stefan; Boersma, Sjoerd; Doekemeijer,Bart; van Wingerden, Jan-Willem; Knudsen, Torben; Kanev, Stoyan; Aparicio-Sanchez, Maria; Fernandes-Correia, Pedro; Chavez-Arroyo, Roberto; Gomez-Iradi, Sugoi; Astrain, David; Cantero, Elena; Schito, Paolo
Publicado en:
Edición 2, 2018
Editor:
Consortium
DOI:
10.5281/zenodo.3463222
Autores:
Sjoerd Boersma, Bart Doekemeijer, Mehdi Vali, Johan Meyers, Jan-Willem van Wingerden
Publicado en:
Wind Energy Science, Edición 3/1, 2018, Página(s) 75-95, ISSN 2366-7451
Editor:
Wind Energy Science
DOI:
10.5194/wes-3-75-2018
Autores:
Bart Doekemeijer, Sjoerd Boersma, Lucy Pao, Torben Knudsen, Jan-Willem van Wingerden
Publicado en:
Wind Energy Science Discussions, 2018, Página(s) 1-30, ISSN 2366-7621
Editor:
Wind Energy Science
DOI:
10.5194/wes-2018-33
Autores:
Jan-Willem van Wingerden, Lucy Pao, Jacob Aho, Paul Fleming
Publicado en:
IFAC-PapersOnLine, Edición 50/1, 2017, Página(s) 4484-4491, ISSN 2405-8963
Editor:
Elsevier
DOI:
10.1016/j.ifacol.2017.08.378
Autores:
Steffen Raach, David Schlipf, Po Wen Cheng
Publicado en:
Wind Energy Science, Edición 2/1, 2017, Página(s) 257-267, ISSN 2366-7451
Editor:
Wind Energy Science
DOI:
10.5194/wes-2-257-2017
Autores:
Ervin Bossanyi
Publicado en:
Journal of Physics: Conference Series, Edición 1037, 2018, Página(s) 032011, ISSN 1742-6588
Editor:
Institute of Physics
DOI:
10.1088/1742-6596/1037/3/032011
Autores:
S. Boersma, B.M. Doekemeijer, S. Siniscalchi-Minna, J.W. van Wingerden
Publicado en:
Renewable Energy, Edición 134, 2019, Página(s) 639-652, ISSN 0960-1481
Editor:
Pergamon Press Ltd.
DOI:
10.1016/j.renene.2018.11.031
Autores:
D Astrain Juangarcia, I Eguinoa, T Knudsen
Publicado en:
Journal of Physics: Conference Series, Edición 1037, 2018, Página(s) 032039, ISSN 1742-6588
Editor:
Institute of Physics
DOI:
10.1088/1742-6596/1037/3/032039
Autores:
J Schreiber, B Salbert, C L Bottasso
Publicado en:
Journal of Physics: Conference Series, Edición 1037, 2018, Página(s) 032012, ISSN 1742-6588
Editor:
Institute of Physics
DOI:
10.1088/1742-6596/1037/3/032012
Autores:
A Fortes-Plaza, F Campagnolo, J Wang, C Wang, CL Bottasso
Publicado en:
Journal of Physics: Conference Series, Edición 1037, 2018, Página(s) 032014, ISSN 1742-6588
Editor:
Institute of Physics
DOI:
10.1088/1742-6596/1037/3/032014
Autores:
B M Doekemeijer, J W van Wingerden, S Boersma, L Y Pao
Publicado en:
Journal of Physics: Conference Series, Edición 753, 2016, Página(s) 052015, ISSN 1742-6588
Editor:
Institute of Physics
DOI:
10.1088/1742-6596/753/5/052015
Autores:
C Wang, J Wang, F Campagnolo, D B Carraón, C L Bottasso
Publicado en:
Journal of Physics: Conference Series, Edición 1037, 2018, Página(s) 062007, ISSN 1742-6588
Editor:
Institute of Physics
DOI:
10.1088/1742-6596/1037/6/062007
Autores:
Marta Bertelè, Carlo L. Bottasso, Stefano Cacciola
Publicado en:
Wind Energy Science, Edición 4/1, 2019, Página(s) 89-97, ISSN 2366-7451
Editor:
Wind Energy Science Journal
DOI:
10.5194/wes-4-89-2019
Autores:
Jiangang Wang, Chengyu Wang, Filippo Campagnolo, Carlo L. Bottasso
Publicado en:
Wind Energy Science, Edición 4/1, 2019, Página(s) 71-88, ISSN 2366-7451
Editor:
Wind Energy Science Journal
DOI:
10.5194/wes-4-71-2019
Autores:
Bart M. Doekemeijer, Sjoerd Boersma, Lucy Y. Pao, Torben Knudsen, Jan-Willem van Wingerden
Publicado en:
Wind Energy Science, Edición 3/2, 2018, Página(s) 749-765, ISSN 2366-7451
Editor:
Wind Energ. Sci., 3, 749–765, 2018
DOI:
10.5194/wes-3-749-2018
Autores:
Steffen Raach, Sjoerd Boersma, Bart Doekemeijer, Jan-Willem van Wingerden, Po Wen Cheng
Publicado en:
Journal of Physics: Conference Series, Edición 1037, 2018, Página(s) 032016, ISSN 1742-6588
Editor:
Institute of Physics
DOI:
10.1088/1742-6596/1037/3/032016
Autores:
Steffen Raach, David Schlipf, Po Wen Cheng
Publicado en:
Journal of Physics: Conference Series, Edición 753, 2016, Página(s) 052009, ISSN 1742-6588
Editor:
Institute of Physics
DOI:
10.1088/1742-6596/753/5/052009
Autores:
SP Mulders, JW van Wingerden
Publicado en:
Journal of Physics: Conference Series, Edición 1037, 2018, Página(s) 032009, ISSN 1742-6588
Editor:
Institute of Physics
DOI:
10.1088/1742-6596/1037/3/032009
Autores:
Renzo Ruisi, Ervin Bossanyi
Publicado en:
Journal of Physics: Conference Series, Edición 1222, 2019, Página(s) 012004, ISSN 1742-6588
Editor:
Institute of Physics
DOI:
10.1088/1742-6596/1222/1/012004
Autores:
Iker Elorza, Carlos Calleja, Aron Pujana-Arrese
Publicado en:
Journal of Physics: Conference Series, Edición 1222, 2019, Página(s) 012024, ISSN 1742-6588
Editor:
Institute of Physics
DOI:
10.1088/1742-6596/1222/1/012024
Autores:
Ervin Bossanyi
Publicado en:
Journal of Physics: Conference Series, Edición 1222, 2019, Página(s) 012023, ISSN 1742-6588
Editor:
Institute of Physics
DOI:
10.1088/1742-6596/1222/1/012023
Autores:
Steffen Raach, Sjoerd Boersma, Jan-Willem van Wingerden, David Schlipf, Po Wen Cheng
Publicado en:
IFAC-PapersOnLine, Edición 50/1, 2017, Página(s) 4498-4503, ISSN 2405-8963
Editor:
Elsevier
DOI:
10.1016/j.ifacol.2017.08.380
Autores:
M. Bertelè, C.L. Bottasso, S. Cacciola
Publicado en:
Journal of Physics: Conference Series, Edición 1037, 2018, Página(s) 032007, ISSN 1742-6588
Editor:
Institute of Physics
DOI:
10.1088/1742-6596/1037/3/032007
Autores:
Iker Elorza, Carlos Calleja and Aron Pujana-Arrese
Publicado en:
2019
Editor:
Energies
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