Experimental characterisation of the wake behind paired vertical-axis wind turbines

被引:42
作者
Vergaerde, Antoine [1 ]
De Troyer, Tim [1 ]
Muggiasca, Sara [2 ]
Bayati, Ilmas [2 ,3 ]
Belloli, Marco [2 ]
Kluczewska-Bordier, Joanna [4 ]
Parneix, Nicolas [4 ]
Silvert, Frederic [4 ]
Runacres, Mark C. [1 ]
机构
[1] Vrije Univ Brussel, Pleinlaan 2, B-1050 Brussels, Belgium
[2] Politecn Milan, Dipartimento Meccan, Via Masa 1, I-20156 Milan, Italy
[3] Maritime Res Inst Netherlands, Haagsteeg, NL-6700 AA Wageningen, Netherlands
[4] Nenuphar, 1 Rue Prof Calmette, F-59000 Lille, France
来源
JOURNAL OF WIND ENGINEERING AND INDUSTRIAL AERODYNAMICS | 2020年 / 206卷
关键词
wake; Vertical-axis wind turbine; Wind tunnel; Experimental; Wind turbine applications; Paired wind turbines; POWER-GENERATION; FLOW; DESIGN; IMPACT;
D O I
10.1016/j.jweia.2020.104353
中图分类号
TU [建筑科学];
学科分类号
0813 ;
摘要
Two vertical-axis wind turbines (VAWTs) benefit from a power increase when placed side by side in close proximity. To study the potential of paired VAWTs for integration in wind farms, wind tunnel wake measurements of lift-driven VAWTs are compared for isolated and three counter-rotating configurations. Because the wake of an isolated VAWT is deflected, the direction of rotation significantly influences the wake of paired VAWTs. The wake of counter-rotating VAWTs where the adjacent blades move downwind, exhibits a similar length, width and replenishment as the wake of an isolated VAWT. The wake of counter-rotating VAWTs with adjacent upwind moving blades, however, significantly differs from an isolated VAWT wake. While its wake length is similar to an isolated VAWT wake, its width and replenishment are not. Because of appealing wake characteristics, paired VAWTs exhibit unique advantages for wind farm applications, and especially for offshore floating wind farms.
引用
收藏
页数:13
相关论文
共 54 条
[1]   Self-similarity and flow characteristics of vertical-axis wind turbine wakes: an LES study [J].
Abkar, Mahdi ;
Dabiri, John O. .
JOURNAL OF TURBULENCE, 2017, 18 (04) :373-389
[2]   Mechanisms of power augmentation in two side-by-side vertical axis wind turbines [J].
Alexander, Aaron S. ;
Santhanakrishnan, Arvind .
RENEWABLE ENERGY, 2020, 148 (148) :600-610
[3]   A comparison of wake measurements in motor-driven and flow-driven turbine experiments [J].
Araya, Daniel B. ;
Dabiri, John O. .
EXPERIMENTS IN FLUIDS, 2015, 56 (07)
[4]   Effects of Reynolds Number on the Energy Conversion and Near-Wake Dynamics of a High Solidity Vertical-Axis Cross-Flow Turbine [J].
Bachant, Peter ;
Wosnik, Martin .
ENERGIES, 2016, 9 (02)
[5]   Characterising the near-wake of a cross-flow turbine [J].
Bachant, Peter ;
Wosnik, Martin .
JOURNAL OF TURBULENCE, 2015, 16 (04) :392-410
[6]   Aerodynamic Measurements on a Vertical Axis Wind Turbine in a Large Scale Wind Tunnel [J].
Battisti, L. ;
Zanne, L. ;
Dell'Anna, S. ;
Dossena, V. ;
Persico, G. ;
Paradiso, B. .
JOURNAL OF ENERGY RESOURCES TECHNOLOGY-TRANSACTIONS OF THE ASME, 2011, 133 (03)
[7]   VELOCITY VECTOR AND TURBULENCE IN THE SYMMETRY PLANE OF A DARRIEUS WIND GENERATOR [J].
BERGELES, G ;
MICHOS, A ;
ATHANASSIADIS, N .
JOURNAL OF WIND ENGINEERING AND INDUSTRIAL AERODYNAMICS, 1991, 37 (01) :87-101
[8]   Offshore wind power development in Europe and its comparison with onshore counterpart [J].
Bilgili, Mehmet ;
Yasar, Abdulkadir ;
Simsek, Erdogan .
RENEWABLE & SUSTAINABLE ENERGY REVIEWS, 2011, 15 (02) :905-915
[9]   A comparison between the dynamics of horizontal and vertical axis offshore floating wind turbines [J].
Borg, M. ;
Collu, M. .
PHILOSOPHICAL TRANSACTIONS OF THE ROYAL SOCIETY A-MATHEMATICAL PHYSICAL AND ENGINEERING SCIENCES, 2015, 373 (2035)
[10]   Offshore floating vertical axis wind turbines, dynamics modelling state of the art. part I: Aerodynamics [J].
Borg, Michael ;
Shires, Andrew ;
Collu, Maurizio .
RENEWABLE & SUSTAINABLE ENERGY REVIEWS, 2014, 39 :1214-1225
123456