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High Efficiency 2-Bladed Utility Wind Turbine Enhanced by CoFlow Jet Active Flow Control

Conference ·
DOI:https://doi.org/10.2514/6.2023-0608· OSTI ID:2417626

The aerodynamic performance and power output of a high efficiency Co-Flow Jet (CFJ) 2-bladed Wind Turbine is studied in this paper. CFJ is a Zero-Net-Mass-Flux (ZNMF) active flow control method that dramatically increases airfoil lift coefficient and suppresses flow separation at a low energy expenditure. The 3D Reynolds Averaged Navier-Stokes (RANS) equations with one-equation Spalart-Allmaras (SA) turbulence model are solved to simulate the 3D flows of the wind turbines. The CFJ-Wind Turbine in this paper is modified from the NREL 3-bladed 3.4 MW reference wind turbine with the same RPM, blade length, distribution of chord, twist, and bending. The CFJ 2-bladed wind turbine utilizes the CFJ-NACA 64 series airfoils at most of the blade span from 31.88\% to the tip. The CFJ injection and suction slots are implemented along the full blade span to enhance the effectiveness and power output. The study shows that the 2-bladed CFJ turbine significantly increases power output compared with the 3-bladed baseline turbine at all wind speeds by 15.8\% at the wind speed of 9.8 m/s and by 25.9\% at 4 m/s respectively. The efficiency enhancement is substantially more at the low wind speed than at high wind speed. This would be very beneficial to increase the annual power output or capacity factor as wind turbines work at the speeds lower than the rated speed for most of the time. The results show that the flow field around the blade surface presents a significant enhanced suction peak near the blade leading edge, which results in a very high tangential force and thus increased wind turbine net power coefficient. Consistent with the previous study for the small NREL Phase VI research wind turbine, this paper demonstrates that CFJ 2-bladed wind turbine is an effective technology to extract more power from the wind at all speeds. This study is just an initial effort to demonstrate the advantage of the CFJ blade with no design optimization. It is believed that there is more potential to further enhance the efficiency improvement.

Research Organization:
National Renewable Energy Laboratory (NREL), Golden, CO (United States)
Sponsoring Organization:
USDOE National Renewable Energy Laboratory (NREL)
DOE Contract Number:
AC36-08GO28308
OSTI ID:
2417626
Report Number(s):
NREL/CP-5000-90732; MainId:92510; UUID:da73df29-cfee-4a2e-ad13-261e6899c6b7; MainAdminId:73270
Country of Publication:
United States
Language:
English

References (24)

General Subdomain Boundary Mapping Procedure for Structured Grid Implicit CFD Parallel Computation journal November 2008
High Efficiency Wind Turbine Using Co-Flow Jet Active Flow Control conference June 2021
Detached-Eddy Simulation of Rotating Stall Inception for a Full-Annulus Transonic Rotor journal July 2012
3D Navier-Stokes computations of a stall-regulated wind turbine journal January 2004
Unsteady aerodynamics associated with a horizontal-axis wind turbine journal July 1996
Numerical Simulation of Pitching Airfoil Performance Enhancement Using Co-Flow Jet Flow Control conference June 2013
Optimal angle of attack for untwisted blade wind turbine journal May 2009
High-Performance Airfoil Using Coflow Jet Flow Control journal August 2007
Jet Effects on Coflow Jet Airfoil Performance journal June 2007
Large Eddy Simulation of Coflow Jet Airfoil at High Angle of Attack journal November 2013
Detached-Eddy Simulation of a Coflow Jet Airfoil at High Angle of Attack journal September 2011
Numerical Study of Three-Dimensional Flows Using Unfactored Upwind-Relaxation Sweeping Algorithm journal May 1996
Full-Annulus Simulation of Nonsynchronous Blade Vibration Excitation of an Axial Compressor journal December 2017
Wind Turbine Efficiency Enhancement by CoFlow Jet Airfoil conference January 2022
IEA Wind TCP Task 37: Systems Engineering in Wind Energy - WP2.1 Reference Wind Turbines report June 2019
Super-Lift Coefficient of Active Flow Control Airfoil: What is the Limit? conference January 2017
Synthetic Jet based Active Flow Control of Dynamic Stall Phenomenon on Wind Turbines Under Yaw Misalignment conference January 2014
Aircraft Control Surfaces Using Co-flow Jet Active Flow Control Airfoil conference June 2018
A one-equation turbulence model for aerodynamic flows conference February 2013
Numerical Investigations of Injection-Slot-Size Effect on the Performance of Coflow Jet Airfoils journal November 2008
Drag Minimization of Co-Flow Jet Control Surfaces at Cruise Conditions conference January 2019
Performance and Energy Expenditure of Coflow Jet Airfoil with Variation of Mach Number journal November 2016
Improvement of Stability and Accuracy for Weighted Essentially Nonoscillatory Scheme journal February 2009
Effect of Injection Slot Size on the Performance of Coflow Jet Airfoil journal July 2006

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