Review of morphing concepts and materials for wind turbine blade applications

Lachenal, Xavier; Daynes, Stephen; Weaver, Paul M.

doi:10.1002/we.531

Cited by 259 publications

(145 citation statements)

References 77 publications

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“…The benefits brought in by morphing flaps are; there is no discontinuities, hinge line and air gap created when the rear part is deflected unlike traditional rigid flaps [45]. Furthermore, morphing flap has better aerodynamic efficiency/performance [53] Several researches about morphing trailing flap have been conducted numerically and experimentally [44,45,[63][64][65][66][67]. Researchers identify morphing flap as a potential element for load reduction in up-scaling wind turbines.…”

Section: Morphing Trailing Flapmentioning

confidence: 99%

Fatigue Loads Mitigation on Horizontal Axis Wind Turbines Using Aerodynamic Devices. A Survey

Muiruri¹,

Motsamai²

2017

JESTR

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The paper presents overview of source loads and aerodynamic techniques that are feasible for fatigue load reduction on large horizontal axis wind turbines. The article highlights the effects of increasing wind turbine rotor diameter on fatigue load, and feasible aerodynamic techniques that can be employed to reduce fatigue load. Increased in fatigue load is critical as current and future horizontal wind turbines are designed of large rotor blades. Increase in size of wind turbines has been elicited by highly demand for clean energy nowadays as well as need to decrease the cost of energy per kilo watt. As the rotor diameter increases in size, so do effects of air loads acting on the blades. The pitch control systems installed with a purpose of controlling such effects are approaching their capability limits. They are unable to dump sudden, high varying air loads associated with fluctuating wind speed on time. As these effects occur repeatedly during operation of wind turbines, they can cause premature failure or permanent damage of major components due to fatigue load accumulation. In overall, the service life of wind turbine can drastically reduce or high operational and maintenance costs are likely to rise up due to frequent downfalls of unplanned maintenance schedules. Therefore, alternative methods rather than pitch control are reviewed that can improve wind turbines efficiency. The paper concludes by analyzing possible opportunities in future.

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Section: Morphing Trailing Flapmentioning

confidence: 99%

Fatigue Loads Mitigation on Horizontal Axis Wind Turbines Using Aerodynamic Devices. A Survey

Muiruri¹,

Motsamai²

2017

JESTR

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“…Recent advancements in additive manufacturing and 4D printing [1,2] facilitate the fabrication of these structures with wide-ranging architectures and geometries. Such progress renders plates and shells, including sandwich and reinforced structures, particularly attractive for many applications in lightweight construction, aerospace and automotive engineering, naval architecture and marine engineering, nanotechnology, biomedical engineering and sports equipment, e.g [3][4][5][6].…”

Section: Introductionmentioning

confidence: 99%

Asymptotic homogenization for modeling of wingbox structures

Hadjiloizi

2018

2018 AIAA/ASCE/AHS/ASC Structures, Structural Dynamics, and Materials Conference

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The asymptotic homogenization technique has been used to analyze a wing box structure consisting of trapezoidally arranged reinforcements encased within thin rectangular plates. Ignoring stress concentration effects at the region of the overlap between the various components, the wingbox structure can be analyzed by handling each constituent independently from each other. To this end, a simpler structure was first considered which was made up of a base plate and a single stiffener web; the results were then extrapolated to those of the wingbox structure via superposition by adding in the contributions of each constituent of the overall unit cell. The work culminated in closed-form expressions for the effective in-plane elastic coefficients of the wingbox. This result demonstrates the attractiveness of the methodology in that it can be used in engineering analysis and design to customize the architecture of a thin-walled reinforced composite by changing some material or geometrical parameters of interest. Such parameters could be the material of the base plate, the spatial arrangement of the reinforcements, the relative sizes of the different constituents.

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“…Many studies have focused on active flow control by considering the employment of SMAs elements for actuation purposes. Examples of morphing applications regard the improvement of the global efficiency of aircraft wings [3][4][5], noise reduction during aircraft take-off [6], the development of a rotor blade control system [7], the fabrication of actuators for tracking helicopter blades while in-flight [8], and the application of aerodynamic control devices for wind turbine blades [9,10]. The notion of smart advanced blades, which can control themselves and reduce (or eliminate) the need for an active control system, is an appealing solution in blade technology to increase efficiency at several different flow regimes.…”

Section: Introductionmentioning

confidence: 99%

Analysis of the Aerodynamic and Structural Performance of a Cooling Fan with Morphing Blade

Suman

Fortini

Aldi

et al. 2017

IJTPP

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Abstract:The concept of smart morphing blades, which can control themselves to reduce or eliminate the need for active control systems, is a highly attractive solution in blade technology. In this paper, an innovative passive control system based on Shape Memory Alloys (SMAs) is proposed. On the basis of previous thermal and shape characterization of a single morphing blade for a heavy-duty automotive cooling axial fan, this study deals with the numerical analysis of the aerodynamic loads acting on the fan. By coupling computational fluid dynamics and finite element method approaches, it is possible to analyze the actual blade shape resulting from both the aerodynamic and centrifugal loads. The numerical results indicate that the polymeric blade structure ensures proper resistance and enables shape variation due to the action of the SMA strips.

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Review of morphing concepts and materials for wind turbine blade applications

Cited by 259 publications

References 77 publications

Fatigue Loads Mitigation on Horizontal Axis Wind Turbines Using Aerodynamic Devices. A Survey

Fatigue Loads Mitigation on Horizontal Axis Wind Turbines Using Aerodynamic Devices. A Survey

Asymptotic homogenization for modeling of wingbox structures

Analysis of the Aerodynamic and Structural Performance of a Cooling Fan with Morphing Blade

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