A novel computational approach for design and performance investigation of small wind turbine blade with extended BEM theory

Jha, Devashish; Singh, Madhu; Thakur, Amarnath

doi:10.1007/s40095-021-00388-y

Cited by 6 publications

(2 citation statements)

References 9 publications

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“…The profile, designed for printing purposes, possesses significant properties that necessitate experimental testing to comprehend the impact of printing on aerodynamic coefficients. Source: [30] .…”

Section: Aerodynamics and Geometry Of The Hydrofoilmentioning

confidence: 99%

3D Printing of a Tidal Turbine Blade Using Two Methods of SLS and FFF of a Reinforced PA12 Composite: A Comparative Study

Rouway,

Nachtane,

Tarfaoui

et al. 2024

SUSTAIN MAR STRUCT

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This study scrutinizes the thermomechanical dynamics of 3D-printed hydrofoil blades utilizing a carbon and glass bead-reinforced thermoplastic polymer. Comparative analyses underscore the pivotal role of polymer reinforcement in augmenting mechanical strength and mitigating deformation and residual stress. The investigation elucidates the expeditious and cost-efficient manufacturing potential of low-cost Fused Filament Fabrication (FFF) printers for small-scale blades, revealing exemplary mechanical performance with nominal deflection and warping in the PA12-CB/GB printed blade. A comprehensive juxtaposition between Selective Laser Sintering (SLS) and FFF printing methods favors SLS due to its isotropic properties, notwithstanding remediable warping. Emphasizing the rigorous marine environment, the study cautions against the anisotropic properties of FFF-printed blades, despite their low mechanical warping. These discernments contribute to hydrofoil design optimization through numerical analysis, shedding light on additive manufacturing’s potential for small blades in renewable energy, while underscoring the imperative for further research to advance these techniques.

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Section: Aerodynamics and Geometry Of The Hydrofoilmentioning

confidence: 99%

3D Printing of a Tidal Turbine Blade Using Two Methods of SLS and FFF of a Reinforced PA12 Composite: A Comparative Study

Rouway,

Nachtane,

Tarfaoui

et al. 2024

SUSTAIN MAR STRUCT

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“…In [15], a detailed review is presented for the design and performance investigation of WT both experimentally and numerically. Blade element-momentum theory has been employed for blade design of a Wind Turbine [11,12,19,20] and impact of turbulence studied [14]. Starting torque behaviour of Wind Turbine has been invertigated in [15].…”

Section: Introductionmentioning

confidence: 99%

NACA2412 airfoil based method for design and aerodynamic analysis of small HAWT using modified BEM approach

Jha¹,

Saurabh²

2023

Sci. Tech. Energ. Transition

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Efficient utilization of wind energy depends on careful selection and suitable design of Wind Turbine (WT) blades. Small scale Wind Turbines (SWT) normally operate in the low range of Angle of Attack (AoA). This makes the task even more difficult for designing and optimization of WT blades. This article deals with an airfoil based computational approach to design the blade for a standalone small scale Horizontal Axis Wind Turbine (HAWT). A procedure has been proposed to find the important parameters and analyze the performance characteristics for a three bladed HAWT operating under the wake rotation. Computational code has been written to find optimum blade profile. Twist angle variation, chord length and other related parameters are determined with the help of program. Comparison between different types of airfoil has been made to figure out the most suitable one. Airfoil selection and design approach are intended to make Wind Turbine blade efficient specially under low range of AoA. Characteristics of the Wind Turbine obtained analytically from this procedure are compared with several other reported earlier in some of the literatures. The result obtained by the proposed procedure is simpler and more efficient than BEM theory – a method normally employed for blade design.

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Design and Aerodynamic Analysis of Small HAWT Using a Novel Computational Approach

Anand,

Deavshish,

Kumar

2023

Lecture Notes in Mechanical Engineering

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A novel computational approach for design and performance investigation of small wind turbine blade with extended BEM theory

Cited by 6 publications

References 9 publications

3D Printing of a Tidal Turbine Blade Using Two Methods of SLS and FFF of a Reinforced PA12 Composite: A Comparative Study

3D Printing of a Tidal Turbine Blade Using Two Methods of SLS and FFF of a Reinforced PA12 Composite: A Comparative Study

NACA2412 airfoil based method for design and aerodynamic analysis of small HAWT using modified BEM approach

Design and Aerodynamic Analysis of Small HAWT Using a Novel Computational Approach

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