Development of a structural optimization strategy for the design of next generation large thermoplastic wind turbine blades

Forcier, Louis-Charles; Joncas, Simon

doi:10.1007/s00158-011-0722-z

Cited by 27 publications

(17 citation statements)

References 15 publications

(19 reference statements)

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“…In the first group (Figure 2(a)), load resultants are applied directly to a small number of sections of the blade, either through a master node which controls the whole section displacement by relations between nodes degrees of freedom (Forcier and Joncas, 2011; Haselbach et al, 2016; Joncas, 2010) or directly onto one (Griffith and Ashwill, 2011; Shokrieh and Rafiee, 2006) or a small number (Lindgaard and Lund, 2010; Lund and Stegmann, 2005) of nodes of the section of the shell FEM. This group consists of approaches where load resultant is applied at the blade tip or at the end of the studied segment (Haselbach et al, 2016; Lindgaard and Lund, 2010; Lund and Stegmann, 2005), and approaches where loads computed at different sections of the blade are applied onto the section where they had been computed (Griffith and Ashwill, 2011; Li et al, 2013; Shokrieh and Rafiee, 2006).…”

Section: State Of the Art Of Load Application Methodsmentioning

confidence: 99%

Load application method for shell finite element model of wind turbine blade

et al. 2018

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It is common to dissociate load computation from structural analysis when carrying out a numerical assessment of a wind turbine blade. Loads are usually computed using a multiphysics and multibody beam finite element model of the whole turbine, whereas detailed structural analysis is managed using shell finite element models. This raises the issue of the application of the loads extracted from the beam finite element model at one node for each section and transposed into the shell finite element model. After presenting the methods found in the literature, a new method is proposed. This takes into account the physical consistency of loads: aerodynamic loads are applied as pressure on the blade surface, and inertial loads are applied as body loads. Corrections imposed by pressure and body load computation in order to match loads from the beam finite element model are proposed and a comparison with two other methods is discussed.

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Section: State Of the Art Of Load Application Methodsmentioning

confidence: 99%

Load application method for shell finite element model of wind turbine blade

et al. 2018

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“…These aeroelastic effects are further coupled with generator dynamics and control system effects. Several recent studies have utilized MDO for wind turbine design (Zakhama and Abdalla 2010;Forcier and Joncas 2012). For example, Ashuri et al (2014) optimized the rotor and tower simultaneously, including satisfaction of relevant aerodynamic and structural constraints.…”

Section: Multidisciplinary Design Optimization Of Wind Turbinesmentioning

confidence: 99%

Multidisciplinary dynamic optimization of horizontal axis wind turbine design

Deshmukh

Allison

2015

Struct Multidisc Optim

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The design of physical (plant) and control aspects of a dynamic system have traditionally been treated as two separate problems, often solved in sequence. Optimizing plant and control design disciplines separately results in sub-optimal system designs that do not capitalize on the synergistic coupling between these disciplines. This coupling is inherent in most actively controlled dynamic systems, including wind turbines. In this case structural and control design both affect energy production and loads on the turbine. This article presents an integrated approach to achieve system-optimal wind turbine designs using codesign, a design methodology that accounts directly for the synergistic coupling between physical and control system design. A case study, based on multidisciplinary simulation, is presented here that demonstrates a promising increase (up to 8%) in annualized wind turbine energy production compared to the results of a conventional sequential design strategy. The case study also revealed specific synergistic mechanisms that enable performance improvements, which are accessible via co-design but not sequential design.

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“…Blade design is here performed with a constrained optimization-based procedure. In formulating an optimization problem, three principal phases must be considered [9,10]: The blade profile structure is shown in Figure 1, given girder location and width parameters, and it defines the ratio which distance that from shear web of before the main girder to front end divides section length is , section width of main girder and section chord ratio is .…”

Section: Optimization Problem Definitionmentioning

confidence: 99%

Optimization Method for Girder of Wind Turbine Blade

Yan

Zhao

Hong

2014

Mathematical Problems in Engineering

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This paper presents a recently developed numerical multidisciplinary optimization method for design of wind turbine blade. The objective was the highest possible blade weight under specified atmospheric conditions, determined by the design giving girder layer and location parameter. Wind turbine blade on box-section beams girder is calculated by ply thickness, main girder and trailing edge. In this study, a realistic 30 m blade from a 1.2 MW wind turbine model of blade girder parameters is established. The optimization evolves a structure which transforms along the length of the blade, changing from a design with spar caps at the maximum thickness and a trailing edge mass to a design with spar caps toward the tip. In addition, the cross-section structural properties and the modal characteristics of a 62 m rotor blade were predicted by the developed beam finite element. In summary, these findings indicate that the conventional structural layout of a wind turbine blade is suboptimal under the static load conditions, suggesting an opportunity to reduce blade weight and cost.

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Development of a structural optimization strategy for the design of next generation large thermoplastic wind turbine blades

Cited by 27 publications

References 15 publications

Load application method for shell finite element model of wind turbine blade

Load application method for shell finite element model of wind turbine blade

Multidisciplinary dynamic optimization of horizontal axis wind turbine design

Optimization Method for Girder of Wind Turbine Blade

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