Modeling a lifting of a surface with an active smart flexible flap

Autores
Tripp, Nicolas Guillermo; Preidikman, Sergio; Mirasso, Anibal Edmundo
Año de publicación
2012
Idioma
inglés
Tipo de recurso
artículo
Estado
versión publicada
Descripción
In the past years, the consumption of energy produced by wind turbines had an exponential growth. This requirement gave momentum to the development of larger turbines with the goal of producing more energy at the same site, reducing the initial investment, and the operation and maintenance costs. In order to achieve this objective, longer, lighter, maintenance-free blades are required so that smaller loads are transferred to the other, more expensive, wind turbine components. The resulting larger flexibility, imposes new challenges to the blade and controller designs; henceforth, new concepts are being developed to add more intelligence into these systems. During the last few years, the electronics industry had invested resources into the research and development of practical applications for piezoelectric ceramic materials. The result of this effort was the development of high precision piezoelectric actuators and sensors, which achieve forces and deformations that are compatible with the ones needed for the control of aerodynamic surfaces. In a former work by the authors, the aeroservoelastic behavior of a two dimensional (2D) wind turbine typical section with an active smart flexible flap was studied. In that work, the potential vibration control properties of an active flexible flap were exposed. In the present work, the study is extended to the three dimensional (3D) space. The flap is modeled as a flexible trailing edge, excited by a piezoelectric actuator, which allows the active morphing of the aerodynamic profile. Structurally, the flap is modeled as a continuum plate, with fixed-free boundary conditions and a piezoelectric actuator at its surface. The flap deflection, relative to the blade surface, is described by the assumed modes method. The flap bending modes are excited actively by means of a commercial piezoelectric actuator. Aerodynamically, the blade-flap system is modeled using an unsteady version of the vortex lattice method. In this model it is assumed that the viscous effects are confined at the boundary layer attached to the surface and the wake shed by the surface. The wake is modeled with vortex rings and it is allowed to move force-free. To capture the physical aspects from the control-fluid-structure interaction, the models are combined using a strong coupling technique. The equations of motion of the system are integrated numerically and interactively in the time domain. In addition, the stability and sensitivity of the system for input perturbations are analyzed. The results show the feasibility of using this type of system in large horizontal axis wind energy turbines.
Fil: Tripp, Nicolas Guillermo. Consejo Nacional de Investigaciones Científicas y Técnicas. Centro Científico Tecnológico Conicet - Mendoza; Argentina. Universidad Nacional de Cuyo. Facultad de Ingeniería; Argentina
Fil: Preidikman, Sergio. Consejo Nacional de Investigaciones Científicas y Técnicas; Argentina. Universidad Nacional de Córdoba; Argentina
Fil: Mirasso, Anibal Edmundo. Universidad Nacional de Cuyo. Facultad de Ingeniería; Argentina
Materia
WIND ENERGY
SMART BLADES
AEROSERVOELASTICITY
PIEZOELECTRIC TRANSDUCERS
Nivel de accesibilidad
acceso abierto
Condiciones de uso
https://creativecommons.org/licenses/by-nc-sa/2.5/ar/
Repositorio
CONICET Digital (CONICET)
Institución
Consejo Nacional de Investigaciones Científicas y Técnicas
OAI Identificador
oai:ri.conicet.gov.ar:11336/72893
Acceder
id CONICETDig_ffb9982f0b92f3a1b19f3cde558a0ab3
oai_identifier_str oai:ri.conicet.gov.ar:11336/72893
network_acronym_str CONICETDig
repository_id_str 3498
network_name_str CONICET Digital (CONICET)
spelling Modeling a lifting of a surface with an active smart flexible flapTripp, Nicolas GuillermoPreidikman, SergioMirasso, Anibal EdmundoWIND ENERGYSMART BLADESAEROSERVOELASTICITYPIEZOELECTRIC TRANSDUCERShttps://purl.org/becyt/ford/2.3https://purl.org/becyt/ford/2In the past years, the consumption of energy produced by wind turbines had an exponential growth. This requirement gave momentum to the development of larger turbines with the goal of producing more energy at the same site, reducing the initial investment, and the operation and maintenance costs. In order to achieve this objective, longer, lighter, maintenance-free blades are required so that smaller loads are transferred to the other, more expensive, wind turbine components. The resulting larger flexibility, imposes new challenges to the blade and controller designs; henceforth, new concepts are being developed to add more intelligence into these systems. During the last few years, the electronics industry had invested resources into the research and development of practical applications for piezoelectric ceramic materials. The result of this effort was the development of high precision piezoelectric actuators and sensors, which achieve forces and deformations that are compatible with the ones needed for the control of aerodynamic surfaces. In a former work by the authors, the aeroservoelastic behavior of a two dimensional (2D) wind turbine typical section with an active smart flexible flap was studied. In that work, the potential vibration control properties of an active flexible flap were exposed. In the present work, the study is extended to the three dimensional (3D) space. The flap is modeled as a flexible trailing edge, excited by a piezoelectric actuator, which allows the active morphing of the aerodynamic profile. Structurally, the flap is modeled as a continuum plate, with fixed-free boundary conditions and a piezoelectric actuator at its surface. The flap deflection, relative to the blade surface, is described by the assumed modes method. The flap bending modes are excited actively by means of a commercial piezoelectric actuator. Aerodynamically, the blade-flap system is modeled using an unsteady version of the vortex lattice method. In this model it is assumed that the viscous effects are confined at the boundary layer attached to the surface and the wake shed by the surface. The wake is modeled with vortex rings and it is allowed to move force-free. To capture the physical aspects from the control-fluid-structure interaction, the models are combined using a strong coupling technique. The equations of motion of the system are integrated numerically and interactively in the time domain. In addition, the stability and sensitivity of the system for input perturbations are analyzed. The results show the feasibility of using this type of system in large horizontal axis wind energy turbines.Fil: Tripp, Nicolas Guillermo. Consejo Nacional de Investigaciones Científicas y Técnicas. Centro Científico Tecnológico Conicet - Mendoza; Argentina. Universidad Nacional de Cuyo. Facultad de Ingeniería; ArgentinaFil: Preidikman, Sergio. Consejo Nacional de Investigaciones Científicas y Técnicas; Argentina. Universidad Nacional de Córdoba; ArgentinaFil: Mirasso, Anibal Edmundo. Universidad Nacional de Cuyo. Facultad de Ingeniería; ArgentinaAsociación Argentina de Mecánica Computacional2012-11info:eu-repo/semantics/articleinfo:eu-repo/semantics/publishedVersionhttp://purl.org/coar/resource_type/c_6501info:ar-repo/semantics/articuloapplication/pdfapplication/pdfhttp://hdl.handle.net/11336/72893Tripp, Nicolas Guillermo; Preidikman, Sergio; Mirasso, Anibal Edmundo; Modeling a lifting of a surface with an active smart flexible flap; Asociación Argentina de Mecánica Computacional; Mecánica Computacional; XXXI; 11-2012; 823-8392591-3522CONICET DigitalCONICETenginfo:eu-repo/semantics/altIdentifier/url/https://cimec.org.ar/ojs/index.php/mc/article/view/4098info:eu-repo/semantics/openAccesshttps://creativecommons.org/licenses/by-nc-sa/2.5/ar/reponame:CONICET Digital (CONICET)instname:Consejo Nacional de Investigaciones Científicas y Técnicas2025-09-03T09:43:36Zoai:ri.conicet.gov.ar:11336/72893instacron:CONICETInstitucionalhttp://ri.conicet.gov.ar/Organismo científico-tecnológicoNo correspondehttp://ri.conicet.gov.ar/oai/requestdasensio@conicet.gov.ar; lcarlino@conicet.gov.arArgentinaNo correspondeNo correspondeNo correspondeopendoar:34982025-09-03 09:43:36.828CONICET Digital (CONICET) - Consejo Nacional de Investigaciones Científicas y Técnicasfalse
dc.title.none.fl_str_mv Modeling a lifting of a surface with an active smart flexible flap
title Modeling a lifting of a surface with an active smart flexible flap
spellingShingle Modeling a lifting of a surface with an active smart flexible flap
Tripp, Nicolas Guillermo
WIND ENERGY
SMART BLADES
AEROSERVOELASTICITY
PIEZOELECTRIC TRANSDUCERS
title_short Modeling a lifting of a surface with an active smart flexible flap
title_full Modeling a lifting of a surface with an active smart flexible flap
title_fullStr Modeling a lifting of a surface with an active smart flexible flap
title_full_unstemmed Modeling a lifting of a surface with an active smart flexible flap
title_sort Modeling a lifting of a surface with an active smart flexible flap
dc.creator.none.fl_str_mv Tripp, Nicolas Guillermo
Preidikman, Sergio
Mirasso, Anibal Edmundo
author Tripp, Nicolas Guillermo
author_facet Tripp, Nicolas Guillermo
Preidikman, Sergio
Mirasso, Anibal Edmundo
author_role author
author2 Preidikman, Sergio
Mirasso, Anibal Edmundo
author2_role author
author
dc.subject.none.fl_str_mv WIND ENERGY
SMART BLADES
AEROSERVOELASTICITY
PIEZOELECTRIC TRANSDUCERS
topic WIND ENERGY
SMART BLADES
AEROSERVOELASTICITY
PIEZOELECTRIC TRANSDUCERS
purl_subject.fl_str_mv https://purl.org/becyt/ford/2.3
https://purl.org/becyt/ford/2
dc.description.none.fl_txt_mv In the past years, the consumption of energy produced by wind turbines had an exponential growth. This requirement gave momentum to the development of larger turbines with the goal of producing more energy at the same site, reducing the initial investment, and the operation and maintenance costs. In order to achieve this objective, longer, lighter, maintenance-free blades are required so that smaller loads are transferred to the other, more expensive, wind turbine components. The resulting larger flexibility, imposes new challenges to the blade and controller designs; henceforth, new concepts are being developed to add more intelligence into these systems. During the last few years, the electronics industry had invested resources into the research and development of practical applications for piezoelectric ceramic materials. The result of this effort was the development of high precision piezoelectric actuators and sensors, which achieve forces and deformations that are compatible with the ones needed for the control of aerodynamic surfaces. In a former work by the authors, the aeroservoelastic behavior of a two dimensional (2D) wind turbine typical section with an active smart flexible flap was studied. In that work, the potential vibration control properties of an active flexible flap were exposed. In the present work, the study is extended to the three dimensional (3D) space. The flap is modeled as a flexible trailing edge, excited by a piezoelectric actuator, which allows the active morphing of the aerodynamic profile. Structurally, the flap is modeled as a continuum plate, with fixed-free boundary conditions and a piezoelectric actuator at its surface. The flap deflection, relative to the blade surface, is described by the assumed modes method. The flap bending modes are excited actively by means of a commercial piezoelectric actuator. Aerodynamically, the blade-flap system is modeled using an unsteady version of the vortex lattice method. In this model it is assumed that the viscous effects are confined at the boundary layer attached to the surface and the wake shed by the surface. The wake is modeled with vortex rings and it is allowed to move force-free. To capture the physical aspects from the control-fluid-structure interaction, the models are combined using a strong coupling technique. The equations of motion of the system are integrated numerically and interactively in the time domain. In addition, the stability and sensitivity of the system for input perturbations are analyzed. The results show the feasibility of using this type of system in large horizontal axis wind energy turbines.
Fil: Tripp, Nicolas Guillermo. Consejo Nacional de Investigaciones Científicas y Técnicas. Centro Científico Tecnológico Conicet - Mendoza; Argentina. Universidad Nacional de Cuyo. Facultad de Ingeniería; Argentina
Fil: Preidikman, Sergio. Consejo Nacional de Investigaciones Científicas y Técnicas; Argentina. Universidad Nacional de Córdoba; Argentina
Fil: Mirasso, Anibal Edmundo. Universidad Nacional de Cuyo. Facultad de Ingeniería; Argentina
description In the past years, the consumption of energy produced by wind turbines had an exponential growth. This requirement gave momentum to the development of larger turbines with the goal of producing more energy at the same site, reducing the initial investment, and the operation and maintenance costs. In order to achieve this objective, longer, lighter, maintenance-free blades are required so that smaller loads are transferred to the other, more expensive, wind turbine components. The resulting larger flexibility, imposes new challenges to the blade and controller designs; henceforth, new concepts are being developed to add more intelligence into these systems. During the last few years, the electronics industry had invested resources into the research and development of practical applications for piezoelectric ceramic materials. The result of this effort was the development of high precision piezoelectric actuators and sensors, which achieve forces and deformations that are compatible with the ones needed for the control of aerodynamic surfaces. In a former work by the authors, the aeroservoelastic behavior of a two dimensional (2D) wind turbine typical section with an active smart flexible flap was studied. In that work, the potential vibration control properties of an active flexible flap were exposed. In the present work, the study is extended to the three dimensional (3D) space. The flap is modeled as a flexible trailing edge, excited by a piezoelectric actuator, which allows the active morphing of the aerodynamic profile. Structurally, the flap is modeled as a continuum plate, with fixed-free boundary conditions and a piezoelectric actuator at its surface. The flap deflection, relative to the blade surface, is described by the assumed modes method. The flap bending modes are excited actively by means of a commercial piezoelectric actuator. Aerodynamically, the blade-flap system is modeled using an unsteady version of the vortex lattice method. In this model it is assumed that the viscous effects are confined at the boundary layer attached to the surface and the wake shed by the surface. The wake is modeled with vortex rings and it is allowed to move force-free. To capture the physical aspects from the control-fluid-structure interaction, the models are combined using a strong coupling technique. The equations of motion of the system are integrated numerically and interactively in the time domain. In addition, the stability and sensitivity of the system for input perturbations are analyzed. The results show the feasibility of using this type of system in large horizontal axis wind energy turbines.
publishDate 2012
dc.date.none.fl_str_mv 2012-11
dc.type.none.fl_str_mv info:eu-repo/semantics/article
info:eu-repo/semantics/publishedVersion
http://purl.org/coar/resource_type/c_6501
info:ar-repo/semantics/articulo
format article
status_str publishedVersion
dc.identifier.none.fl_str_mv http://hdl.handle.net/11336/72893
Tripp, Nicolas Guillermo; Preidikman, Sergio; Mirasso, Anibal Edmundo; Modeling a lifting of a surface with an active smart flexible flap; Asociación Argentina de Mecánica Computacional; Mecánica Computacional; XXXI; 11-2012; 823-839
2591-3522
CONICET Digital
CONICET
url http://hdl.handle.net/11336/72893
identifier_str_mv Tripp, Nicolas Guillermo; Preidikman, Sergio; Mirasso, Anibal Edmundo; Modeling a lifting of a surface with an active smart flexible flap; Asociación Argentina de Mecánica Computacional; Mecánica Computacional; XXXI; 11-2012; 823-839
2591-3522
CONICET Digital
CONICET
dc.language.none.fl_str_mv eng
language eng
dc.relation.none.fl_str_mv info:eu-repo/semantics/altIdentifier/url/https://cimec.org.ar/ojs/index.php/mc/article/view/4098
dc.rights.none.fl_str_mv info:eu-repo/semantics/openAccess
https://creativecommons.org/licenses/by-nc-sa/2.5/ar/
eu_rights_str_mv openAccess
rights_invalid_str_mv https://creativecommons.org/licenses/by-nc-sa/2.5/ar/
dc.format.none.fl_str_mv application/pdf
application/pdf
dc.publisher.none.fl_str_mv Asociación Argentina de Mecánica Computacional
publisher.none.fl_str_mv Asociación Argentina de Mecánica Computacional
dc.source.none.fl_str_mv reponame:CONICET Digital (CONICET)
instname:Consejo Nacional de Investigaciones Científicas y Técnicas
reponame_str CONICET Digital (CONICET)
collection CONICET Digital (CONICET)
instname_str Consejo Nacional de Investigaciones Científicas y Técnicas
repository.name.fl_str_mv CONICET Digital (CONICET) - Consejo Nacional de Investigaciones Científicas y Técnicas
repository.mail.fl_str_mv dasensio@conicet.gov.ar; lcarlino@conicet.gov.ar
_version_ 1842268612985880576
score 13.13397

Publicaciones similares