A Closed Loop Controller Design Which Can Minimize the Wind Effects on a Parabolic Solar Tracker

J. Díaz-Salgado; O. M. Huerta-Chávez; E. A.Villegas Jimenez; E. Enciso-Contreras; L. A. Cortés-Marín; C. Ortiz-Cil

doi:10.1007/978-3-030-45402-9_30

A Closed Loop Controller Design Which Can Minimize the Wind Effects on a Parabolic Solar Tracker

J. Díaz-Salgado, O. M. Huerta-Chávez, E. A.Villegas Jimenez, E. Enciso-Contreras, L. A. Cortés-Marín, C. Ortiz-Cil

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Resumen

In the present work, it was conducted a steady-state fluid analysis to obtain the aerodynamic coefficients of a Parabolic Solar Tracker (PST) for different azimuth and elevation angles. A computational fluid dynamic (CFD) wind flow analysis technique was applied to model an extreme weather condition called North Wind (NW), which can severely affect the PST under operational conditions. The North Wind case simulated was validated using experimental data without bottom effects in order to verify the degree of approximation between the results obtained with CFD approach. The obtained aerodynamic coefficients were used to: (i) establish both analytical and numerical models for each PST degree of freedom for dynamic analysis and simulation purposes, (ii) design different closed loop controllers which can minimize the wind effects and (iii) to establish a correct dimensioning of the control actuators.

Idioma original	Inglés
Páginas (desde-hasta)	310-326
Número de páginas	17
Publicación	Mechanisms and Machine Science
Volumen	86
DOI	https://doi.org/10.1007/978-3-030-45402-9_30
Estado	Publicada - 2020
Publicado de forma externa	Sí

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title = "A Closed Loop Controller Design Which Can Minimize the Wind Effects on a Parabolic Solar Tracker",

abstract = "In the present work, it was conducted a steady-state fluid analysis to obtain the aerodynamic coefficients of a Parabolic Solar Tracker (PST) for different azimuth and elevation angles. A computational fluid dynamic (CFD) wind flow analysis technique was applied to model an extreme weather condition called North Wind (NW), which can severely affect the PST under operational conditions. The North Wind case simulated was validated using experimental data without bottom effects in order to verify the degree of approximation between the results obtained with CFD approach. The obtained aerodynamic coefficients were used to: (i) establish both analytical and numerical models for each PST degree of freedom for dynamic analysis and simulation purposes, (ii) design different closed loop controllers which can minimize the wind effects and (iii) to establish a correct dimensioning of the control actuators.",

keywords = "CFD, Parabolic Solar Tracker, Solar energy and control",

author = "J. D{\'i}az-Salgado and Huerta-Ch{\'a}vez, {O. M.} and Jimenez, {E. A.Villegas} and E. Enciso-Contreras and Cort{\'e}s-Mar{\'i}n, {L. A.} and C. Ortiz-Cil",

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doi = "10.1007/978-3-030-45402-9_30",

language = "Ingl{\'e}s",

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T1 - A Closed Loop Controller Design Which Can Minimize the Wind Effects on a Parabolic Solar Tracker

AU - Díaz-Salgado, J.

AU - Huerta-Chávez, O. M.

AU - Jimenez, E. A.Villegas

AU - Enciso-Contreras, E.

AU - Cortés-Marín, L. A.

AU - Ortiz-Cil, C.

PY - 2020

Y1 - 2020

N2 - In the present work, it was conducted a steady-state fluid analysis to obtain the aerodynamic coefficients of a Parabolic Solar Tracker (PST) for different azimuth and elevation angles. A computational fluid dynamic (CFD) wind flow analysis technique was applied to model an extreme weather condition called North Wind (NW), which can severely affect the PST under operational conditions. The North Wind case simulated was validated using experimental data without bottom effects in order to verify the degree of approximation between the results obtained with CFD approach. The obtained aerodynamic coefficients were used to: (i) establish both analytical and numerical models for each PST degree of freedom for dynamic analysis and simulation purposes, (ii) design different closed loop controllers which can minimize the wind effects and (iii) to establish a correct dimensioning of the control actuators.

AB - In the present work, it was conducted a steady-state fluid analysis to obtain the aerodynamic coefficients of a Parabolic Solar Tracker (PST) for different azimuth and elevation angles. A computational fluid dynamic (CFD) wind flow analysis technique was applied to model an extreme weather condition called North Wind (NW), which can severely affect the PST under operational conditions. The North Wind case simulated was validated using experimental data without bottom effects in order to verify the degree of approximation between the results obtained with CFD approach. The obtained aerodynamic coefficients were used to: (i) establish both analytical and numerical models for each PST degree of freedom for dynamic analysis and simulation purposes, (ii) design different closed loop controllers which can minimize the wind effects and (iii) to establish a correct dimensioning of the control actuators.

KW - CFD

KW - Parabolic Solar Tracker

KW - Solar energy and control

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U2 - 10.1007/978-3-030-45402-9_30

DO - 10.1007/978-3-030-45402-9_30

M3 - Artículo

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SN - 2211-0984

VL - 86

SP - 310

EP - 326

JO - Mechanisms and Machine Science

JF - Mechanisms and Machine Science

ER -

A Closed Loop Controller Design Which Can Minimize the Wind Effects on a Parabolic Solar Tracker

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