Diseño óptimo de armaduras empleando optimización con ondas del agua

Carlos Millán Páramo

doi:10.17981/ingecuc.13.2.2017.11

Autores/as

Carlos Millán Páramo Universidad Tecnológica Federal de Paraná. Curitiba (Brasil) Universidad de Sucre. Sincelejo (Colombia) http://orcid.org/0000-0002-0004-6063

DOI:

https://doi.org/10.17981/ingecuc.13.2.2017.11

Palabras clave:

Optimización con ondas del agua, optimización estructural, armaduras, metaheurística

Resumen

Introducción: En los últimos años, la importancia de los aspectos económicos en el campo de las estructuras ha motivado a muchos investigadores a emplear nuevos métodos para minimizar el peso de las estructuras. El objetivo principal de la optimización estructural (diseño óptimo) es minimizar el peso de las estructuras al tiempo que se satisfacen todos los requerimientos impuestos por los códigos de diseño.
Objetivo: En este estudio, el algoritmo Optimización con Ondas del Agua (Water Wave Optimization - WWO), es implementado para resolver el problema de optimización estructural de armaduras en 2D y 3D.
Metodología: El estudio está compuesto por tres fases principales: 1) formulación del problema de optimización estructural; 2) estudio de los fundamentos y parámetros que controlan al algoritmo WWO y 3) evaluar el desempeño del WWO en problemas optimización de armaduras reportadas en la literatura especializada.
Resultados: Los valores de peso, peso promedio, desviación estándar y número total de análisis ejecutados para converger al diseño óptimo conseguidos con WWO indican que el algoritmo es una buena herramienta para minimizar el peso de armaduras sujetas a restricciones de esfuerzo y desplazamientos.
Conclusiones: Se observó que el algoritmo WWO es eficaz, eficiente y robusto, para resolver diversos tipos de problemas, con diferentes números de elementos. Además, WWO requiere menor número de análisis para converger al diseño óptimo en comparación con otros algoritmos

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Citas

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Diseño óptimo de armaduras empleando optimización con ondas del agua

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