利用仿生学优化薄壳网孔尺寸,寻求可持续解决方案

IF 0.5 Q4 ENGINEERING, BIOMEDICAL Journal of Biomimetics, Biomaterials and Biomedical Engineering Pub Date : 2023-07-31 DOI:10.4028/p-XYcl3m
Pennarasi Gunasekaran, S. Nachiar, S. Subramanian, A. Sekar
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引用次数: 0

摘要

大自然总是有能力在工程和科学的各个领域为人类的日常生活提供各种解决方案。仿生一词是指采用自然界的解决方案来解决复杂问题的过程,指的是分析环境以获得可持续的解决方案。这一概念被用于工程和科学的各个领域。这个概念现在也出现在建筑领域。仿生概念用于分析结构元素的行为,这些结构元素在环境和建筑之间形成共生关系。在建筑领域中,薄壁结构是轻质结构,其优选作为覆盖高跨度的屋顶元件,并且还具有美观的外观。在这项研究中,考虑了三种不同形状,如具有不同升跨比的球形、圆形和椭圆形。考虑将人类头骨形状反射成薄壳结构的概念,因为来自环境的反射有助于解决工程和科学的复杂问题。本研究的重点是使用Ansys 18.1软件进行数值分析的网格收敛性研究。薄壳的厚度、跨度和隆起等参数取自扫描的人类头骨模型的几何特征,并与标准头骨模型进行了比较。根据结果,对所考虑的三种不同形状的网格尺寸进行了优化,并预测了最有效的模型。这些结果是基于等效应力与各个模型的理论应力进行比较而获得的。这项研究启发了环境中自然可用的形式,将其纳入建筑和技术领域,以获得可持续的解决方案。
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Optimizing Mesh Sizes of Thin Shells Using Biomimicry for a Sustainable Solution
Nature always has the ability to offer various solutions in day-to-day life of humans in various fields of engineering and science. The term biomimicry refers to the process of adopting solutions from nature to solve complicated problems that refers to analysing the environment for sustainable solutions. This concept is used in various fields of engineering and science. This concept is emerging now in the field of construction also. Biomimics concept is used in analysing the behaviour of structural elements which forms a symbiosis between the environment and construction. In the field of construction, thin shell structures are lightweight structures that are preferred as roof elements for covering high spans and also gives an aesthetic appearance. In this study, three different shapes like spherical with different rise to span ratios, circular and elliptical are considered. The concept of reflecting the human skull shape into thin shell structures was considered, because the reflection from the environment helps in solving the complicated problems of both engineering and sciences. This study focused on the mesh convergence study for numerical analysis using Ansys 18.1 software. The parameters of the thin shells such as thickness, span and rise were taken from the geometrical characteristics of scanned human skull models in comparison with the standard skull models. From the results, mesh sizes were optimized for the three different shapes considered and also predicted the most efficient model. These results were obtained based on the equivalent stress in comparison with the theoretical stresses of the respective models. This study inspires the naturally available forms in the environment to incorporate it in the field of construction and technology for a sustainable solution.
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CiteScore
1.40
自引率
14.30%
发文量
73
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