2D Mesh Study of Simulated Mechanical Loading on Thoracic Cross-Sectional Image

2021 4th International Conference on Bio-Engineering for Smart Technologies (BioSMART) Pub Date : 2021-12-08 DOI:10.1109/BioSMART54244.2021.9677819

Samar Shaabeth, Zahraa Abdeljaleel

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Abstract

Mesh quality is considered a verification step in the validation procedure for computational modelling. In this paper, the element meshing size was studied using computational mesh quality check method for two dimensional computed tomographic image of the human thorax. Three cases of healthy adults (aged 60, 45 and 36) were scanned and two layers for each set of images were segmented and modelled with two pinpoint mechanical loading (CPR and Kick). Segmentation was done using SOLIDWORKS software while meshing and simulation were performed using ANSYS. The meshing method was performed in the modelling simulation software and five-element sizes were tested for the geometry (3, 2, 1, 0.7, and 0.5 mm). In each case, simulation was run with recording the strain and total deformation for comparing the strain range change while changing the element size. Additional parameters for the simulation software were measured to record the mesh quality before each simulation ensuring the convergence each time. In conclusion, meshing element size was found to be a significant factor even for two-dimensional finite element model and element size reduction can be limited to 0.7mm without the need for further reduction for lower computational time and effort.

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胸部横断面图像模拟机械载荷的二维网格研究

网格质量被认为是计算建模验证过程中的一个验证步骤。本文采用计算网格质量检验方法对人体胸部二维计算机层析图像的单元网格尺寸进行了研究。对3例健康成人(60岁、45岁和36岁)进行扫描，并对每组图像进行两层分割，并用两种精确机械载荷(CPR和Kick)建模。采用SOLIDWORKS软件进行分割，采用ANSYS软件进行网格划分和仿真。在建模仿真软件中进行网格划分方法，并对几何尺寸(3,2,1,0.7和0.5 mm)进行了五元尺寸测试。在每种情况下，进行模拟，记录应变和总变形，比较改变单元尺寸时应变范围的变化。在每次模拟前，对仿真软件的附加参数进行测量，以记录网格质量，确保每次的收敛性。综上所述，即使对于二维有限元模型，网格单元尺寸也是一个重要的影响因素，为了减少计算时间和工作量，可以将网格单元尺寸减小到0.7mm，而无需进一步减小。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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2021 4th International Conference on Bio-Engineering for Smart Technologies (BioSMART)

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