H. Cheikh Sleiman, Murilo Henrique Moreira, Alessandro Tengattini, S. Dal Pont
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This study proposes a connection between tomography images and mesoscale models through a workflow that mainly employs open-source tools. This workflow is illustrated through the digitization of a Portland cement concrete sample, stemming from neutron tomographies and resulting in a numerical finite element mesh. The proposed workflow is flexible, allowing for the conversion of images from various sources, such as x-ray or neutron tomographies, to different numerical representations of the domain, such as finite element meshes or even a discrete domain required by discrete element methods, while preserving real morphologies with an accuracy proportionate to the specific need of the problem. Beside its generalizability, our method also offers automated labelling of the different domains and boundaries in both the volumetric and surface meshes, which is often necessary for assigning material properties and boundary conditions. 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引用次数: 0
摘要
层析成像等全场技术在复杂现象的研究中正变得越来越重要,尤其是在时空演变至关重要的情况下,如多孔介质中的水分传输或裂缝萌发。这些技术提供了对局部过程的独特见解,对这些过程的量化有助于提高我们的认识和改进描述这些过程的模型。然而,通过尝试明确表示异质性并模拟其在过程中的作用,可以进一步推动模型验证。这些模型一旦通过验证,就可以用来进行 "虚拟实验",克服实验的局限性(如样本大小和数量、边界和初始条件的精细控制)。本研究建议通过主要采用开源工具的工作流程,将断层扫描图像与中尺度模型连接起来。该工作流程以波特兰水泥混凝土样本的数字化为例来说明,其源于中子断层扫描,并产生了数值有限元网格。建议的工作流程非常灵活,可将不同来源的图像(如 X 射线或中子断层扫描)转换为不同的域数值表示,如有限元网格,甚至是离散元方法所需的离散域,同时保留真实形态,其精度与问题的特定需求成正比。除通用性外,我们的方法还能自动标注体积网格和曲面网格中的不同域和边界,这对于分配材料属性和边界条件来说通常是必要的。最后,这项工作中描述的一系列图像、几何和网格处理步骤可在 GitHub 存储库中获取。
From tomographic imaging to numerical simulations: an open-source workflow for true morphology mesoscale FE meshes
Full-field techniques such as tomography are becoming progressively more central in the study of complex phenomena, in particular where spatiotemporal evolution is crucial, as in moisture transport or crack initiation in porous media. These techniques provide a unique insight in the local process whose quantification allows the improvement of our understanding and of the models describing them. Nevertheless, the model validation can be pushed further by attempting to explicitly represent the heterogeneities and simulate their role in the processes. Once validated, these models can be used to perform “virtual experiments”, and overcome the limitations of the experiments (e.g., sample size and number, fine control of the boundary and initial conditions). This study proposes a connection between tomography images and mesoscale models through a workflow that mainly employs open-source tools. This workflow is illustrated through the digitization of a Portland cement concrete sample, stemming from neutron tomographies and resulting in a numerical finite element mesh. The proposed workflow is flexible, allowing for the conversion of images from various sources, such as x-ray or neutron tomographies, to different numerical representations of the domain, such as finite element meshes or even a discrete domain required by discrete element methods, while preserving real morphologies with an accuracy proportionate to the specific need of the problem. Beside its generalizability, our method also offers automated labelling of the different domains and boundaries in both the volumetric and surface meshes, which is often necessary for assigning material properties and boundary conditions. Finally, the series of image, geometry and mesh processing steps described in this work are made available on a GitHub repository.