Nonwovens modelling: a review of finite-element strategies

Farukh, Farukh; Demirci, Emrah; Ali, Hassan; Acar, Memiş; Pourdeyhimi, Behnam; Silberschmidt, Vadim V.

doi:10.1080/00405000.2015.1022088

Cited by 13 publications

(5 citation statements)

References 27 publications

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“…Due to lower computational costs, two-dimensional models in the transverse plane, for which the networks are generated by the sequential random deposition of fibers connected together at their intersections, have been used to determine the in-plane mechanical behavior of specimens with thickness of order of one tenth or less of average fiber length [6,[15][16][17]. By means of these models, it is possible to directly compute the in-plane mechanical properties for the entire solution domain, which is computationally expensive; or to solve the boundary value problem (BVP) on the representative volume element (RVE), which is usually in the form of repetitive structural units representing the subscales of the material, resulting in the effective mechanical properties [18][19][20].…”

Section: Introductionmentioning

confidence: 99%

On the computational homogenization of three-dimensional fibrous materials

Karakoҫ

Paltakari

Taciroğlu

2020

Composite Structures

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Section: Introductionmentioning

confidence: 99%

On the computational homogenization of three-dimensional fibrous materials

Karakoҫ

Paltakari

Taciroğlu

2020

Composite Structures

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“…In microstructural models, geometrical and other physical properties are modeled for each constituent separately, which increases the computational cost. However, it is possible to determine the stresses and strains in each constituent accurately wherein the properties of the material and its constituents can be directly related to each other in microstructural models [18].…”

Section: Introductionmentioning

confidence: 99%

Geometrical and spatial effects on fiber network connectivity

Karakoç

Hiltunen

Paltakari

2017

Composite Structures

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For fibrous materials such as nonwoven fabrics, paper and paperboards, inter-fiber bonds play a critical role by holding fibers, thus providing internal cohesion. Being a physical phenomenon, inter-fiber bonds occur at every fiber crossing and can be also geometrically detected. In relation to the idea, a statistical geometrical model was developed to investigate the effects of fiber geometry, (i.e. length and cross-sectional properties), spatial distribution, (i.e. location and orientation), and specimen size on fiber network connectivity, which refers to inter-fiber bonds at fiber crossings. In order to generate the fiber network, a geometrical fiber deposition technique was coded in Mathematica technical computing software, which is based on the planar projections and intersections of fibers and provided as supplementary material to the present article. According to this technique, fiber geometries in discrete rectangular prismatic segments were generated by using uniform distributions of the geometrical and spatial parameters and projected onto the transverse plane. Then, projected geometries were trimmed within the transverse boundaries of the specified specimen shape, rectangular prism in this particular study. After this step, fiber crossings were determined through a search algorithm, which was also used as the basis for the fiber spatial regeneration. Thereafter, fibers were accumulated on top of each other by taking fiber crossings into account and eventually fiber networks based on selected properties were formed. By means of the proposed technique, a series of simulation experiments were conducted on paper fiber networks to investigate the correlation between the fiber network connectivity and fiber length, cross-sectional properties, orientation and specimen length, width and thickness.

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“…У роботах [110][111][112][113][114][115][116][117][118][119][120][121][122][123][124][125][126] розглянуті питання моделювання властивостей матеріалів мережевої структури у різних аспектах. Так, у [111] відзначено, що волокнисті матеріали, такі як папір, неткані матеріали, текстиль, біоматеріали на основі наноцелюлози, полімерні сітки і композити, є широко використовуваними універсальними інженерними матеріалами.…”

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“…Огляди стосовно моделювання властивостей волоконних иатеріалів описані у [116,123,124]. Зокрема, у статті [116] розглядаються основні стратегії, що використовуються для моделювання механічної поведінки нетканих матеріалів, яка визначається структурою їх волокнистих сіток і механічною поведінкою складових їх волокон або ниток. У першій частині обговорюються основні параметри, що впливають на мережеву структуру нетканих матеріалів.…”

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Development of Statistically Averaged Models of Deformation of Materials With Random Network Structure of Differently Oriented Fibers

Tkachuk¹

2021

МіСАПР

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The paper describes the developed statistically averaged models of deformation of materials with a random network structure of differently oriented fibers. New methods of stress-strain analysis and micromacromechanical models of material deformation in the volume of bodies made of material with a network structure taking into account structural and physical nonlinearities have been created. These models are based on the micromechanics of network structures at the level of statistical sets of their chains. The novelty of approaches, models, methods and results is the creation of theoretical foundations for the analysis of the deformation of non-traditional network materials. Nonlinear mathematical models of material deformation in the form of a chaotic network structure of one-dimensional fragments are proposed, which are constructed involving fundamentally new approaches to the description of physical and mechanical properties at the micro level of statistical sets of fiber chains and spatial homogenization of their macroproperties. Compared to traditional models, they more adequately model the features of material deformation in the form of spatial chaotic and ordered network structures, as they do not involve a number of additional non-physical hypotheses. This creates fundamentally new opportunities not only for analyzing the properties of such materials, but also when creating new ones with specified properties. Using the created methods, models and research tools, the basis for solving a number of model and applied problems has been created. The nature of deformation of non-traditional materials with a network structure of one-dimensional elements is determined. The macro-properties of these materials are established on the basis of the developed micromechanical models, variational formulations and averaging methods. Keywords: stress-strain state, network structures, contact interaction, finite element method, contact pressure, machine parts, variational formulation

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Nonwovens modelling: a review of finite-element strategies

Cited by 13 publications

References 27 publications

On the computational homogenization of three-dimensional fibrous materials

On the computational homogenization of three-dimensional fibrous materials

Geometrical and spatial effects on fiber network connectivity

Development of Statistically Averaged Models of Deformation of Materials With Random Network Structure of Differently Oriented Fibers

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