Your search keyword '"Israfilova, Alina"' showing total 5 results

1. Isogeometric analysis for accurate modeling of rolling tires

Author

Garcia, Mario A., Israfilova, Alina, Liang, Guanqun, Zhao, Tong, Wei, Yintao, and Kaliske, Michael

Published

2022

2. Isogeometric Analysis for Tire Simulations: From Mesh Generation to High Precision Results

Author

Israfilova, Alina, primary, Garcia, Mario A., additional, and Kaliske, Michael, additional

Published

2021

3. Local Refinement in Isogeometric Analysis of Complex Tire Models

Author

Israfilova, Alina, primary, Garcia, Mario A., additional, and Kaliske, Michael, additional

Published

2021

4. Изо-геометрический метод расчета как альтернатива стандартному методу конечных элементов

Author

Israfilova, Alina, Kutrunov, Vladimir, Garcia Tzintzun, Mario Alejandro, and Kaliske, Michael

Subjects

rational B-splines, Isogeometric analysis, Finite element method, NURBS, рациональные B-сплайны, метод конечных элементов, FEAP, Изо-геометрический анализ

Abstract

В статье рассмотрена модификация метода конечных элементов, так называемый изо-геометрический метод, использующая в качестве базисных функций рациональные B-сплайны (NURBS). Новый подход должен предотвратить аппроксимацию геометрии рассчитываемого тела и обеспечить гладкость базисных функций на границе конечных элементов. В статье выполнен краткий обзор рациональных B-сплайнов, описаны их основные свойства, выполнен обзор существующих на сегодняшний день программных продуктов, в которых описанный метод реализован в той или иной степени. В тексте приведены примеры расчета простых твердых тел в программе FEAP (Finite Element Analysis Program) для сопоставления результатов, полученных стандартным и модифицированным методами. В изо-геометрическом методе расчета геометрия тела остается точной независимо от размера расчетной сетки, что повышает точность решения контактных задач и анализа композитных тел. Знакопостоянность рациональных B-сплайнов повышает качество получаемых полей искомых переменных. Геометрия для расчета может быть получена напрямую из графических редакторов CAD без изменения, что является необходимым шагом по направлению к внедрению технологий BIM в проектировании. Преимущества описанного метода делают его выгодной альтернативой при расчете тел с криволинейными очертаниями., In the article, the modification of the Finite Element Method, the so-called Isogeometric Analysis, which employs rational B-splines (NURBS) as basis-functions is considered. The new approach is aimed to prevent approximation of the geometry and provide higher continuity on elements’ borders. A brief review of rational B-splines is made, their basic properties are described, a review of existing today software products in which the described method is implemented to some extent is executed. In the contribution, a numerical example of analysis for a simple solid body in FEAP (Finite Element Analysis Program) is given for comparing results obtained by standard and modified methods. In the Isogeometric approach, the geometry of the analysed body stays exact no matter how coarse is the computational mesh. This leads to the more robust solution of the contact problems and of the composites analysis. Non-negative basis functions increase the quality of the created continuous variable fields. Moreover, the geometry for analysis can be obtained directly from CAD graphical editors, which becomes an important step towards the introduction of BIM technology in engineering design. The advantages of this method illustrate that it can be preferred for structural analysis of solids especially in cases when complex curved geometry has to be considered.

Published

2019

5. Local Refinement in Isogeometric Analysis of Detailed Tire Models.

Author

Israfilova, Alina, Garcia, Mario A., and Kaliske, Michael

Subjects

*ISOGEOMETRIC analysis, *FINITE element method, *ZONE melting, *RELATIVE velocity, *SAMPLING (Process), *TRACKING algorithms

Abstract

Isogeometric Analysis (IGA) and its unconventional basis functions bring undeniable benefits to the numerical analysis of solid bodies with a complex geometrical shape such as pneumatic tires. This approach erases barriers between the stage of design and the computational environment. Preservation of the exact geometrical description of the real body and the nature of functions at hand allow for higher precision of simulations for different physical phenomena. This contribution is aimed to show further developments in the framework for rolling simulation of tires using IGA. The large support of Non‐Uniform Rational B‐Splines (NURBS) provides continuous variable fields along the contact patch. Truncated hierarchical B‐splines (THB‐splines), implemented into an in‐house Finite Element Analysis (FEA) code, improve the modeling of tires by locally refining the contact zone. Global extraction operators bring the hierarchical concept as close as possible to a standard FEA code structure, flattening the set of nested layers of mesh into a sequence of single‐level elements. Furthermore, an algorithm for the computation of the accelerations at material points based on the relative velocities is adapted. The outlook of this development is the intention to use this algorithm in possible combination with analytical models for the in‐situ estimation of forces and to capture certain mechanical behavior which often are not tracked in experiments or hard and too costly to reproduce. The sampling procedure within the hierarchically nested basis is elaborated with attention to required adjustments for the nested parent‐child layered analytical meshes created via the introduction of the selective global multilevel extraction operators. Numerical simulations of rolling tires at steady‐state using IGA are presented. The evaluation and comparison of the developed framework are done using uniformly refined and locally refined models in IGA as well as classical FEA models. [ABSTRACT FROM AUTHOR]

Published

2023