Elastic, Plastic Behavior of Rotor : Part 1, Analysis of Axi-Symmetric Rotor Whose Radius Varies in Axial Direction

Three-dimensional structure of trabecular bone can be modeled by 2D or 3D Voronoi structure. The effect of missing cell walls on the mechanical properties of 2D honeycombs is a first step towards understanding the effect of local bone resorption due to osteoporosis. In patients with osteoporosis, bone mass is lost first by thinning and then by resorption of the trabeculae [1]. Furthermore, creep response is important to analyze in cellular solids when the temperature is high relative to the melting temperature. For trabecular bone, as body temperature (38 °C) is close to the denaturation temperature of collagen (52 °C), trabecular bone creeps [1]. Over the half of the osteoporotic vertebral fractures that occur in the elderly, are the result of the creep and fatigue loading associated with the activities of daily living [2]. The objective of this work is to understand the effect of missing walls and filled cells on elastic-plastic behavior of both regular hexagonal and non-periodic Voronoi structures using finite element analysis. The results show that the missing walls have a significant effect on overall elastic properties of the cellular structure. For both regular hexagonal and Voronoi materials, the yield strength of the structure decreased by more than 60% by introducing 10% missing walls. In contrast, the results indicate that filled cells have much less effect on the mechanical properties of both regular hexagonal and Voronoi materials.

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Thermal Annealing Effect on Elastic-Plastic Behavior of Al-Si-Cu Structural Films Under Uniaxial and Biaxial Tension

Journal of Microelectromechanical Systems ◽

10.1109/jmems.2013.2257985 ◽

2013 ◽

Vol 22 (6) ◽

pp. 1414-1427 ◽

Cited By ~ 7

Author(s):

Takahiro Namazu ◽

Masayuki Fujii ◽

Hiroki Fujii ◽

Kei Masunishi ◽

Yasushi Tomizawa ◽

...

Keyword(s):

Thermal Annealing ◽

Biaxial Tension ◽

Annealing Effect ◽

Plastic Behavior ◽

Elastic Plastic

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Elastic-plastic bending of the pipeline under combined loading

SCIENCE & TECHNOLOGIES OIL AND OIL PRODUCTS PIPELINE TRANSPORTATION ◽

10.28999/2541-9595-2021-11-4-372-377 ◽

2021 ◽

pp. 372-377

Author(s):

Виктор Миронович Варшицкий ◽

Евгений Павлович Студёнов ◽

Олег Александрович Козырев ◽

Эльдар Намикович Фигаров

Keyword(s):

Internal Pressure ◽

Limit State ◽

Bending Moment ◽

Axial Direction ◽

Longitudinal Force ◽

Combined Loading ◽

Dimensional Problem ◽

Elastic Plastic ◽

Pipeline Section ◽

Thin Walled Pipe

Рассмотрена задача упругопластического деформирования тонкостенной трубы при комбинированном нагружении изгибающим моментом, осевой силой и внутренним давлением. Решение задачи осуществлено по разработанной методике с помощью математического пакета Matcad численным методом, основанным на деформационной теории пластичности и безмоментной теории оболочек. Для упрощения решения предложено сведение двумерной задачи к одномерной задаче о деформировании балки, материал которой имеет различные диаграммы деформирования при сжатии и растяжении в осевом направлении. Проведено сравнение с результатами численного решения двумерной задачи методом конечных элементов в упругопластической постановке. Результаты расчета по инженерной методике совпадают с точным решением с точностью, необходимой для практического применения. Полученные результаты упругопластического решения для изгибающего момента в сечении трубопровода при комбинированном нагружении позволяют уточнить известное критериальное соотношение прочности сечения трубопровода с кольцевым дефектом в сторону снижения перебраковки. Применение разработанной методики позволяет ранжировать участки трубопровода с непроектным изгибом по степени близости к предельному состоянию при комбинированном нагружении изгибающим моментом, продольным усилием и внутренним давлением. The problem of elastic plastic deformation of a thin-walled pipe under co-binned loading by bending moment, axial force and internal pressure is considered. The problem is solved by the developed method using the Matcad mathematical package by a numerical method based on the deformation theory of plasticity and the momentless theory of shells. To simplify the solution of the problem, it is proposed to reduce a twodimensional problem to a one-dimensional problem about beam deformation, the material of which has different deformation diagrams under compression and tension in the axial direction. Comparison with the results of numerical solution of the two-dimensional problem with the finite element method in the elastic plastic formulation is carried out. The obtained results of the elastic-plastic solution for the bending moment in the pipeline section under combined loading make it possible to clarify criterion ratio of the strength of the pipeline section with an annular defect in the direction of reducing the rejection. Application of the developed approach allows to rank pipeline sections with non-design bending in the steppe close to the limit state under combined loading of the pipeline with bending moment, longitudinal force and internal pressure.

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Load Regime Diagram of a Pipe With Cyclically Plastic Bending

10th International Conference on Nuclear Engineering, Volume 1 ◽

10.1115/icone10-22100 ◽

2002 ◽

Author(s):

Yanping Yao ◽

Ming-Wan Lu

Keyword(s):

Axial Force ◽

Bending Moment ◽

Boundary Curve ◽

Plastic Behavior ◽

Cyclic Bending ◽

Elastic Plastic ◽

Linear Elastic ◽

Load Regime ◽

Reversed Cyclic ◽

Cyclic Bending Moment

The criteria of piping seismic design based on linear elastic analysis has been proved to be conservative, which is mainly because the influence of plastic deformation on piping dynamic response is neglected. In the present paper, a pipe under seismic excitation is simplified as an beam with tubular cross section subjected to steady axial force and fully reversed cyclic bending moment, and the elastic-plastic behavior of the pipe is studied. Various behavior of the pipe under different combinations of axial force and cyclic bending moment is discussed and the boundary curve equations between them are obtained. Also the load regime diagram for a pipe which is formed by the boundary curve equations in the loading plane is given, from which the elastic-plastic behavior of the pipe can be determined directly.

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