Mohamed T. Abdel-Fattah scite author profile

This paper introduces a finite-element solution for simulating the filling process of ground-supported concrete silos filled with saturated granular material. An elasto-plastic axisymmetric finite-element model is used to represent both the granular material and the concrete silo. The interaction between the two materials is modeled using interface elements to allow for relative movement. The filling process is idealized via a multi-stage numerical technique capable of representing both undrained and drained conditions for the granular material. The effects of the relative stiffness between the foundation and wall are examined, as are the boundary conditions at the top of the structure (the roof details).Depending on the drainage properties of the stored material, the effect of the filling process may be time-dependent. The excess pore water pressure resulting from the filling process may cause a substantial increase in the hoop stresses in the wall. The predicted internal forces may be influenced by the foundation rigidity, but not by the boundary condition at the top of the wall.The results of these analyses may be used to design experiments to evaluate existing silos, or to develop filling strategies to minimize loads on existing structures.

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Behavior of Integral Frame Abutment Bridges Due to Cyclic Thermal Loading: Nonlinear Finite-Element Analysis

Abdel-Fattah¹,

Abdel-Fattah

2019

J. Bridge Eng.

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Behaviour of elevated concrete silos filled with saturated solids

Abdel-Fattah¹,

Moore²,

Abdel-Fattah³

2006

Can. J. Civ. Eng.

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A finite-element solution is introduced for simulating the filling process of elevated concrete silos filled with saturated solids. An axisymmetric finite-element model is used to represent both the solids and the structure. The bulk solids are modeled using an elastoplastic model, whereas the structure is modeled using a linear elastic model. The interaction between the two materials is modeled using interface elements to permit relative movement. The filling process is idealized via a multistage numerical technique capable of representing both undrained and drained conditions. The effect of the filling process may be time-dependent. The excess pore-water pressure caused by the filling process may significantly influence the magnitudes of internal forces. Moreover, the design critical sections of the same silo element may correspond to different bulk solid conditions (undrained or drained). Practically, the ring beam stiffness may only influence hoop compressions in the silo elements at the wall-hopper junction. The results presented may be used to design tests to evaluate existing silos.Résumé : Une solution par éléments finis pour la simulation du processus d'ensilage des silos en béton surélevés remplis de solides saturés est présentée. Un modèle par éléments finis axisymétriques est utilisé pour représenter à la fois les solides et la structure. Les solides en vrac sont modélisés en utilisant un modèle élasticimétrique, alors que la structure est modélisée en utilisant un modèle élastique linéaire. L'interaction entre les deux matériaux est modélisée en utilisant des éléments d'interface afin de permettre un mouvement relatif. Le processus de remplissage est idéalisé par une technique numérique à plusieurs étages capable de représenter à la fois les conditions non drainées et les conditions drainées. L'effet du processus d'ensilage peut être dépendant du temps. La pression interstitielle excessive causée par le processus d'ensilage peut grandement influencer les amplitudes des forces internes. De plus, les sections importantes pour la conception du même élément de silo peuvent correspondre à différentes conditions de solides en vrac (non drainés et drainés). En pratique, la rigidité de la poutre annulaire peut seulement influencer les compressions des cerceaux dans les éléments de silos à la jonction mur-trémie. Les résultats présentés peuvent être utilisés pour concevoir des essais visant à évaluer les silos existants.Mots clés : silo en béton surélevé, ensilage, analyse par éléments finis, modèle élasticimétrique, consolidation, trémie, rigidité de la poutre annulaire.[Traduit par la Rédaction] Abdel-Fattah et al. 239

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Modeling and safety assessment of a piled raft comprising defective piles

Abdel-Fattah¹,

Hemada²,

Abdel-Fattah³

2014

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