Finite element analysis of fracture statistics of ceramics: Effects of grain size and pore size distributions

In this article, the effects of Cu microstructure on the mechanical properties and extrusion of through-silicon vias (TSVs) were studied based on two types of TSVs with different microstructure. A direct correlation was found between the grain size and the mechanical properties of the vias. Both an analytical model and finite element analysis (FEA) were used to establish the relationship between the mechanical properties and via extrusion. The effect of via/Si interface on extrusion was also studied by FEA. The results suggest small and uniform grains in the Cu vias, as well as stronger interfaces between the via and Si led to smaller via extrusion, and are thus preferable for reduced via extrusion failure and improved TSV reliability.

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Modelling Microstructure Evolution in ATI 718Plus® Alloy

Key Engineering Materials ◽

10.4028/www.scientific.net/kem.716.352 ◽

2016 ◽

Vol 716 ◽

pp. 352-359

Author(s):

Aleksey Reshetov ◽

Olga Bylya ◽

Michal Gzyl ◽

Malgorzata Rosochowska ◽

Paul Blackwell

Keyword(s):

Finite Element Analysis ◽

Grain Size ◽

Finite Element ◽

Grain Growth ◽

Microstructure Evolution ◽

Deformation Process ◽

Main Trend ◽

Main Body ◽

Element Analysis ◽

Average Grain Size

The present study details the results of finite element analysis (FEA) based predictions for microstructure evolution in ATI 718Plus® alloy during the hot deformation process. A detailed description of models for static grain growth and recrystallisation is provided. The simulated average grain size is compared with those experimentally measured in aerofoil parts after forging trials. The proposed modified JMAK model has proved to be valid in the main body of the forging. The results predicted for the surface are less accurate. The recrystallised grain size on the surface is smaller than in the centre of the part which corresponds to the experimental results and reflects the main trend.

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Microstructure Prediction during Hot Deformation Using New Dynamic Recrystallization Model and Finite Element Analysis

Key Engineering Materials ◽

10.4028/www.scientific.net/kem.611-612.483 ◽

2014 ◽

Vol 611-612 ◽

pp. 483-488

Author(s):

Ho Won Lee ◽

Young Seon Lee ◽

Seong Hoon Kang

Keyword(s):

Finite Element Analysis ◽

Grain Size ◽

Finite Element ◽

Dynamic Recrystallization ◽

Hot Deformation ◽

Pure Copper ◽

Hot Compression ◽

State Variables ◽

Element Analysis ◽

Average Grain Size

In this study, dynamic recrystallization during nonisothermal hot deformation was numerically simulated by finite element analysis and new physically based dynamic recrystallization model. The dynamic recrystallization model was developed based on mean field approach by assuming grain aggregate as representative volume element. For each grain aggregate, changes of state variables such as dislocation density and grain size were calculated using three sub-models for work hardening, nucleation, and nucleus growth. The developed dynamic recrystallization model was validated by comparing with isothermal hot compression of pure copper. Finally, developed dynamic recrystallization model was combined with finite element method to predict the local changes of microstructure and average grain size during nonisothermal hot compression of pure copper and hot tube extrusion of austenitic stainless steel. The simulation results were in reasonably good agreement with experimentally determined microstructures.

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Finite Element Analysis of Porosity Effects on Mechanical Properties for Tissue Engineering Scaffold

Biointerface Research in Applied Chemistry ◽

10.33263/briac112.88368843 ◽

2020 ◽

Vol 11 (2) ◽

pp. 8836-8843

Keyword(s):

Mechanical Properties ◽

Tissue Engineering ◽

Finite Element Analysis ◽

Finite Element ◽

Pore Size ◽

Young’S Modulus ◽

Young's Modulus ◽

Vital Role ◽

Tissue Engineering Scaffolds ◽

Element Analysis

Porosity plays a vital role in the development of tissue engineering scaffolds. It influences the biocompatibility performance of the scaffolds by increasing cell proliferation and allowing the transportation of the nutrients, oxygen, and metabolites in the blood rapidly to generate new tissue structure. However, a high amount of porosity can reduce the mechanical properties of the scaffold. Thus, this study aims to determine the geometry of the porous structure of a scaffold which exhibits good mechanical properties while maintaining its porosity at a percentage of more than 80%. Circle and square geometries were used since they are categorized as simple geometry. A unit cell of 12mm x 12mm x 12mm for square shape and pore area of 25π mm2 for circle shape was modeled and simulated by using Finite Element Analysis. The simulation consists of a compression test that determines which geometry exhibits better Young’s Modulus. Since the circle geometry has better Young’s Modulus, the pore size was furthered varied while maintaining the porosity of the scaffold to be above 80%. The same method of the simulation was done on the models. The result shows that the smallest pore size model has the highest Young’s Modulus, which still able to maintain the porosity at 80%.

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