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finite element simulation

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<span class="search-highlight">Finite</span>-<span class="search-highlight">element</span> <span class="search-highlight">simulation</span> of a Teflon. l&#x2F;d = 1 sample in a split-Hopkinso...

Finite-element simulation of a Teflon. l/d = 1 sample in a split-Hopkinso...

in Split-Hopkinson Pressure Bar Testing of Soft Materials > Mechanical Testing and Evaluation
Published: 01 January 2000
Fig. 6 Finite-element simulation of a Teflon. l/d = 1 sample in a split-Hopkinson pressure bar test. The early stages of the ringup of the Teflon sample toward achieving a uniform uniaxial stress state is reflected by the nonuniform strain rate as a function of position within the sample More
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Postprocessing <span class="search-highlight">finite</span>-<span class="search-highlight">element</span> <span class="search-highlight">simulation</span> data for comparison to diffraction...

Postprocessing finite-element simulation data for comparison to diffraction...

in Crystal-Scale Simulations Using Finite-Element Formulations > Fundamentals of Modeling for Metals Processing
Published: 01 December 2009
Fig. 4 Postprocessing finite-element simulation data for comparison to diffraction data More
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Meshes used for <span class="search-highlight">finite</span> <span class="search-highlight">element</span> method <span class="search-highlight">simulation</span> of the cogging process

Meshes used for finite element method simulation of the cogging process

in Finite Element Method Applications in Bulk Forming > Metalworking: Bulk Forming
Published: 01 January 2005
Fig. 2 Meshes used for finite element method simulation of the cogging process More
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<span class="search-highlight">Finite</span> <span class="search-highlight">element</span> method (FEM) <span class="search-highlight">simulation</span> of material flow and form filling. S...

Finite element method (FEM) simulation of material flow and form filling. S...

in Forming of Magnesium Alloys > Metalworking: Sheet Forming
Published: 01 January 2006
Fig. 30 Finite element method (FEM) simulation of material flow and form filling. Source: Ref 32 More
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Results of computer <span class="search-highlight">simulation</span> (using Flux2D <span class="search-highlight">finite</span> <span class="search-highlight">element</span> software) of in...

Results of computer simulation (using Flux2D finite element software) of in...

in Principles of Induction Heating > Induction Heating and Heat Treatment
Published: 09 June 2014
Fig. 31 Results of computer simulation (using Flux2D finite element software) of induction hardening of selected areas of cup-shaped component using 2 two-turn inductors and “U”-shaped magnetic flux concentrator after 8 s of heating. Source: Ref 35 More
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Results of numerical computer <span class="search-highlight">simulation</span> using <span class="search-highlight">finite</span>-<span class="search-highlight">element</span> analysis (FEA...

Results of numerical computer simulation using finite-element analysis (FEA...

in Estimation of the Basic Induction Process Parameters > Induction Heating and Heat Treatment
Published: 09 June 2014
Fig. 5 Results of numerical computer simulation using finite-element analysis (FEA) of the sequential dynamics of end heating of carbon steel bars processed transversely inside an oval coil. Temperature variation at four critical points is indicated as N1, N2, N3, and N4. Due to the symmetry More
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Results of <span class="search-highlight">finite</span>-<span class="search-highlight">element</span> analysis <span class="search-highlight">simulation</span> of surface hardening the end ...

Results of finite-element analysis simulation of surface hardening the end ...

in Principles of Induction Hardening and Inspection > Induction Heating and Heat Treatment
Published: 09 June 2014
Fig. 14 Results of finite-element analysis simulation of surface hardening the end of a carbon steel shaft and al temperature distribution at different stages of heating (1, 4, and 9.3 s) along the surface, 3 mm (0.12 in.) below the surface, and 5 mm (0.20 in.) below the surface in (a) to (c More
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Example for flow chart heat treatment <span class="search-highlight">simulation</span>; FEM, <span class="search-highlight">finite</span> <span class="search-highlight">element</span> metho...

Example for flow chart heat treatment simulation; FEM, finite element metho...

in Distortion in Tool Steels[1] > Heat Treating of Irons and Steels
Published: 01 October 2014
Fig. 15 Example for flow chart heat treatment simulation; FEM, finite element method; TTT, time temperature transformation diagram, DSC, differential scanning calorimetry. Source: Ref 4 More
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Geometry of shear-slitting <span class="search-highlight">simulation</span>. (a) <span class="search-highlight">Finite</span>-<span class="search-highlight">element</span> model setup for t...

Geometry of shear-slitting simulation. (a) Finite-element model setup for t...

in Modeling Sheet Shearing Processes for Process Design > Metals Process Simulation
Published: 01 November 2010
Fig. 17 Geometry of shear-slitting simulation. (a) Finite-element model setup for the shear-slitting process. (b) Deformed configuration for 0° rake and 0° cant angles More
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Meshes used for <span class="search-highlight">finite</span> <span class="search-highlight">element</span> method <span class="search-highlight">simulation</span> of the cogging process

Meshes used for finite element method simulation of the cogging process

in Finite Element Method Applications in Bulk Forming[1] > Metals Process Simulation
Published: 01 November 2010
Fig. 2 Meshes used for finite element method simulation of the cogging process More
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Comparison of predicted temperature of the <span class="search-highlight">simulation</span> using <span class="search-highlight">finite</span>-<span class="search-highlight">element</span>-...

Comparison of predicted temperature of the simulation using finite-element-...

in Modeling Thermomechanical Effects on Additive Manufacturing > Additive Manufacturing Processes
Published: 15 June 2020
Fig. 16 Comparison of predicted temperature of the simulation using finite-element-analysis-based thermomechanical modeling and in situ thermocouple measurements shows a good match of peak temperature and trend. Source: Ref 26 More
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<span class="search-highlight">Finite</span>-<span class="search-highlight">element</span> mesh (left) and resin flow-front <span class="search-highlight">simulation</span> (right) for resi...

Finite-element mesh (left) and resin flow-front simulation (right) for resi...

in Computer-Aided Design and Manufacturing > Composites
Published: 01 January 2001
Fig. 12 Finite-element mesh (left) and resin flow-front simulation (right) for resin transfer molding injection More
Book Chapter

Crystal-Scale Simulations Using Finite-Element Formulations

By P.R. Dawson, D.E. Boyce
Series: ASM Handbook
Volume: 22A
Publisher: ASM International
Published: 01 December 2009
DOI: 10.31399/asm.hb.v22a.a0005424
EISBN: 978-1-62708-196-2
..., elastic and plastic behaviors of single crystals, refinements to the single-crystal constitutive, and crystal-scale finite-element. The article also presents examples that illustrate the capabilities of the formulations at the length scales. crystal-scale simulations finite-element formulations...
Abstract
This article provides an explanation on how crystal plasticity is implemented within finite element formulations by the use of physical length scales: crystal scale and continuum scale. It provides theoretical formulations for kinematic framework for deforming crystals and polycrystals, elastic and plastic behaviors of single crystals, refinements to the single-crystal constitutive, and crystal-scale finite-element. The article also presents examples that illustrate the capabilities of the formulations at the length scales.
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Deep-learning-based topology optimization approach, with (a) <span class="search-highlight">element</span>-remova...

Deep-learning-based topology optimization approach, with (a) element-remova...

in Data Analytics and Machine Learning in Metal Additive Manufacturing—Challenges, Segmentations, and Applications > Additive Manufacturing Design and Applications
Published: 30 June 2023
Fig. 3 Deep-learning-based topology optimization approach, with (a) element-removal strategy based on finite-element simulation (FEM, finite-element model), (b) deep learning model combining U-net and long short-term memory (LSTM) nets, and (c) application on two- and 3D topology optimization More
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(a) Soil bin test and <span class="search-highlight">finite</span>-<span class="search-highlight">element</span> analysis <span class="search-highlight">simulated</span> draft force for (b)...

(a) Soil bin test and finite-element analysis simulated draft force for (b)...

in Wear and Tribology in Agricultural Machinery > Friction, Lubrication, and Wear Technology
Published: 31 December 2017
Fig. 43 (a) Soil bin test and finite-element analysis simulated draft force for (b) the rectangular flat and triangular blades. Adapted from Ref 80 More
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<span class="search-highlight">Finite</span>-<span class="search-highlight">element</span> output for <span class="search-highlight">simulating</span> (a) Temperature (b) microstructure (c)...

Finite-element output for simulating (a) Temperature (b) microstructure (c)...

in Simulation of Steels Prone to Quench Cracking > Heat Treating of Irons and Steels
Published: 01 October 2014
Fig. 27 Finite-element output for simulating (a) Temperature (b) microstructure (c) max. principal stress in the model (d) in the critical zone of the model for a steel valve component 2 s after beginning of quench. Source: Ref 67 More
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<span class="search-highlight">Finite</span> <span class="search-highlight">element</span> (FE) <span class="search-highlight">simulations</span> and corresponding extrusions. These example...

Finite element (FE) simulations and corresponding extrusions. These example...

in Conventional Hot Extrusion > Metalworking: Bulk Forming
Published: 01 January 2005
Fig. 22 Finite element (FE) simulations and corresponding extrusions. These examples illustrate the degree to which commercially available three-dimensional FE software can predict metal flow through an extrusion die and the resulting distortion of the part. (a) The outward distortion More
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Results of a <span class="search-highlight">finite</span>-<span class="search-highlight">element</span> analysis used to <span class="search-highlight">simulate</span> chip segmentation dur...

Results of a finite-element analysis used to simulate chip segmentation dur...

in High-Speed Machining > Machining
Published: 01 January 1989
Fig. 7 Results of a finite-element analysis used to simulate chip segmentation during high-speed machining. The results correspond to a cutting speed of 1800 m/min (6000 sfm) and a rake angle of 5°. (a) Initial geometry, time = 0.0 s. (b) Geometry at 0.005 s. (c) Geometry at 0.008 s. (d More
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<span class="search-highlight">Finite</span>-<span class="search-highlight">element</span> model used to <span class="search-highlight">simulate</span> the compaction of the part shown in ...

Finite-element model used to simulate the compaction of the part shown in ...

in Modeling of Powder Metallurgy Processes > Metals Process Simulation
Published: 01 November 2010
Fig. 25 Finite-element model used to simulate the compaction of the part shown in Fig. 22 More
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Comparison of measured earing profiles for deep-drawn cups of aluminum allo...

Comparison of measured earing profiles for deep-drawn cups of aluminum allo...

in Modeling and Simulation of the Forming of Aluminum Sheet Alloys > Metalworking: Sheet Forming
Published: 01 January 2006
Fig. 27 Comparison of measured earing profiles for deep-drawn cups of aluminum alloy 2090-T3 with predictions from finite element simulations (using two different yield functions) and an analytical model. Source: Ref 195 More