Particle modeling of dynamic fracture simulations of a 2D polymeric material (nylon-6,6) subject to the impact of a rigid indenter

This paper employs particle modeling (PM) for the simulation of dynamic fragmentation in a 2D polymeric material (nylon-6,6) subject to the impact of a rigid indenter. A new particle interaction scheme (nearest–second neighboring particle interaction) is raised in an attempt to eliminate a mesh bias...

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Bibliographic Details
Published inComputational materials science Vol. 44; no. 2; pp. 449 - 463
Main Authors Wang, G., Al-Ostaz, A., Cheng, A.H.-D., Raju Mantena, P.
Format Journal Article
LanguageEnglish
Published Amsterdam Elsevier B.V 01.12.2008
Elsevier
Subjects
Applied sciences
Dynamic fracture
Exact sciences and technology
Impact
Mechanical properties
Microscale material randomness
Particle modeling
Physical properties
Polymer industry, paints, wood
Properties and testing
Technology of polymers
46.30.Nz
Impact
83.20.-d
40.30.My
Dynamic fracture
61.43.Bn
68.45.Kg
83.80.Nb
Particle modeling
Microscale material randomness
Crack array
Nylon
Fracture mechanics
Deflection
Particle motion
Rupture
Dynamic properties
Indentation
Fragmentation
Finite element method
Particle interaction
Crack
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Summary:This paper employs particle modeling (PM) for the simulation of dynamic fragmentation in a 2D polymeric material (nylon-6,6) subject to the impact of a rigid indenter. A new particle interaction scheme (nearest–second neighboring particle interaction) is raised in an attempt to eliminate a mesh bias in the direction of fracture propagation that a regular lattice model with uniform axial linkage possesses in common. The modeling results compare favorably with the according experimental observations, in terms of the impact load and energy profiles, the specimen deflection value at the peak of the load, and the eventual crack pattern. A mesh dependence problem of PM is discovered while using different mesh resolutions and preliminarily investigated. Furthermore, a number of investigations are conducted accounting for other parameters: (i) sharpness of indenter (flat, small or large curvature), (ii) different drop velocity of indenter, and (iii) microscale perturbation in the material’s property. These investigations show that the dynamic response of the impact and the resultant fracture patterns are dependent on the material’s constitutive property, the geometric shape of indenter, and the impact velocity.
Bibliography:ObjectType-Article-2
SourceType-Scholarly Journals-1
ObjectType-Feature-1
content type line 23
ISSN:0927-0256
1879-0801
DOI:10.1016/j.commatsci.2008.04.014