Computational investigation of impact energy absorption capability of polyurea coatings via deformation-induced glass transition

▶ Impact of a projectile with a polyurea-coated steel plate is studied numerically. ▶ A transient non-linear dynamics finite-element approach is employed. ▶ Deformation-induced energy-dissipation/absorption mechanisms are investigated. ▶ Evidence is provided for a high strain-rate deformation-induce...

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Published in:Materials science & engineering. A, Structural materials : properties, microstructure and processing Structural materials : properties, microstructure and processing, 2010-11, Vol.527 (29), p.7741-7751
Main Authors: Grujicic, M., Pandurangan, B., He, T., Cheeseman, B.A., Yen, C.-F., Randow, C.L.
Format: Article
Language:English
Subjects:
Applied sciences
Blast/impact energy absorption coating
Coatings
Computation
Computational analysis
Deformation mechanisms
Exact sciences and technology
Glass transition
Mathematical analysis
Mathematical models
Mechanical properties
Physical properties
Plates (structural members)
Polymer industry, paints, wood
Polyurea
Polyureas
Projectiles
Properties and testing
Technology of polymers
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Summary:▶ Impact of a projectile with a polyurea-coated steel plate is studied numerically. ▶ A transient non-linear dynamics finite-element approach is employed. ▶ Deformation-induced energy-dissipation/absorption mechanisms are investigated. ▶ Evidence is provided for a high strain-rate deformation-induced glass transition. ▶ Beneficial role of this transition in absorbing projectile energy is confirmed. A number of experimental investigations reported in the open literature have indicated that the application of polyurea coatings can substantially improve blast and ballistic impact resistance/survivability of buildings, vehicles and laboratory test plates. While several potential mechanisms (e.g., shock-impedance mismatch, shock-wave dispersion, fracture-mode conversion and strain delocalization) have been proposed for the observed enhancement in the blast-wave/projectile-energy absorption, direct experimental or analytical evidence for the operation of these mechanisms has been lacking. Recently, it has been proposed that transition of polyurea between its rubbery-state and its glassy-state under high deformation-rate loading conditions is another possible mechanism for the improved ballistic impact resistance of polyurea-coated structures/test plates. In the present work, an attempt is made to provide computational support for this deformation-induced glass transition based energy-dissipation/absorption mechanism. Towards that end, a series of finite-element analyses of the projectile/coated-plate interactions are carried out using a transient non-linear dynamics finite-element approach. The results obtained are used to assess the extent of energy absorption and to identify the mode of failure of the test plate as a function of the imposed impact conditions. The results obtained show that the mechanical response of polyurea under impact conditions is a fairly sensitive function of the difference between the test temperature and the glass transition temperature. Specifically, when this difference is large, polyurea tends to display high-ductility behavior of a stereotypical elastomer in its rubbery-state. On the other hand, when the test temperature is closer to the glass transition temperature, polyurea tends to transform into its glassy-state during deformation and this process is associated with viscous type energy-dissipation. It is also argued that additional energy absorbing/dissipating mechanisms may contribute to the superior ballistic/blast protection
ISSN:0921-5093
1873-4936
DOI:10.1016/j.msea.2010.08.042