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Title: Cohesive finite element modeling of the delamination of HTPB binder and HMX crystals under tensile loading

Abstract

Accurately modeling the mechanical behavior of the polymer binders and the degradation of interfaces between binder and crystal is important to science-based understanding of the macro-scale response of polymer bonded explosives. The paper presents a description of relatively a simple bi-crystal HMX-HTPB specimen and associated tensile loading experiment including computed tomography imaging, the pertinent constitutive theory, and details of numerical simulations used to infer the behavior of the material during the delamination process. Within this work, mechanical testing and direct numerical simulation of this relatively simple bi-crystal system enabled reasonable isolation of binder-crystal interface delamination, in which the effects of the complicated thermomechanical response of explosive crystals were minimized. Cohesive finite element modeling of the degradation and delamination of the interface between a modified HTPB binder and HMX crystals was used to reproduce observed results from tensile loading experiments on bi-crystal specimens. Several comparisons are made with experimental measurements in order to identify appropriate constitutive behavior of the binder and appropriate parameters for the cohesive traction-separation behavior of the crystal-binder interface. This research demonstrates the utility of directly modeling the delamination between binder and crystal within crystal-binder-crystal tensile specimen towards characterizing the behavior of these interfaces in a manner amenablemore » to larger scale simulation of polycrystalline PBX materials. One critical aspect of this approach is micro computed tomography imaging conducted during the experiments, which enabled comparison of delamination patterns between the direct numerical simulation and actual specimen. In addition to optimizing the cohesive interface parameters, one important finding from this investigation is that understanding and representing the strain-hardening plasticity of HTPB binder is important within the context of using a cohesive traction-separation model for the delamination of a crystal-binder system.« less

Authors:
ORCiD logo [1]; ORCiD logo [1];  [1];  [1]
  1. Los Alamos National Lab. (LANL), Los Alamos, NM (United States)
Publication Date:
Research Org.:
Los Alamos National Lab. (LANL), Los Alamos, NM (United States)
Sponsoring Org.:
USDOE
OSTI Identifier:
1425764
Report Number(s):
LA-UR-17-27403
Journal ID: ISSN 0020-7403
Grant/Contract Number:
AC52-06NA25396
Resource Type:
Journal Article: Accepted Manuscript
Journal Name:
International Journal of Mechanical Sciences
Additional Journal Information:
Journal Volume: 140; Journal ID: ISSN 0020-7403
Country of Publication:
United States
Language:
English
Subject:
42 ENGINEERING; cohesive finite element HMX HTPB delamination

Citation Formats

Walters, David J., Luscher, Darby J., Yeager, John D., and Patterson, Brian M.. Cohesive finite element modeling of the delamination of HTPB binder and HMX crystals under tensile loading. United States: N. p., 2018. Web. doi:10.1016/j.ijmecsci.2018.02.048.
Walters, David J., Luscher, Darby J., Yeager, John D., & Patterson, Brian M.. Cohesive finite element modeling of the delamination of HTPB binder and HMX crystals under tensile loading. United States. doi:10.1016/j.ijmecsci.2018.02.048.
Walters, David J., Luscher, Darby J., Yeager, John D., and Patterson, Brian M.. Tue . "Cohesive finite element modeling of the delamination of HTPB binder and HMX crystals under tensile loading". United States. doi:10.1016/j.ijmecsci.2018.02.048.
@article{osti_1425764,
title = {Cohesive finite element modeling of the delamination of HTPB binder and HMX crystals under tensile loading},
author = {Walters, David J. and Luscher, Darby J. and Yeager, John D. and Patterson, Brian M.},
abstractNote = {Accurately modeling the mechanical behavior of the polymer binders and the degradation of interfaces between binder and crystal is important to science-based understanding of the macro-scale response of polymer bonded explosives. The paper presents a description of relatively a simple bi-crystal HMX-HTPB specimen and associated tensile loading experiment including computed tomography imaging, the pertinent constitutive theory, and details of numerical simulations used to infer the behavior of the material during the delamination process. Within this work, mechanical testing and direct numerical simulation of this relatively simple bi-crystal system enabled reasonable isolation of binder-crystal interface delamination, in which the effects of the complicated thermomechanical response of explosive crystals were minimized. Cohesive finite element modeling of the degradation and delamination of the interface between a modified HTPB binder and HMX crystals was used to reproduce observed results from tensile loading experiments on bi-crystal specimens. Several comparisons are made with experimental measurements in order to identify appropriate constitutive behavior of the binder and appropriate parameters for the cohesive traction-separation behavior of the crystal-binder interface. This research demonstrates the utility of directly modeling the delamination between binder and crystal within crystal-binder-crystal tensile specimen towards characterizing the behavior of these interfaces in a manner amenable to larger scale simulation of polycrystalline PBX materials. One critical aspect of this approach is micro computed tomography imaging conducted during the experiments, which enabled comparison of delamination patterns between the direct numerical simulation and actual specimen. In addition to optimizing the cohesive interface parameters, one important finding from this investigation is that understanding and representing the strain-hardening plasticity of HTPB binder is important within the context of using a cohesive traction-separation model for the delamination of a crystal-binder system.},
doi = {10.1016/j.ijmecsci.2018.02.048},
journal = {International Journal of Mechanical Sciences},
number = ,
volume = 140,
place = {United States},
year = {Tue Feb 27 00:00:00 EST 2018},
month = {Tue Feb 27 00:00:00 EST 2018}
}

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