TY - GEN
T1 - An integrated approach linking process to structural modeling with microstructural characterization for injection-molded long-fiber thermoplastics
AU - Nguyen, Ba Nghiep
AU - Bapanapalli, Satish K.
AU - Smith, Mark T.
AU - Kunc, Vlastimil
AU - Frame, Barbara J.
AU - Norris, Robert E.
AU - Phelps, Jay H.
AU - Tucker, Charles L.
AU - Jin, Xiaoshi
AU - Wang, Jin
PY - 2008
Y1 - 2008
N2 - The objective of our work is to enable the optimum design of lightweight automotive structural components using injection-molded long fiber thermoplastics (LFTs). To this end, an integrated approach that links process modeling to structural analysis with experimental microstructural characterization and validation is developed. First, process models for LFTs are developed and implemented into processing codes (e.g. ORIENT, Moldflow) to predict the microstructure of the as-formed composite (i.e. fiber length and orientation distributions). In parallel, characterization and testing methods are developed to obtain necessary microstructural data to validate process modeling predictions. Second, the predicted LFT composite microstructure is imported into a structural finite element analysis by ABAQUS to determine the response of the as-formed composite to given boundary conditions. At this stage, constitutive models accounting for the composite microstructure are developed to predict various types of behaviors (i.e. thermoelastic, viscoelastic, elastic-plastic, damage, fatigue, and impact) of LFTs. Experimental methods are also developed to determine material parameters and to validate constitutive models. Such a process-linked-structural modeling approach allows an LFT composite structure to be designed with confidence through numerical simulations. Some recent results of our collaborative research will be illustrated to show the usefulness and applications of this integrated approach.
AB - The objective of our work is to enable the optimum design of lightweight automotive structural components using injection-molded long fiber thermoplastics (LFTs). To this end, an integrated approach that links process modeling to structural analysis with experimental microstructural characterization and validation is developed. First, process models for LFTs are developed and implemented into processing codes (e.g. ORIENT, Moldflow) to predict the microstructure of the as-formed composite (i.e. fiber length and orientation distributions). In parallel, characterization and testing methods are developed to obtain necessary microstructural data to validate process modeling predictions. Second, the predicted LFT composite microstructure is imported into a structural finite element analysis by ABAQUS to determine the response of the as-formed composite to given boundary conditions. At this stage, constitutive models accounting for the composite microstructure are developed to predict various types of behaviors (i.e. thermoelastic, viscoelastic, elastic-plastic, damage, fatigue, and impact) of LFTs. Experimental methods are also developed to determine material parameters and to validate constitutive models. Such a process-linked-structural modeling approach allows an LFT composite structure to be designed with confidence through numerical simulations. Some recent results of our collaborative research will be illustrated to show the usefulness and applications of this integrated approach.
KW - Applications-automotive
KW - Fiber composite materials-long fiber systems
KW - Injection molding
KW - Micromechanics
KW - Modeling methodology
UR - http://www.scopus.com/inward/record.url?scp=78249286856&partnerID=8YFLogxK
M3 - Conference contribution
AN - SCOPUS:78249286856
SN - 9781934551042
T3 - International SAMPE Technical Conference
BT - SAMPE Fall Technical Conference and Exhibition - Multifunctional Materials
T2 - 2008 SAMPE Fall Technical Conference and Exhibition - Multifunctional Materials: Working Smarter Together, SAMPE '08
Y2 - 8 September 2008 through 11 September 2008
ER -