Reinforcement of elastomers to obtain anisotropic material properties
Publikationen: Thesis / Studienabschlussarbeiten und Habilitationsschriften › Dissertation
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2021.
Publikationen: Thesis / Studienabschlussarbeiten und Habilitationsschriften › Dissertation
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TY - BOOK
T1 - Reinforcement of elastomers to obtain anisotropic material properties
AU - Beter, Julia
N1 - embargoed until null
PY - 2021
Y1 - 2021
N2 - The demand of fiber reinforced elastomers representing a new material class with unique capabilities is constantly growing. By constituting hyperelastic elastomers as interesting matrix material, these flexible composites with direction-dependent behavior allows the development of tailored stimuli-responsive properties triggered by load coupling effects like tension-twist or bending-twist mechanisms. The state of the art regarding the comprehensive material characterization for fiber reinforced elastomers and their load coupling effects showed that current findings for material-specific and suitable test concepts are still barely analyzed. Thus, the objective of this thesis is to provide profound knowledge of the material behavior, reliable testing possibilities and functional solutions concerning fiber reinforced elastomers especially for potential smart composite applications. Therefore, a systematic simplification of a test chain from micro- to macromechanical characterization is realized. A suitable step-by-step principle with conclusive transfer criteria are implemented. Due to the significant influence of the fiber-matrix interaction on the composite performance, the fiber-matrix adhesion and interfacial properties are investigated using fiber debond techniques including further tailored surface treatments to prove the impact on the adhesion. Regarding the material characterization exposed to cyclic loading by dynamic mechanical and step cycle analysis, the investigation of the energy absorption capacity, dynamic properties and force redirecting ability leading to load- and time-dependent behavior is necessary. Another part is the study of load coupling mechanism and the development and verification of a suitable material-related test concept. Based on the findings from the developed test chain especially for fiber reinforced elastomers, the need of correct transfer criteria for a systematic step-by-step simplification and the importance of precise material data evaluation due to their significant effects on the fiber-matrix interaction was demonstrated. Overall, the fiber bundle pull-out test can be considered as intermediate step representing a link between micro- to macromechanical testing enabling an adequate material study on the fiber-matrix adhesion performance. For the tension-twist load coupling characterization, the verification of the novel test concept offers a promising basis to investigate mechanical triggered load-coupling effects.
AB - The demand of fiber reinforced elastomers representing a new material class with unique capabilities is constantly growing. By constituting hyperelastic elastomers as interesting matrix material, these flexible composites with direction-dependent behavior allows the development of tailored stimuli-responsive properties triggered by load coupling effects like tension-twist or bending-twist mechanisms. The state of the art regarding the comprehensive material characterization for fiber reinforced elastomers and their load coupling effects showed that current findings for material-specific and suitable test concepts are still barely analyzed. Thus, the objective of this thesis is to provide profound knowledge of the material behavior, reliable testing possibilities and functional solutions concerning fiber reinforced elastomers especially for potential smart composite applications. Therefore, a systematic simplification of a test chain from micro- to macromechanical characterization is realized. A suitable step-by-step principle with conclusive transfer criteria are implemented. Due to the significant influence of the fiber-matrix interaction on the composite performance, the fiber-matrix adhesion and interfacial properties are investigated using fiber debond techniques including further tailored surface treatments to prove the impact on the adhesion. Regarding the material characterization exposed to cyclic loading by dynamic mechanical and step cycle analysis, the investigation of the energy absorption capacity, dynamic properties and force redirecting ability leading to load- and time-dependent behavior is necessary. Another part is the study of load coupling mechanism and the development and verification of a suitable material-related test concept. Based on the findings from the developed test chain especially for fiber reinforced elastomers, the need of correct transfer criteria for a systematic step-by-step simplification and the importance of precise material data evaluation due to their significant effects on the fiber-matrix interaction was demonstrated. Overall, the fiber bundle pull-out test can be considered as intermediate step representing a link between micro- to macromechanical testing enabling an adequate material study on the fiber-matrix adhesion performance. For the tension-twist load coupling characterization, the verification of the novel test concept offers a promising basis to investigate mechanical triggered load-coupling effects.
KW - intelligenter Verbundwerkstoff
KW - intelligente Werkstoffe
KW - flexibler Verbundwerkstoff
KW - faserverstärktes Elastomer
KW - Lastkopplungsmechanismus
KW - Viskoelastizität
KW - Faser-Matrix Grenzfläche
KW - Faser-Matrix Haftung
KW - Oberflächenmodifikation
KW - chemische Modifizierung
KW - Grenzflächen
KW - Faserbündel-Auszugsversuch
KW - Faserauszug
KW - Faser-Matrix Lösverfahren
KW - smart composite
KW - smart material
KW - flexible composite
KW - fiber-reinforced elastomer
KW - load-coupling mechanism
KW - viscoelasticity
KW - fiber–matrix interface
KW - fiber‐matrix adhesion
KW - surface modification
KW - chemical sizing
KW - interface
KW - fiber bundle pull-out test
KW - fiber pull-out
KW - fiber‐matrix debond technique
M3 - Doctoral Thesis
ER -