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Temperature-dependent deformation an...

Degenhardt, David.

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Temperature-dependent deformation and fracture behavior of a talcum-filled co-polymer

Record Type:	Electronic resources : Monograph/item
Title/Author:	Temperature-dependent deformation and fracture behavior of a talcum-filled co-polymer/ by David Degenhardt.
Author:	Degenhardt, David.
Published:	Wiesbaden :Springer Fachmedien Wiesbaden : : 2020.,
Description:	xxvi, 121 p. :ill., digital ;24 cm.
[NT 15003449]:	Material Modeling; Yield Functions and Flow Rules -- Static and Dynamic Material Testing -- Temperature-dependent Material Model -- Model Validation with Component Tests.
Contained By:	Springer eBooks
Subject:	Copolymers - Mechanical properties. -
Online resource:	https://doi.org/10.1007/978-3-658-30155-2
ISBN:	9783658301552

Temperature-dependent deformation and fracture behavior of a talcum-filled co-polymer
Degenhardt, David.

Temperature-dependent deformation and fracture behavior of a talcum-filled co-polymer[electronic resource] /by David Degenhardt. - Wiesbaden :Springer Fachmedien Wiesbaden :2020. - xxvi, 121 p. :ill., digital ;24 cm. - AutoUni - schriftenreihe,band 1471867-3635 ;. - AutoUni - schriftenreihe ;band 147..

Material Modeling; Yield Functions and Flow Rules -- Static and Dynamic Material Testing -- Temperature-dependent Material Model -- Model Validation with Component Tests.

David Degenhardt develops an elasto-viscoplastic material model in order to predict the temperature and strain rate-dependent deformation and fracture behavior of thermoplastic polymers. The model bases on three supporting ambient temperatures, where a thermoplastic polymer has been characterized profoundly at the stress states 1) uni-axial tension and compression, 2) bi-axial tension and 3) shear. The core of the material model builds a pressure-dependent yield function with a non-associated flow rule. Further, it contains an analytical hardening law and a strain rate-dependent fracture criterion. The model is validated with components subjected to impact loading at different ambient temperatures. The comparison of the simulation and the experiments shows that stiffness, hardening, fractures strain as well as thicknesses can be well captured. Contents Material Modeling; Yield Functions and Flow Rules Static and Dynamic Material Testing Temperature-dependent Material Model Model Validation with Component Tests Target Groups Scientists and students in the field of material sciences and simulation Practitioners in industry in the field of material characterization About the Author David Degenhardt is a calculation engineer in the chassis development department of a German automobile manufacturer and earned his doctorate while working at the Technische Universitat Carolo-Wilhelmina zu Braunschweig, Germany.

ISBN: 9783658301552

Standard No.: 10.1007/978-3-658-30155-2doiSubjects--Topical Terms:

3450887
Copolymers
--Mechanical properties.

LC Class. No.: QD281.P6 / D444 2020

Dewey Class. No.: 620.192

Temperature-dependent deformation and fracture behavior of a talcum-filled co-polymer
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505 0 $a Material Modeling; Yield Functions and Flow Rules -- Static and Dynamic Material Testing -- Temperature-dependent Material Model -- Model Validation with Component Tests.
520 $a David Degenhardt develops an elasto-viscoplastic material model in order to predict the temperature and strain rate-dependent deformation and fracture behavior of thermoplastic polymers. The model bases on three supporting ambient temperatures, where a thermoplastic polymer has been characterized profoundly at the stress states 1) uni-axial tension and compression, 2) bi-axial tension and 3) shear. The core of the material model builds a pressure-dependent yield function with a non-associated flow rule. Further, it contains an analytical hardening law and a strain rate-dependent fracture criterion. The model is validated with components subjected to impact loading at different ambient temperatures. The comparison of the simulation and the experiments shows that stiffness, hardening, fractures strain as well as thicknesses can be well captured. Contents Material Modeling; Yield Functions and Flow Rules Static and Dynamic Material Testing Temperature-dependent Material Model Model Validation with Component Tests Target Groups Scientists and students in the field of material sciences and simulation Practitioners in industry in the field of material characterization About the Author David Degenhardt is a calculation engineer in the chassis development department of a German automobile manufacturer and earned his doctorate while working at the Technische Universitat Carolo-Wilhelmina zu Braunschweig, Germany.
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