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Investigation of cleavage fracture under dynamic loading conditions: Part II numerical analysis

: Tlatlik, J.

Postprint urn:nbn:de:0011-n-4644084 (2.5 MByte PDF)
MD5 Fingerprint: 513ae81211c0b587e971acabc90051fe
Erstellt am: 09.08.2019

Engineering fracture mechanics 184 (2017), S.22-38
ISSN: 0013-7944
Bundesministerium für Wirtschaft und Technologie BMWi
Zeitschriftenaufsatz, Elektronische Publikation
Fraunhofer IWM ()
dynamic fracture mechanic; cleavage fracture; local approach; Master Curve concept; finite element method

Part I of this study was an extensive fractographic investigation that covered the topics local crack arrest, and cleavage fracture-inducing mechanisms under dynamic loading situations. Also, it produced data regarding the origin of cleavage fracture. Now, this data is used for the numerical part of this study. First, the development of temperature and strain rate increase at the origin of cleavage fracture is conducted, and linked to discrepancies regarding experiments and the Master Curve concept in a phenomenological way. Then, cleavage fracture controlling mechanical field variables at the origin of fracture are analyzed, whereas very similar conditions regarding crack initiation and propagation are found when compared to quasi-static data. The influence of wave phenomena is examined as well. Finally, micromechanical simulations showed that a local temperature increase at the particle–matrix interface does not influence fracture behavior either, and that conclusively, the actual physical mechanism of cleavage fracture initiation (crack initiation and instability) takes place under the same conditions at elevated loading rates as under quasi-static conditions. Ultimately, the mechanisms responsible for the shortcomings of the Master Curve concept under dynamic loading conditions are identified, and current local approach concepts need to be adjusted to consider local crack arrest to be reliable.