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Simulating ductile crack growth in carbon steel using an extended finite element method (XFEM)

 Simulating ductile crack growth in carbon steel using an extended finite element method (XFEM)
Autor(en): , ,
Beitrag für IABSE Symposium: Engineering the Future, Vancouver, Canada, 21-23 September 2017, veröffentlicht in , S. 2543-2550
DOI: 10.2749/vancouver.2017.2543
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A novel methodology for simulation of crack growth in a 3D steel model is presented. This methodology is vital for the safe and full design of steel elements under harsh environment. The methodolog...
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Bibliografische Angaben

Autor(en): (College of Engineering & Informatics, National University of Ireland Galway, Ireland)
(College of Engineering & Informatics, National University of Ireland Galway, Ireland)
(College of Engineering & Informatics, National University of Ireland Galway, Ireland)
Medium: Tagungsbeitrag
Sprache(n): Englisch
Tagung: IABSE Symposium: Engineering the Future, Vancouver, Canada, 21-23 September 2017
Veröffentlicht in:
Seite(n): 2543-2550 Anzahl der Seiten (im PDF): 8
Seite(n): 2543-2550
Anzahl der Seiten (im PDF): 8
Jahr: 2017
DOI: 10.2749/vancouver.2017.2543
Abstrakt:

A novel methodology for simulation of crack growth in a 3D steel model is presented. This methodology is vital for the safe and full design of steel elements under harsh environment. The methodology, which is based on the extended finite element method (XFEM), neither requires the updating mesh over the course of the analysis, nor the priori definition of a crack length. Many other methods require the definition of crack and/or location of the crack to predict fracture. The methodology was validated against measurements from conventional static tests. The tests were carried out on the coupons of structural hollow tubes that are fabricated of 40x40x2.5SHS, 50x25x2.5RHS, 20x20x2.0SHS (mm) sections. Predictions of crack growth are used to study the behaviour of axially loaded steel to fracture. A major benefit is that the proposed method can be advanced for modelling fracture/fatigue of moderate to large structures to earthquakes.