Ductile Failure and Safety Optimization of Gas Pipeline
Subject Areas : EngineeringP Zamani 1 , A Jaamialahmadi 2 , M Shariati 3
1 - Department of Mechanical Engineering, Ferdowsi University of Mashhad, Mashhad, Iran
2 - Department of Mechanical Engineering, Ferdowsi University of Mashhad, Mashhad, Iran
3 - Department of Mechanical Engineering, Ferdowsi University of Mashhad, Mashhad, Iran
Keywords:
Abstract :
[1] Underwood J.H., 1972, Stress intensity factors for internally pressurized thick-walled cylinders, American Society for Testing and Materials 513 : 59-70.
[2] Raju I.S., Newman J.C., 1980, Stress-intensity factors for internal and external surface cracks in cylindrical vessels, Journal of Pressure Vessel Technology 102(4): 293-298.
[3] Newman J.C., 1976, Fracture analysis of surface and through cracks in cylindrical pressure vessels, National Aeronautics and Space Administration 39: 21-33.
[4] Liu A., 1996, Rockwell International Science Center, ASM Handbook Fatigue and Fracture.
[5] Lee S.L., Ju J.B., Kim W.S., Kwon D., 2004, Weld crack assessments in API X65 pipeline: failure assessments diagrams with variations in representative mechanical properties, Materials Science and Engineering 373(1): 122-130.
[6] Oh C.K, Kim Y.J, Baek J.H., Kim Y.P., Kim W.S., 2007, Ductile failure analysis of API X65 pipes with notch-type defects using a local fracture criterion, International Journal of Pressure Vessels and Piping 84: 512-525.
[7] Sandvik A., Ostby E., Thaulow C., 2008, A probabilistic fracture mechanics model including 3D ductile tearing of bi-axially loaded pipes with surface cracks, Engineering Fracture Mechanics 75: 76-96.
[8] Pluvinage G., Capelle J., Schmitt G., Mouwakeh M., 2012, Doman failure assessment diagrams for defect assessment of gas pipes, 19th European Conference on Fracture, Kazan, Russia.
[9] Zhang B., Ye C., Liang B., Zhang Z., Zhi Y., 2014, Ductile failure analysis and crack behavior of X65 buried pipes using extended finite element method, Engineering Failure Analysis 45: 26-40.
[10] Ghajar R., Mirone G., Keshavarz A., 2013, Ductile failure of X100 pipeline steel-Experiments and fractography, Materials & Design 43: 513-525.
[11] Sharma K., Singh I.V., Mishra B.K., Maurya S.K., 2014, Numerical simulation of semi-elliptical axial crack in pipe bend using XFEM, Journal of Solid Mechanics 6(2): 208-228.
[12] Dimic I., Medjo B., Rakin M., Arsic M., Sarkocevic Z., Sedmak A., 2014, Failure prediction of gas and oil drilling rig pipelines with axial defects, Procedia Materials Science 3: 955-960.
[13] Ainsworth R.A., 1984, The assessment of defects in structures of strain hardening material, Engineering Fracture Mechanics 19(4):633-642.
[14] Anderson T.L., Osage D.A., 2000, API 579: a comprehensive fitness-for-service guide , International Journal of Pressure Vessels and Piping 77(14):953-963.
[15] API 579, 2000, Recommended Practice for Fitness for Service, American Petroleum Institute.
[16] BS7910, 1999, Guide and Methods for Assessing the Acceptability of Flaws in Fusion Welded Structures, British Standard Institutions.
[17] R-6,1998, Assessment of the Integrity of Structures Containing Defects, British Energy.
[18] BS EN ISO 7448, 1999, Metallic Materials Determination of Plan-Strain Fracture Toughness, British Standard Institution.
[19] Shahraini S.I., Hashemi S.H., 2014, Effects of surface crack length and depth variations on gas transmission pipeline safety, Modares Mechanical Engineering 14:26-32.
[20] Habbit, Karlsson, Sorensen, 2007, Abaqus/Standard Analysis User’s Manual, USA.
