Proceedings of the ... International Conference on Offshore Mechanics and Arctic Engineering, Volume 3American Society of Mechanical Engineers, 2001 - Arctic regions |
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Page 108
... alloys have found their uses for spherical shells of deep submergence No. Category 1 23 4 5 6 78 9 10 11 = 2 12 13 14 15 1965 17 18 19 22 20 21 Non - Ferrous Metal Steel Material Composite Rope Name of Material Aluminum Alloy Titanium Alloy ...
... alloys have found their uses for spherical shells of deep submergence No. Category 1 23 4 5 6 78 9 10 11 = 2 12 13 14 15 1965 17 18 19 22 20 21 Non - Ferrous Metal Steel Material Composite Rope Name of Material Aluminum Alloy Titanium Alloy ...
Page 112
... Aluminum Alloy 5.3 Test after 1 - year exposure Specimens after 1 - year exposure were reclaimed as scheduled from ... alloys was lower than that of unjointed specimens and failed at the joint . Though defective welding was found in one of ...
... Aluminum Alloy 5.3 Test after 1 - year exposure Specimens after 1 - year exposure were reclaimed as scheduled from ... alloys was lower than that of unjointed specimens and failed at the joint . Though defective welding was found in one of ...
Page 149
... aluminium alloy AlMg3 has been chosen for this carrier because of its good corrosion resistance and lightweight in comparison to its maximal modulus of elasticity . The use of titanium has also been examined . Although titanium would ...
... aluminium alloy AlMg3 has been chosen for this carrier because of its good corrosion resistance and lightweight in comparison to its maximal modulus of elasticity . The use of titanium has also been examined . Although titanium would ...
Contents
Fatigue Capacity | 1 |
OMAE2001MAT3011 | 11 |
OMAE2001MAT3013 | 17 |
Copyright | |
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analysis applied Arctic Engineering assessment axial base metal bending brittle buckling calculated CGHAZ Charpy impact Charpy impact test components compressive Conference on Offshore crack arrest crack growth criterion CTOD test cycle defined deformation developed discrete displacement distribution DQEM ductile crack initiation dynamic effect elastic equation evaluated failure fatigue cracks ferrite Figure finite element flexible pipe FPSO Fracture Mechanics fracture toughness function fusion line hot spot hull indentation linepipe loading material maximum mechanical properties Mechanics and Arctic method microstructure node notch obtained Offshore Mechanics offshore structures parameters performed pipeline predicted pressure region Rio de Janeiro riser S-N curves shown in Fig shows simulated specimens steel plates stress concentration stress intensity factor surface cracks surface layer Table temperature tensile strength thermal thickness underwater underwater welding virgin steel Weibull distribution weld metal weld toe welded joints weldment yield strength