Proceedings of the ... International Conference on Offshore Mechanics and Arctic Engineering, Volume 2, Parts 1-2American Society of Mechanical Engineers, 2000 - Arctic regions |
From inside the book
Results 1-3 of 85
Page 1085
... increase stiffness with depth . Ice Gouge Width The influence of an increased gouge width ( w = 25m ) was considered . For the finite element models , the maximum springline subgouge deformation was u = 1.300m and u = 2.167m for the ...
... increase stiffness with depth . Ice Gouge Width The influence of an increased gouge width ( w = 25m ) was considered . For the finite element models , the maximum springline subgouge deformation was u = 1.300m and u = 2.167m for the ...
Page 1189
... increase the steel temperature in the field joint to 100 ° C or more , causing a temporary reduction of the field joint stiffness . Tensile tests documented that the limit of elasticity is significantly reduced at increased temperature ...
... increase the steel temperature in the field joint to 100 ° C or more , causing a temporary reduction of the field joint stiffness . Tensile tests documented that the limit of elasticity is significantly reduced at increased temperature ...
Page 1254
... increase in velocity induces an increase in breaking loads but has no effect on the force due to the ride - up component . We also examined the data included in Lau's ( 1995 ) compilation . It showed no evidence that velocity or the ...
... increase in velocity induces an increase in breaking loads but has no effect on the force due to the ride - up component . We also examined the data included in Lau's ( 1995 ) compilation . It showed no evidence that velocity or the ...
Contents
OMAE2000OSU OFT3007 | 878 |
OMAE2000OSU OFT4061 147 | 894 |
OMAE2000MAT2079 | 911 |
Copyright | |
36 other sections not shown
Other editions - View all
Common terms and phrases
alloys application ASME assessment axial bending buckling calculated coefficient composite Copyright corrosion crack growth CTOD cycles deformation depth displacement distribution DQEM drag coefficient drilling fluid Engineering equation failure fatigue crack Figure finite element fire flexible pipe flow flowline FM analysis fracture mechanics function grade gradient hammer peening increase initial inspection installation insulation interlayer layer length lift coefficient material maximum method mode operation parameters peening pipeline plastic plate predicted pressure probabilistic production propagation properties PWHT reduced velocity reliability resistance riser seabed shear shielding gas shown simulation SINTEF SN curves soil span specimens Statoil steel strain strength stress intensity factor stress range surface Table temperature tensile thermal thickness titanium tubular joints tundra turbidity current values vertical loop vessel weld metal weld toe yield strength yield stress Zeepipe