Proceedings of the ... International Conference on Offshore Mechanics and Arctic Engineering, Volume 1; Volume 7, Part 1American Society of Mechanical Engineers, 1988 - Arctic regions |
From inside the book
Results 1-3 of 68
Page 122
... angle NACA 0021 0.16 0.14 h = 0.62 R = 25 × 105 S = 0.42 0.12 C = 0.075 p 0.10 0.08 0.06 0.04H 0.02- ---- Without le slat With le stat B = 20 ° 0 0.1 0.2 0.3 0.4 ( b ) Variation of p * with stall which the stall occurs on the offset ...
... angle NACA 0021 0.16 0.14 h = 0.62 R = 25 × 105 S = 0.42 0.12 C = 0.075 p 0.10 0.08 0.06 0.04H 0.02- ---- Without le slat With le stat B = 20 ° 0 0.1 0.2 0.3 0.4 ( b ) Variation of p * with stall which the stall occurs on the offset ...
Page 423
... angle of the main wings and advance speed of the towing vessel when the towing point , dimensions of the vehicle and towing cable are given . The relations between the submerged depth , wing angle and advance speed are obtained from ...
... angle of the main wings and advance speed of the towing vessel when the towing point , dimensions of the vehicle and towing cable are given . The relations between the submerged depth , wing angle and advance speed are obtained from ...
Page 427
... angle as shown in Fig.17- ( g ) . The attack angle & of the main wings is determined by the following equation ; 8 = 80 + a , ( z * - z ) ( 27 ) in which is the estimated value by using the statical calculations , a , is the position ...
... angle as shown in Fig.17- ( g ) . The attack angle & of the main wings is determined by the following equation ; 8 = 80 + a , ( z * - z ) ( 27 ) in which is the estimated value by using the statical calculations , a , is the position ...
Contents
FLOATING PRODUCTION SYSTEMS | 1 |
Semisubmersible Floating Production for the Gulf of Mexico | 13 |
OFFSHORE MECHANICS | 23 |
Copyright | |
41 other sections not shown
Other editions - View all
Common terms and phrases
adsorber amplitude analysis angle Arctic Engineering axial bending buoy buoyancy cable calculated coefficient compliant tower components Conference on Offshore curve damage diameter displacement drag coefficient drilling dynamic effect energy equation equipment fatigue Figure finite element flexible floating production flow function horizontal hydrodynamic installation jacket kips length linear load marine mass matrix maximum measured Mechanics and Arctic method mode mode shapes model tests modulus mooring line mooring system motion natural frequency nonlinear obtained Offshore Mechanics Offshore Technology Conference operation parameters performance pile pipe pipe materials pipeline platform polyester pressure production riser random wave ratio response rope rotation RPIT shear shear modulus shear strength shown in Fig simulation soil static stiffness strength stress structure subsea surface syntactic foam turbine uranium vane velocity vertical vessel water depth wave forces wave height wave power weight wellhead wire