Proceedings of the ... International Conference on Offshore Mechanics and Arctic Engineering, Volume 1; Volume 7, Part 1American Society of Mechanical Engineers, 1988 - Arctic regions |
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Page 74
... amplitude , b ) ( amplitude 4 , c ) phase , and d ) phase in transition region , for an I.D. exciter ( see Fig . 3. ) . ( a ) Near field region Remote field region ( b ) ( c ) ( a ) ( e ) ( f ) ( g ) ( h ) ( i ) Amplitude ( j ) Phase ...
... amplitude , b ) ( amplitude 4 , c ) phase , and d ) phase in transition region , for an I.D. exciter ( see Fig . 3. ) . ( a ) Near field region Remote field region ( b ) ( c ) ( a ) ( e ) ( f ) ( g ) ( h ) ( i ) Amplitude ( j ) Phase ...
Page 230
... amplitude through quasi - static or low frequency cyclic testing methods . This can also be complicated for soft marine clays . Plastic deformation may start at low strain ranges with little or no non - linear elastic region , and the ...
... amplitude through quasi - static or low frequency cyclic testing methods . This can also be complicated for soft marine clays . Plastic deformation may start at low strain ranges with little or no non - linear elastic region , and the ...
Page 385
... Amplitude ( g ) 100 IM 0.1 Cross - flow In - flow 0.01 10 20 30 40 U ( m / s ) Fig . 3 The acceleration amplitude of oscillation ( logarithmic scale ) versus the upstream flow velocity , U , for 231 ° , m 295 , 8 - 0.011 . to correspond ...
... Amplitude ( g ) 100 IM 0.1 Cross - flow In - flow 0.01 10 20 30 40 U ( m / s ) Fig . 3 The acceleration amplitude of oscillation ( logarithmic scale ) versus the upstream flow velocity , U , for 231 ° , m 295 , 8 - 0.011 . to correspond ...
Contents
FLOATING PRODUCTION SYSTEMS | 1 |
OFFSHORE MECHANICS | 23 |
Early Production Systems in the North | 31 |
Copyright | |
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