Difference between revisions of "Introductory SPH Iceberg-capsize Simulations"
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| − | ! style="width:500px" | In this model a | + | ! style="width:500px" | In this model an oscillation piston creates waves within a 250 cm x 50 cm x 50 cm tank. A solid block of 900 kg/m^3 density floats on one side of the tank and capsizes under the influence of the standing waves.The color of each fluid particle corresponds to its velocity magnitude (m/s) at each time step. |
! {{#ev:youtube|r6vm1F5vpmM}} | ! {{#ev:youtube|r6vm1F5vpmM}} | ||
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| − | ! style="width:500px" | In this | + | ! style="width:500px" | In this view the motion of the particles at the boundary of the model iceberg are shown. The color of each solid particle corresponds to its acceleration magnitude (m/s^2) at each time step. |
! {{#ev:youtube|B9TRacHKikE}} | ! {{#ev:youtube|B9TRacHKikE}} | ||
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Latest revision as of 16:31, 9 October 2015
| In this model an oscillation piston creates waves within a 250 cm x 50 cm x 50 cm tank. A solid block of 900 kg/m^3 density floats on one side of the tank and capsizes under the influence of the standing waves.The color of each fluid particle corresponds to its velocity magnitude (m/s) at each time step. | |
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| In this view the motion of the particles at the boundary of the model iceberg are shown. The color of each solid particle corresponds to its acceleration magnitude (m/s^2) at each time step. |
