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This book assesses the state-of-the-art in computational fluid
dynamics (CFD) applied to ship hydrodynamics and provides
guidelines for the future developments in the field based on the
Gothenburg 2010 Workshop. It presents ship hull test cases,
experimental data and submitted computational methods, conditions,
grids and results. Analysis is made of errors for global
(resistance, sinkage and trim and self-propulsion) and local flow
(wave elevations and mean velocities and turbulence) variables,
including standard deviations for global variables and propeller
modeling for self-propulsion. The effects of grid size and
turbulence models are evaluated for both global and local flow
variables. Detailed analysis is made of turbulence modeling
capabilities for capturing local flow physics. Errors are also
analyzed for head-wave seakeeping and forward speed diffraction,
and calm-water forward speed-roll decay. Resistance submissions are
used to evaluate the error and uncertainty by means of a systematic
verification and validation (V&V) study along with statistical
investigations. Post-workshop experimental and computational
studies are conducted and analyzed for evaluation of facility
biases and to draw more concrete conclusions regarding the most
reliable turbulence model, appropriate numerical methods and grid
resolution requirements, respectively.
This book explores computational fluid dynamics applied to ship
hydrodynamics and provides guidelines for the future developments
in the field based on the Tokyo 2015 Workshop. It presents ship
hull test cases, experimental data and submitted computational
methods, conditions, grids and results. Analysis is made of errors
for global (resistance, sinkage, trim and self-propulsion) and
local flow (wave elevations, mean velocities and turbulence)
variables, including standard deviations for global variables. The
effects of grid size and turbulence models are evaluated for both
global and local flow variables. Detailed analysis is made of
turbulence modeling capabilities for capturing local flow physics.
Errors and standard deviations are also assessed for added
resistance (captive test cases) and course keeping/speed loss (free
running test cases) in head and oblique waves. All submissions are
used to evaluate the error and uncertainty by means of a systematic
verification and validation (V&V) study along with statistical
investigations.
This book explores computational fluid dynamics applied to ship
hydrodynamics and provides guidelines for the future developments
in the field based on the Tokyo 2015 Workshop. It presents ship
hull test cases, experimental data and submitted computational
methods, conditions, grids and results. Analysis is made of errors
for global (resistance, sinkage, trim and self-propulsion) and
local flow (wave elevations, mean velocities and turbulence)
variables, including standard deviations for global variables. The
effects of grid size and turbulence models are evaluated for both
global and local flow variables. Detailed analysis is made of
turbulence modeling capabilities for capturing local flow physics.
Errors and standard deviations are also assessed for added
resistance (captive test cases) and course keeping/speed loss (free
running test cases) in head and oblique waves. All submissions are
used to evaluate the error and uncertainty by means of a systematic
verification and validation (V&V) study along with statistical
investigations.
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