Abstract For an accurate evaluation of the increase in skin friction due to various surface topographies on ships, i.e. plate roughness, coatings, or bio fouling, both experimental measurements and a numerical evaluation of those measurements are necessary. The measurements are necessary as no other practical method exists to evaluate the skin friction coefficient on most surface topographies, and numerical evaluation is required to compute the roughness effects of varying ship types and speeds. Therefore, a method for measuring the skin friction coefficient for bio-fouled and structured surfaces at full-scale friction velocity is presented, and a validation of the design and measuring procedures is given. For the ship frictional resistance calculations, the Computational Fluid Dynamics (CFD) code ShipFlow has been modified to take the added friction into account.
[1]
R. W. Fox,et al.
Introduction to fluid mechanics, 3rd edition
,
1985
.
[2]
F. R. Hama.
Boundary Layer characteristics for smooth and rough surfaces
,
1954
.
[3]
F. White.
Viscous Fluid Flow
,
1974
.
[4]
A. D. Young,et al.
An Introduction to Fluid Mechanics
,
1968
.
[5]
C. F. Colebrook,et al.
Experiments with Fluid Friction in Roughened Pipes
,
1937
.
[6]
H. Schlichting.
Boundary Layer Theory
,
1955
.
[7]
Michael Leer-Andersen.
Two studies of ship flows
,
1999
.
[8]
L Johansson.
THE LOCAL EFFECT OF HULL ROUGHNESS ON SKIN FRICTION: CALCULATIONS BASED ON FLOATING ELEMENT DATA AND THREE-DIMENSIONAL BOUNDARY LAYER THEORY
,
1985
.