Ship Measurement
Stability of Surface Vessels I
A vessel floating on the water surface: a stable system
“Balance of Stability”: Heeling moment = Righting moment
Since Archimedean Principle applies: Weight Force = Buoyancy Force
-> balance of ship stability: heeling lever = righting lever
Stability of Surface Vessels II
Basic of Ship Resistance I
Basic of Ship Resistance II
Reynolds - and Froude Number
Problem in model tests:
Similarity according to Froude and according to Reynolds must be kept between model and real ship.
This is not possible due to the same viscosity of the water around the model and the ship.
Adimiralty Formula
The first and rough determination of required porpulsion power of a ship has always been done by naval architects by lookng at comparable ship designs, i.e. similar size, similar shape, speed.
Prognosis according to “Admiralty Forumla”
The so called Admiralty Formula is also based on the known resistance (or the propulsion power) of an existing comparable shop, i.e. the ships hull should have a comparable shape
-> do not compare a “fat” bulk carrier with a “slim” frigate", but rather
-> compare a frigate with a frigate or a corvette
The formula was developped by the British Admiralty as a quick and handy prognosis method.
The Ships Propeller: Main Means of Propulsion
Propeller:
Input: Rotating Power (Torque x Revolutions)
Output: Advancing Power (Thrust x Ship Speed)
Propeller in free flow: efficiency between approx. 0,5 and 0,72
Propeller behind the ship: efficiency can increase
The best propeller is the “large diameter, slow turning propeller”
Restrictions:
space behind aft ship for propeller arrangement (draught, beam)
power / speed requirements (bulk carrier vs. frigate)
propeller load / cavitation
Propeller: Cavitating Tip Vortex
Heavily loaded (and often not purpose designed) propellers show -> cavitation
-> bubbles / “tubes” of pressure below steam pressure
-> can damage material when they collapse
-> create sharp UW noise when the collapse
Description of Hull Characteristics
Main seakeeping / seagoing properties of naval ships
speed -> and respective power requirement
turning circle
stopping distance from max. speed
behaviour in sea states / ship motions
Resistance and propulsion, dependency of hull shape vs. speed / Froude Number
frigate / destroyer designs optimized for at least two speeds:
cruising speed (18-21 kts) and
maximum speed (27-31 kts)
-> different in comparision with merchant vessels, optimzed for one cruising speed
long range for naval ships today more important than high speed
-> i.e. optimize hull shape for cruising speed
mostly two-shaft- / two-propeller-vessels today
submerged stern -> hydrodynamically positive (virtually “longer ship”) good for ships with F_N > 0,3
-> since the 1980ies: broad stern also favourablle for spacy helo - deck at rear
Propulsion of frigates and corvettes
Three criteria:
aft ship geometry
number of shafts
selected max. speed and max. power
Today: gas turbines, high-speed diesel engines, controllable pitch propeller — reverse speed -> maneuvering, continously variable ~ 20 MW per shaft
minimize shaft inclination (reduce eddies and cavitation)
necessary gap between ship’s hull and propeller
undisturbed flow to propeller has priority vs. exploitation of wake -> homogeneous wake field
ETA_H=(1-t)/(1-w)
typical for frigates and corvettes: 0.995 - 1.080
typical for merchant ships: 1.04 - 1.25
Essential criteria for frigate / corvette / naval propellers:
low noise / vibrations
low cavitation overall
late cavitation inception, i.e. at highest possible speed
Seakeeping behaviour of frigates acc. to USN and NATO
Essential ship motion criteria for corvettes / frigates / destroyers
“green water” on deck
“slamming”, especially at the fore ship
emergence of the sonar dome
Zuletzt geändertvor 2 Jahren
