Difference between revisions of "Bucketeers Glossary"
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;Natural speed | ;Natural speed | ||
− | :The natural speed can be used to compare the relative 'fastness' of a ship. Alternative to the more | + | :The natural speed can be used to compare the relative 'fastness' of a ship. Alternative to the more scientifically defined ''Hull speed'' |
:Natural speed in knots is the square root of the waterline length ('''L<sub>WL</sub>''') in feet or alternatively by taking 1,81 times the square root of the the waterline length ('''L<sub>WL</sub>''') in meters. | :Natural speed in knots is the square root of the waterline length ('''L<sub>WL</sub>''') in feet or alternatively by taking 1,81 times the square root of the the waterline length ('''L<sub>WL</sub>''') in meters. | ||
:''example: a hull with an L<sub>WL</sub> of 225 feet ( 68,58 meters ) has an natural speed of 15 knots'' | :''example: a hull with an L<sub>WL</sub> of 225 feet ( 68,58 meters ) has an natural speed of 15 knots'' |
Revision as of 22:11, 6 January 2019
People who work in shipbucket scale, often get a lot of comments containing words not commonly found in the english language or even words meaning different things when applied to ships and ship design. This page is created by Acelanceloet to provide a reference for such words. This article will provide an explanation of words describing ships dimensions (both real and relative), ship shapes, ship stability etc. It is allowed and even encouraged to improve, add to and expand these explanations. Definitions too complicated to fit in a few sentences deserve their own articles in the future, which will be linked from this page.
Dimensions
- Length over all
- Abbreviated as LOA
- The length from extreme bow to extreme stern of the hull of a ship.
- Length on Waterline
- Abbreviated as LWL
- The length of a ship on the design waterline.
- Length between perpendiculars
- Abbreviated as LPP
- The length of a ship between fore perpendicular and aft perpendicular
- Aft Perpendicular
- Abbreviated as A.P.
- Depending on the ships design, either
- The aftmost side of the rudder post
- The centerline of the rudder stock if there is no rudder post
- ships with unusual stern shapes normally don't use the "perpendicular" description. If they do though, it either follows a 'rule length' or is the aft end of the design waterline.
- Fore Perpendicular
- Abbreviated as F.P.
- The point where the bow of a ship enters the water when at design draft, fore end of the design waterline
- Beam
- Abbreviated as B
- The greatest width of a ship, measured in the inner shell.
- Largest Beam
- Abbreviated as BMAX
- The greatest width of a ship, including shell thickness.
- Depth
- Abbreviated as D
- The distance between the top of the keel to the top of the deck beam at side of the uppermost continuous deck, measured amidships. (= 0,5*LWL)
- Draft
- Abbreviated as T
- The greatest distance between keel and waterline at a load condition. If just the draft is given, this is design draft.
- Draft over all
- Abbreviated as TOA
- The distance between the waterline and the lowest point of the ship.
- Displacement
- Abbreviated as Δ
- The volume of water a ship "displaces" when it's total weight is in the water. Equal to Volume * density of the water. Displacement in meters is equal to the ships weight in metric tons.
- Equal to Volume when the ship is in fresh water (density = 1t/m3)
- Volume
- Abbreviated as ∇
- The volume of a ship below the design waterline.
Coefficients
These coefficients are ways to make a ships particulars dimensionless, so they can be compared between ships of different shape and size.
- Block Coefficient
- Abbreviated as Cb
- Coefficient describing the ratio of volume a ship occupies from a block of it's main underwater dimensions, thus describing the 'fullness' of a ship. Full ships such as oil tankers have a high block coefficient, sailboats a low.
- Equal to Volume divided by LWL * B * T
- Midship Coefficient
- Abbreviated as Cm or Cx
- Coefficient describing the ratio of cross sectional area of a slice of a ship (at midship Cm and at the largest section for Cx) occupies of a rectangle having the same width and depth as this underwater section of the hull. This defines the fullness of the midships body, a high midship coefficient describes a boxy (cargo ship) hull, while a low midship coefficient means an very cut away midsection.
- Equal to the cross section area divided by B * T
- Prismatic Coefficient
- Abbreviated as Cp
- Coefficient describing the ratio of volume a ship occupies from a prism of the same length as the ship and the cross section equal to the cross sectional area of the largest underwater section of the hull (midship section). This coefficient is used to evaluate the distribution of volume in the underbody, a low prismatic coefficient indicates fine ends, a high prismatic coefficient indicates full bow and stern. Planing hulls tend to have high prismatic coefficients, efficient displacement hulls tend to have a low prismatic coefficient.
- Equal to Volume divided by LWL * B * T * Cm
- Can also be found by dividing the block coefficient by the prismatic coefficient.
- Waterplane Coefficient
- Abbreviated as Cw
- Coefficient describing the ratio of area a ship occupies from a rectangle of it's main waterline dimensions, thus describing the 'fullness' of a ships waterplane. A low waterplane coefficient indicates fine ends while a high waterplane coefficient indicates fuller ends. A high waterplane coefficient improves stability as well as handling behaviour in (relatively) rough conditions, while a low waterplane coefficient might result in a higher wavemaking resistance.
- Equal to Waterplane area divided by LWL * B
Special numbers and dimensions
- Froude number
- Abbreviated as Fn
- Reynolds number
- Hull speed
- The hull speed is the speed at which the wavelength of the wave produced by a ship is exactly as long as the ships waterline. This is the maximum speed a ship can efficiently reach in displacement mode. This is because at this speed, the stern is no longer supported by the second top of the bow wave, so the ship starts to sail up it's own wave.
- Hull speed in knots can be calculated by taking 1,34 times the square root of the the waterline length (LWL) in feet or alternatively by taking 2,43 times the square root of the the waterline length (LWL) in meters.
- example: a hull with an LWL of 225 feet ( 68,58 meters ) has an hull speed of 20,1 knots
- Natural speed
- The natural speed can be used to compare the relative 'fastness' of a ship. Alternative to the more scientifically defined Hull speed
- Natural speed in knots is the square root of the waterline length (LWL) in feet or alternatively by taking 1,81 times the square root of the the waterline length (LWL) in meters.
- example: a hull with an LWL of 225 feet ( 68,58 meters ) has an natural speed of 15 knots
- Metacentric height
- Righting arm