Hull (watercraft)

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A hull is the body of a ship or boat. It is a central concept in floating vessels as it provides the buoyancy that keeps the vessel from sinking.

"Hull Form"

1 General features
2 Hull shape
3 Appendages
4 Terms
5 Metrics
6 History
7 Notes
8 References
9 See also
10 External links

[edit] General features

Nearly all watercraft, from small boats to the largest ships, adhere to a general form that serves the needs of stability and efficient propulsion, featuring:

horizontal cross-sections that have narrow, usually pointed, fronts (at the bow),
smooth widening from the bow until roughly the middle of the length (midships), and often narrowing smoothly but usually significantly to the extreme end (the stern), whose width may range from a large to an insignificant fraction of the beam.

[edit] Hull shape

Hulls come in many varieties but are grouped primarily as follows:

Moulded, round bilged or soft-chined

defined as smooth curves

Chined or Hard-chined

have at least one pronounced knuckle throughout all or most of their length

After this they can be categorized as:

Displacement

the hull is supported exclusively or predominantly by the pressure of water displaced by the hull

Semi-displacement, or semi-planing

the hull form is capable of developing a moderate amount of dynamic lift, however, most of the vessel's weight is still supported through displacement

Planing

the Planing Hull form is configured to develop positive dynamic pressure so that its draft decreases with increasing speed. (see: Planing (sailing)).

The inverted bell shape of the hull, with smaller payload the waterline cross-section is less, hence the resisitance is less and the speed is higher. With higher payload the outward bend provides smoother performance in waves.

Many hulls have composite shape, e.g., a fine entry forward and inverted bell shape aft.

[edit] Appendages

A protrusion below the waterline forward is called a bulbous bow and is fitted on some hulls to reduce the wave making resistance drag and thus increase fuel efficiency. Bulbs fitted at the stern are less common but accomplish a similar task. (see also : Naval architecture)

A keel may be fitted on a hull to increase the transverse stability, directional stability or to create lift.

Control devices such as a rudder, trim tabs or stabilizing fins may be fitted.

[edit] Terms

Bow is the frontmost part of the hull

Stern is the rear-most part of the hull

Portside is the left side of the boat when facing the Bow

Starboard is the right side of the boat when facing the Bow

Waterline is an imaginary line circumscribing the hull that matches the surface of the water when the hull is not moving.

Midships is the midpoint of the LWL (see below). It is half-way from the forwardmost point on the waterline to the rear-most point on the waterline.

Baseline an imaginary reference line used to measure vertical distances from. It is usually located at the bottom of the hull.

[edit] Metrics

"LWL & LOA"

Hull forms are defined as follows:

Block Measures that define the principal dimensions. They are:

Length Overall (LOA) is the extreme length from one end to the other.
Length on the Waterline (LWL) is the length from the forwardmost point of the waterline measured in profile to the stern-most point of the waterline.
Length Between Perpendiculars (LBP or LPP) is the length of the summer load waterline from the stern post to the point where it crosses the stem. (see also p/p)
Beam or breadth (B) is the width of the hull. (ex: BWL is the maximum beam at the waterline)
Depth or moulded depth (D) is the vertical distance measured from the top of the keel to the underside of the upper deck at side. ^[1]
Draft (d) or (T) is the vertical distance from the bottom of the hull to the waterline.
Freeboard (FB) is the difference between Depth and draft.

"Beam, draft & Depth"

Form Derivatives that are calculated from the shape and the Block Measures. They are:

Volume (V or ∇) is the volume of water displaced by the hull.
Displacement (Δ) is the weight of water equivalent to the immersed volume of the hull.
Longitudinal Centre of Buoyancy (LCB) is the longitudinal distance from a point of reference (often Midships) to the centre of the displaced volume of water when the hull is not moving. Note that the Longitudinal Centre of Gravity or centre of the weight of the vessel must align with the LCB when the hull is in equilibrium.
Vertical Centre of Buoyancy (VCB) is the vertical distance from a point of reference (often the Baseline) to the centre of the displaced volume of water when the hull is not moving.
Longitudinal Centre of Floatation (LCF) is the longitudinal distance from a point of reference (often Midships) to the centre of the area of waterplane when the hull is not moving. This can be visualized as being the area defined by the water's surface and the hull.

Coefficients ^[2] help compare hull forms as well:

1) Block Coefficient (C_b) is the volume (V) divided by the LWL x BWL x T. If you draw a box around the submerged part of the ship, it is the ratio of the box volume occupied by the ship. It gives a sense of how much of the block defined by the L_wl, B_wl & draft (T) is filled by the hull. Full forms such as oil tankers will have a high C_b where fine shapes such as sailboats will have a low C_b.

$C_b = \frac {V}{L_{wl} \cdot B_{wl} \cdot T}$

2) Midship Coefficient (C_m or C_x) is the B_wl x draft divided by the cross-sectional area (A_x) of the slice at Midships (or at the largest section for C_x). It displays the ratio of the largest underwater section of the hull to a rectangle of the same overall width and depth as the underwater section of the hull. This defines the fullness of the underbody. A low Cm indicates a cut-away mid-section and a high Cm indicates a boxy section shape. Sailboats have a cut-away mid-section with low C_x whereas cargo vessels have a boxy section with high C_x to help increase the C_b.

$C_m = \frac {A_m}{B_{wl} \cdot T}$

3) Prismatic Coefficient (C_p) is the volume (V) divided by L_wl x A_x. It displays the ratio of the underwater volume of the hull to a rectangular block of the same overall length as the underbody and with cross-sectional area equal to the largest underwater section of the hull. This is used to evaluate the distribution of the volume of the underbody. A low Cp indicates a full mid-section and fine ends, a high Cp indicates a boat with fuller ends. Planing hulls and other highspeed hulls tend towards a higher C_p. Efficient displacement hulls travelling at a low Froude number will tend to have a low C_p.

$C_p = \frac {V}{L_{wl} \cdot A_m}$

4) Waterplane Coefficient (C_w) is the waterplane area divided by L_wl x B_wl. The waterplane coefficient expresses the fullness of the waterplane, or the ratio of the waterplane area to a rectangle of the same length and width. A low Cw figure indicates fine ends and a high Cw figure indicates fuller ends. High Cw improves stability as well as handling behavior in rough conditions.

$C_w = \frac {A_w}{L_{wl} \cdot B_{wl}}$

Note:

$C_b = {C_{p} \cdot C_{m} }$

[edit] History

Rafts have a hull of sorts, however, hulls of the earliest design are thought to have each consisted of a hollowed out tree bole: in effect the first canoes. Hull form then proceeded to the Coracle shape and on to more sophisticated forms as the science of Naval architecture advanced.

[edit] Notes

^ International Convention on Tonnage Measurement of Ships, 1969. International Conventions. Admiralty and Maritime Law Guide (1969-6-23). Retrieved on 2007-10-27., Annex 1, Regulations for determining gross and net tonnages of ships, Reg. 2(2)(a). In ships with rounded gunwales, the upper measurement point is take to the point at which the planes of the deck and side plating intersect. Id., Reg. 2(2)(b). Ships with stepped decks are measured to a line parallel with the upper part. Id., Reg. 2(2)(c).
^ Rawson, E.C. & Tupper (1976), Basic Ship Theory Vol 1 (2nd ed.), Longman, pp. 12-14, ISBN 058244523X

[edit] References

Hayler, William B.; Keever, John M. (2003). American Merchant Seaman's Manual. Cornell Maritime Pr. ISBN 0-87033-549-9.
Turpin, Edward A.; McEwen, William A. (1980). Merchant Marine Officers' Handbook, 4th, Centreville, MD: Cornell Maritime Press. ISBN 0-87038-056-X.

[edit] See also

[edit] External links

Description of hydrostatics and coefficients

v • d • e Parts of a sailing ship

Anchor · Anchor windlass · Beakhead · Bilgeboard · Boom brake · Bow · Capstan · Centreboard · Crow's nest · Daggerboard · Deck · Figurehead · Forecastle · Gunwale · Hull · Jackline · Keel · Keel (Canting) · Leeboard · Mast · Orlop deck · Poop deck · Quarter gallery · Rudder · Steering wheel · Skeg · Stern · Tiller · Top · Winch

v • d • e

Ship measurements

Length

Length overall · Length between perpendiculars · Length at the waterline

Breadth

Beam

Depth

Draft · Moulded depth · Freeboard

Volume

Worldwide	Gross tonnage · Net tonnage

Specialized	Panama Canal/Universal Measurement System · Thames measurement tonnage

Archaic	Gross register tonnage · Net register tonnage

Capacity

Deadweight tonnage · Twenty-foot equivalent unit

Weight

Displacement · Loaded displacement · Standard displacement · Light displacement · Normal displacement

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Hull (watercraft)

From Wikipedia, the free encyclopedia

Contents

[edit] General features

[edit] Hull shape

[edit] Appendages

[edit] Terms

[edit] Metrics

[edit] History

[edit] Notes

[edit] References

[edit] See also

[edit] External links

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