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Bulbous Bow Hull
Design
What Is a Bulbous Bow?
by Paul Bruno
The
strongest resistance any vessel faces in standard operations comes from
displacement as the hull moves through the water.
Waves
that climb the bow are water being pushed aside faster than it can move away.
It
takes a lot of power to overcome the viscosity and mass of water and that means burning fuel, which adds to
costs.
A
bulbous bow is an extension of the hull just below the waterline.
It
has many subtle shape variations but it’s basically a rounded front portion
that flares out slightly as it blends into the traditional displacement hull
construction.
These
forward protrusions are about twice as long as the width of the base and they
would usually not extend forward past the top of the bow.
The
basic principle is to create a low-pressure zone to eliminate the bow wave and
reduce drag.
First
appearing on the USS Delaware in 1910, the bulbous bow was a controversial
design of U.S. Navy Ship Architect David W. Taylor.
Much
of the controversy disappeared ten years later when passenger ships began
exploiting the design to increase speeds.
Hulls
built with bulbous bow sections are common today.
Under
certain conditions, this type of design is very efficient at redirecting forces
of hydrodynamic resistance and drag.
There
is a movement against bulbous bows that allows greater flexibility of ships at
a time when "slow steaming" is a way to save fuel.
Good Conditions for Bulbous
Bows
The
design of a ship with a bulbous bow is discussed in many textbooks and
technical articles.
It is
often referred to as a theory or an art, which is a short way of saying nobody
is 100 percent sure of what they are writing.
There
are details to be worked out but modern builders have proprietary ways of
analyzing and integrating all hydrodynamic aspects of their hulls and these
methods are strict secrets.
A
bulbous bow works best under certain conditions and good design gives
efficiency gains throughout the range of these factors.
Speed –
At low speeds, a bulbous bow will trap water above the bulb without forming a
low-pressure zone to cancel the bow wave. This leads to increased drag and loss
of efficiency.
Each
design has what is known as most efficient hull speed, or often just hull
speed. This term refers to the speed where the shape of the hull is acting on
the water is such a way to produce the minimum possible drag.
This
ideal hull speed might not be the top speed of a ship because at some point the
lower pressure zone created by the bow features becomes larger than necessary.
A
zone of lower pressure water that is larger than the hull is inefficient and
leads to reduced rudder response.
Ideally,
the cone of lower pressure water will collapse just before the props. This
gives the prop blades something to push against and limits cavitation at the
props and rudder.
Cavitation
will lead to reduced efficiency of props, sluggish steering, and excessive wear
of hull and drive components.
Size – Vessels under 49
feet (15 m) do not have enough wetted area to take advantage of a bulbous bow.
The
amount of drag on a hull is related to its wetted area. The structure of the
bulb also increases drag and at a certain point, the benefits shrink to zero.
Conversely,
larger ships with a high proportion of waterline to frontal area use the
bulbous bow most effectively.
Bad Conditions for Bulbous Bows
Rough
Seas – While a traditional hull rises with the wave, a hull
with a bulbous bow can dig in even if it is designed to lift the bow under
normal conditions.
The
issue of trim is one of the most deeply dividing aspects of bow design among
naval architects.
There
is also a huge psychological aspect among crews who perceive this bow design as
dangerous in storms.
There
is some truth that these bows dig into wave faces but there is little proof
that it is more dangerous than traditional designs.
Ice –
Some ice breaking ships do have a special shape of a bulbous bow that is
heavily reinforced. Most bulbous bows are prone to damage since they are the
first point of contact with an obstacle.
In
addition to ice, large debris and fixed objects like dock faces can damage
these extended underwater bows.
Paul Bruno
United
States Coast Guard licensed Ship Master with Passenger Certification.
A
marine contractor familiar with all ship systems who has worked in the industry
for more than 20 years.
Has
a USCG Master's License and a degree in Creative Nonfiction and
Technical Writing, from the University of Wisconsin.
Experience
Paul
Bruno is a former writer for ThoughtCo who contributed work for over five years
on the maritime industry. He has worked with a variety of vessels throughout
his maritime career, including various commercial ships as well as the Great
Lakes schooner reproduction "Dennis Sullivan." As a marine
contractor, Paul is familiar with all ship systems, and his lifelong passion
for electronics has led to a focus on marine hardware and software development.
When he is not working, Paul's favorite hobby is knot work, keeping busy with
the nearly 4,000 documented knots, splices, and eyes.
Education
USCG
Master's License, 1993
Creative
Nonfiction and Technical Writing, University of Wisconsin, Milwaukee and
University of Waikato, Hamilton NZ
Paul
Bruno
ThoughtCo and Dotdash
ThoughtCo is a premier
reference site focusing on expert-created education content. We are one of the
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