In materials science, liquefaction is a process that generates a liquid from a solid or a gas or that generates a non-liquid phase which behaves in accordance with fluid dynamics. It occurs both naturally and artificially.
www.marinetraffic.com – pic credit
Bulk Jupiter, a
Bahamas registered cargo ship, sank off
the coast of Vietnam in Jan 2015. On 2 January 2015 Bulk Jupiter sank off the
coast of Vũng Tàu, Vietnam. She departed from Kuantan, Malaysia on 30 December
2014 with a cargo of 46,400 tons of bauxite and a crew of 19 Filipinos.Its owners were to state - “From the general
alarm sounding in the early morning hours of January 2nd, and abandon ship was
heard on the intercom, it took only minutes before the vessel had developed a
heavy list to starboard. The cook made his way starboard and jumped overboard.
The vessel sank shortly thereafter.” The cook, Angelito Rojas, was rescued
after 8 – 9 hours and the bodies of two other crew men recovered. Apart from no
other bodies or wreckage could be found.
Bauxite
is a sedimentary rock with a relatively high aluminum content. It is the
world's main source of aluminum. Bauxite consists mostly of the aluminium
minerals ~ in 1821 the French geologist
Pierre Berthier discovered bauxite near the village of Les Baux in Provence,
southern France. In 1861, French chemist
Henri Sainte-Claire Deville named the substance "bauxite". Solid
cargoes like crushed ore or sand can suddenly turn to liquid… and cause the
ship to sink. And the phenomenon happens more frequently than you might think. ~ is what was read today in an interesting
report in BBC. (reproduced report by Susan Gourvenec From The Conversation)
Think of a
dangerous cargo, and toxic waste or explosives might come to mind. But granular
cargoes such as crushed ore and mineral sands are responsible for the loss of
numerous ships every year. On average, 10 ‘solid bulk cargo’ carriers have been
lost at sea each year for the last decade. Solid bulk cargoes – defined as
granular materials loaded directly into a ship’s hold – can suddenly turn from
a solid state into a liquid state, a process known as liquefaction. And this
can be disastrous for any ship carrying them – and their crew.
In 2015, the
56,000-tonne bulk carrier Bulk Jupiter rapidly sunk around 300km (187 miles)
south-west of Vietnam, with only one of its 19-strong crew surviving. This
prompted warnings from the International Maritime Organisation (IMO) about the
possible liquefaction of the relatively new solid bulk cargo bauxite (an
aluminium ore). A lot is known about the physics of the liquefaction of
granular materials from geotechnical and earthquake engineering. The vigorous
shaking of the Earth causes pressure in the ground water to increase to such a
level that the soil ‘liquefies’. Yet despite our understanding of this
phenomenon, and the guidelines in place to prevent it occurring, it is still
causing ships to sink and taking their crew with them.
Solid bulk
cargoes can suddenly turn from a solid state into a liquid state, which can be
disastrous for any ship carrying them !!Solid bulk cargoes are typically ‘two-phase’ materials as they contain
water between the solid particles. When the particles can touch, the friction
between them makes the material act like a solid (even though there is liquid
present). But when the water pressure rises, these inter-particle forces reduce
and the strength of the material decreases. When the friction is reduced to
zero, the material acts like a liquid (even though the solid particles are
still present). A solid bulk cargo that is apparently stable on the quayside
can liquefy because pressures in the water between the particles build up as it
is loaded onto the ship. This is especially likely if, as is common practice,
the cargo is loaded with a conveyor belt from the quayside into the hold, which
can involve a fall of significant height. The vibration and motion of the ship
from the engine and the sea during the voyage can also increase the water
pressure and lead to liquefaction of the cargo.
When a solid
bulk cargo liquefies, it can shift or slosh inside a ship’s hold, making the
vessel less stable. A liquefied cargo can shift completely to one side of the
hold. If it regains its strength and reverts to a solid state, the cargo will
remain in the shifted position, causing the ship to permanently tilt or ‘list’
in the water. The cargo can then liquefy again and shift further, increasing
the angle of list. At some point, the angle of list becomes so great that water
enters the hull through the hatch covers, or the vessel is no longer stable
enough to recover from the rolling motion caused by the waves. Water can also
move from within the cargo to its surface as a result of liquefaction and
subsequent sloshing of this free water can further impact the vessel’s
stability. Unless the sloshing can be stopped, the ship is in danger of
sinking.
The
International Maritime Organisation has codes governing how much moisture is
allowed in solid bulk cargo in order to prevent liquefaction. So why does it
still happen? The technical answer is that the existing guidance on stowing and
shipping solid bulk cargoes is too simplistic. Liquefaction potential depends
not just on how much moisture is in a bulk cargo but also other material
characteristics, such as the particle size distribution, the ratio of the
volume of solid particles to water and the relative density of the cargo, as
well as the method of loading and the motions of the vessel during the voyage.
The production and transport of new materials, such as bauxite, and increased processing of traditional ores before they are transported, means more cargo is being carried whose material behavior is not well understood. This increases the risk of cargo liquefaction. Commercial agendas also play a role. For example, pressure to load vessels quickly leads to more hard loading even though it risks raising the water pressure in the cargoes. And pressure to deliver the same tonnage of cargo as was loaded may discourage the crew of the vessel draining cargoes during the voyage. To tackle these problems, the shipping industry needs to better understand the material behaviour of solid bulk cargoes now being transported and prescribe appropriate testing. New technology could help. Sensors in a ship’s hold could monitor the water pressure of the bulk cargo. Or the surface of the cargo could be monitored, for example using lasers, to identify any changes in its position. The challenge is developing a technology that is cheap enough, quick to install and robust enough to survive loading and unloading of the cargo. If these challenges can be overcome, combining data on the water pressure and movement of the cargo with information on the weather and the ship’s movements could produce a real-time warning of whether the cargo was about to liquefy. The crew could then act to prevent the water pressure in the cargo rising too much, for example, by draining water from the cargo holds (to reduce water pressure) or changing course of the vessel to avoid particularly bad weather (to reduce ship motions). Or if that were not possible, they could evacuate the vessel. In this way, this phenomenon of solid bulk cargo liquefaction could be overcome, and fewer ships and crew would be lost at sea.
Bulk Jupiter sank off the coast of Vietnam in Jan 2015.Early reports indicated that the likely cause of the sinking was sudden loss of stability from the bauxite cargo.There was a circular of IMO warning ship's masters about the liquefaction hazards of bauxite.They were warned not to accept bauxite for carriage unless: • the moisture limit for the specific cargo is certified as less than the indicative moisture limit of 10% and the particle size distribution as is detailed in the individual schedule for bauxite in the IMSBC Code; or • the cargo is declared as Group A (cargoes that may liquefy) and the shipper declares the transportable moisture limit (TML) and moisture content; or • the cargo has been assessed as not presenting Group A properties.
With regards – S. Sampathkumar 18th Sept 2018. http://www.bbc.com/future/story/20180905-the-cargo-ships-that-liquefy:This article originally appeared on The Conversation, and republished under a Creative Commons license.
