Today there are four containment systems in use for new build vessels. Two of the designs are of the self-supporting type, while the other two are of the membrane type and today the patents are owned by
Gaztransport & Technigaz (GTT). There is a trend towards the use of the two different membrane types instead of the self-supporting storage systems. This is most likely because prismatic membrane tanks utilize the hull shape more efficiently and thus have less void space between the cargo-tanks and ballast tanks. As a result of this, Moss-type design compared to a membrane design of equal capacity will be far more expensive to transit the
Suez Canal. However, self-supporting tanks are more robust and have greater resistance to sloshing forces, and will possibly be considered in the future for offshore storage where bad weather will be a significant factor.
Moss tanks (spherical IMO type B LNG tanks) Named after the company that designed them, the Norwegian company Moss Maritime, the Spherical IMO type B LNG tanks are spherical in shape. Most Moss type vessels have four or five tanks. The outside of the tanks have a thick layer of foam insulation that is either fitted in panels or in more modern designs wound round the tank. Over this insulation is a thin layer of "tinfoil" which allows the insulation to be kept dry with a nitrogen atmosphere. This atmosphere is constantly checked for any methane that would indicate a leak of the tank. Also the outside of the tank is checked at three-month intervals for any cold spots that would indicate breakdown in the insulation. The tank is supported around its circumference by the equatorial ring, which is supported by a large circular skirt, known as a data-couple that is a unique combination of aluminum and steel, which takes the weight of the tank down to the ship's structure. This skirt allows the tank to expand and contract during cool-down and warm-up operations. During cool-down or warm-up the tank can expand or contract about . Because of this expansion and contraction all piping into the tank comes in the top and is connected to the ship's lines via flexible bellows. Inside each tank there is a set of spray heads. These heads are mounted around the equatorial ring and are used to spray LNG onto the tank walls to reduce the temperature. Tanks normally have a working pressure of up to , but this can be raised for emergency discharge. If both main pumps fail then to remove the cargo, the tank's safety valves are adjusted to lift at 100 kPa (1 bar). Then the filling line which goes to the bottom of the tank is opened along with the filling lines of the other tanks on board. The pressure is then raised in the tank with the defective pumps which pushes the cargo into the other tanks where it can be pumped out.
IHI (prismatic IMO type B LNG tanks) Designed by Ishikawajima-Harima Heavy Industries, the
self-supporting prismatic type B (SPB) tank is currently employed in only two vessels. Type B tanks limit sloshing problems, an improvement over Membrane LNG carrier tanks which may break due to sloshing impact, therefore destroying the ship's hull. This is also of prime relevance for
FPSO LNG (or FLNG). In addition, IMO type B LNG tanks can sustain internal accidental damage due for example to internal equipment releases. This was incorporated into the design following several incidents that occurred inside membrane LNG tanks.
TGZ Mark III Designed by
Technigaz, these tanks are of the membrane type. The membrane consists of stainless steel with 'waffles' to absorb the thermal contraction when the tank is cooled down. The primary barrier, made of corrugated stainless steel of about thickness is the one in direct contact with the cargo liquid (or vapour in empty tank condition). This is followed by a primary insulation which in turn is covered by a secondary barrier made of a material called "triplex" which is basically a metal foil sandwiched between glass wool sheets and compressed together. This is again covered by a secondary insulation which in turn is supported by the ship's hull structure from the outside. From the inside of the tank outwards, the layers are: • LNG • Primary barrier of 1.2 mm thick corrugated/waffled 304L stainless steel • Primary insulation (also called the interbarrier space) • Secondary barrier within triplex membrane • Secondary insulation (also called the insulation space) • Ship's hull structure.
GT96 Designed by
Gaztransport, the tanks consists of a primary and secondary thin membrane made of the material
Invar which has almost no thermal contraction. The insulation is made out of plywood boxes filled with perlite and continuously flushed with nitrogen gas. The integrity of both membranes is permanently monitored by detection of hydrocarbon in the nitrogen. An evolution is proposed by NG2, with the replacement of nitrogen by argon as the flushed inert and insulation gas. Argon has a better insulation power than nitrogen, which could save 10% of boil-off gas.
CS1 CS1 stands for Combined System Number One. It was designed by the now merged
Gaztransport & Technigaz companies and consists of the best components of both MkIII and No96 systems. The primary barrier is made of invar , and secondary from Triplex. The primary and secondary insulation consists of polyurethane foam panels. Three vessels with CS1 technology were built by one shipyard, but established shipyards have decided to maintain production of the MKIII and NO96. ==Reliquefaction and boil-off==