Abstract
Liquid Natural Gaz -LNG- carriers must provide cryogenic reliability and safety for at least 40 years. Most of the insulation systems belong to the so-called membrane type, in which the “insulation complex” is composed of a metal membrane as a barrier, a plywood panel, insulation foam and a plywood panel glued to the inner hull. During construction and exploitation at cryogenic temperature, an impact of the membrane may occur and could lead to a LNG leakage. In order to evaluate this risk, and the role of the plywood in the perforation process of the membrane, a series of original impact tests are carried out at room and cryogenic temperatures on metal-plywood samples thanks to a specially designed catapult. In order to obtain a reliable numerical simulation of the impact, a series of impact and out of plane compression tests at room and cryogenic temperatures are carried out. Thanks to a design experiment, we identified the influence of the moisture content, from 2% up to 30%, and of the temperature, from − 173 ∘ C up to +20 ∘ C, on the strain rate sensitivity of the plywood.
Highlights
Liquefied Natural Gas shipping transport is receiving more and more attention
Most of the insulation systems belong to the so-called membrane type, in which the “insulation complex” is composed of a metal membrane as a barrier (1.2 mm thick, 304 grade stainless steel), a plywood panel (12 mm thick, crossply plywood made from 9 birch veneers birch wood), insulation foam (Reinforced PolyUrethane Foam), and a plywood panel glued to the inner hull
Our work focuses on these interactions during the out of plane compression of the tested birch plywood
Summary
Liquefied Natural Gas shipping transport is receiving more and more attention. LNG carriers must provide cryogenic reliability and safety for at least 40 years. An impact of the membrane may occur and could lead to a LNG leakage. The results of the first tests lead us to conclude that the plywood plays a great role in the absorption of the impact energy. The out of plane behaviour of the plywood is studied under various experimental conditions of moisture content (MC), strain rate and temperature. As some other works revealed it, temperature [1], MC [2] and strain rate [3] have a great effect on the wood behaviour. A huge interaction between temperature, strain rate and moisture content influences the stress plateau level [4, 5]. Our work focuses on these interactions during the out of plane compression of the tested birch plywood
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