Browse > Article
http://dx.doi.org/10.26748/KSOE.2019.048

Analysis of Shear Behavior and Fracture Characteristics of Plywood in Cryogenic Environment  

Son, Young-Moo (Department of Naval Architecture and Ocean Engineering, Pusan National University)
Kim, Jeong-Dae (Department of Naval Architecture and Ocean Engineering, Pusan National University)
Oh, Hoon-Kyu (Research Institute, Hyundai Heavy Industries Co. Ltd)
Kim, Yong-Tai (Research Institute, Hyundai Heavy Industries Co. Ltd)
Park, Seong-Bo (Research Institute, Hyundai Heavy Industries Co. Ltd)
Lee, Jae-Myung (Department of Naval Architecture and Ocean Engineering, Pusan National University)
Publication Information
Journal of Ocean Engineering and Technology / v.33, no.5, 2019 , pp. 394-399 More about this Journal
Abstract
Plywood is a laminated wood material where alternating layers are perpendicular to each other. It is used in a liquefied natural gas (LNG) carrier for an insulation system because it has excellent durability, a light weight, and high stiffness. An LNG cargo containment system (LNG CCS) is subjected to loads from gravity, sloshing impact, hydrostatic pressure, and thermal expansion. Shear forces are applied to an LNG CCS locally by these loads. For these reasons, the materials in an LNG CCS must have good mechanical performance. This study evaluated the shear behavior of plywood. This evaluation was conducted from room temperature ($25^{\circ}C$) to cryogenic temperature ($-163^{\circ}C$), which is the actual operating environment of an LNG storage tank. Based on the plywood used in an LNG storage tank, a shear test was conducted on specimens with thicknesses of 9 mm and 12 mm. Analyses were performed on how the temperature and thickness of the plywood affected the shear strength. Regardless of the thickness, the strength increased as the temperature decreased. The 9 mm thick plywood had greater strength than the 12 mm thick specimen, and this tendency became clearer as the temperature decreased.
Keywords
Liquefied gas storage tank; Cryogenic; Plywood; Shear Behavior; Fracture characteristic;
Citations & Related Records
연도 인용수 순위
  • Reference
1 Arswendy, A., Moan, T., 2015. Strength and stiffness assesssment of an LNG containment system - Crushing and buckling failure analysis of plywood components. Engineering Failure Analysis, 48, 247-258.   DOI
2 Barron, R.F., 1985. Cryogenic systems. 2nd Edition, Clarendon Press, Oxford.
3 Choi, S., Sankar, B.V., 2007. Fracture toughness of transverse cracks in graphite/epoxy laminates at cryogenic conditions. Composites Part B: Engineering, 38(2), 193-200.   DOI
4 Clark, A.F., 1968, Low temperature thermal expansion of some metallic alloys, Cryogenics, 8, 282-289.   DOI
5 Green, D.W., Evans, J.W., Logan, J.D., Nelson, W.J., 1999. Adjusting modulus of elasticity of lumber for changes in temperature. Wood Engineering, 49(10), 82-94.
6 Khashaba, U.A., 2004. In-plane shear properties of cross-ply composite laminates with different off-axis angles. Composite Structures, 65(2), 167-177.   DOI
7 Kim, J.H., Choi, S.W., Park, D.H., Park, S.B., Kim, S.K., Park, K.J., Lee, J.M., 2018. Effects of cryogenic temperature on the mechanical and failure characteristics of melamine-urea-formaldehyde adhesive plywood. Cryogenics, 91, 36-46.   DOI
8 Kim, J.H., Park, D.H., Lee, C.S., Park, K.J., Lee, J.M., 2015. Effect of cryogenic thermal cycle and immersion on the mechanical characteristics of phenol-resin bonded plywood. Cryogenics, 72, 90-102.   DOI
9 Moubarik, A., Pizzi, A., Allal, A., Charrier, F., Charrier, B., 2009. Cornstarch and tannin in phenol-formaldehyde resins for plywood production. Industrial Crops and Products, 30, 188-193.   DOI
10 Kuo, J.F., Campbell, R.B., Hoie. S.M., Rinehart, A.J., Sandstrom, R.E., Yung, T.W., 2009. LNG tank sloshing assessment methodology - The new generation. International Journal of Offshore and Polar Engineering, 19, 241-253.
11 Park, S.B., Lee, C.S., Choi, S.W., Kim, J.H., Bang, C.S., Lee, J.M., 2016. Polymeric foams for cryogenic temperature application: Temperature range for non-recovery and brittle-fracture of microstructure. Composite Structures, 136, 258-269.   DOI
12 Park, Y.I., Lee, J.H., 2018. Buckling strength of GTT NO96 LNG Carrier cargo containment system. Ocean Engineering, 154, 43-58.   DOI
13 Yang, C.G., Xu, L., Chen, N., 2007. Thermal expansion of polyurethane foam at low temperature. Energy Conversion and Management, 48, 481-485.   DOI