| |
1. |
Abtew, M.A. Boussu, F. Bruniaux, P. Loghin, C. Cristian, I. Chen, Y. & Wang L., 2018. Influences of fabric density on mechanical and moulding behaviours of 3D warp interlock para-aramid fabrics for soft body armour application. Composite Structures, 204, pp.402-418.
|
2. |
Adkins, R.E. & Sutton, H.E., 1994. Economics of liquefied natural gas production, transport and distribution for end use as a transportation fuel, In Advances in cryogenic engineering, Springer, Boston, MA, pp.45-54.
|
3. |
An, Q. et al., 2018. Tailored glass fiber interphases via electrophoretic deposition of carbon nanotubes: Fiber and interphase characterization. Composites Science and Technology, 166, pp.131-139.
|
4. |
ASTM Standards, 2013. C1239‐13 Standard practice for reporting uniaxial strength data and estimating weibull distribution parameters for advanced ceramics. |
5. |
Bai, R. et al., 2020. Shear deformation and energy absorption analysis of flexible fabric in yarn pullout test. Composites Part A: Applied Science and Manufacturing, 128, 105678.
|
6. |
Choi, S.W., Roh, J.U., Kim, M.S., & Lee, W.I., 2012. Analysis of two main LNG CCS(Cargo Containment System) insulation boxes for leakage safety using experimentally defined thermal properties. Applied Ocean Research, 37, pp.72-89.
|
7. |
Han, S. et al., 2009. Experimental study on the structural behavior of secondary barrier of Mark-III LNG CCS, In ASME 2009 28th International Conference on Ocean, Offshore and Arctic Engineering, pp.101-107.
|
8. |
ISO, E. 2286-2: 1998. Rubber-or plastics-coated fabrics–determination of roll characteristics–Part, 2. |
9. |
ISO, P. 1421: 2001. Rubber-or plastics-coated fabrics–determination of tensile strength andelongation at break. |
10. |
Nam, S., Yu, Y.H., Choi, I. & Bang, C.S., 2014. Fracture toughness improvement of polyurethane adhesive joints with chopped glass fibers at cryogenic temperatures. Composite Structures, 107, pp.522-527.
|
11. |
Oh, D.J., Lee, J.M., Chun, M.S. & Kim, M.H., 2017. Reliability evaluation of a LNGC insulation system with a metallic secondary barrier. Composite Structures, 171, pp.43-52.
|
12. |
Olteanu, D. & Freeman, L., 2010. The evaluation of median-rank regression and maximum likelihood estimation techniques for a two-parameter Weibull distribution. Quality Engineering, 22(4), pp.256-272.
|
13. |
Osada, T., Nakai, A. & Hamada, H., 2003. Initial fracture behavior of satin woven fabric composites. Composite structures, 61(4), pp.333-339.
|
14. |
Pan, N. & Yoon, M.Y., 1993. Behavior of yarn pullout fromwoven fabrics: Theoretical and experimental. Textile Research Journal, 63(11), pp.629-637.
|
15. |
Pan, N., 1996. Analysis of woven fabric strengths: prediction of fabric strength under uniaxial and biaxial extensions. Composites Science and Technology, 56(3), pp.311-327.
|
16. |
Peirce, F.T., 1926. Tensile tests for cotton yarns:“the weakest link” theorems on the strength of long and of composite specimens. The Journal of the Textile Institute, 17, pp.355-368.
|
17. |
Ristaniemi, A. Stenroth, L. Mikkonen, S. & Korhonen, R.K., 2018. Comparison of elastic, viscoelastic and failure tensile material properties of knee ligaments and patellar tendon. Journal of biomechanics, 79, pp.31-38.
|
18. |
Shahpurwala, A.A. & Schwartz, P., 1989. Modeling woven fabric tensile strength using statistical bundle theory. Textile Research Journal, 59(1), pp.26-32
|
19. |
Szcześniak, L, Rachocki, A. & Tritt-Goc, J., 2008. Glass transition temperature and thermal decomposition of cellulose powder. Cellulose, 15(3), pp.445-451.
|
20. |
Yoon, S.H., 2011. Design of the composite sandwich panel of the hot pad for the bonding of large area adhesive films. Composite structures, 94(1), pp.102-113.
|