JOURNAL BROWSE
Search
Advanced SearchSearch Tips
Stress and Displacement Analysis of Arctic Frostheave with Gas Pipeline using Finite Element Method
facebook(new window)  Pirnt(new window) E-mail(new window) Excel Download
 Title & Authors
Stress and Displacement Analysis of Arctic Frostheave with Gas Pipeline using Finite Element Method
Kim, Kyung Il; Yeom, Kyu Jung; Oh, Kyu Hwan; Kim, Woo Sik;
  PDF(new window)
 Abstract
According to the interest of the arctic's resources rising, many countries are making moves to develop these resources. Korea has also undergone negotiations with Russia to develop natural gas resources in Siberia, which is geographically relatively close. However, the Arctic resources market is dominate, it is essential to develop construction techniques that are suited for the Arctic. Gas pipelines in the Arctic are affected by frost heave due to the region's extremely low temperatures, a condition that is not present in Korea, making it vital to develop a finite element method (FEM) model. This research paper study a model of gas pipe lines in the Arctic and frost heave using FEM.
 Keywords
finite element method;arctic;pipeline;frost heave;elasto-plastic;
 Language
Korean
 Cited by
 References
1.
Kim, Young jin, Kang, Jae Mo, Kim, Young Suk and Hong, Seung Seo., "Anlysis of Environmental and Geographic Charactieristic and Respurece Development Condition", Civil Expo, 4331-4334, (2007)

2.
Michael Bradshaw., "A New Energy Age in Pacific Russia: Lessons from the Sakhalin Oil and Gas Projects", Eurasian Geography and Economics, 51(3), 330-359, (2010) crossref(new window)

3.
Kim, Woo Sik, "Technology trend of energy pipe", KSME, 54(1), 53-57, (2014)

4.
Alska Stand Alone Gas Pipline, "Design Methodology to Address Frost heave Potential", (2011)

5.
Kazuhiko O'hashi, "Study on the unique design, construction and operation of gas pipelines in the permafrost of east siberia", Kyoto university, (1997)

6.
Mackenzie Valley Pipeline, "Arctic Engineering", (2004)

7.
Arnold Verruijt., "Soil Mechanics", (2004)

8.
J. S. Dugdale, D. K. C. MacDonald, "The Thermal Expansion of Solids", Physical Review Letters, 89, 832-, (1952)

9.
Klaus-Dieter Keller, QtiPlot, "Density of ice and water as function of temperature", (2012)

10.
Kim, Hyung sik, Kim, Woo Sik, Bang, In Hwan, Oh, Kyuhwan and Hong, Sung Ho., "Analysis of Stresses on Buried Natural Gas Pipeline Subjected to Ground Subsidence", KOSOS, 13(2), 54-64, (1998)

11.
Lee, Ouk Sub and Kim, Dong Hyeok., "Effect of Ground Subsidence on Reliability of Buried Pipelines", KSPE, 21(1), 173-180, (2004)

12.
Yaping Wu, Yu Sheng, Yong Wang, Huijun Jin, Wu Chen., "Stresses and deformations in a buried oil pipeline subject to differential frost heave in permafrost regions", Cold Regions Science and Technology, 64, 256-261, (2010) crossref(new window)

13.
Zhi Wen, Yu Sheng, Huijin Jin, Shuangyang Li, Guoyu Li, Yonghong Niu., "Thermal elastoplastic computation model for a buried oil pipeline in frozen ground", Cold Regions Science and Technology, 64, 248-255, (2010) crossref(new window)

14.
Levy, Bass, Stern, "Handbook of Elastic Properties of Solids, Liquids, and Gases", (2000)

15.
ASME B31.8 (2010)