DOI QR코드

DOI QR Code

Fluid Structure Interaction Analysis of Membrane Type LNG CCS Experiencing the Sloshing Impact by Impinging Jet Model

멤브레인형 LNG 화물창의 강도평가를 위해 적용된 분사모델을 이용한 유체구조 연성해석에 관한 연구

  • Hwang, Se Yun (Department of Naval Architecture and Ocean Engineering, Inha Univ.) ;
  • Lee, Jang Hyun (Department of Naval Architecture and Ocean Engineering, Inha Univ.)
  • 황세윤 (인하대학교 조선해양공학과) ;
  • 이장현 (인하대학교 조선해양공학과)
  • Received : 2014.10.30
  • Accepted : 2014.12.11
  • Published : 2015.02.28

Abstract

The reliable sloshing assessment methods for LNG CCS(cargo containment system) are important to satisfy the structural strength of the systems. Multiphase fluid flow of LNG and Gas Compressibility may have a large effect on excited pressures and structural response. Impinging jet model has been introduced to simulate the impact of the LNG sloshing and analyze structural response of LNG CCS as a practical FSI(fluid structure interaction) method. The practical method based on fluid structure interaction analysis is employed in order to evaluate the structural strength in actual scale for Mark III CCS. The numerical model is based on an Euler model that employs the CVFEM(control volume based finite element method). It includes the particle motion of gas to simulate not only the interphase interaction between LNG liquid and gas and the impact load on the LNG insulation box. The analysis results by proposed method are evaluated and discussed for an effectiveness of FSI analysis method.

LNG 선박에서 발생하는 슬로싱 충격하중은 다상유동 및 기체의 압축효과에 따라 CCS에서 발생하는 압력과 구조응답에 큰 영향을 미칠 수 있다. 본 연구에서는 슬로싱 운동 시 LNG의 유동에 의해 발생하는 슬로싱 충격을 시뮬레이션하기 위해서 다상유동을 적용한 수치해석 모델을 제시하였으며, 그 결과를 실험과 비교하여 타당성을 검토하였다. 또한 효율적인 구조 응답 계산을 위해 분사모델을 이용한 유체구조 연성해석 방법에 대해서 검토하고 멤브레인형 Mark III 화물창의 강도평가에 적용하여 LNG 화물창의 강도평가를 위한 가능성을 검토하였다.

Keywords

References

  1. ABS (2006) Guidance Note on Assessment of Membranetype LNG Containment Systems under Sloshing Loads.
  2. ANSYS (2009) ANSYS.CFX Theory Manual.
  3. Graczyk, M., Moan, T. (2011) Structural Response to Sloshing Excitation in Membrane LNG Tank, J. Offshore Mech. & Arctic Eng., 133(2), pp.133-144.
  4. Graczyk, M., Moan, T., Rognebakke, O. (2006) Probabilistic Analysis of Characteristic Pressure for LNG Tanks. J. Offshore Mech. & Arctic Eng.-Trans. ASME, 128(2), pp.133-144. https://doi.org/10.1115/1.2185128
  5. GTT Co., Ltd., (2014) http://www.gtt.fr/, productmark-iii-system I
  6. to, H., Suh, Y.S., Chun, S.E., Satish Kumar, Y.V., Ha, M.K., Park, J.J., Yu, H.C., Wang, B. (2008) A Direct Assessment Approach for Structural Strength Evaluation of Cargo Containment System under Sloshing Inside LNGC Tans based on Fluid Structure Interaction, Proc. 27th Int. Conf. Offshore Mech. & Arctic Eng., Estoril, Portugal, 5, pp.835-845.
  7. Kim, S.Y., Kim, Y.H., Ryu, M.C., Kim, Y.S. (2010) Prescreening and Statistical Evaluation of Sloshing-Induced Impact Pressure, Proc. Soc. Naval Arch of Korea, pp.514-523.
  8. Lee, S.J., Yang, Y.S., Kim S.C., Lee J.H. (2011) Strength Assessment Procedure of LNG CCS under Sloshing Load Based on the Direct Approach, Proc. Twenty-first (2011) Int. Offshore & Polar Eng. Conf., Hawaii, USA, pp.183-190.
  9. Lloyd. (2009) Ship Right-Sloshing Assessment Guidance Document for Membrane Tank Operations.
  10. Nho, I.S., Ki, M.S., Lee, J.M., Kim, S.C. (2011) A Study on the Sloshing Impact Response Analysis for Insulation System of Mark III LNG Cargo Containment System, Proc. Twenty-first Int. Offshore & Polar Eng. Conf.,, Hawaii, USA, pp.206-210.
  11. Wang, B., Han, S.K., Kim, Y.S., Park, Y.I., Shin, Y. (2009) Sloshing Model Tests and Strength Assessment of the NO96 Containment System, Proc. 19th Int Offshore & Polar Eng. Conf, ISOPE, Osaka, Japan, 3, pp.261-268.