随着能源需求的增加和人们环保意识的增强,天然气作为一种清洁能源越来越受到青睐。对于液化天然气的海上长距离运输,LNG船无疑是最有效、最经济的选择。耐波性作为船舶安全性能的一个重要指标,在船舶的设计和运营过程中必须考虑。本文采用挪威船级社SESAM软件计算了LNG船在规则波中的六自由度运动响应,研究航速和浪向对其运动的影响。根据相关要求制作船模进行其在规则波中的耐波性试验,并将计算结果跟试验结果进行对比。结果表明:浪向对其运动响应影响较大,横浪时升沉、横摇响应最大,迎浪时纵摇响应最大;计算结果与试验结果的变化规律吻合较好。
With increasing demand for energy and the enhancement of environment consciousness, the natural gas as a clean energy has drawn more and more attention. For long-distance offshore transportation of liquefied natural gas, undoubtedly, LNG vessel is the most effective and economical choice. Seakeeping performance as an important indicator of the safety performance of the ship, it should be taken into account during the progress of designing and operating. In present paper, the soft SESAM of DNV is used to calculate the six degree motion response of LNG ship in regular waves, studying the influence of forward speed and wave direction. According to relevant requirement, ship model is made and its seakeeping experiment is conducted, and then compared the calculated result with the experiment result. The results showed that:the wave direction has great influence on its motion response, heave and roll is the largest when encountering transverse wave, while pitch is the largest at the case of head sea; the variation trend of calculated result and experiment result has a good agreement.
2016,38(3): 25-30 收稿日期:2015-05-08
DOI:10.3404/j.issn.1672-7619.2016.03.006
分类号:U661.32
作者简介:刘永清(1990-),男,硕士研究生,研究方向为船舶运动响应。
参考文献:
[1] SCLAVOUNOS P D, NAKOS D E. Stability analysis of panel methods for free-surface flows with forward speed[C]//Proceedings of the 17th symposium naval hydrodynamics. Hague, The Netherlands:National Academy of Sciences, 1988:29-48.
[2] NAKOS D E. Ship wave patterns and motions by a three dimensional rankine panel method[D]. Massachusetts, USA:Massachusetts Institute of Technology, 1990.
[3] KRING D C. Time domain ship motions by a three-dimensional Rankine Panel method[D]. Massachusetts, USA:Massachusetts Institute of Technology, 1994.
[4] LEE S J, KIM M H, LEE D H, et al. The effects of LNG-tank sloshing on the global motions of LNG carriers[J]. Ocean Engineering, 2007, 34(1):10-20.
[5] SONG M J, KIM K H, KIM Y. Numerical analysis and validation of weakly nonlinear ship motions and structural loads on a modern containership[J]. Ocean Engineering, 2011, 38(1):77-87.
[6] 陈震, 文俊华. 五体船侧体布局对纵向运动性能的影响[J]. 上海交通大学学报, 2011, 45(4):494-504. CHEN Zhen, WEN Jun-hua. The influence of side hulls layout on longitudinal motion of pentamaran in wave[J]. Journal of Shanghai Jiaotong University, 2011, 45(4):494-504.
[7] 文俊华. 五体船波浪载荷和运动特性研究[D]. 上海:上海交通大学, 2012.
[8] 孙政, 江克进, 王小宁, 等. 穿梭LNG船耐波性的模型试验与理论计算[C]//第十三届全国水动力学学术会议暨第二十六届全国水动力学研讨会论文集. 青岛:中国力学学会, 2014:1256-1261. SUN Zheng, JIANG Ke-jin, WANG Xiao-ning, et al. Seakeeping experiment and theoretical study of shuttle LNG carrier[C]//Proceedings of the 13th National Hydrodynamics Conference and 26th Hydrodynamics National Symposium. Qingdao:The Chinese Society of Theoretical and Applied Mechanics, 2014:1256-1261.
[9] 李积德. 船舶耐波性[M]. 哈尔滨:哈尔滨工程大学出版社, 2007.
[10] 戴遗山, 段文洋. 船舶在波浪中运动的势流理论[M]. 北京:国防工业出版社, 2008.
