Caisson Breakwater for LNG and Bulk Terminals: A Study on Limiting Wave Conditions for Caisson Installation

Yu Lin, Ghassan El Chahal, Yanlin Shao
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引用次数: 1

Abstract

As the worldwide oil and gas market continues to grow and environmental concerns with respect to in-port offloading of gas have increased, there has been a boom of interest in new liquefied natural gas LNG terminals in the past years. Loading - offloading operations at LNG and bulk terminals are generally protected by a breakwater to ensure high operability. For these terminals, caisson breakwaters are generally a preferred solution in water depth larger than 15 m due to its advantages compared to rubble mound breakwaters. The caisson installation is generally planned to be carried out in the period where sea conditions are relatively calm. However, many of these terminal locations are exposed to swell conditions, making the installation particularly challenging and subject to large downtime. There is no clear guidance on the caisson installation process rather than contractors’ experiences from different projects/sites. Therefore, studies are required in order to provide general guidance on the range of acceptable wave conditions for the installation operations and to have a better understanding of the influence of the caisson geometry. This paper presents a numerical study to determine the limiting wave conditions for caisson installing operations at larger water depth of 30–35 m for a confidential project along the African coast. Three caisson sizes/geometries are considered in order to assess and compare the wave-structure hydrodynamic interaction. The linear frequency-domain hydrodynamic analysis is performed for various seastates to determine the limiting wave conditions. Viscous effects due to flow separation at the sharp edges of the caisson are considered by using a stochastic linearization approach, where empirical drag coefficients are used as inputs. Parametric studies on caisson size and mooring stiffness are also presented, which can be used as a basis for future optimization. The uncertainty in the applied empirical viscous drag coefficients taken from the literature is examined by using a range of different drag coefficients. Further, the use of clearance-independent hydrodynamic coefficients (e.g. added mass and damping) may be questionable when the caisson is very close to the seabed, due to a possible strong interaction between caisson bottom and seabed. This effect is also checked quantitatively by a simplified approach. The findings of the study are presented in the form of curves and generalized to be used by designers and contractors for general guidance in future projects.
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LNG和散货码头的沉箱防波堤:沉箱安装的极限波浪条件研究
随着全球石油和天然气市场的持续增长,以及对港口天然气卸载的环境问题的关注日益增加,在过去的几年里,人们对新建液化天然气接收站的兴趣激增。液化天然气和散货码头的装卸作业通常由防波堤保护,以确保高操作性。对于这些码头来说,沉箱防波堤由于其相对于碎石丘防波堤的优势,通常是水深大于15米的首选解决方案。沉箱安装一般计划在海况相对平静的时期进行。然而,这些终端中的许多位置都暴露在膨胀条件下,使得安装特别具有挑战性,并且需要长时间停机。没有关于沉箱安装过程的明确指导,而不是承包商在不同项目/地点的经验。因此,需要进行研究,以便为安装作业提供可接受的波浪条件范围的一般指导,并更好地了解沉箱几何形状的影响。本文对某非洲沿海机密工程在30 ~ 35 m大水深处进行沉箱安装作业的极限波浪条件进行了数值研究。为了评估和比较波浪-结构水动力相互作用,考虑了三种沉箱尺寸/几何形状。对不同海况进行了线性频域水动力分析,确定了极限波条件。采用随机线性化方法,将经验阻力系数作为输入,考虑由沉箱尖锐边缘处的流动分离引起的粘性效应。对沉箱尺寸和系泊刚度进行了参数化研究,为今后的优化提供了依据。应用经验粘性阻力系数的不确定性,从文献中采取了使用不同的阻力系数的范围进行检查。此外,当沉箱非常靠近海床时,由于沉箱底部与海床之间可能存在强烈的相互作用,使用与间隙无关的水动力系数(例如,增加的质量和阻尼)可能会受到质疑。用一种简化的方法定量地检验了这种效应。研究结果以曲线的形式呈现,并被设计师和承包商用于未来项目的一般指导。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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