Spray Icing on ONEGA Vessel- A Comparison of Liquid Water Content Expressions

Volume 5A: Ocean Engineering Pub Date : 2022-06-05 DOI:10.1115/omae2022-79919

S. Dhar, E. Samuelsen, M. Naseri, K. G. Aarsæther, K. Edvardsen

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引用次数: 2

Abstract

The hazards associated with ice accretion primarily due to impinging freezing sea spray on ship structures are considered among serious safety concerns for ships operating in the colder regions. An accurate sea-spray icing-estimation model to evaluate the ice accumulation during operations in these regions can make marine operations safer. The accuracy of the present icing models for estimating icing on ships is substantially dependent on the incoming spray flux generated by the wave-ship interaction. In order to illustrate this, the vessel icing incident of the fishing vessel ONEGA is considered, which capsized after encountering heavy icing. In this study, the ONEGA vessel is modeled using a stability-calculation program. Then assuming the vessel to maintain minimum stability criteria prior to icing, the minimum likely amount of ice accumulation in the exposed locations that destabilized the vessel is estimated. This estimation is compared against another method used to evaluate ice thickness over the period ONEGA was accreting ice. The latter method utilizes the operational weather forecasting model used by MET Norway — “Marine-Icing model for the Norwegian COast Guard (MINCOG)”. The MINCOG model uses spray-flux estimations based on past empirical observations mainly obtained from fishing trawlers. The spray-flux consists of important elements like the liquid-water content (lwc) and the spray-generation frequency. An analysis is carried out applying different formulations for these two elements proposed by different researchers to see the variation in evaluating the total ice accumulation. After noticing the difference in results in total ice thickness from the stability and the icing-model methods used in this study, it is concluded that more investigation and field measurements are needed concerning the neglecting of the contribution of wind-generated spray in the spray flux formula used in MINCOG. Accordingly, multiple real-time spray measurements to develop a more suitable spray-flux formulation may improve the ice accumulation estimation over a longer time period.

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ONEGA容器上的喷雾结冰——液态水含量表达式的比较

对于在寒冷地区航行的船舶来说，冰的增加所带来的危害是一个严重的安全问题。建立准确的海喷冰量估算模型，对海上作业过程中的积冰量进行评估，可以提高海上作业的安全性。目前估算船舶结冰的结冰模型的精度很大程度上取决于波浪与船舶相互作用产生的入射喷雾通量。为了说明这一点，以ONEGA渔船遇重冰倾覆事件为例进行了分析。在本研究中，使用稳定性计算程序对ONEGA船进行了建模。然后，假设船舶在结冰之前保持最低稳定性标准，则估计在使船舶不稳定的暴露位置可能积聚的最小冰量。这一估计与另一种用于评估ONEGA增冰期间冰厚的方法进行了比较。后一种方法利用挪威气象局使用的业务天气预报模式-“挪威海岸警卫队(MINCOG)的海洋结冰模式”。MINCOG模型使用基于过去主要从拖网渔船获得的经验观测的喷雾通量估计。喷雾通量由液水含量(lwc)和喷雾产生频率等重要因素组成。应用不同研究人员提出的这两个要素的不同公式进行分析，以观察总积冰量的变化。在注意到本研究中使用的稳定性和结冰模型方法在总冰厚计算结果上的差异后，得出结论认为，对于MINCOG使用的喷雾通量公式中忽略风生喷雾的贡献，需要进行更多的调查和现场测量。因此，通过多次实时喷雾测量来开发更合适的喷雾通量配方，可以在更长的时间内改进冰积累估算。

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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Volume 5A: Ocean Engineering

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