Clemens Krautwald, Constantin Schweiger, David Schürenkamp, Nils Goseberg
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引用次数: 0
Abstract
Offshore structures become colonized by marine orga-nisms after a short period of time, whose common benthic communities depend among others on geographic location, water depth, water temperature, food supply, salinity and oxygen content of the water (Kröncke and Bergfeld, 2003; Shi et al., 2012). While biofouling can be categorized in biological terms as bivalves, kelp, algae, barnacles, tubeworms and other species (van der Stap et al., 2016; Wilhelmsson and Malm, 2008), engineers mostly distinguish between hard and soft marine growth based on the strength of their outer shell alone (Shi et al., 2012; Skaugset and Baarholm, 2008). Due to an increasing demand for sustainable energy, the offshore renewables industry experiences significant growth. However, many uncertainties persist in the consideration of biofouling, specifically when calculating loads accor-ding to the Morison concept, the influence of marine fouling on fatigue reassessment, on the flow velocities around cylinders and the vortex formation under waves. For the first time, the flow around cylinders with different artificial marine biofouling was recorded and analyzed in an extensive experimental study using a comprehensive 4D particle tracking velocimetry (PTV) system.
近海结构在短时间内被海洋生物占领,其共同的底栖生物群落除其他外取决于地理位置、水深、水温、食物供应、盐度和水的氧含量(Kröncke和Bergfeld, 2003;Shi et al., 2012)。生物污垢在生物学上可分为双壳类、海带、藻类、藤壶、管虫和其他物种(van der Stap et al., 2016;Wilhelmsson和Malm, 2008),工程师主要根据其外壳的强度来区分硬和软海洋生长(Shi et al., 2012;Skaugset and Baarholm, 2008)。由于对可持续能源的需求不断增加,海上可再生能源行业经历了显着增长。然而,在考虑生物污染时仍然存在许多不确定性,特别是在根据morrison概念计算载荷时,海洋污染对疲劳重新评估的影响,对圆柱体周围流速的影响以及波浪下涡的形成。利用综合四维粒子跟踪测速(PTV)系统,首次记录和分析了不同人工海洋生物污染条件下圆柱体周围的流动情况。
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