Feasibility of a passive tidal floating upweller system for the nursery culture of bivalve spat

IF 4.3 2区农林科学 Q2 AGRICULTURAL ENGINEERING

Aquacultural Engineering Pub Date : 2025-09-16 DOI:10.1016/j.aquaeng.2025.102638

Mohamed Salman , Vladislav Sorokin , Andrew G. Jeffs , Sebastian McDonald , Michael MacDonald , Colin Whittaker , Bradley M. Skelton

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Abstract

High losses of juvenile bivalves, such as oysters, clams, and mussels, during nursery culture reduce the overall efficiency of aquaculture production of many species. These losses can be mitigated through effective contained nursery culture systems, which provide sufficient flow of water containing suspended food particles to facilitate the growth of juveniles, usually in an upwelling arrangement. Raw seawater can be used to provision upwelling nursery systems with flowing water containing particulate food, but it requires substantial energy input to pump large volumes. This study sought to eliminate the energy inputs for nursery culture by conducting a feasibility study on a tidally driven floating upweller system (FLUPSY) using a comprehensive simulation and experimental study approach. A passive tidal FLUPSY was designed based on established designs, followed by comprehensive computational fluid dynamics simulations in flume and ocean fluid domains. The results from laboratory flow visualisation experiments showed good agreement with the simulations. Field experiments further validated the simulation results, and the observed flow velocities mirrored those obtained from simulations. However, the results of both the simulations and experiments revealed that despite an upward trend along the inclined intake ramp, the flow near the spat location in the passive tidal FLUPSY was relatively low. As such, an optimisation study was carried out to increase the FLUPSY's outlet velocity, which showed that a three times increase in inlet area resulted in 62 % of the incoming tidal flow being conveyed through the passive tidal FLUPSY. Nevertheless, the disproportion between the FLUPSY's inlet and outlet areas presents challenges to commercial viability. These results provide valuable insight into the feasibility of a passive tidal FLUPSY for bivalve aquaculture and underscore the need to further explore alternative active tidal FLUPSY designs to address these limitations.

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双壳贝苗圃养殖被动潮汐上升流系统的可行性

幼双壳类，如牡蛎、蛤蜊和贻贝，在苗圃养殖期间大量损失，降低了许多物种水产养殖生产的整体效率。这些损失可以通过有效的苗圃培养系统来减轻，苗圃培养系统通常以上升流的方式提供含有悬浮食物颗粒的足够水流，以促进幼鱼的生长。生海水可以用来为上升流的苗圃系统提供含有颗粒食物的流动水，但它需要大量的能量输入才能泵出大量的水。本研究采用综合模拟和实验研究的方法，对潮汐驱动的浮动上升流系统（FLUPSY）进行可行性研究，试图消除苗圃养殖的能量输入。在已有设计的基础上设计了被动潮汐FLUPSY，并在水槽和海洋流体领域进行了全面的计算流体动力学模拟。室内流场可视化实验结果与仿真结果吻合较好。现场实验进一步验证了模拟结果，观测到的流速与模拟结果相吻合。然而，模拟和实验结果都表明，在被动潮汐FLUPSY中，尽管沿倾斜进气道坡道有上升趋势，但靠近口口位置的流量相对较低。因此，进行了一项优化研究，以增加FLUPSY的出口速度，结果表明，进口面积增加三倍，导致62% %的来潮流量通过被动潮汐FLUPSY输送。然而，FLUPSY的进口和出口区域之间的不平衡对商业可行性提出了挑战。这些结果为双壳类水产养殖被动潮汐FLUPSY的可行性提供了有价值的见解，并强调了进一步探索替代主动潮汐FLUPSY设计以解决这些局限性的必要性。

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来源期刊

Aquacultural Engineering 农林科学-农业工程

CiteScore

8.60

自引率

10.00%

发文量

审稿时长

>24 weeks

期刊介绍： Aquacultural Engineering is concerned with the design and development of effective aquacultural systems for marine and freshwater facilities. The journal aims to apply the knowledge gained from basic research which potentially can be translated into commercial operations. Problems of scale-up and application of research data involve many parameters, both physical and biological, making it difficult to anticipate the interaction between the unit processes and the cultured animals. Aquacultural Engineering aims to develop this bioengineering interface for aquaculture and welcomes contributions in the following areas: – Engineering and design of aquaculture facilities – Engineering-based research studies – Construction experience and techniques – In-service experience, commissioning, operation – Materials selection and their uses – Quantification of biological data and constraints