Sedimentation efficiency evaluation of an aquaculture tank through experimental floc characterization and CFD simulation

IF 3.6 2区农林科学 Q2 AGRICULTURAL ENGINEERING

Aquacultural Engineering Pub Date : 2023-08-01 DOI:10.1016/j.aquaeng.2023.102343

Boris Miguel López-Rebollar, Daury García-Pulido, Carlos Diaz-Delgado, Ivan Gallego-Alarcón, Juan Antonio García-Aragón, Humberto Salinas-Tapia

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引用次数: 0

Abstract

One of the most important parameters for the proper functioning of an aquaculture tank is water quality. The survival and healthy growth of fish depends on it. The main factors affecting water quality are the remains of food and feces of fish which form cohesive particles called flocs that are kept within the tank or in the modules of the recirculating aquaculture system (RAS). Through the application of non-invasive optical techniques such as particle tracking velocimetry (PTV) it was possible to experimentally characterize the particles from aquaculture tanks obtaining diameters and settling velocity distribution, which allowed estimating the effective density of the flocs. With these parameters, the discrete phase model (DPM) was applied using computational fluid dynamics (CFD) to estimate the position and velocity of the particles within a prototype tank with geometry that promotes hydrodynamics suitable for particles sedimentation while maintaining the conditions for fish growth. Through an experimental validation it was verified that by having a tank with circular geometry, central settler made of concentric cylinders, perimeter gratings and outlet spillway cone, it is possible to achieve an efficiency of 77.91–90% of particles sedimentation not exceeding 1 h in the process. Thus, through computer simulation coupled with experimental validation, it was possible to establish geometric parameters for the design of aquaculture tanks with self-cleaning characteristics under the sustainable scheme of water recirculation and reuse.

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通过实验絮凝物特性和CFD模拟评价养殖池的沉降效率

水产养殖池正常运行的最重要参数之一是水质。鱼类的生存和健康生长取决于此。影响水质的主要因素是鱼类的食物残渣和粪便，它们形成被称为絮凝物的粘性颗粒，这些颗粒被保存在水箱或循环水产养殖系统（RAS）的模块中。通过应用粒子跟踪测速仪（PTV）等非侵入性光学技术，可以对水产养殖池中的粒子进行实验表征，从而获得直径和沉降速度分布，从而估计絮凝物的有效密度。有了这些参数，使用计算流体动力学（CFD）应用离散相模型（DPM）来估计原型池中颗粒的位置和速度，该原型池的几何形状促进了适合颗粒沉积的流体动力学，同时保持了鱼类生长的条件。通过实验验证，验证了通过具有圆形几何形状的水槽、由同心圆柱体制成的中央沉降器、周边格栅和出口溢洪道锥体，可以在该过程中实现77.91–90%的颗粒沉降效率，不超过1小时。因此，通过计算机模拟和实验验证，有可能在水循环和再利用的可持续方案下，为具有自清洁特性的水产养殖水箱的设计建立几何参数。

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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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