The Standard and Reverse Mode Operation of a Hydrocyclone for Microplastic Separation

Microplastics Pub Date : 2024-01-09 DOI:10.3390/microplastics3010002

T. Senfter, Andreas Walter, Lukas Dür, Florian Alber, Manuel Berger, M. Kraxner, M. Pillei

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Abstract

Harmonization in the analytical framework is needed to detect, define and further categorize plastics released into the environment. In the range of particles smaller than 200 μm, hydrocyclones (HCs) have proven their capacity in removing microplastics efficiently by offering technical advantages at low operational costs. This publication aims to expand scientific knowledge by introducing four commercially available, low-priced microplastics to a pilot-scale HC setting. The physicochemical characteristics of particles as well as the separation efficiency of the test rig were investigated in depth. Particles with a density of >1000 kg/m3 passed the primary vortex and were discharged into the underflow, allowing us to employ standard mode operation. Particles with a density of <1000 kg/m3 entered the secondary vortex and were removed through the overflow. As expected, separation efficiencies were found to be higher for particles revealing a greater density difference when compared with the mobile phase water. Furthermore, an increase in the inlet volume flow revealed significant positive impacts on the separation efficiency for three plastics to a certain threshold. Data on standard and reverse mode operations presented in this publication can lay out an important source for the harmonization and standardization of future HC research, with the goal of overcoming plastic pollution by developing economically competitive separation processes.

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用于分离微塑料的水力旋流器的标准和反向运行模式

需要统一分析框架，以检测、定义和进一步分类排放到环境中的塑料。在小于 200 μm 的颗粒范围内，水力旋流器（HC）以低运营成本提供技术优势，证明了其高效去除微塑料的能力。本出版物旨在通过在试验规模的水力旋流器环境中引入四种市售低价微塑料来扩展科学知识。我们对颗粒的物理化学特征以及试验装置的分离效率进行了深入研究。密度大于 1000 kg/m3 的颗粒通过了主涡流并被排入底流，使我们能够采用标准模式运行。密度小于 1000 kg/m3 的颗粒进入二级涡流，通过溢流排出。不出所料，与流动相水相比，密度差异较大的颗粒的分离效率更高。此外，进口体积流量的增加对三种塑料的分离效率有显著的正面影响。本出版物中提供的标准和反向模式操作数据可为未来 HC 研究的协调和标准化提供重要依据，其目标是通过开发具有经济竞争力的分离工艺来消除塑料污染。

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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Microplastics

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