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61,005 resultsShowing papers similar to Effect of hydrocyclone design in microplastics-water separation by using computational fluid dynamics simulations
ClearEffect of hydrocyclone size on microplastics separation: a computational fluid dynamics investigation
Researchers used computer fluid dynamics simulations to test how the size of a hydrocyclone — a cone-shaped device that uses spinning water to separate particles — affects its ability to remove microplastics from water. Smaller hydrocyclones generated stronger centrifugal forces and recovered more microplastics, though they also required more energy, revealing a trade-off that engineers must balance in real-world water treatment systems.
Optimising miniaturised hydrocyclones for enhanced separation of microplastics
Researchers optimized the design of miniaturized hydrocyclones for separating small microplastics in the 5-20 micrometer range from water. Using computational fluid dynamics simulations, they identified optimal inlet geometry and flow conditions that significantly improved particle separation efficiency. The study demonstrates that mini-hydrocyclones could serve as a compact and energy-efficient technology for removing very small microplastics from water treatment systems.
Computational fluid dynamics and artificial neural network based modeling of microplastics seperation using hydrocyclone
This study used computational fluid dynamics and artificial neural networks to model the separation of microplastics using hydrocyclone technology, aiming to improve removal efficiency for these environmental contaminants from water. The combined modeling approach provided a framework for optimizing hydrocyclone design for microplastic removal.
Numerical study on the mechanism of microplastic separation from water by cyclonic air flotation
This numerical study modeled the separation of microplastics from water using cyclone separators, optimizing design parameters and flow conditions to improve removal efficiency across different particle sizes and densities.
High-efficiency microplastic removal in water treatment based on short flow control of hydrocyclone: Mechanism and performance
Researchers developed an improved mini-hydrocyclone device that removes over 98% of microplastics from water, a 34% improvement over conventional designs. The device uses tiny overflow channels to prevent small plastic particles from escaping during the separation process. This technology could be scaled up for industrial water treatment, helping to remove microplastics before treated water reaches the environment or drinking water supplies.
Comparative study of the performance of conventional and modified hydrocyclones in the removal of microplastics in aqueous media.
Researchers compared the performance of conventional and modified hydrocyclone designs for removing microplastics and nanoplastics from aqueous media, evaluating design modifications that could improve separation efficiency given growing evidence of microplastic ingestion risks to humans and animals.
The Standard and Reverse Mode Operation of a Hydrocyclone for Microplastic Separation
Researchers tested whether hydrocyclones — low-cost centrifugal separation devices — could efficiently separate microplastics from water, finding that particles denser than water were captured in standard mode while lighter particles required reverse mode operation. The system effectively separated all four test microplastic types based on density, suggesting hydrocyclones are a scalable, low-energy option for removing microplastics from industrial and municipal water streams.
In depth characterisation of hydrocyclones: Ascertaining the effect of geometry and operating conditions on their performance
Researchers conducted detailed experiments on hydrocyclones — spinning devices used to separate solids from liquids in industrial waste streams — testing how the shape, size, and operating pressure together affect how well they work. Their findings provide practical guidance for designing more efficient industrial water recycling and waste treatment systems.
High-Efficiency Microplastic Sampling Device Improved Using CFD Analysis
This study used computational fluid dynamics analysis to redesign a microplastic water sampling device, improving its hydrodynamic performance and collection efficiency to address the lack of standardized sampling equipment for environmental microplastic monitoring.
Cyclone Shapes for Sand and Microplastic Separation: Efficiency and Reynolds Number Relationships
This study compared three cyclone separator designs for their ability to separate microplastics from beach sand, finding that a cone-shaped design achieved near-perfect efficiency for denser plastic types but lower efficiency for lightweight Styrofoam. Cyclone-based separation offers a promising mechanical approach for cleaning microplastics from coastal sediments at scale.
Migration and Removal of Microplastics in a Dual-Cone Mini-Hydrocyclone
Researchers analysed microplastic migration and separation in a dual-cone mini-hydrocyclone using a numerically verified model, examining how feed flow rate, MP volume fraction, and particle density affect separation efficiency. They found that separation efficiency improved with higher flow rates (reaching 78.56% at 10 m/s for 50 micrometre MPs) but decreased at higher MP volume fractions due to particle collisions, while MPs with densities below water achieved near-complete separation of 98.51%.
Enhanced microplastic removal using a mini-hydrocyclone with microbubbles
Researchers improved microplastic separation from water by combining mini-hydrocyclones with microbubble injection, finding that the microbubbles reduced apparent microplastic density and substantially improved separation efficiency for particles with densities similar to water.
Research on the Enhancement of the Separation Efficiency for Discrete Phases Based on Mini Hydrocyclone
Researchers used numerical simulations to identify the key factors controlling separation efficiency in miniature hydrocyclones for offshore oil production fluids, providing design guidance for improving the separation of fine droplets and solid particles in space-constrained marine platforms.
Capturing Microplastics from Aquatic Systems Using Vortex-based Cyclone Technique
This study developed a vortex-based cyclone technique to capture microplastics from water, offering an alternative to filtration and sedimentation methods. The approach could be applied in water treatment to efficiently separate microplastics before they enter drinking water supplies or waterways.
Pengaruh Debit Aliran Terhadap Kinerja Pemisahan Limbah Microplastik Tersuspensi Menggunakan Hydrocyclone Dual Inlet Port
Researchers investigated the effect of varying flow rates on the separation performance of a dual-inlet hydrocyclone for removing suspended microplastic waste from water, measuring separation efficiency and microplastic classification outcomes across multiple flow rate conditions to optimize centrifugal separation as a practical treatment technology for microplastic-contaminated water.
Fluid Flow and Structural Analysis for the Design of Portable Microplastic Collection System
Researchers evaluated the separation performance of four cyclone system designs for a portable microplastic collection device, testing their ability to separate microplastic particles of 10, 50, and 100 µm from sand under fluid flow conditions. They found that a single-chamber internal structure achieved the highest separation efficiency, with improved performance for particles larger than 50 µm, and that structural analysis confirmed safety factors exceeding 1.5 for all integrated components.
Fluid Flow and Structural Analysis for the Design of Portable Microplastic Collection System
Researchers evaluated the separation performance of four cyclone system designs for a portable microplastic collection device, testing their ability to separate microplastic particles of 10, 50, and 100 µm from sand under fluid flow conditions. They found that a single-chamber internal structure achieved the highest separation efficiency, with improved performance for particles larger than 50 µm, and that structural analysis confirmed safety factors exceeding 1.5 for all integrated components.
Assessing Hydrocyclone System’s Efficiency in Water-Borne Microplastics Capture Using Online Microscopy Sensors
Researchers evaluated the efficiency of a hydrocyclone-based system for capturing water-borne microplastics, integrating online microscopy sensors to provide real-time monitoring of capture effectiveness and feedback for adaptive control under varying operating conditions.
Optimization of elutriation device for filtration of microplastic particles from sediment
Researchers optimized an elutriation device — which uses upward water flow to separate particles by density — achieving high microplastic recovery rates from sediment by adjusting flow rate and column diameter. The optimized device provides a practical, low-cost tool for extracting microplastics from environmental sediment samples in research and monitoring programs.
Towards a More Sustainable Water Treatment: Design of a Hydrodynamic Test Rig and Testing of a Novel Microplastic Filter Using Biomimetics
Researchers designed a hydrodynamic test rig and a novel biomimetic microplastic filter inspired by aquatic filter-feeding organisms, aiming to improve solid-liquid separation in water treatment. The study demonstrates how biological filtration strategies can inform more sustainable industrial microplastic removal approaches.
Coupled CFD-DEM modelling to assess settlement velocity and drag coefficient of microplastics
Researchers used computational fluid dynamics coupled with particle simulations to model how the size, shape, and density of microplastics affect their settling velocity and drag in water. Accurate physical models of microplastic behavior are essential for predicting where particles accumulate in rivers, lakes, and the ocean.
Evaluation of a Water Treatment System for Removing Microplastic in an Aqueous Media
Researchers evaluated the microplastic removal efficiency of a hybrid water treatment system combining a Bradley-type hydrocyclone, sand filter, and polymeric microfiltration membrane, applying mass balance equations and solid-liquid separation models to determine removal performance across different MP size fractions.
New method for extracting microplastics from sediments using a hydrocyclone and sieve
Researchers developed a faster way to pull microplastics out of sediment using a hydrocyclone — a device that spins water and particles using centrifugal force — processing about 10 kg of sediment in just 30 seconds. This is dramatically faster than current lab methods and could help scientists study microplastic pollution at much larger scales without needing toxic chemicals.
Research Status and Trends of Hydrodynamic Separation (HDS) for Stormwater Pollution Control: A Review
This systematic review synthesizes two decades of research on hydrodynamic separation (HDS) devices — physical systems that use vortex flow to separate particles from stormwater runoff — covering their design principles, performance, and limitations. While HDS systems effectively remove sediment and some pollutants, their performance for removing microplastics varies significantly depending on particle size and density. The review is relevant to microplastics management because stormwater is a major pathway for microplastics entering waterways, and evaluating how well current infrastructure captures them is essential for improving urban water management.