{"title":"利用磁场从水流中分离 Fe3O4 纳米粒子的数值研究:三维模拟","authors":"Mozhgan Farzin, Amin Haghighi Poshtiri, Ramin Kouhikamali","doi":"10.1177/09544062241259613","DOIUrl":null,"url":null,"abstract":"The development of magnetic separation technology using magnetic nanoparticles offers a promising avenue for targeted drug delivery and dealing with the upcoming water crises, environmental pollution and the gradual mineral resource depletion. In this study, a three-dimensional Lagrangian Discrete Phase Model (DPM) is carried out to simulate the performance of Fe<jats:sub>3</jats:sub>O<jats:sub>4</jats:sub> nanoparticles to improve the separation process under the influence of an external magnetic field within a horizontal pipe. The crucial role of the drag force in capture efficiency (CE) prompted its examination, simulating various drag models for groups of particles. The Stokes-Cunningham model, showing a 3.59% average error is a suitable choice compared to experimental results. The research examines the impact of effective parameters, including flow velocity, magnetic field intensity, wire location, particle size and mass flow rate, and pipe diameter on CE and flow pattern. The results show that increasing nanoparticle concentration reshapes the flow pattern due to secondary flows without significantly changing separation efficiency. Moreover, decreasing flow velocity, diminishes drag force and enhances magnetic force impact. Specifically, reducing the velocity to a third increases CE by 37%. Furthermore, capture capacity varies approximately linearly with electric current. Due to the magnetic force’s role as a volumetric force in interphase momentum transfer, the increase in particle size from 200 to 500 nm at 3 × 10<jats:sup>5</jats:sup> A enhances CE by nearly 50%. However, increasing the pipe diameter diminishes particle capture, attributed to higher Reynolds numbers. According to the results, the impact of increasing magnetic field intensity and particle size on CE improvement is notably more pronounced compared to the effect of flow velocity reduction. A comparative analysis of three injection types reveals that using the group injection type helps to select an appropriate injection location to increase CE and identify the final positions of nanoparticles.","PeriodicalId":20558,"journal":{"name":"Proceedings of the Institution of Mechanical Engineers, Part C: Journal of Mechanical Engineering Science","volume":"115 1","pages":""},"PeriodicalIF":1.8000,"publicationDate":"2024-07-23","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":"{\"title\":\"Numerical study on Fe3O4 nanoparticle separation from water flow using magnetic field: A 3D simulation\",\"authors\":\"Mozhgan Farzin, Amin Haghighi Poshtiri, Ramin Kouhikamali\",\"doi\":\"10.1177/09544062241259613\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"The development of magnetic separation technology using magnetic nanoparticles offers a promising avenue for targeted drug delivery and dealing with the upcoming water crises, environmental pollution and the gradual mineral resource depletion. In this study, a three-dimensional Lagrangian Discrete Phase Model (DPM) is carried out to simulate the performance of Fe<jats:sub>3</jats:sub>O<jats:sub>4</jats:sub> nanoparticles to improve the separation process under the influence of an external magnetic field within a horizontal pipe. The crucial role of the drag force in capture efficiency (CE) prompted its examination, simulating various drag models for groups of particles. The Stokes-Cunningham model, showing a 3.59% average error is a suitable choice compared to experimental results. The research examines the impact of effective parameters, including flow velocity, magnetic field intensity, wire location, particle size and mass flow rate, and pipe diameter on CE and flow pattern. The results show that increasing nanoparticle concentration reshapes the flow pattern due to secondary flows without significantly changing separation efficiency. Moreover, decreasing flow velocity, diminishes drag force and enhances magnetic force impact. Specifically, reducing the velocity to a third increases CE by 37%. Furthermore, capture capacity varies approximately linearly with electric current. Due to the magnetic force’s role as a volumetric force in interphase momentum transfer, the increase in particle size from 200 to 500 nm at 3 × 10<jats:sup>5</jats:sup> A enhances CE by nearly 50%. However, increasing the pipe diameter diminishes particle capture, attributed to higher Reynolds numbers. According to the results, the impact of increasing magnetic field intensity and particle size on CE improvement is notably more pronounced compared to the effect of flow velocity reduction. 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引用次数: 0
摘要
利用磁性纳米粒子开发磁性分离技术为靶向给药和应对即将到来的水危机、环境污染和矿产资源逐渐枯竭提供了一条前景广阔的途径。本研究利用三维拉格朗日离散相模型(DPM)模拟了 Fe3O4 纳米粒子在水平管道内受外磁场影响时改善分离过程的性能。阻力在捕获效率(CE)中的关键作用促使我们对其进行研究,并模拟了颗粒组的各种阻力模型。与实验结果相比,斯托克斯-坎宁安模型的平均误差为 3.59%,是一个合适的选择。研究考察了有效参数对 CE 和流动模式的影响,包括流速、磁场强度、导线位置、颗粒大小和质量流量以及管道直径。结果表明,纳米粒子浓度的增加会因二次流而改变流动模式,但不会显著改变分离效率。此外,降低流速可减少阻力,增强磁力影响。具体来说,将流速降低到三分之一,CE 会增加 37%。此外,捕获能力与电流大致呈线性关系。由于磁力在相间动量传递中起到体积力的作用,在 3 × 105 A 电流条件下,粒径从 200 纳米增加到 500 纳米,CE 提高了近 50%。然而,由于雷诺数较高,增加管道直径会减少颗粒捕获。结果表明,与流速降低的影响相比,磁场强度和颗粒尺寸的增加对 CE 改善的影响更为明显。对三种喷射类型的比较分析表明,使用分组喷射类型有助于选择合适的喷射位置来提高 CE 值,并确定纳米粒子的最终位置。
Numerical study on Fe3O4 nanoparticle separation from water flow using magnetic field: A 3D simulation
The development of magnetic separation technology using magnetic nanoparticles offers a promising avenue for targeted drug delivery and dealing with the upcoming water crises, environmental pollution and the gradual mineral resource depletion. In this study, a three-dimensional Lagrangian Discrete Phase Model (DPM) is carried out to simulate the performance of Fe3O4 nanoparticles to improve the separation process under the influence of an external magnetic field within a horizontal pipe. The crucial role of the drag force in capture efficiency (CE) prompted its examination, simulating various drag models for groups of particles. The Stokes-Cunningham model, showing a 3.59% average error is a suitable choice compared to experimental results. The research examines the impact of effective parameters, including flow velocity, magnetic field intensity, wire location, particle size and mass flow rate, and pipe diameter on CE and flow pattern. The results show that increasing nanoparticle concentration reshapes the flow pattern due to secondary flows without significantly changing separation efficiency. Moreover, decreasing flow velocity, diminishes drag force and enhances magnetic force impact. Specifically, reducing the velocity to a third increases CE by 37%. Furthermore, capture capacity varies approximately linearly with electric current. Due to the magnetic force’s role as a volumetric force in interphase momentum transfer, the increase in particle size from 200 to 500 nm at 3 × 105 A enhances CE by nearly 50%. However, increasing the pipe diameter diminishes particle capture, attributed to higher Reynolds numbers. According to the results, the impact of increasing magnetic field intensity and particle size on CE improvement is notably more pronounced compared to the effect of flow velocity reduction. A comparative analysis of three injection types reveals that using the group injection type helps to select an appropriate injection location to increase CE and identify the final positions of nanoparticles.
期刊介绍:
The Journal of Mechanical Engineering Science advances the understanding of both the fundamentals of engineering science and its application to the solution of challenges and problems in engineering.