DERIVATION FOR ELECTRIC CURRENT REGULATION EQUATION OF A GRADIENT MAGNETIC FIELD TO CONTROL SUSPENDING MAGNETIC PARTICLES INSIDE DIALYSATE SOLUTION

被引:0
|
作者
Lu, Junfeng [1 ]
Lu, Wen-qiang [2 ]
机构
[1] Chinese Acad Sci, Tech Inst Phys & Chem, Key Lab Cryogen, Beijing 100190, Peoples R China
[2] Univ Chinese Acad Sci, Beijing 100049, Peoples R China
来源
PROCEEDINGS OF THE ASME 5TH INTERNATIONAL CONFERENCE ON MICRO/NANOSCALE HEAT AND MASS TRANSFER, 2016, VOL 2 | 2016年
关键词
Adsorption; magnetic particles; magnetic hemodialysis (HD); HEMODIALYSIS; MEMBRANE;
D O I
暂无
中图分类号
O414.1 [热力学];
学科分类号
摘要
To allow a better adsorption performance inside a novel magnetic adsorption device designed in the process of hemodialysis, the mechanical properties of magnetic absorbents trapped inside a two-phase system are studied in this paper. A gradient magnetic coil field was assumed to produce the magnetic driving force that balances other hydraulic forces for the adsorbents. Applying this field, a complement practical form of winding equation for the solenoid coil is obtained. The case studies are also made in this paper to explore the design of the field.
引用
收藏
页数:6
相关论文
共 26 条
  • [1] Derivation for Electric Current Regulation Equation of a Gradient Magnetic Field to Control Suspending Magnetic Particles Inside Dialysate Solution
    Lu, Junfeng
    Lu, Wen-Qiang
    JOURNAL OF HEAT TRANSFER-TRANSACTIONS OF THE ASME, 2018, 140 (01):
  • [2] Induction of cell death by magnetic particles in response to a gradient magnetic field inside a uniform magnetic field
    Carlos David Amaya-Jaramillo
    Adriana Patricia Pérez-Portilla
    José Javier Serrano-Olmedo
    Milagros Ramos-Gómez
    Journal of Nanoparticle Research, 2017, 19
  • [3] Induction of cell death by magnetic particles in response to a gradient magnetic field inside a uniform magnetic field
    David Amaya-Jaramillo, Carlos
    Patricia Perez-Portilla, Adriana
    Javier Serrano-Olmedo, Jose
    Ramos-Gomez, Milagros
    JOURNAL OF NANOPARTICLE RESEARCH, 2017, 19 (10)
  • [4] Derivation of ferrofluid lubrication equation for slider bearings with variable magnetic field and rotations of the carrier liquid as well as magnetic particles
    Rajesh C. Shah
    Rajiv B. Shah
    Meccanica, 2018, 53 : 857 - 869
  • [5] Derivation of ferrofluid lubrication equation for slider bearings with variable magnetic field and rotations of the carrier liquid as well as magnetic particles
    Shah, Rajesh C.
    Shah, Rajiv B.
    MECCANICA, 2018, 53 (4-5) : 857 - 869
  • [6] Electric current and field control of vortex structures in cylindrical magnetic nanowires
    Fernandez-Roldan, Jose A.
    del Real, Rafael P.
    Bran, Cristina
    Vazquez, Manuel
    Chubykalo-Fesenko, Oksana
    PHYSICAL REVIEW B, 2020, 102 (02)
  • [7] SEGREGATION CONTROL AT DIRECTIONAL SOLIDIFICATION USING MAGNETIC FIELD AND ELECTRIC CURRENT
    Kaldre, I.
    Fautrelle, Y.
    Etay, J.
    Bojarevics, A.
    Buligins, L.
    MAGNETOHYDRODYNAMICS, 2015, 51 (03): : 445 - 451
  • [8] Regulation of the welding current magnetic field during electric arc welding of pipes
    Shchetinin S.V.
    Shchetinina V.A.
    Fedun V.I.
    Welding International, 2020, 34 (4-6) : 242 - 249
  • [9] Sedimentation of Fe3O4 nanosized magnetic particles in water solution enhanced in a gradient magnetic field
    I. Medvedeva
    M. Uimin
    A. Yermakov
    A. Mysik
    I. Byzov
    T. Nabokova
    V. Gaviko
    N. Shchegoleva
    S. Zhakov
    V. Tsurin
    O. Linnikov
    I. Rodina
    V. Platonov
    V. Osipov
    Journal of Nanoparticle Research, 2012, 14
  • [10] Sedimentation of Fe3O4 nanosized magnetic particles in water solution enhanced in a gradient magnetic field
    Medvedeva, I.
    Uimin, M.
    Yermakov, A.
    Mysik, A.
    Byzov, I.
    Nabokova, T.
    Gaviko, V.
    Shchegoleva, N.
    Zhakov, S.
    Tsurin, V.
    Linnikov, O.
    Rodina, I.
    Platonov, V.
    Osipov, V.
    JOURNAL OF NANOPARTICLE RESEARCH, 2012, 14 (03)
123