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High Power Laser and Particle Beams, Volume. 34, Issue 8, 082002(2022)

Fast calculation of polishing powder sedimentation characteristics in magnetorheological polishing area under gradient magnetic field based on Kahan linearization

Hang Yang1, Shuai Zhang1, Yunfei Zhang2,3, Wen Huang2,3, and Jianguo He2
Author Affiliations
  • 1School of Engineering, Zunyi Normal University, Zunyi 563006, China
  • 2Institute of Mechanical Manufacturing Technology, China Academy of Engineering Physics, Mianyang 621900, China
  • 3Key Laboratory of Ultra-precision Processing Technology, China Academy of Engineering Physics, Chengdu 610200, China
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    AbstractGet PDF(in Chinese)
    Figures&Tables (11)
    Equations (12)
    References (18)
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    Figures & Tables(11)
    Schematic diagram of polishing powder sedimentation in the magnetorheological polishing area

    Fig. 1. Schematic diagram of polishing powder sedimentation in the magnetorheological polishing area

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    Sedimentation distribution cloud diagram of the polishing powder in the polishing area when the rotating speed ω of the polishing wheel is 100 r/min to 275 r/min

    Fig. 2. Sedimentation distribution cloud diagram of the polishing powder in the polishing area when the rotating speed ω of the polishing wheel is 100 r/min to 275 r/min

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    Influence of the polishing wheel speed on the deposition of polishing powder in the polishing area

    Fig. 3. Influence of the polishing wheel speed on the deposition of polishing powder in the polishing area

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    Sedimentation distribution cloud diagram of the polishing powder in the polishing area when the embedding depth h of polishing powder is between 0.65 mm and 1.00 mm

    Fig. 4. Sedimentation distribution cloud diagram of the polishing powder in the polishing area when the embedding depth h of polishing powder is between 0.65 mm and 1.00 mm

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    Influence of embedding depth on the sedimentation of polishing powder in the polishing area

    Fig. 5. Influence of embedding depth on the sedimentation of polishing powder in the polishing area

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    Sedimentation distribution cloud diagram of the polishing powder in the polishing area when the mass fraction w0 of the hydroxy/iron powder is 20% to 90%

    Fig. 6. Sedimentation distribution cloud diagram of the polishing powder in the polishing area when the mass fraction w0 of the hydroxy/iron powder is 20% to 90%

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    Influence of the mass fraction of hydroxyl iron powder on the sedimentation of polishing powder in the polishing area

    Fig. 7. Influence of the mass fraction of hydroxyl iron powder on the sedimentation of polishing powder in the polishing area

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    • Table 1. Experimental physical parameters

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      Table 1. Experimental physical parameters

      particle diameter/μm air-silicon soil tensor/N silicone oil viscosity/Pa·s silicone oil density/(kg·m−3) import and export pressure/Pa radius of curvature of the polishing wheel/mm
      50.040.9730.94101325150

    • Table 2. Different speed parameters of polishing wheel

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      Table 2. Different speed parameters of polishing wheel

      mass fraction/%embedded depth /mmpolishing rotation /r/min
      701.1100
      701.1125
      701.1150
      701.1175
      701.1200
      701.1225
      701.1250
      701.1275

    • Table 3. Different embedding depth parameters

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      Table 3. Different embedding depth parameters

      mass fraction/%polishing rotation/(r·min−1) embedded depth h/mm
      701500.65
      701500.70
      701500.75
      701500.80
      701500.85
      701500.90
      701500.95
      701501.00

    • Table 4. Changing the mass fraction of hydroxyl iron powder in polishing powder

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      Table 4. Changing the mass fraction of hydroxyl iron powder in polishing powder

      silicone oil viscosity/(mPa·s) hydroxy liron powder/μm mass fraction w0/%
      97.3520
      97.3530
      97.3540
      97.3550
      97.3560
      97.3570
      97.3580
      97.3590
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    Hang Yang, Shuai Zhang, Yunfei Zhang, Wen Huang, Jianguo He. Fast calculation of polishing powder sedimentation characteristics in magnetorheological polishing area under gradient magnetic field based on Kahan linearization[J]. High Power Laser and Particle Beams, 2022, 34(8): 082002

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    Paper Information

    Category: Inertial Confinement Fusion Physics and Technology

    Received: Aug. 16, 2021

    Accepted: May. 13, 2022

    Published Online: Aug. 8, 2022

    The Author Email:

    DOI:10.11884/HPLPB202234.210353

    Topics

    laser devices and laser physics
    Lasers and Laser Optics
    Laser physics
    laser manufacturing
    Instrumentation, Measurement and Metrology