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研究生: 謝明憲
Ming-Xian Xei
論文名稱: 轉注成型充填過程中邊界效應之數值模擬
指導教授: 洪勵吾
Lih-Wu Hourng
口試委員:
學位類別: 碩士
Master
系所名稱: 工學院 - 機械工程學系
Department of Mechanical Engineering
畢業學年度: 89
語文別: 中文
論文頁數: 71
中文關鍵詞: 樹脂轉注成型Brinkman方程式stokes方程式
外文關鍵詞: Resin Transfer Molding, Brinkman equation
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    • 摘要 Ⅰ 英文摘要 Ⅱ 目錄 Ⅲ 表目錄 Ⅴ 圖目錄 Ⅵ 符號說明 Ⅷ 第一章、緒論 1 1-1 前言 1 1-2 文獻回顧 3 1-3 研究方向 13 第二章、理論模式 14 2-1 纖維束內流場 14 2-2 纖維束外流場 15 2-3 空孔度 16 2-4 滲透度 16 2-5 毛細數 17 2-6 無因此分析 18 第三章、數值方法 20 3-1 數值模擬 20 3-2 數值計算步驟 21 3-3 流動面的收斂 22 第四章、結果與討論 25 第五章、結論 30 第六章、參考文獻 32 表 43 圖 44 附錄 70 附錄A 70 表 目 錄 表1纖維蓆空孔度與滲透度對照表 43 圖 目 錄 圖1-1纖維束編織示意圖 44 圖2-1纖維束內、外流場交互作用情形 45 圖2-2交界面移動元素路徑示意圖 46 圖2-3樹脂為牛頓流體假設之合理性 47 圖2-4物理定義域示意圖 48 圖2-5邊界條件示意圖 49 圖3-1(a)主要程式流程圖 50 圖3-1(b)Simpler程式流程圖 51 圖3-2流場格點座標分佈情形 52 圖3-3流動面擷取方法示意圖 53 圖4-1(a)(b)利用非交錯格點所模擬壓力場示意圖 54 圖4-2交錯隔點配置示意圖 55 圖4-3縫隙與纖維束平均入口壓力隨時間變化圖 56 圖4-4(a)當纖維束滲透度為 時,流動面隨時間變化情形 57 圖4-4(b)當纖維束滲透度為 時,流動面隨時間變化情形 58 圖4-4(c)當纖維束滲透度為 時,流動面隨時間變化情形 59 圖4-5邊界層厚度隨纖維束滲透度增減之變化圖 60 圖4-6(a)當縫隙大小 為8時,流動面隨時間變化情形 61 圖4-6(b)當縫隙大小 為10時,流動面隨時間變化情形 62 圖4-6(c)當縫隙大小 為12時,流動面隨時間變化情形 63 圖4-7邊界層厚度隨縫隙大小增減之變化 64 圖4-8(a)(b) 當縫隙大小 分別為1,6時,流場壓力分佈情形 65 圖4-8(c)(d) 當縫隙大小 分別為10,16時,流場壓力分佈情形 66 圖4-9(a)縫隙平均入口壓力與縫隙大小關係圖 67 圖4-9(b)纖維束平均入口壓力與縫隙大小關係圖 68 圖4-10文獻[66]所模擬之流動面隨時間變化圖 69

    1. J. P .Coulter and S. I. Guceri, “Resin Transfer Molding , Process view, Modeling and Research Opportunities,” Proc. of the ASME Manufacturing Inter. Altlanta, 79-86 (1988).
    2. M. V. Bruschke and S. G. Advani, “A finite Element/Control Volume Approach to Mold Filling in Anisotropic Porous Media,” Polymer Composites, 11, 398-405 (1990).
    3. W. B. Young, K. Rupel, K. Han, L. J. Lee and M. J. Liou, “Analysis of Resin Injection Molding in Molds with Preplaced Fiber Mats. II: Numerical Simulation and Experiments of Mold
    Filling,” Polymer Composites, 12, 30-38 (1991).
    4. W. B. Young, K. Han, L. H. Fong, L. J. Lee and M. J. Liou, “Flow Simulation in Molds with Preplaced Fiber mats,” Polymer Composites, 12, 391-403 (1991).
    5. F. Trochu and R. Gauvin, “Limitations of a Boundary-Fitted Finite Difference Method for the Simulation of the Resin Transfer Molding Process,” J. of Reinforced Plastics and Composites, 11, 772-786 (1992).
    6. A. W. Chan and S. T. Hwang, “Modeling Nonisothermal Impregnation of Fibrous Media With Reactive Polymer Resin,” Polymer Engineering and Science, 32, 310-318 (1992).
    7. C. H. Wu, T. J. Wang and L. J. Lee, “Trans-Plane Fluid Permeability Measurement and Its Applications in Liquid Composite Molding,” Polymer Composites, 15, 289-298 (1994).
    8. K., L. Han, L. J. Lee and M. Liou, “Fiber Mat Deformation in Liquid Composite Molding. I: Experiment Analysis,” Polymer Composites, 14, 144-150 (1993) .
    9. K. Han, L. J. Lee and M. Liou, “Fiber Mat Deformation in Liquid Composite Molding. II: Modeling,” Polymer Composites, 14, 151-160 (1993).
    10. L. Fong, J. Xu and L. J. Lee, “Preforming Analysis of Thermoformable Glass Fiber Mats - Deformation Modes and Reinforcement Characterization,” Polymer Composites, 15, 134-146 (1994).
    11. T. J. Wang, C. H. Wu and L. J. Lee, “In-Plane Permeability Measurement and Analysis in Liquid Composite molding,” Polymer Composites, 15, 278-288 (1994).
    12. K. Han, L. Trevino, W. B. Young, L. J. Lee and M. J. Liou, “Fiber Mat Deformation During Mold Filling in Structural RIM,” The 46th Annual Conference of the Composites Institute of the Society of the Plastics Industry Inc., Feb., 18-21 (1991).
    13. C. J. Wu, L. W. Hourng and J. C. Liao, “Numerical and Experimental Study on the Edge Effect of Resin Transfer Molding,” J. of Reinforced Plastics and Composites, 14, 694-722 (1995).
    14. C. J. Wu and L. W. Hourng, “Permeable Boundary Condition For Numerical Simulation in Resin Transfer Molding,” Polymer Engineering and Science, 35, 1272-1281 (1995).
    15. L. Trevino, K. Rupel, W. B. Young, M. J. Liou and L. J. Lee, “Analysis of Resin Injection Molding in Molds with Preplaced Fiber Mats I: Permeability and Compressibility Measurements,” Polymer Composites, 12, 20-29 (1991).
    16. B. R. Gebart, “Permeability of Unidirectional Reinforcements for RTM,” J. of Composite Materials, 26, 1100-1133 (1992).
    17. A. W. Chan and S. T. Hwang, “Anisotropic In-plane Permeability of Fabric Media,” Polymer Engineering and Science, 31, 1233-1239 (1991).
    18. A. W. Chan, D. E. Larive and R. J. Morgan, “Anisotropic Permeability of Fiber Preforms: Constant Flow Rate Measure,” J. of Composite Material, 27, 996-1008 (1993).
    19. R. S. Parnas and A. J. Salem, “A Comparison of the Unidirectional and Radial In-plane Flow of Fluids Through Woven Composite Reinforcements,” Polymer Composites, 14, 383-394 (1993).
    20. Z. Cai and A. L. Berdichevsky, “Numerical Simulation on the Permeability Variations of a Fiber Assembly,” Polymer Composites, 14, 529-539 (1993).
    21. A. L. Berdichevsky and Z. Cai, “Preform Permeability Predictions by Self-Consistent Method and Finite Element Simulation,” Polymer Composites, 14, 132-143 (1993).
    22. Z. Cai and A. L. Berdichevsky, “An Improved Self-Consistent Method for Estimating the Permeability of a Fiber Assembly,” Polymer Composites, 14, 314-323 (1993).
    23. R. Gauvin, A. Kerachni and B. Fisa, “Variation of Mat Surface Density and Its Effect on Permeability Evaluation for RTM Modeling,” J. of Reinforced Plastics and Composites, 13-Apr, 371-383 (1994).
    24. A. Hammami, F. Trochu, R. Gauvin and S. Wirth, “Directional Permeability Measurement of Deformed Reinforcement,” J. of Reinforced Plastics and Composites, 15, 552-562 (1996).
    25. Wen-Bin Young, “Three-Dimensional Nonisothermal Mold Filling Simulations in Resin Transfer Molding,” Porlymer Composites, 15, 118-127 (1994).
    26. K. J. Bowles and S. Frimpong, “Void Effects on the Interlaminar Shear Strength of Unidirectional Graphite-Fiber-Reinforced Composites,” J. of Composite Material, 26, 1487-1509 (1992).
    27. J. S. Hayward and B. Harris, “Effect of Process Variables on The Quality of RTM Mouldings,” SAMPE J., 26, 39-46 (1990).
    28. T. S. Lundstrom, B. R. Gebart and C. Y. Lundemo, “Void Formation in RTM,” J. of Reinforced Plastics and Composites, 12, 1339-1349 (1993).
    29. T. S. Lundstrom and B. R. Gebart, “Influenced From Process Parameters on Void Formation in Resin Transfer Molding,” Polymer Composites, 15, 25-33 (1994).
    30. Y. T. Chen, H. T. Daves and C. W. Macosko, “Wetting of Fiber Mats for Composites Manufacturing: I. Visualization Experiments,” AICHE Journal, 41, 2261-2273 (1995).
    31. S. G. Damani and L. J. Lee, “The Resin-Fiber Interface in Polyurethane and Polyurethane-Unsaturated Polyester Hybrid,” Polymer Composites, 11, 174-183 (1990).
    32. C. W. Macosko, RIM Fundamentals of Reaction Injection Molding, Oxford University, New York (1989).
    33. T. A. K. Kadiq, S. G. Advani and R. S. Parnas. “Experimental Investigation of Transverse Flow Through Aligned Cylinders,” International J. Multiphase Flow, 21, 755-774 (1995).
    34. A. W. Chan and R. J. Morgan, “Modeling Preform Impregnation and Void Formation in Resin Transfer Molding of Unidirectional Composites,” SAMPE QUARTERLY, April., 48-52 (1992).
    35. A. W. Chan and R. J. Morgan, “Tow Impregnation During Resin Transfer Molding of Bi-Directional Nonwoven Fabrics,” Polymer Composites, 14, 335-340 (1993).
    36. R. S. Parnas and F. R. Phelan Jr., “The Effect of Heterogeneous Porous Media on Mold Filling in Resin Transfer Molding,” SAMPE QUARTERLY, January., 53-60 (1991).
    37. Y. T. Chen, C. W. Macosko and H. T. Daves, “Wetting of Fiber Mats for Composites Manufacturing: II. Air Entrapment Model,” AICHE Journal, 41, 2274-2281 (1995).
    38. W. B. Young, “The Effect of Surface Tension on Tow Impregnation of Unidirectional Fibrous Preform in Resin Transfer Molding,” J. of Composite Materials, 30, 1191-1209 (1996).
    39. G. L. Batch, Y. T. Chen. and C. W. Macosko, “Capillary Impregnation of Aligned Fibrous Beds: Experiments and Model,” J. of Reinforced Plastics and Composites, 15, 1027-1051 (1996).
    40. N. Patel, V. Rohatgi and L. J. Lee, “Micro Scale Flow Behavior and Void Formation Mechanism During Impregnation Through a Undirection Stitched Fiberglass Mat,” Polymer Engineering and Science, 35, 837-851 (1995).
    41. N. Patel and L. J. Lee, “Effects of Fiber Mat Architecture on Void Formation and Removal in Liquid Composite Molding,” Polymer Composites, 16, 386-399 (1995).
    42. V. Rohatgi, N. Patel and L. J. Lee, “Experimental Investigation of Flow-Induced Microvoids During Impregnation of Unidirectional Stitched,” Polymer Composites, 17, 161-170 (1996).
    43. N. Patel, V. Rohatgi, and L. J. Lee, “Influence of Processing and Material Variables on Resin-Fiber Interface in Liquid Composite Molding,” Polymer Composites, 14, 161-172 (1993).
    44. A. D. Mahale, R. K. Prud''homme and L. Rebenfeld, “Quantitative Measurement of Voids Formed During Liquid Impregnation of Nonwoven Multifilament Glass Networks Using an Optical Visualization Technique,” Polymer Engineering and Science, 32, 319- 326 (1992).
    45. W. B. Young and C. W. Tseng, “Study on the Pre-Heated Temperatures and Injection Pressures of the RTM Process,” J. of Reinforced Plastics and Composites, 13, 467-482 (1994).
    46. J. Bear, Dynamics of Fluids in Porous Media, Dover Publications, New York (1972).
    47. F. A. L. Dullien, Porous Media Fluid Transport and Pore Structure, Academic Press, New York (1979).
    48. T. A. Witten and L. M. Sander, “Diffusion-Limited Aggregation,” Physical Review B, 27, 5686-5697 (1983).
    49. R. Chandler, J. Koplik, K. Lerman and J. F. Willemsen, “Capillary Displacement And Percolation In Porous Media,” J. Fluid Mech., 119, 249-267 (1982).
    50. M. M. Dias and A. C. Payatakes, “Net Models For Two-Phase Flow In Porous Media,” Part 1.Immiscible Microdisplacement of Nonwetting Fluids” J. Fluid Mech., 164, 305-336 (1986).
    51. N. Patel and L. J. Lee. “Modeling of Void Formation and Removal in Liquid Composite Molding. Part I: Wettability Analysis,” Polymer Composites, 17, 96-103 (1996).
    52. N. Patel and L. J. Lee. “Modeling of Void Formation and Removal in Liquid Composite Molding. Part II: Model Development and Implementation,” Polymer Composites, 17, 104-114 (1996).
    53. C.Y. Chang and L.W. Hourng, “Study on Void Formation in Resin Transfer Molding,” Polymer Engineering and Science, 12, 809-818 (1998).
    54. C.Y. Chang and L.W. Hourng, “Numerical Simulation for the Transverse Impregnation in Resin Transfer Molding,” J. of reinforced Plastics and Composites, 17, 165-182 (1998).
    55. K. M. Pillai and S. G. Advani. “Numerical Simulation of Unsaturated Flow in Woven Fiber Preforms During the Resin Transfer Molding Process,” Polymer Composites, 19, 71-80 (1998).
    56. G. S. Beavers and D. D. Joseph, “Boundary Conditions at a Naturally Permeable Wall,” J. Fluid Mechanics, 30, 197-207 (1967).
    57. I. P. Jones, “Low Reynolds Number Flow Past a Porous Spherical Shell,” Proc. Camb. Phil. Soc., 73, 231-238 (1973).
    58. S. Haber and R. Mauri, “Boundary Conditions for Darcy’s Flow through Porous Media,” Int. J. Multiphase Flow, 9, 561-574 (1983).
    59. R. A. Wooding, “Steady State Free Thermal Convection of Liquid in a Saturated Permeable Medium,” J. Fluid Mechanics, 2, 273-285 (1957).
    60. H. C. Brinkman, “A Calculation of the Viscous Force Exerted by a Flowing Fluid on a Dense Swarm of Particles,” Appl. Sci. Res., A1, 27-34 (1947a).
    61. H. C. Brinkman, “On the Permeability of Media Consisting of Closely Packed Porous Particles,” Appl. Sci. Res., A1, 81-86 (1947b).
    62. D. A. Nield and A. Bejan, Convection in Porous Media, Springer-Verlag, New York (1992).
    63. P. D. Thomas and J. F. Middlecoff, “Direct Control of the Grid Point Distribution in Meshes Generated by Elliptic Equation,” AIAA J., 18, 654-656 (1980).
    64. 張智淵, 轉注成型充填過程中氣泡形成之數值模擬, 國立中央大學機械工程研究所博士論文(1997).
    65. Suhas V. Patankar, Numerical Heat Transfer and Fluid Flow, Hemisphere Publications, New York (1980).
    66. Issacson E. and Keller H.B., Analysis of Numerical Methods, Wiley, New York (1966).
    67. Todd J., Survey of Numerical Analysis, McGraw-Hill, New York (1962).
    68. Schoenberg I. J., Quarterly of applied Mathematics, 4, 45-99 (1946).
    69. Kreyzing Z., Advanced engineering Mathematics, Wiley, New Work (1988).
    70. 廖致欽, 轉注成型之滲透率的量測與流場觀察, 國立中央大學機械工程學系碩士論文(1994).

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