參考文獻 |
1. F. Yang and W. Yang, Kinetics and size effect of grain rotations in nanocrystals with rounded triple junctions, Scripta Materialia, 2009, 61, p. 919-922.
2. C.M. Hu, C.M. Lai, P.W. Kao, N.J. Ho, and J.C. Huang, Quantitative measurements of small scaled grain sliding in ultra-fine grained Al–Zn alloys produced by friction stir processing, Materials Characterization, 2010, 61, p. 1043-1053.
3. H. Raman, G. Luckey, G. Kridli, and P. Friedman, Development of Accurate Constitutive Models for Simulation of Superplastic Forming, Journal of Materials Engineering and Performance, 2007, 16, p. 284-292.
4. Fukaya-Sky, Superplastic 5083 alloy "ALNOVI-1", SKY Aluminium Co., LTD., 1994, p. 1-9.
5. D.G. Sanders, The Current State-of-the Art and the Future of in Airframe manufacturing using Superplastic Forming Technology, 2001: Materials Science Forum, 357-359, p. 17-22.
6. Z. Zeng, Y. Zhang, Y. Zhou, and Q. Jin, Superplastic Forming of Aluminum Alloy Car Body Panels, Materials Science Forum, 2005, 475-479, p. 3025-3028.
7. Y. Luo, S.G. Luckey, W.B. Copple, and P.A. Friedman, Comparison of Advanced SPF Die Technologies in the Forming of a Production Panel, Journal of Materials Engineering and Performance, 2008, 17, p. 142-152.
8. L. Hefti, Commercial Airplane Applications of Superplastically Formed AA5083 Aluminum Sheet, Journal of Materials Engineering and Performance, 2007, 16, p. 136-141.
9. 林維帥, 熱引伸輔助超塑成形製作機翼整流罩之設計及分析, 國立中央大學機械工程研究所碩士論文, 2012, p. 12.
10. 劉亞倫, 超塑性鋁合金5083快速成形之空孔與金相組織研究, 國立中央大學機械工程研究所碩士論文, 2001, p. 72.
11. M.A. Khaleel, H.M. Zbib, and E.A. Nyberg, Constitutive modeling of deformation and damage in superplastic materials, International Journal of Plasticity, 2001, 17, p. 277-296.
12. Y.-M. Hwang, J.-S. Yang, T.-R. Chen, J.C. Huang, and W.-U. Wu, Analysis of superplastic blow-forming in a conical closed die, International Journal of Mechanical Sciences, 1998, 40, p. 867-885.
13. P. Krajewski and A. Morales, Tribological issues during quick plastic forming, Journal of Materials Engineering and Performance, 2004, 13, p. 700-709.
14. P.-h. Sun, H.-y. Wu, W.-s. Lee, S.-h. Shis, J.-y. Perng, and S. Lee, Cavitation behavior in superplastic 5083 Al alloy during multiaxial gas blow forming with lubrication, International Journal of Machine Tools and Manufacture, 2009, 49, p. 13-19.
15. Z. Chen and P.F. Thomson, Friction against superplastic aluminium alloys, Wear, 1996, 201, p. 227-232.
16. Y. Luo, S.G. Luckey, P.A. Friedman, and Y. Peng, Development of an advanced superplastic forming process utilizing a mechanical pre-forming operation, International Journal of Machine Tools and Manufacture, 2008, 48, p. 1509-1518.
17. J. Liu, M.-J. Tan, Y. Aue-u-lan, A.W. Jarfors, K.-S. Fong, and S. Castagne, Superplastic-like forming of non-superplastic AA5083 combined with mechanical pre-forming, The International Journal of Advanced Manufacturing Technology, 2011, 52, p. 123-129.
18. L.M. Ren, S.H. Zhang, G. Palumbo, D. Sorgente, and L. Tricarico, Numerical simulation on warm deep drawing of magnesium alloy AZ31 sheets, Materials Science and Engineering: A, 2009, 499, p. 40-44.
19. H. Palaniswamy, G. Ngaile, and T. Altan, Finite element simulation of magnesium alloy sheet forming at elevated temperatures, Journal of Materials Processing Technology, 2004, 146, p. 52-60.
20. G. Luckey Jr, P. Friedman, and K. Weinmann, Design and experimental validation of a two-stage superplastic forming die, Journal of Materials Processing Technology, 2009, 209, p. 2152-2160.
21. G. Yaofu, G. Naicheng, Z. Daren, and H. Mancai, The superplastic forming of metal sheets using a die of refractory concrete, Journal of Materials Processing Technology, 1992, 30, p. 159-166.
22. A.K. Ghosh and C.H. Hamilton, Superplastic Forming of a Long Rectangular Box Section -- Analysis and Experiment, Rockwell International, Thousand Oaks, California, 1979, p. 245-273.
23. M. Vulcan, K. Siegert, and D. Banabic, The Influence of Pulsating Strain Rates on the Superplastic Deformation Behaviour of Al-Alloy AA5083 Investigated by Means of Cone Test, Materials Science Forum, 2004, 447-448, p. 139-144.
24. D. Banabic, M. Vulcan, and K. Siegert, Bulge Testing under Constant and Variable Strain Rates of Superplastic Aluminium Alloys, CIRP Annals - Manufacturing Technology, 2005, 54, p. 205-208.
25. N. Chandra and D. Kannan, Superplastic sheet metal forming of a generalized cup part i: uniform thinning, Journal of Materials Engineering and Performance, 1992, 1, p. 801-810.
26. L. Carrino and G. Giuliano, Modelling of superplastic blow forming, International Journal of Mechanical Sciences, 1997, 39, p. 193-199.
27. Y. Chen, K. Kibble, R. Hall, and X. Huang, Numerical analysis of superplastic blow forming of Ti–6Al–4V alloys, Materials & Design, 2001, 22, p. 679-685.
28. R. Hambli, A. Potiron, F. Guerin, and B. Dumon, Numerical pressure prediction algorithm of superplastic forming processes using 2D and 3D models, Journal of Materials Processing Technology, 2001, 112, p. 83-90.
29. R. Hambli and A. Potiron, Comparison between 2D and 3D numerical modeling of superplastic forming processes, Computer Methods in Applied Mechanics and Engineering, 2001, 190, p. 4871-4880.
30. P. Hu, Y.Q. Liu, Y.X. Li, and J. Lian, Rigid viscoplastic finite element analysis of the gas-pressure constrained bulging of superplastic circular sheets into cone disk shape dies, International Journal of Mechanical Sciences, 1997, 39, p. 487-496.
31. P.K.D.V. Yarlagadda, P. Gudimetla, and C. Adam, Finite element analysis of high strain rate superplastic forming (SPF) of Al–Ti alloys, Journal of Materials Processing Technology, 2002, 130–131, p. 469-476.
32. G.Y. Li, M.J. Tan, and K.M. Liew, Three-dimensional modeling and simulation of superplastic forming, Journal of Materials Processing Technology, 2004, 150, p. 76-83.
33. S.G. Luckey Jr, P.A. Friedman, and K.J. Weinmann, Correlation of finite element analysis to superplastic forming experiments, Journal of Materials Processing Technology, 2007, 194, p. 30-37.
34. F.S. Jarrar, L.G. Hector Jr, M.K. Khraisheh, and A.F. Bower, New approach to gas pressure profile prediction for high temperature AA5083 sheet forming, Journal of Materials Processing Technology, 2010, 210, p. 825-834.
35. S. Kalpakjian, Manufacturing Processes for Engineering Materials, Journal of Applied Metalworking, 1985, 3, p. 446.
36. 王善民, Ti-6Al-4V之超塑性成形製程模擬與分析, 國立中央大學機械工程研究所碩士論文, 2003, p. 22.
37. R. Verma, P.A. Friedman, A.K. Ghosh, S. Kim, and C. Kim, Characterization of superplastic deformation behavior of a fine grain 5083 Al alloy sheet, Metallurgical and Materials Transactions A, 1996, 27, p. 1889-1898.
38. X. Jiang, J. Cui, and L. Ma, An Experimental Study of Cavity Nucleation During Superplastic Deformation, Material Research Society, 1990, 196, p. 51-56.
39. H.-y. Wu, J.-y. Perng, S.-h. Shis, C.-h. Chiu, S. Lee, and J.-y. Wang, Cavitation characteristics of a superplastic 5083 Al alloy during gas blow forming, Journal of Materials Science, 2006, 41, p. 7446-7453.
40. S. Kalpakjian and S.R. Schmid, Manufacturing Engineering and Technology, Pearson Prentice Hall, 2006, p. 446.
41. MatWeb, MATERIAL PROPERTY DATA. Available from: http://www.matweb.com/.
42. N. Chandra, Constitutive behavior of superplastic materials, International Journal of Non-Linear Mechanics, 2002, 37, p. 461-484.
43. J.G. Kaufman, Properties of Aluminum Alloys: Tensile, Creep, and Fatigue Dada at High and Low Temperatures, ASM International, 2006, p. 131.
44. T.H. Courtney, Mechanical Behavior of Materials, McGraw-Hill, 2000, p. 56. |