|
|
|
| Densification mechanism of Ti-1Al-8V-5Fe alloy by spark plasma sintering |
| LI Wenjie, ZENG Fanhao, LI Lei, WANG Ziwei, LIU Honghao, PENG Yirui, GU Yi |
| National Key Laboratory of Science and Technology for National Defence on High-Strength Structural Materials, Central South University, Changsha 410083, China |
|
|
|
|
Abstract TiH2, FeV80, Al and Fe powders were used as raw materials, and the spark plasma sintering was used to prepare Ti-1Al-8V-5Fe (Ti185) alloys at 800-1 200 ℃ for 10min. The effective stress exponent (n) and the densification activation energy (Qd) were evaluated by the sintering densification curve and mature creep model, which were used to study the densification kinetics of Ti185 alloys. The results showed that the alloys were rapidly densified without obvious grain growth at low temperature (800-1 000 ℃). When sintering temperature reached 1 100 ℃, the alloys were slowly densified with obvious grain growth. During sintering at 800-1 000 ℃, the densification stage in the early stage of dwelling had low effective stress exponent n and apparent activation energy Qd(n=1, Qd=52 kJ/mol), which was the stage of low effective stress, and grain boundary diffusion controlled the densification process of alloys. However, the later stage of dwelling corresponded to a higher effective stress stage, with n=3 and Qd=175.7 kJ/mol. The densification mechanism of the alloys was controlled by dislocation climbing.
|
|
Received: 24 May 2020
Published: 18 September 2020
|
|
|
|
|
|
[1] 许国栋, 王桂生. 钛金属和钛产业的发展[J]. 稀有金属, 2009, 33(6): 903-912.
XU Guodong, WANG Guisheng.Development of titanium metal and titanium industry[J]. Chinese Journal of Rare Metals, 2009, 6: 903-912.
[2] DEVARAJ A, JOSHI V V, SRIVASTAVA A, et al.A low-cost hierarchical nanostructured beta-titanium alloy with high strength[J]. Nature Communications, 2016, 7: 11176.
[3] BANERJEE D, WILLIAMS J C.Perspectives on titanium science and technology[J]. Acta Materialia, 2013, 61(3): 844-879.
[4] JAMES G F.The effect of processing and heat treatment on the microstructure and properties of Ti-1Al-8V-5Fe[J]. Rare Metal Materials and Engineering, 2006, 35(S1): 209-212.
[5] JOSHI V V, LAVENDER C, MOXSON VS, et al.Development of Ti-6Al-4V and Ti-1Al-8V-5Fe alloys using low-cost TiH2 powder feedstock[J]. Journal of Materials and Engineering Performance, 2013, 22: 995-1003.
[6] HAMID A, HATEM Z.
[7] 高思宇, 刘平, 王春明, 等. 粉末冶金法低成本制备Ti-1Al- 8V-5Fe合金的组织和性能[J]. 粉末冶金技术, 2014, 32(6): 427-430.
GAO Siyu, LIU Ping, WANG Chunming, et al.Microstructure and mechanical properties of low-cost Ti-1Al-8V-5Fe alloy using PM method[J]. Powder Metallurgy Technology, 2014, 32(6): 427-430.
[8] ZHANG Y, WANG C, ZHANF Y, et al.Fabrication of low-cost Ti-1Al-8V-5Fe by powder metallurgy with TiH2 and FeV80 alloy[J]. Materials and Manufacturing Processes, 2017, 32(16): 1869-1873.
[9] ZHANF Y, ZHANG Z, LIU S, et al.The powder metallurgy performance of Ti-1Al-8V-5Fe alloys with unsaturated titanium hydride[J]. Materials and Manufacturing Processes, 2018, 33(16): 1830-1834.
[10] MUNIZR Z A, ANSELMI T U, OHYANAGI M.The effect of electric field and pressure on the synthesis and consolidation of materials: A review of the spark plasma sintering method[J]. Journal of Materials Science, 2006, 41(3): 763-777.
[11] CHEN H, ZENG F h. Densification behavior and mechanical properties of spark plasma reaction sintered ZrB2-ZrC-B4C ceramics from B4C-Zr system[J]. Ceramics International, 2019, 45(9): 12122-12129.
[12] LIU J A, ZENG F H, ZOU Z H.Continuum modeling of B4C densification during spark plasma sintering[J]. Journal of Materials Research, 2017, 32(17): 3425-3433.
[13] YANG C, ZHU M D.Influence of powder properties on densification mechanism during spark plasma sintering[J]. Scripta Materialia, 2017, 139: 96-99.
[14] WESTON N S, DERGUTI F, TUBDALL A, et al.Spark plasma sintering of commercial and development titanium alloy powders[J]. Journal of Materials Science, 2015, 50(14): 4860-4878.
[15] WANG Y, ZHANG C.Microstructure characterization and mechanical properties of TiAl-based alloys prepared by mechanical milling and spark plasma sintering[J]. Materials Characterization, 2017, 128: 75-84.
[16] WANG J W, WANG Y, LIU Y, et al.Densification and microstructural evolution of a high niobium containing TiAl alloy consolidated by spark plasma sintering[J]. Intermetallics, 2015, 64: 70-77.
[17] BERNARD-GRANGER G, GUIZARD C.Spark plasma sintering of a commercially available granulated zirconia powder: I. Sintering path and hypotheses about the mechanism controlling densification[J]. Acta Materialia, 2007, 55(10): 3493-3504.
[18] BERNARD-GRANGER G, GUIZARD C.Densification mechanism involved during spark plasma sintering of a codoped α-alumina material: Part I. Formal sintering analysis[J]. Journal of Materials Research, 2009, 24(1): 179-186.
[19] FEDORCHENKO I M, SKOROKHOD V V.Theory and practice of sintering[J]. Powder Metallurgy & Metal Ceramics, 1967, 6(10): 790-805.
[20] ZHANG M, LI R D, YUAN T C, et al.Effect of low-melting-point sintering aid on densification mechanisms of boron carbide during spark plasma sintering[J]. Scripta Materialia, 2019, 163: 34-39.
[21] BERNARD-GRANGER G, ADDAD A, FANTOZZI G, et al.Spark plasma sintering of a commercially available granulated zirconia powder: Comparison with hot-pressing[J]. Acta Materialia, 2010, 58(9): 3390-3399.
[22] SANTANACH J G, WEIBEL A, ESTOURNES C, et al.Spark plasma sintering of alumina: Study of parameters, formal sintering analysis and hypotheses on the mechanism (s) involved in densification and grain growth[J]. Acta Materialia, 2011, 59(4):1400-1408.
[23] BERNARD-GRANGER G, AMANDINE Néri, NAVONE C, et al.Spark plasma sintering of a p-type Si1-xGex alloy: Identification of the densification mechanism by isothermal and anisothermal methods[J]. Journal of Materials Science, 2012, 47(10):4313-4325.
[24] HELLE A S, EASTERLING K E, ASHBY M F.Hot-isostatic pressing diagrams: New developments[J]. Acta Metallurgica, 1985, 33(12): 2163-2174.
[25] LAM D C C, LANGE F F, EVANS A G. Mechanical properties of partially dense alumina produced from powder compacts[J]. Journal of the American Ceramic Society, 1994, 77: 2113-2117.
[26] MA X, LI F, CAO J, et al.Study on the deformation behavior of β phase in Ti-10V-2Fe-3Al alloy by micro-indentation[J]. Journal of Alloys and Compounds, 2017, 703: 298-308.
[27] DONG J, LI F, WANG C.Micromechanical behavior study of α phase with different morphologies of Ti-6Al-4V alloy by microindentation[J]. Materials Science and Engineering A, 2013, 580: 105-113.
[28] YANG Y F, LUO S D, SCHAFFER G B, et al.Sintering of Ti-10V-2Fe-3Al and mechanical properties[J]. Materials Science and Engineering A, 2011, 528(22/23): 6719-6726.
[29] PANIGRAHI B B, Godkhindi M M, DAS K, et al.Sintering kinetics of micrometric titanium powder[J]. Materials Science and Engineering A, 2005, 396(1/2): 255-262.
[30] ANTOU G, GUYOT P, PRADEILLES N, et al.Identification of densification mechanisms of pressure-assisted sintering: application to hot pressing and spark plasma sintering of alumina[J]. Journal of Materials Science, 2015, 50(5): 2327-2336.
[31] JIRI K, HANKA B, JOSEF S, et al.Manufacturing of fine-grained titanium by cryogenic milling and spark plasma sintering[J]. Materials Science and Engineering A, 2019, 772: 138783.
[32] DENG S, YUAN T, LI R, et al.Spark plasma sintering of pure tungsten powder: Densification kinetics and grain growth[J]. Powder Technology, 2017, 310: 264-271.
[33] WEERTMAN J.Dislocation climb theory of steady-state creep[J]. Journal of Applied Physics, 1968, 61: 681-694.
[34] WEERTMAN J.Steady-state creep through dislocation climb[J]. Journal of Applied Physics, 1957, 28(3): 362-364. |
|
|
|
2020, Vol. 25 
