留言板

尊敬的读者、作者、审稿人, 关于本刊的投稿、审稿、编辑和出版的任何问题, 您可以本页添加留言。我们将尽快给您答复。谢谢您的支持!

姓名
邮箱
手机号码
标题
留言内容
验证码
Volume 26 Issue 1
Jan.  2019
Turn off MathJax
目录
数据统计

分享

计量
  • 文章访问数:  499
  • HTML全文浏览量:  99
  • PDF下载量:  25
  • 被引次数: 0
文章导航 >  矿物冶金与材料学报(英文)  > 2019  >  26(1): 64-75
Renuprava Dalai, Siddhartha Das, and Karabi Das, Relationship between the microstructure and properties of thermomechanically processed Fe-17Mn and Fe-17Mn-3Al steels, Int. J. Miner. Metall. Mater., 26(2019), No. 1, pp. 64-75. https://doi.org/10.1007/s12613-019-1710-3
Cite this article as:
Renuprava Dalai, Siddhartha Das, and Karabi Das, Relationship between the microstructure and properties of thermomechanically processed Fe-17Mn and Fe-17Mn-3Al steels, Int. J. Miner. Metall. Mater., 26(2019), No. 1, pp. 64-75. https://doi.org/10.1007/s12613-019-1710-3
shu
引用本文 PDF XML SpringerLink
研究论文

Relationship between the microstructure and properties of thermomechanically processed Fe-17Mn and Fe-17Mn-3Al steels

  • Department of Metallurgical and Materials Engineering, Indian Institute of Technology, Kharagpur 721302, India

  • 通讯作者:

    Karabi Das    E-mail: karabi@metal.iitkgp.ernet.in

  • Two austenitic Mn steels (Fe-17Mn and Fe-17Mn-3Al (wt%, so as the follows)) were subjected to thermomechanical processing (TMP) consisting of forging followed by solutionization and hot rolling. The rolled samples were annealed at 650 and 800℃ to relieve the internal stress and to induce recrystallization. The application of TMP and heat treatment to the Fe-17Mn/Fe-17Mn-3Al steels refined the austenite grain size from 169 μm in the as-solutionized state to 9-13 μm, resulting in a substantial increase in hardness from HV 213 to HV 410 for the Fe-17Mn steel and from HV 210 to HV 387 for the Fe-17Mn-3Al steel. The elastic modulus values, as evaluated by the nanoindentation technique, increased from (175±11) to (220±12) GPa and from (163±15) to (205±13) GPa for the Fe-17Mn and Fe-17Mn-3Al steels, respectively. The impact energy of the thermomechanically processed austenitic Mn steels was lower than that of the steels in their as-solutionized state. The addition of Al to the Fe-17Mn steel decreased the hardness and elastic modulus but increased the impact energy.
    • Research Article

    Relationship between the microstructure and properties of thermomechanically processed Fe-17Mn and Fe-17Mn-3Al steels

    + Author Affiliations
      Abstract
    • Two austenitic Mn steels (Fe-17Mn and Fe-17Mn-3Al (wt%, so as the follows)) were subjected to thermomechanical processing (TMP) consisting of forging followed by solutionization and hot rolling. The rolled samples were annealed at 650 and 800℃ to relieve the internal stress and to induce recrystallization. The application of TMP and heat treatment to the Fe-17Mn/Fe-17Mn-3Al steels refined the austenite grain size from 169 μm in the as-solutionized state to 9-13 μm, resulting in a substantial increase in hardness from HV 213 to HV 410 for the Fe-17Mn steel and from HV 210 to HV 387 for the Fe-17Mn-3Al steel. The elastic modulus values, as evaluated by the nanoindentation technique, increased from (175±11) to (220±12) GPa and from (163±15) to (205±13) GPa for the Fe-17Mn and Fe-17Mn-3Al steels, respectively. The impact energy of the thermomechanically processed austenitic Mn steels was lower than that of the steels in their as-solutionized state. The addition of Al to the Fe-17Mn steel decreased the hardness and elastic modulus but increased the impact energy.
      • FullText(HTML)
    • loading
      • Supplements(0)
      • References(36)
    • [1]
      H.S. Avery, Austenitic Manganese Steel, Metals Handbook, American Society for Metals, USA, 1961, p. 834.
      [2]
      X.D. Du, G.D. Sun, Y.F. Wang, J.F. Wang, and H.Y. Yang, Abrasion behavior of high manganese steel under low impact energy and corrosive conditions, Adv. Tribol., 2009(2009), art. No. 685648.
      [3]
      A.K. Srivastava and K. Das, Microstructure and abrasive wear study of (Ti,W)C-reinforced high-manganese austenitic steel matrix composite, Mater. Lett., 62(2008), No. 24, p. 3947.
      [4]
      Y.F. Wang, C.M. Qiu, C.G. Lu, and L. Zhang, Effect of conventional cold rolling on wear-resisting performance of high manganese steel, Adv. Mater. Res., 284-286(2011), p. 1493.
      [5]
      J. Mendez, M. Ghoreshy, W.B.F. Mackay, T.J.N. Smith, and R.W. Smith, Weldability of austenitic manganese steel, Mater. Process. Technol., 153-154(2008), p. 596.
      [6]
      F.C. Zhang and T.Q. Lei, A study of friction-induced martensitic transformation for austenitic manganese steel, Wear, 212(1997), No. 2, p. 195.
      [7]
      S.R. Allahkaram, Causes of catastrophic failure of high Mn steel utilized as crusher overlaying shields, Int. J. Eng. Trans. B, 21(2008), No. 1, p. 55.
      [8]
      I. El-Mahallawi, R. Abdel-Karim, and A. Naguib, Evaluation of effect of chromium on wear performance of high manganese steel, Mater. Sci. Technol., 17(2001), No. 11, p. 1385.
      [9]
      E.G. Moghaddam, N. Varahram, and P. Davami, On the comparison of microstructural characteristics and mechanical properties of high-vanadium austenitic manganese steels with the Hadfield steel, Mater. Sci. Eng. A, 532(2012), p. 260.
      [10]
      S.A. Torabi, K. Amini, and M. Naseri, Investigating the effect of manganese content on the properties of high manganese austenitic steels, Int. J. Adv. Des. Manuf. Technol., 10(2017), No. 1, p. 75.
      [11]
      D.S. Lu, Z.Y. Liu, W. Li, Z. Liao, H. Tian, and J.Z. Xian, Influence of carbon content on wear resistance and wear mechanism of Mn13Cr2 and Mn18Cr2 cast steels, China Foundary, 12(2015), No. 1, p. 39.
      [12]
      S.R. Ge, Q.L. Wang, and J.X. Wang, The impact wear-resistance enhancement mechanism of medium manganese steel and its applications in mining machines, Wear, 376-377(2017), p. 1097.
      [13]
      Y.K. Lee and J. Han, Current opinion in medium manganese steel, Mater. Sci. Technol., 31(2014), No. 7, p. 843.
      [14]
      J. Wang, Q.L. Wang, X. Zhang, and D.K. Zhang, Impact and rolling abrasive wear behavior and hardening mechanism for hot-rolled medium-manganese steel, J. Tribol., 140(2018), No. 3, p. 1.
      [15]
      H.T. Si, R.L. Xiong, F. Song, Y.H. Wen, and H.B. Peng, Wear resistance of austenitic steel Fe-17Mn-6Si-0.3C with high silicon and high manganese, Acta Metall. Sin. Engl. Lett., 27(2014), No. 2, p. 352.
      [16]
      Y.H. Wen, H.B. Peng, H.T. Si, R.L. Xiong, and D. Raabe, A novel high manganese austenitic steel with higher work hardening capacity and much lower impact deformation than Hadfield manganese steel, Mater. Des., 55(2014), p. 798.
      [17]
      C. Prasad, P. Bhuyan, C. Kaithwas, R. Saha, and S. Mandal, Microstructure engineering by dispersing nano-spheroid cementite in ultrafine-grained ferrite and its implications on strength-ductility relationship in high carbon steel, Mater. Des., 139(2018), p. 324.
      [18]
      D.H. Jeong, F. Gonzalez, G. Palumbo, K. Aust, and U. Erb, The effect of grain size on the wear properties of electrodeposited nanocrystalline nickel coatings, Scripta Mater., 44(2001), No. 3, p. 493.
      [19]
      T.A. El-Bitar and E.M. El-Banna, Improvement of austenitic Hadfield Mn-steel properties by thermomechanical processing, Can. Metall. Q., 39(2000), No. 3, p. 361.
      [20]
      A. Goldberg, O.A. Ruano, and O.D. Sherby, Development of ultrafine microstructures and superplasticity in Hadfield manganese steels, Mater. Sci. Eng. A, 150(1992), No. 2, p. 187.
      [21]
      S. Kang, Y.S. Jung, J.H. Jun, and Y.K. Lee, Effects of recrystallization annealing temperature on carbide precipitation, microstructure, and mechanical properties in Fe-18Mn-0.6C-1.5 Al TWIP steel, Mater. Sci. Eng. A, 527(2010), No. 3, p. 745.
      [22]
      B.K. Zuidema, D.K. Subramanyam, and W.C Leslie, The effect of aluminum on the work hardening and wear resistance of Hadfield manganese steel, Metall. Trans. A, 18(1987), No. 9, p. 1629.
      [23]
      R.W. Smith and W.B.F Mackay, Austenitic manganese steels -developments for heavy haul rail transportation, Can. Metall. Q., 42(2003), No. 3, p. 333.
      [24]
      K.M. Mussert, W.P. Vellinga, A. Bakker, and S. Van Der Zwaag, A nano-indentation study on the mechanical behaviour of the matrix material in an AA6061-Al2O3 MMC, J. Mater. Sci., 37(2002), No. 4, p. 789.
      [25]
      J.W. Leggoe, Determination of the elastic modulus of microscale ceramic particles via nanoindentation, J. Mater. Res., 19(2004), No. 8, p. 2437.
      [26]
      W.C. Oliver and G.M. Pharr, Measurement of hardness and elastic modulus by instrumented indentation:Advances in understanding and refinements to methodology, J. Mater. Res., 19(2004), No. 1, p. 3.
      [27]
      D.J. Shuman, A.L.M. Costa, and M.S. Andrade, Calculating the elastic modulus from nanoindentation and microindentation reload curves, Mater. Charact., 58(2007), No. 4, p. 380.
      [28]
      G.E. Dieter, Mechanical Metallurgy, McGraw Hill UK Ltd., New York, 1986, p. 280.
      [29]
      A. Helth, S. Pilz, T. Kirsten, L. Giebeler, J. Freudenberger, M. Calin, J. Eckert, and A. Gebert, Effect of thermomechanical processing on the mechanical biofunctionality of a low modulus Ti-40Nb alloy, J. Mech. Behav. Biomed. Mater., 65(2017), p. 137.
      [30]
      T. Otomo, H. Matsumoto, N. Nomura, and A. Chiba, Influence of cold-working and subsequent heat-treatment on Young's modulus and strength of Co-Ni-Cr-Mo alloy, Mater. Trans., 51(2010), No. 3, p. 434.
      [31]
      A. Torrents, H. Yang, and F.A. Mohamed, Effect of annealing on hardness and the modulus of elasticity in bulk nanocrystalline nickel, Metall. Mater. Trans. A, 41(2010), No. 3, p. 621.
      [32]
      S. Reeh, D. Music, T. Gebhardt, M. Kasprzak, T. Japel, S. Zaefferer, D. Raabe, S. Richter, A. Schwedt, J. Mayer, B. Wietbrock, G. Hirt, and J.M. Schneider, Elastic properties of face-centred cubic Fe-Mn-C studied by nanoindentation and ab initio calculations, Acta Mater., 60(2012), No. 17, p. 6025.
      [33]
      C. Chen, X.Y. Feng, B. Lv, Z.N. Yang, and F.C. Zhang, A study on aging carbide precipitation behavior of hadfield steel by dynamic elastic modulus, Mater. Sci. Eng. A, 677(2016), p. 446.
      [34]
      D. Singh, P.N. Rao, and R. Jayaganthan, Microstructures and impact toughness behavior of Al 5083 alloy processed by cryorolling and afterwards annealing, Int. J. Miner. Metall. Mater., 20(2013), No. 8, p. 759.
      [35]
      C.F. Wang, M.Q. Wang, J. Shi, W.J. Hui, and H. Dong, Effect of microstructure refinement on the strength and toughness of low alloy martensitic steel, J. Mater. Sci. Technol., 23(2007), No. 5, p. 659.
      [36]
      A.A. Astaf'ev, Effect of grain size on the properties of manganese austenitic steel 110G13L, Met. Sci. Heat Treat., 39(1997), No. 5, p. 198.
      • Relative Articles
      Cited By

    Catalog


    • /

      返回文章
      返回

      版权所有 ©《矿物冶金与材料学报(英文)》编辑部

      地址:北京市海淀区学院路30号邮政编码:100083

      电子邮箱:journal@ustb.edu.cn电话:+86-10-62332875

      本系统由 北京仁和汇智信息技术有限公司 开发    百度统计