Hot torsion continuous tests were performed on a high carbon, high chromium cold work die steel (D2) and a water hardenable carbon tool steel (W1) at strain rates of 0·1, 1, and 4 s-1 in the temperature ranges of 900 to 1150°C for D2 and 900 to 1200°C for W1. The stress–strain (σ–ɛ) curves rose to a peak stress σp, then declined to a steady state value σss, typical of dynamic recrystallisation (DRX). The commencement and effective completion (99%) of DRX are obtained from θ–σ and σ–ɛ curves respectively where θ is the strain hardening rate dσ/dɛ. The kinetics of DRX are assumed to follow an Avrami equation whereas the time tss for 99% DRX is related to σss and temperature by a sinh function. The equilibrium recrystallised grain size Ds decreases with increase in σss and Z, the Zener–Hollomon temperature compensated strain rate. Due to the presence of carbides, which stimulate nucleation, D2 generally has faster DRX kinetics than W1.
Get full access to this article
View all access options for this article.
References
1.
BEVERM. B.t al. : in ‘Progress in materials science (17)’, (ed. ChalmersB. et al), 23-88; 1973, London, Pergamon.
2.
ROBERTSW.: in ‘Deformation processing and microstructure’, (ed. KraussA. G.), 109-184; 1983, Materials Park, OH, ASM International.
3.
IMBERTC. A. C. and MCQUEENH. J.: Mater. Sci. Eng. A, to be published.
4.
IMBERTC. A. C. and MCQUEENH. J.: Mater. Sci. Technol., 2000, 16, 524–531.
5.
MCQUEENH. J.: Metall. Trans. A, 8A, 1977,807–825.
6.
MCQUEENH. J. and BOURELLD. L.: J. Met., 1987, 39, (9), 28–35.
7.
MCQUEENH. J. and KASSNERM. E.: ‘Superplasticity in aerospace’, (ed. HelkkenenH. C. and McNelleyT. R.), 77-96; 1988, Warrendale, PA, AIME.
RYANN. D. and MCQUEENH. J.: High Temp. Technol., 1990, 8, 185–200.
10.
MCQUEENH. J.: Trans. Japan Inst. Metals, 1968, 9, 170–177.
11.
SAHJ. P. and SELLARSC. M.: ‘Hot working and forming processes’, (ed C. M. Sellars and G. J. Davies), 62-66; 1980, London, The Metals Society.
12.
MCQUEENH. J.: Met. Forum (Australia), 1981, 4, 81–91.
13.
RICHARDSR and SHEPPARDT.: Mater. Sci. Technol., 1986, 2, 841–846.
14.
RYANN. D. and MCQUEENH. J.: Can. Met. Q., 1990, 29, 147–162.
15.
MCQUEENH. J., RYANN. D., ZARIPOVAR., and FARKHUTDINOVK.: Proc. 37th Mech. Working and Steel Processing Conf., Hamilton, ON, Canada, October 1995, AIME,883–984.
16.
RYANN. D. and MCQUEENH. J.: Mater. Sci. Eng., 1986, 81, 259–272.
17.
EVANGELISTAE., RYANN. D., and MCQUEENH. J.: Mater. Sci. Technol., 1987, 5, 50–58.
18.
RYANN. D. and MCQUEENH. J.: J. Mater. Process. Technol., 1990, 21, 177–199.
19.
RYANN. D. and MCQUEENH. J.: High Temp. Technol., 1990, 8, 27–44.
20.
MCQUEENH. J., EVANGELISTAE., and RYANN. D.: Proc. Int. Conf. on ‘Recrystallization in metallic materials’, (ed. ChandraT.), 89-100; 1990, Warrendale, PA, TMS-AIME.
21.
MCQUEENH. J., YUES., RYANN. D., and FRYE.: J. Mater. Process. Technol., 1995, 53, 293–310.
22.
SELLARSC. M.: Philos. Trans. R. Soc. (London) A, 1978, 288, 147–158.
23.
JONASJ. J. and SAKAIT.: ‘Deformation, processing and microstructure,’ (ed. KraussG.), 185-230; 1983, Materials Park, OH, ASM International.
24.
SAKAIT. and JONASJ. J.: Acta Metall., 1984, 32, 189–209.
25.
ROBERTSW.: in ‘Strength of metals and alloys’, (ed. McQueenH. J. et al), Vol. 3, 1859–1891; 1985, Oxford, Pergamon.
26.
SELLARSC. M.: Met. Forum, 1981, 4, 75–80.
27.
ELFMARKJ.: Czech. J. Phys., 1985, B35,269–274.
28.
IMBERTC. A. C and MCQUEENH. J.: Mater. Sci. Eng. A, to be published.
29.
IMBERTC., RYANN. D., and MCQUEENH. J.: Metall. Trans. A, 1984, 15A, 1855–1864.
30.
MILOVIĆR., ANGELIĆM., MONOJLOVIĆD., DARRIJANOVIĆM., and DROBNJAKD.: 5th Int. Symp. on ‘Plasticity and resistance to metal deformation’, Herceg-Novi, Yugoslavia, April 1986, The Ferrous Metallurgical Institute,199–214.
31.
IMBERTC. A. C. and MCQUEENH. J.: in ‘Hot workability of steels and light alloys/composites’, (ed. McQueenH. J. et al.), 451-458; 1996, Montreal, Metals Society CIM.
32.
IMBERTC. A. C. and MCQUEENH. J.: in ‘Hot workability of steels and light alloys/composites’, (ed. McQueenH. J. et al), 459-466; 1996, Montreal, Metals Society CIM.
33.
MCQUEENH. J. and IMBERTC. A. C.: in ‘Deformation, processing and properties of structural materials’, (ed. TaleffE. et al); 2000, Warrendale, PA, TMS-AIME (to be published).
34.
IMBERTC. A. C. and MCQUEENH. J.: Can. Metall. Q., to be published.
35.
FULOPS., CADIENK. C., LUTONM. J., and MCQUEENH. J.: J. Test Eval., 1977, 5, 419–426.
36.
RYANN. D., MCQUEENH. J., and JONASJ. J.: Can. Metall. Q., 1983, 22, 369–378.
37.
Standard E562-89, ASTM, Philadelphia, PA, USA, 1995.
38.
KAYSERF. and coM.Met. Prog., 1952, 61, (6), 79–85.
39.
Standard E112-88, ASTM, Philadelphia, PA, USA, 1995.
BERNSHTEINM. L., KAPUTKINAL. M., PROKOSHKINS. D., and DOBATKINS. V.: Acta Metall., 1985, 33, 247–254.
42.
KASSNERM. E. and MILLERA. K.: ‘New developments in stainless steel technology’, (ed. LulaR. A.), 19-28; 1985, Metals Park, OH, ASM International.
43.
DONADILLEC., ROSSARDC., and THOMASB.: ‘Annealing processes — recovery, recrystallization and grain growth’, (ed. HansenN. et al), 285-290; 1986, Roskilde, Riso National Laboratory.
44.
CHOQUETP., LAMBERTERIEB. DE, PERDRIXC., and BIAUSSERH.: Report 1099, IRSID, Saint-Germain-en-Laye, France, 1987.
45.
CINGARAA., GERMAINL. ST, and MCQUEENH. J.: in ‘Processing, microstructure and properties of HSLA steels’, (ed. DeardoA.); 91-114, 1988, Warrendale, TMS-AIME.
46.
EVANGELISTAE., RYANN. D., and MCQUEENH. J.: Metall. Sci. Technol., 1991, 9, 75–92.
47.
MCQUEENH. J., RYANN. D., and EVANGELISTAE.: ‘Recrystallization ‘92’, (ed. FuentesM. and SevillanoJ. G.), 435-440; 1992, Aedermannsdorf, Trans Tech.
48.
PERDRIXC.: Recherche Ceca No. 7210—EA/311, Institut de Recherches de la Sidérugie Française, Maizieres, France, 1993.
49.
MCQUEENH. J., YUES., RYANN. D., and FRYE.: in ‘Advanced materials and technologies’, (ed. DobrzanskiL. A.), 295-332; 1995, Giliwice, Silesian Technical University.
50.
AHLBLOMB.: Report IM-1208, The Royal Institute of Technology, Stockholm, 1977.
51.
ROBERTSW., BODENH., and AHLBLOMB.: Met. Sci., 1979, 13, 195–205.
52.
LUTONM. J. and SELLARSC. M.: Acta. Metall., 1969, 17, 1033–1043.
53.
ELFMARKJ.: Hutn. Listy, 1971, 26, 107–113.
54.
ELFMARKJ.: Czech. J. Phys., 1986, B36,873–881.
55.
LÜCKEK. and DETERTK.: Acta Metall., 1957, 5, 628–637.
56.
LÜCKEK. and STUWEH. P.: ‘Recovery and recrystallization of metals’, (ed. HimmelL.), 171-210; 1962, New York, Interscience.
57.
CAHNJ. W.: Acta Metall., 1962, 10, 789–798.
58.
HILLERTM.: Met. Sci., 1979, 13, 118–124.
59.
MCQUEENH. J. and JONASJ. J.: in ‘Plastic deformation of metals’, (ed. ArsenaultR. J.), 393-491; 1975, New York, Academic Press.
60.
EVANSR. W. and DUNSTANG. R.: J. Inst. Met., 1971, 99, 4–14.
61.
KALISHD. and LEFEBVREB. G.: Metall. Trans. A, 1975, 6A, 1319–1324.
62.
CHIAE. H. and STARKEE. A.: Metall. Trans. A, 1977, 8A, 825–832.
63.
EVANGELISTAE., MCQUEENH. J., and BONETTIE.: in ‘Deformation of multiphase and particle-containing materials’, (ed. HansenN.), 243-250; 1983, Roskilde, Riso National Laboratory.
64.
LESLIEW. C., MICHALAKJ. T., and AULF. W.: in ‘Iron and its ductile solid solutions’, (ed. SpencerC. W. and WernerF. E.), 119-216; 1963, New York, Interscience.
65.
DOHERTYR. D. and MARTINJ. W.: Trans. ASM, 1964,57, 874–884.
66.
GAWNED. T. and HIGGINSG. T.: J. Mat. Sci., 1971, 6, 403–412.
67.
JONASJ. J., SELLARSC. M., and W. J. MCG.TEGART: Metall. Rev., 1969, 130, (14), 1–24.
68.
HONEYCOMBER. W. K. and PETHENR. W.: J. Less-Common Met., 1972, 28, 201–212.
69.
BARRACLOUGHD. R.: ‘Hot working and recrystallization of a stainless and low-alloy steel’, PhD thesis, University of Sheffield, 1974.
70.
ROSSARDC. and BLAINP.: MeM. Sci. Rev. Metall., 1959, 56, 285–299.
71.
SAKUIS., SAKAIT., and TAKEISHIK.: Testu-to-Hagane (J. Iron Steel Inst. Jpn), 1976, 62, 856–865.
72.
SAKUIS., SAKAIT., and TAKEISHIK.: Trans. Iron Steel Inst., 1977, 17, 718–725.
