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The Influence of Cold Working and Recrystallization on the Homogenization of As-cast Cu-50 wt.% Ni Alloy

  • Rejane Aparecida Nogueira and Angelo Fernando Padilha
Published/Copyright: November 30, 2021
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International Journal of Materials Research
From the journal International Journal of Materials Research Volume 88 Issue 3

Abstract

The effects of cold working and recrystallization on the homogenization of a Cu-50 wt.% Ni alloy have been investigated by electron probe microanalysis and other complementary techniques. The occurrence of homogenization has been explained by the synergism of 3 factors: deformation alters interdendritic spacing and diffusion distances, crystalline defects enhance diffusion and microstructure sweeping by grain boundaries during recrystallization assists solute redistribution by grain boundary diffusion.

Abstract

Die Einflüsse von Kaltverformung und Rekristallisation auf die Homogenisierung einer Cu-50 Gew.-% Ni-Gußlegierung wurden mit Hilfe von Elektronenstrahlmikroanalyse und anderen komplementären Methoden untersucht. Das Auftreten der Homogenisierung wurde durch das Zusammenwirken von drei Faktoren erklärt. Durch die Verformung ändern sich der interdendritische Abstand und die Diffusionswege, Gitterbaufehler beschleunigen die Diffusion, und das Durchlaufen des Gefüges von Korngrenzen während der Rekristallisation vereinfacht die Umverteilung des Mischkristalls mittels Korngrenzendiffusion.

Rejane Aparecida Nogueira Instituto de Pesquisas Energéticas e Nucleares Comissão Nacional de Energia Nuclear, C.P. 11049 − Pinheiros − CEP 05422-970 São Paulo, Brasil
Angelo Fernando Padilha Escola Politécnica da Universidade de São Paulo, Departamento de Engenharia Metalúrgica e de Materiais C.P. 8174 − CEP 05508-900 São Paulo, Brasil

Literature

1 Weinberg, F.; Buhr, R.K.: J. Iron Steel Inst. 207 (1969) 1114 – 21.Search in Google Scholar

2 Cole, G.S.: Metall. Trans. 2 (1971) 357 – 70.10.1007/BF02663323Search in Google Scholar

3 Martin, J.W.; Doherty, R.D.: Stability of Microstructure in Metallic Systems, Cambridge University Press, Cambridge (1976) 30 – 34.Search in Google Scholar

4 Falleiros, I.G.S.: Metallography 5 (1972) 125 – 37.10.1016/0026-0800(72)90050-XSearch in Google Scholar

5 Granger, D.A.; Bower, T.F.: J. Inst. Metals 98 (1970) 353 – 63.Search in Google Scholar

6 Feest, E.A; Doherty, R.D.: Metall. Trans. 4 (1973) 125 – 36.10.1007/BF02649611Search in Google Scholar

7 Fletcher, A.J.; King, S.; Rickinson, B.; Atkinson, H.: Mater. Sc. Techn. 9 (1993) 555 – 61.10.1179/mst.1993.9.7.555Search in Google Scholar

8 Butrymowicz, D.B.; Manning, J.R.; Read, M.E.: Diffusion Rate Data and Mass Transport Phenomena for Copper system. In: National Bureau of Standards. Diffusion in metals data center, Washington, USA, DC 20234 (1977) 194 – 233.Search in Google Scholar

9 Kurz, W.; Fisher, D.J.: Fundamentals of Solidification, 3rd edition, Trans. Tech. Publication, Aedermannsdorf, Switzerland (1989) 289 – 292.Search in Google Scholar

10 Politis, C.; Johnson, W.L.: J. Appl. Phys. 60 (1986) 1147 – 51.10.1063/1.337359Search in Google Scholar

11 Fecht, H.J.; Hellstern, E.; Fu, Z.; Johnson, W.L.: Metall. Trans. A 21A (1990) 2333 – 7.10.1007/BF02646980Search in Google Scholar

12 Gottstein, G.; Steffen, H.; Hemminger, W.; Hoschek, G.; Broxterman, K.; Grewe, H.G.; Lang, E.: Scripta metall. 9 (1975) 791 – 6.10.1016/0036-9748(75)90242-2Search in Google Scholar

13 Guilemany, J.M.; Fernández, J.; Peregrin, F.; Guixá, O.: Recrystallization 92. Proc. Int. Conf., Trans. Tech. Publication, Aedermannsdorf, Switzerland (1993) 655 – 60.Search in Google Scholar
Received: 1996-04-03
Published Online: 2021-11-30

© 1997 Carl Hanser Verlag, München

Articles in the same Issue

  1. Frontmatter
  2. Aufsätze
  3. Segregation and Precipitation during Solidification of Titanium and Nitrogen Containing Iron Alloys
  4. Microtexture and Orientation Relations Analysis in Surroundings of Shear Bands in Monocrystalline Copper
  5. Correlation Between Microstructure and Creep Behavior of the High-Temperature Ti Alloy IMI 834
  6. The Influence of Cold Working and Recrystallization on the Homogenization of As-cast Cu-50 wt.% Ni Alloy
  7. Casting of Particulate Al-base Composites
  8. Creep Crack Growth and Fractal Dimension of the Grain-boundary Fracture in Austenitic 21Cr–4Ni–9Mn Steel
  9. The Energy Release Rate of Nonlinear Double Cantilever Beam Specimens
  10. Thermodynamic Properties of Solid Aluminium– Iron Alloys
  11. An Assessment of Thermodynamic Equilibria in the Ag–Al–Cu–Mg Quaternary System in Relation to Precipitation Reactions
  12. Experimental Study of Phase Equilibria in the Fe–Cr –Mn System in the Temperature Range 1073 to 1373 K
  13. Thermodynamic Properties and Phase Equilibria in the Ca–Sb System
  14. Phase Equilibria in the Ti-rich Corner of the Ti –Si –Al System
  15. Mitteilungen der Deutschen Gesellschaft für Materialkunde e.V.
  16. Personen
  17. Fortbildung
  18. Terminkalender
https://doi.org/10.3139/ijmr-1997-0239

Articles in the same Issue

  1. Frontmatter
  2. Aufsätze
  3. Segregation and Precipitation during Solidification of Titanium and Nitrogen Containing Iron Alloys
  4. Microtexture and Orientation Relations Analysis in Surroundings of Shear Bands in Monocrystalline Copper
  5. Correlation Between Microstructure and Creep Behavior of the High-Temperature Ti Alloy IMI 834
  6. The Influence of Cold Working and Recrystallization on the Homogenization of As-cast Cu-50 wt.% Ni Alloy
  7. Casting of Particulate Al-base Composites
  8. Creep Crack Growth and Fractal Dimension of the Grain-boundary Fracture in Austenitic 21Cr–4Ni–9Mn Steel
  9. The Energy Release Rate of Nonlinear Double Cantilever Beam Specimens
  10. Thermodynamic Properties of Solid Aluminium– Iron Alloys
  11. An Assessment of Thermodynamic Equilibria in the Ag–Al–Cu–Mg Quaternary System in Relation to Precipitation Reactions
  12. Experimental Study of Phase Equilibria in the Fe–Cr –Mn System in the Temperature Range 1073 to 1373 K
  13. Thermodynamic Properties and Phase Equilibria in the Ca–Sb System
  14. Phase Equilibria in the Ti-rich Corner of the Ti –Si –Al System
  15. Mitteilungen der Deutschen Gesellschaft für Materialkunde e.V.
  16. Personen
  17. Fortbildung
  18. Terminkalender
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