Structure and fatigue properties of 08Kh18N10T steel after equal-channel angular pressing and heating

Russian Metallurgy (Metally)

Volumn 2012, Issue 11, 2012, Pages 954-962

  Dobatkin, S V ^a   Terent'ev, V F ^a   Skrotzki, W ^b   Rybalchenko, O V ^a   Pankova, M N ^c   Prosvirnin, D V ^a   Zolotarev, E V ^a  

^a BAIKOV INSTITUTE OF METALLURGY AND MATERIALS SCIENCE   (Russian Federation)

^b DRESDEN UNIVERSITY OF TECHNOLOGY   (Germany)

^c BARDIN CENTRAL RESEARCH INSTITUTE OF FERROUS METALLURGY   (Russian Federation)

Author keywords

[No Author keywords available]

Indexed keywords

ANNEALING TWINS; AUSTENITIC; CORROSION-RESISTANT; CYCLIC DEFORMATIONS; CYCLIC TESTS; DEFORMATION TWIN; DYNAMIC RECOVERY; FATIGUE LIMIT; FATIGUE PROPERTIES; FATIGUE STRENGTH; LATH MARTENSITE; STRUCTURAL ELEMENTS; SUBGRAIN STRUCTURES;

AUSTENITE; DEFORMATION; DYNAMIC RECRYSTALLIZATION; FATIGUE OF MATERIALS; FATIGUE TESTING; MARTENSITE; MARTENSITIC TRANSFORMATIONS; PRESSING (FORMING);

MARTENSITIC STEEL;

EID: 84874791639     PISSN: 00360295     EISSN: 15556255     Source Type: Journal    
DOI: 10.1134/S0036029512110043     Document Type: Article

References (34)

1. R. Z. Valiev and I. V. Aleksandrov, Nanostructured Materials Produced by Severe Plastic Deformation (Logos, Moscow, 2000).
2. R. Z. Valiev and I. V. Aleksandrov, Bulk Nanostructural Metallic Materials (Akademkniga, Moscow, 2007).
3. Bulk Nanostructured Materials, Ed. by M. J. Zehetbauer and Y. T. Zhu (Wiley, Weinheim, 2009).
4. S. V. Dobatkin, R. Z. Valiev, L. M. Kaputkina, N. A. Krasilnikov, O. V. Sukhostavskaya, and V. S. Komlev, "Recrystallization of Steels with Submicrocrystalline Structure," Recrystallization and Related Phenomena 13, 907-912 (1999).
5. A. M. Patselov, V. P. Pilyugin, E. G. Chernyshov, T. I. Chashchukhina, L. M. Voronova, G. G. Taluts, and Yu. A. Ivonin, "Nanostructure and Phase Composition of Steel 12Kh18N10T after Deformation under Pressure," in Structure and Properties of Nanocrystalline Materials, Ed. by N. Noskova and G. Taluts (IFM UrO RAN, Yekaterinburg, 1999), pp. 37-44.
6. S. S. M. Tavares, D. Gunderov, V. Stolyrov, and J. M. Neto, "Phase Transformation Induced by Severe Plastic Deformation in the AISI 304L Stainless Steel," Mater. Sci. Eng. A 358, 32-36 (2003).
7. O. V. Rybalchenko, S. V. Dobatkin, L. M. Kaputkina, G. I. Raab, and N. A. Krasilnikov, "Strength of Ultra-Grained Corrosion-Resistant Steels after Severe Plastic Deformation," Mat. Sci. Eng. A 387-389, 244-248 (2004).
8. A. Vorhauer, S. Kleber, and R. Pippan, "Microstructure of Austenitic and Ferritic Steels Produced by Severe Plastic Deformation and Subsequent Annealing," in Ultrafine Grained Materials (TMS, Warrendale, 2004), Vol. III, pp. 629-634.
9. S. Scheriau, Z. Zhang, S. Kleber, and R. Pippan, "Deformation Mechanisms of a Modified 316L Austenitic Steel Subjected to High Pressure Torsion," Mater. Sci. Eng. A 528, 2776-2786 (2011).
10. I. Yu. Litovchenko, A. N. Tyumentsev, N. V. Shevchenko, and A. V. Korznikov, "Evolution of Structural and Phase States at Large Plastic Deformations of an Austenitic Steel 17Cr-14Ni-2Mo," Fiz. Met. Metalloved. 112(4), 436-448 (2011).
11. I. I. Kositsyna, V. V. Sagaradze, and V. I. Kopylov, "Formation of High-Strength and High-Plastic State in Metastable Austenitic Steels by the Method of Equal-Channel Angular Pressing," Fiz. Met. Metalloved. 88(5), 84-94 (1999).
12. G. G. Yapici, I. Karaman, Z. P. Luo, and Y. I. Chumlyakov, "Grain Refinement and Mechanical Twinning in Severely Deformed AISI 316L Stainless Steel at High Temperatures," in Ultrafine Grained Materials (TMS, Warrendale, 2004), Vol. III, pp. 291-296.
13. S. V. Dobatkin, O. V. Rybal'chenko, and G. I. Raab, "Formation of a Submicrocrystalline Structure in Austenitic 08Kh18N10T Steel during Equal-Channel Angular Pressing Followed by Heating," Russian Metallurgy (Metally), No. 1, 45-52 (2006).
14. S. V. Dobatkin, O. V. Rybal'chenko, and G. I. Raab, "Structure Formation, Phase Transformations and Properties in Cr-Ni Austenitic Steel after Equal-Channel Angular Pressing and Heating," Mater. Sci. Eng. A 463, 41-45 (2007).
15. H. Ueno, K. Kakihata, Y. Kaneko, S. Hashimoto, and A. Vinogradov, "Nanostructurization Assisted by Twinning during Equal Channel Angular Pressing of Metastable 316L Stainless Steel," J. Mater. Sci. 46(12), 4276-4283 (2011).
16. A. Belyakov, T. Sakai, H. Miura, and R. Kaibyshev, "Substructures and Internal Stresses Developed under Warm Severe Deformation of Austenitic Stainless Steel," Scripta Materialia 42, 319-325 (2000).
17. A. Belyakov, K. Tsuzaki, H. Miura, and T. Sakai, "Effect of Initial Microstructures on Grain Refinement in a Stainless Steel by Large Strain Deformation," Acta Materialia 51, 847-861 (2003).
18. H. Miura, H. Hamaji, and T. Sakai, "Microstructural Evolution during Severe Deformation in Austenitic Stainless Steel with Second Phase Particles," in Nanomaterials by Severe Plastic Deformation (Wiley, Weinheim, 2002), pp. 375-380.
19. A. Belyakov, T. Sakai, and H. Miura, "Microstructure and Deformation Behaviour of Submicrocrystalline 304 Stainless Steel Produced by Severe Plastic Deformation," Mater. Sci. Eng. A 319-321, 867-871 (2001).
20. H. Miura, H. Hamaji, T. Sakai, N. Fujita, and N. Yoshinaga, "Effect of Second Phase Particles on Ultrafine Grain Evolution during Multi-Directional Forging of Austenitic Stainless Steel," Mater. Sci. Forum 503/504, 293-298 (2006).
21. J. Talonen and H. Hanninen, "Formation of Shear Bands and Strain-Induced Martensite during Plastic Deformation of Metastable Austenitic Stainless Steels," Acta Materialia 55, 6108-6118 (2007).
22. R. Z. Valiev, A. V. Korznikov, and R. R. Mulyukov, "Structure and Properties of Metallic Materials with a Submicrocrystalline Structure," Fiz. Met. Metalloved., No. 4, 70-86 (1992).
23. S. V. Dobatkin, "Mechanical Properties of Ultrafine-Grained Aluminum Alloys and the Possibility of Their Application," Tekhnol. Legkikh Splavov, No. 3, 5-17 (2011).
24. Y. Estrin and A. Vinogradov, "Fatigue Behaviour of Light Alloys with Ultrafine Grain Structure Produced by Severe Plastic Deformation: An Overview," Intern. J. Fatigue 32, 898-907 (2010).
25. V. F. Terent'ev, S. V. Dobatkin, D. V. Prosvirnin, I. O. Bannykh, O. V. Rybal'chenko, and G. I. Raab, "Fatigue Strength of Austenitic Kh18N10T Steel after Equal-Channel Angular Pressing," Deform. Razr. Mater., No. 10, 30-38 (2008).
26. V. F. Terent'ev, S. V. Dobatkin, S. A. Nikulin, V. I. Kopylov, D. V. Prosvirnin, S. O. Rogachev, and I. O. Bannykh, "Effect of Equal-Channel Angular Pressing on the Fatigue Strength of Titanium and a Zirconium Alloy," Deform. Razr. Mater., No. 8, 48-57 (2010).
27. H. Ueno, K. Kakihata, Y. Kaneko, S. Hashimoto, and A. Vinogradov, "Enhanced Fatigue Properties of Nanostructured Austenitic SUS 316L Stainless Steel," Acta Materialia 59, 7060-7069 (2011).
28. V. Patlan, A. Vinogradov, K. Higashi, and K. Kitagawa, "Overview of Fatigue Properties of Fine Grain 5056 Al-Mg Alloy Processed by Equal-Channel Angular Pressing," Mater, Sci. Eng., Ser. A 300, 171-182 (2001).
29. V. F. Terent'ev, S. V. Dobatkin, D. V. Prosvirnin, I. O. Bannykh, V. I. Kopylov, and V. N. Serebryanyi, "Fatigue Strength of MA2-1 Magnesium Alloy after Equal-Channel Angular Pressing," Metally, No. 5, 79-86 (2010).
30. V. F. Terent'ev, S. V. Dobatkin, V. I. Kopylov, D. V. Prosvirnin, and N. V. Bakunova, "Static and Cyclic Fracture of a Submicrocrystalline Al-Mg-Sc Alloy," Materialovedenie, No. 2, (2013).
31. Y. Iwahashi, Z. Horita, M. Nemoto, and T. G. Langdon, "The Process of Grain Refinement in Equal-Channel Angular Pressing", Acta Mater. 46(9), 3317-3331 (1998).
32. E. V. Shelekhov and T. A. Sviridova, "Programs for X-ray Diffraction Analysis of Polycrystals," Metalloved. Term. Obrab. Met., No. 8, 16-19 (2000).
33. A. Weidner, A. Glage, and H. Biermann, "In-situ Characterization of the Microstructure Evolution during Cyclic Deformation of Novel Cast TRIP Steel," Proc. Eng. 2, 1961-1971 (2010).
34. A. Glage, A. Weidner, and H. Bierman, "Cyclic Deformation Behavior of Three Austenitic Cast CrMnNi TRIP/TWIP Steels with Various Ni Content," Steel Res. Int. 82, 1040-1047 (2011).