Название |
Hot physical simulation of δ-ferrite behavior at production and welding of high-nitrogen corrosion-resistant
steels |
Информация об авторе |
Peter the Great St. Petersburg Polytechnic University (St. Petersburg, Russia):
A. A. Kazakov, Dr. Eng., Prof., Head of “Metallurgical Examination” Lab., E-mail: kazakov@thixomet.ru A. I. Zhitenev, Engineer, “Metallurgical Examination” Lab., E-mail: zhitenev@thixomet.ru P. A. Ishpaev, Magister, “Metallurgical Examination” Lab.
National Research Center “Kurchatov Institute” — Central Research Institute of Structural Materials “Prometey” (St. Petersburg, Russia):
O. V. Fomina, Dr. Eng., Head of the Research and Production Complex “Organization and Management of R&D, Computer Science and Computer Technology, Quality Management and Copyright Protection” P. V. Melnikov, Cand. Eng., Head of Department |
Библиографический список |
1. Kalinin G. Yu., Mushnikova S. Yu., Nesterova E. V., Fomina O. V., Kharkov A. A. Research of structure and properties of a high-strength corrosion-resistant nitrogen steel C0.04Cr20Ni6Mn11Mo2NVNb. Voprosy Materialovedenia (Materials Science Issues). 2006. No. 1 (45). p. 45–54. 2. Blinov G. Yu., Pojmenov I. L., Kulikova O. I., Karelin F. R., Shurygina I. A., Glebov V. V., Kalenihin Yu. N. Influence of hot deformation on structure and mechanical properties of nitrogen nonmagnetic steels. Structure and Physicomechanical Properties of Nonmagnetic Steels. Moscow: Science, 1986. p. 30–33. 3. Kaputkina L. M., Svyazhin A. G., Smarygina I. V., Kindop V. E. Influence of nitrogen and copper on hardening of austenitic chromium-nickelmanganese stainless steel. CIS Iron and Steel Review. 2016. Vol. 12. pp. 30–34. 4. Pickering F. B. Physical Metallurgy and the Design of Steels. London. Applied Science Publishers. 1978. 275 p. 5. Kujanpaa V. P., David S. A., White C. L. Formation of Hot Cracks in Austenitic Stainless Steel Welds — Solidification Cracking. Welding Research Supplement. 1986. No. 204. pp. 203–212. 6. Demk H. Deformation under Hot Working Conditions. London: The Iron and Steel Institute. 1968. 135 p. 7. Kane R. H. The Hot Deformation of Austenite. Pergamon Press. 1977. 457 p. 8. Brooks J. A., Thompson A. W., Williams J. C. A fundamental study of the beneficial effects of δ-ferrite in reducing weld cracking. Welding Journal. 1984. No. 3. pp. 71–83. 9. Priceputu I. L., Moisa B., Chiran A., Nicolescu G., Bacinschi Z. Delta ferrite influence in AISI 321 stainless steel welded tubes. The Scientific Bulletin of Valahia University: Materials and Mechanics. 2011. No. 6 (year 9). pp. 87–96. 10. Schaffler A. I. Constitution diagram for stainless steel weld metal. Metal Progress. 1949. No. 56. pp. 680–680. 11. DeLong W. T., Ostorm G. A., Szumachowski E. R. Measurement and calculation of ferrite in stainless steel weld metal. Welding Journal. 1956. No. 35 (11). рр. 521–528. 12. Speidel M. High Nitrogen Steels. Proceedings of the 10th International Conference on High Nitrogen Steels. 2009. p. 121. 13. Kazakov A. A., Shakhmatov A. V., Kolpishon E. Yu. Cast structure and an inheritance of high chromium steel with nitrogen. Heavy Mechanical Engineering. 2015. No. 1-2. p. 19–24. 14. Kazakov A. A., Oryshchenko A. S., Fomina O. V., Zhitenev A. I., Vihareva T. V., Control of the δ-ferrite origin in nitrogenous chromium nickel manganese steels. Voprosy materialovedenia (Materials Science Issues). 2017. No. 1(89). pp. 7–12. 15. Kazakov A. A., Fomina O. V., Zhitenev A. I., Melnikov P. V. Physico-chemical fundamentals of controlling the δ-ferrite origin while welding by austenitic-ferritic materials. Voprosy materialovedenia (Materials Science Issues). 2018. No. 4 (96). pp. 42–52. 16. David S. A. Ferrite Morphology and Variations in Ferrite Content in Austenitic Stainless Steel Welds. Welding Research Supplement. 1981. April. pp. 63-71. 17. Suutala N., Takalo T., Moisio T. The Relationship Between Solidification and Microstructure in Austenitic and Austenitic-Ferritic Stainless Steel Weld. Metallurgical Transactions. 1979. Vol. 10. Issue 4. pp. 512-514. 18. TU 14-1-2921-80. Welding steel wire. Grade SVC0.01Cr19Ni11Mo4V (EP647). 19. Kazakov A, Kiselev D. Industrial Application of Thixomet. Metallography, Microstructure, and Analysis. 2016. Vol. 5. Iss.4. pp. 294-301. DOI: 10.1007/s13632-016-0289-6. 20. Bale C., Bélisle E., Chartrand P., Decterov S., Eriksson G., Hack K., Jung I.-H., Kang Y.-B., Melançon J., Pelton A., Robelin C., Petersen S. FactSage Thermochemical Software and Databases — Recent Developments. Calphad-computer Coupling of Phase Diagrams and Thermochemistry. 2009. Vol. 33. pp. 295–311. 21. Golod V. M. Theory and computer analysis of foundry processes. Saint-Petersburg: Peter the Great St. Petersburg Polytechnic University. 2018. 243 p. 22. Vitek J. M., David S. A. The Sigma Phase Transformation in Austenitic Stainless Steels. Welding Research Supplement. 1986. April. pp. 106–112. 23. Leone G. L., Kerr H. W. The Ferrite to Austenite Transformation in Stainless Steels. Welding Research Supplement. 1980. January. pp. 13–22. 24. Kokawa H., Kuwana T., Yamamoto A. Crystallographic Characteristics of Delta Ferrite Transformations in f 304L Weld Metal at Elevated Temperatures. Welding Research Supplement. 1989. March. pp. 92–101. 25. Fukumoto, S., Iwasaki, Y., Motomura, H., Fukuda, Y. Dissolution behavior of -ferrite in Continuously Cast Slabs of SUS304 during Heat Treatment. ISIJ International. 2012. Vol. 52. No. 1. pp. 74–79. 26. Saied M. Experimental and numerical modeling of the dissolution of delta ferrite in the Fe–Cr–Ni system: application to the austenitic stainless steels. Materials University Grenoble. Alpes. 2016. p. 220. 27. David S. A., Vitek J. M., Hebble T. L. Effect of Rapid Solidification on Stainless Steel Weld Metal Microstructure and Its Implications on the Schaeffler Diagram. Welding Research Supplement. 1987. September. pp. 289-300. 28. Elmer J. W., Allen S. M., Eagar T. W. Microstructural Development during Solidification of Stainless Steel Alloys. Metallurgical Transaction. 1989. Vol. 20A. p. 2117–2131. 29. Inoue H., Koseki T. Clarification of Solidification Behaviors in Austenitic Stainless Steels Based on Welding Process. Nippon steel technical report. 2007. No. 95. pp. 62–70. 30. Folmer M. Kinetics of new phase formation. Мoscow: Science. 1986. 208 p. 31. Koumatos K., Muehlemann A. A theoretical investigation of orientation relationships and transformation strains in steels. Acta Crystallization. 2017. No. 73. pp. 115–123. 32. Lifshitz I. M., Slyozov V. V. The kinetics of precipitation from supersaturated solid solutions. Journal of Physics and Chemistry of Solids. 1961. Vol. 19. No. 1-2. pp. 35–50. 33. Wagner C. Theorie der alterung von niderschlagen durch umlösen (Ostwald Reifung). Zeitschrift für Elektrochemie. 1961. Vol. 65. pp. 581–591. 34. Valiente Bermejo M.A. A Mathematical Model to Predict δ-Ferrite Content in Austenitic Stainless Steel Weld Metals. Welding in the World. 2012. Vol. 56. pp. 48–68. |