PROFILING THE ROUND TUBE INTO THE HEXAGON FROM HIGH BORON CONTENT STEEL

Hex tube from steel with a high content of boron, which is a material of construction for the manufacture of racks for storage of spent nuclear fuel, was produced. It has been shown that the steel has a completely satisfactory technological plasticity for profi ling rolling (drawing) in a circular tube as in the hexagonal at elevated and at room temperature. 

1. Cardoso P.H.S., Kwietniewski C., Porto J.P., Reguly A., Strohaecker T.R. The infl uence of delta ferrite in the AISI 416 stainless steel hot workability. Mater. Sci. and Eng. 2003. Vol. 351, pp. 1–8.

2. Liou H., Pan Y., Hsieh R., Tsai W. Effects of Alloying Elements on the Mechanical Properties and Corrosion Behaviors of 2205 Duplex Stainless Steels. JMEPEG. 2001. Vol. 10, pp. 231–241.

3. Xiao Y., Guo C. Constitutive modelling for high temperature behavior of 1Cr12Ni3Mo2VNbN martensitic steel. Mater. Sci. and Eng A. 2011. Vol. 528, pp. 5081–5087.

4. Cabrera J.M., Mateo A., Llanes L., Prado J.M., Anglada M. Hot deformation of duplex stainless steels. J. of Mater. Proc. Tech. 2003. Vol. 143–144, pp. 321–325.

5. Sivaprasad P.V., Venugopal S., Venugopal S., Maduraimuthu V., Vasudevan M., Mannan S.L., Prasad Y.V.R.K., Chaturvedi R.C. Validation of processing maps for a 15Cr–15Ni–2.2Mo–0.3Ti austenitic stainless steel using hot forging and rolling tests. J. of Mater. Proc. Tech. 2003. Vol. 132, pp. 262–268.

6. Fang Y.L., Liu Z.Y., Song H.M., Jiang L.Z. Hot deformation behavior of a new austenite–ferrite duplex stainless steel containing high content of nitrogen. Mater. Sci. and Eng. A. 2009. Vol. 526, pp. 128–133.

7. Shulga A.V. A comparative study of the mechanical properties and the behavior of carbon and boron in stainless steel cladding tubes fabricated by PM HIP and traditional technologies. J. of Nuc. Mater. 2013. Vol. 434, pp. 133–140.

8. Mejía I., Bedolla-Jacuinde A., Maldonado C., Cabrera J.M. Determination of the critical conditions for the initiation of dynamic recrystallization in boron microalloyed steels. Mater. Sci. and Eng. A. 2011. Vol. 528, pp. 4133-4140.

9. Pozdnyakov A.V., Churyumov A.Yu., Tsar’kov A.A., Bazlov A.I., Solonin A.N. Infl uence of the ratio Ti/B on the microstructure and the hardness of the steel with a high content of boron. Izvestiya VUZov. Chernaya metallurgiya = Izvestiya – Ferrous Metallurgy. 2014, no. 1, pp. 43–45. (In Russ.).

10. Churyumov A.Yu., Khomutov M.G., Pozdnyakov A.V., Mukhanov E.L. Study of the structure and high-temperature mechanical properties of a steel with an elevated content of boron. Metal Science and Heat Treatment, 2014, Oct.5, p. 3.

11. Churyumov A.Yu., Khomutov M.G., Tsar’kov A.A., Pozdnyakov A.V., Solonin A. N., Mukhanov E.L Study of the structure and mechanical properties of corrosion-resistant steel with a high concentration of boron at elevated temperatures. Physics of Metals and Metallography, 2014, Vol.115, no. 8, pp. 809–813.

12. Churyumov A.Yu., Khomutov M.G., Solonin A.N., Mukhanov E.L., Efimov V.M. Comparative analysis of models of the flow stress of corrosion-resistant steel with a high content of boron, based on the Arrhenius type equation and artifi cial neural networks. Metally, 2014, no. 4, pp. 30-34. (In Russ.).

13. Saf’yanov A.V., Burakov A.P., Osadchii V.Ya., Klimov N.P., Matyushin A.Yu., Levshunov M.A. Ways to reduce material consumption in the production of hexagonal pipe size 257×6×4300 mm of boron steel for the storage of spent nuclear fuel. Proizvodstvo prokata, 2014, no. 8, pp. 18–25. (In Russ.).

14. Fedorov A.A., Komarov A.V., Saf’yanov A.V., Khristenko V.K., Osadchii V.Ya. Development of innovative technologies and the development of mass production of steel pipes of hex ES 82 for storage of spent nuclear fuel. Proizvodstvo prokata, 2009, no. 3, pp. 32–37. (In Russ.).

15. Saf’yanov A.V., Fedorov A.A., Osadchii V.Ya. Puti snizheniya raskhoda metalla pri proizvodstve shestigrannykh trubzago tovok s razmerom «pod klyuch» 250+2,0/-3,0k×6+2,0/-1,0k×4300+80/-30 mm iz borsoderzhashchikh marok stali dlya trans portirovki i uplotnennogo khraneniya otrabotannogo yader-nogo topliva. Truby – 2011 [Ways to reduce material consumption in the production of pipes, hexagonal pieces with a size of “turnkey” 250 + 2.0 / + 2.0 -3,0×6 / -1,0×4300 + 80 / -30 mm of boron steels for the transportation and compact storage of spent nuclear fuel]. Part. 2. In: Sb. dokladov XIX mezhdunarodnoi nauchno-tekhnicheskoi konferentsii [Reports of XIX International Scientifi c and Technical Conference “Tubes – 2011”]. pp. 216–224. (In Russ.).

16. Fedorov A.A., Saf’yanov A.V., Ignat’ev V.V. etc. Sposob proizvodstva trubnykh zagotovok dlya izgotovleniya shestigrannykh chekhlovykh trub iz nizkoplastichnoi stali s soderzhaniem bora 1.3–1.8 % [Process for producing round billets for production of hexagonal shroud tubes of low ductility steel containing 1.3-1.8% of boron]. Patent RF no. 2226133, Byulleten’ Izobretenii 2004, no. 9. (In Russ.).

17. Pyatakova L.L., Mozharov M.V., Sirotkina M.A., Dyuzheva T.A. Effect of boron on the cold brittleness of medium-carbon steel. Metal science and Heat Treatment. 1971, no. 2, pp. 62–64.

18. Guseinov R. K. Properties of structural steel doped with boron. Metal science and Heat Treatment, 1991, no. 7, pp. 35–37.

19. Zaslavskii A.Ya., Mushtakova T.L. Ductile properties of boron steels for cold die forging. Metal science and Heat Treatment. 1992, no. 3, pp. 17–21.

20.