Название |
Influence of diffusion alloying of structural steels by nickel and copper in the medium of low-melting liquid-metal solutions on their corrosion resistance |
Реферат |
The paper considered the effect of Ni-Cu-based coatings obtained by diffusion metallization from a medium of low-melting liquid metal solutions on corrosion resistance of structural steels. It was revealed that diffusion saturation of Ni-Cu steels U8, Kh12MF, 40Kh, steel 20 formed diffusion coatings with a thickness of 10-42 μm on their surface. Thickness of the coatings depended on the modes of diffusion saturation and the coated material. It was found out that corrosion resistance of the coated materials increases in the environment of 30 % aqueous HCl and 3 % NaCl solutions with rise of the diffusion saturation temperature. The maximum corrosion resistance was obtained after diffusion saturation at the temperature of 1070 °C. Ni-Cu-based coatings allow to reduce the corrosion rate of steels in the NaCl environment: for the steel U8 by 26.21 times, for the steel Kh12MF by 21.48 times, for the steel 40Kh by 18.46 times, for the steel steel 20 by 13.9 times. Corrosion rate of steels in HCl environment is also reduced: for the steel U8 by 20.23 times, for the steel Kh12MF by 20.06 times, for the steel 40Kh by 17.35 times, for the steel 20 by 11.45 times. It was revealed that chromium-alloyed steels are undergone additional alloying coating with chromium, diffusing from the coated sample, which allows to obtain a minimal corrosion rate in both HCl and NaCl environments. Thus, the corrosion rate of steel Kh12MF after Ni-Cu coating in NaCl was 0.025 g/(m2·h), in HCl – 0.289 g/(m2·h). The highest corrosion rate was detected on the samples made of U8 steel: in NaCl 0.032 g/(m2·h), in HCl – 0.039 g/(m2·h).
The research was conducted under financial support of Kuban scientific fund within the frameworks of scientific and innovation project No. NIP-20.1/22.17. |
Библиографический список |
1. Xiang Hou, Hao Wang, Qun Yang, Yanxia Chen, Linjiang Chai, Bo Song, Ning Guo, Shengfeng Guo, Zhongwen Yao. Microstructure and properties of Cr-AlN composite coating prepared by pack-cementation on the surface of Al-containing ODS steel. Surface and Coatings Technology. 2022. Vol. 447. 128842. 2. Vikrant Singh, Anil Kumar Singla, Anuj Bansal. Impact of HVOF sprayed Vanadium Carbide (VC) based novel coatings on slurry erosion behaviour of hydro-machinery SS316 steel. Tribology International. 2022. Vol. 176. 107874. 3. Jing Liang, Ye Liu, Sheng Yang, Xiuyuan Yin, Suiyuan Chen, Changsheng Liu. Microstructure and wear resistance of laser cladding Ti-Al-Ni-Si composite coatings. Surface and Coatings Technology. 2022. Vol. 445. 128727. 4. Kuchumova I. D., Batraev I. S., Cherkasova N. Yu., Ukhina A. V., Shtertser A. A., Khorkhe A. M. Corrosion resistance of detonation coatings Fe66Cr10Nb5B19 in the conditions of salt mist environment. Obrabotka materialov (tekhnologiya, oborudovanie, instrumenty). 2020. Vol. 22. No. 3. pp. 95-105. 5. Burkov A. A., Pyachin S. A., Vlasova N. M., Astapov I. A., Kulik M. A. Improvement of corrosion-resistant and tribotechnical properties of Ti6Al4V alloy via deposition of electric spark Ti-Al-Si-C coatings. Obrabotka materialov (tekhnologiya, oborudovanie, instrumenty). 2018. Vol. 20. No. 3. pp. 85-96. 6. Hai Zhao, Yi Ding, Jinghui Li, Gao Wei, Mingya Zhang. Corrosion resistance of laser melting deposited Cu-bearing 316L stainless steel coating in 0.5 M H2SO4 solution. Materials Chemistry and Physics. 2022. Vol. 291. 126572. DOI: 10.1016/j.matchemphys.2022.126572 7. Hong-Qiang Fan, Peng Lu, Xuan Zhu, Yashar Behnamian, Qian Li. Development of superhydrophobic and corrosion resistant coatings on carbon steel by hydrothermal treatment and fluoroalkyl silane self-assembly. Materials Chemistry and Physics. 2022. Vol. 290. 126569. DOI: 10.1016/j.matchemphys.2022.126569 8. Kang Yang, Cheng Chen, Guozheng Xu, Zitao Jiang, Shihong Zhang, Xia Liu. HVOF sprayed Ni–Mo coatings improved by annealing treatment: microstructure characterization, corrosion resistance to HCl and corrosion mechanisms. Journal of Materials Research and Technology. 2022. Vol. 19. pp. 1906-1921. 9. Gulyashinov P. A., Mishigdorzhiin U. L., Ulakhanov N. S. Influence of boriding and aluminizing on structure and microhardness of low-carbon steels. Obrabotka materialov (tekhnologiya, oborudovanie, instrumenty). 2022. Vol. 24. No. 2. pp. 91-101. 10. Gurevich L. M., Pronichev D. V., Kulevich V. P., Slautin O. V., Naumenko V. A., Kharlamov V. O. Study of corrosion resistance of aluminizing intermetallide coatings in the alloys of Fe-Cr-Al system. Metallurg. 2023. No.1. pp. 74-79. 11. Krylova T. A., Ivanov K. V., Chumakov Yu. A., Trotsenko R. V. Corrosion resistance and wear resistance of coatings, obtained via the method of out-of-vacuum electron beam facing of refractory carbides on low-carbon steel. Neorganicheskie materialy. 2020. Vol. 56. No. 3. pp. 343-347. 12. Sokolov A. G., Bobylyov E. E. Features and regularities in formation of diffusion nickel-copper coatings on steels in the medium of low-melting liquid-metal solutions. CIS Iron and Steel Review. 2022. Vol. 23. pp. 56–60. 13. Sokolov E. G., Ozolin A. V., Svistun L. I. Cobalt mass transfer through the liquid phase in sintering of Sn-Cu-Co and Sn-Cu-Co-W powder materials. JP Journal of Heat and Mass Transfer. 2019. Vol. 16 (2). pp. 297-305. 14. Sokolov A. G., Bobylyov E. E., Plomodyalo R. L. Influence of carburization on the structure and properties of functional diffusion coatings based on titanium carbide on TiC-WC-Co and WCCo alloys. Lett. Mater. 2020. Vol. 10 (4). pp. 410-415. 15. Sokolov A. G., Popov R. A., Bobylyov E. E., Storozhenko I. D. Device for diffusion metallization in the environment of low-melting liquid metal solutions. RF Patent 2767108 No. 2021114415. Filed 20.05.2021. Published 16.03.2022. Bulletin No. 8. 9 p. |