Structural-phase state of the surface layer of low-carbon steel after electrolytic-plasma modification
DOI:
https://doi.org/10.26577/RCPh.2021.v78.i3.08Keywords:
Electrolyte-plasma modification, martensite, microstructure, hardening, hardnessAbstract
An alternative technology of strengthening by electrolytic-plasma modification of low-carbon alloy steel for the wedge columns binding for stop valves has been developed. The processing of steel 20X samples was carried out on an experimental installation, the optimal processing modes were determined experimentally. Simulation of the treated surface makes it possible to assume that during the electrolytic-plasma heating of parts, along with quenching, chemical modification of the metal surface layers occurs. The volt-temperature characteristic with the superposition of real time on the proposed processing clearly shows a significant reduction in the time for hardening, relative to traditional hardening methods of similar steel. Also, energy consumption and, accordingly, the cost of the part and the product as a whole are significantly reduced. Electrolyte-plasma modification promotes the transformation of coarse-grained pearlite-ferrite microstructure into quenched martensite. An increase in hardness relative to the initial state indicates an increase in physical and mechanical properties after electrolyte-plasma treatment. The advantage of the method of electrolytic-plasma treatment consists in low energy consumption at high quenching rates, the possibility of local surface treatment; there are prerequisites for creating a semi-industrial installation for an alternative electrolyte-plasma hardening.
References
2 M.B. Doudkin, K.K. Kombayev, A.I. Kim, B.N. Azamatov and Zh.Zh. Azamatova, IJMPERD, 10, 747–758 (2020).
3 Yu.A. Geller and A.G. Rakhshtat, Materials Science, 456 (1989). (in Russ).
4 D. Pogrebnyak and O. P. Kulmenteva, Technical Physics Letters, 8, 2-6 (2003). (in Russ).
5 K.K. Kombayev, M.V. Doudkin, A.I. Kim, M. Mlynczak and B.K. Rakhadilov, News Of the national academy of sciences of the republic of Kazakhstan, 4(436), 222 – 229 (2019).
6 Method of electrolyte-plasma hardening of drill bit parts: pat. 23178 RK: IPC C21D1 / 78 (2009.01), C21D 1/34 (2009.01). (in Russ).
7 B.K. Rakhadilov, Zh.B. Sagdoldina, I.A. Ocheredko, K.K. Kombaev and A.K. Khassenov, Eurasian Physical Technical Journal, (32), 43-47 (2019).
8 E. Kozha, D.U. Smagulov, G.E. Akhmetova and K.K. Kombaev, News of national academy of sciences of the republic of Kazakhstan, 4(424), 219-225 (2017).
9 Y.F. Jiang, Y.F. Bao and K. Yang, Journal of Iron Steel Research, 11, 39-45 (2012).
10 J. Wu, W. Xue and B. Wang, Journal of Alloys and Compounds, 245, 9-15 (2014).
11 B. Wang, W.B. Xue, J. Wu, X.Y. Jin and M. Hua, Journal of Alloys and Compounds, 578, 162-169 (2013).
12 Yu.N. Tyurin and A.D. Pogrebnyak, Journal of Technical Physics, 72 (11), 119-120 (2002). (in Russ).
13 S.H. Alavi, C. Dehghanian and P. Taheri, Surface engineering, 27, 509-514 (2011).
14 B. Wang, X.Y. Jin, W.B. Xue, Z.L. Wu, J.C. Du and J. Wu High, Surface and Coatings Technology, 232, 142-149 (2013).
15 J. Wu, W. Xue, X. Jin, Applied Physics Letters, 103, 031905 (2013).
16 Y.F. Jiang, Y.F. Bao, K. Yang, Journal of Iron Steel Research, 19(11), 39-45 (2012).
17 Y.F. Jiang, T. Geng, Y.F. Bao and Y. Zhu, Surface and Coatings Technology, 216, 232-236 (2013).
18 J.H. Kong, T. Takeda and M. Okumiya, 13th International Conference on Plasma Surface Engineering, Germany, 157-160 (2012).
19 M.K. Skakov and Sh.R. Kurbanbekov, Bulletin of the Kazakhstan National Technical University, 4 (2013). (in Russ).
20 M.K. Skakov and B.K. Rakhadilov, Bulletin of the Kazakhstan National Technical University, 3 (2012). (in Russ).
21 M.K. Skakov, B.K. Rakhadilov and E.G. Batyrbekov, Bulletin of the Kazakhstan National Technical University, 3 (2014). (in Russ).
22 M.K. Zarchi, M.H. Shariat, S.A. Dehghan and S. Solhjoo, Journal of Materials Research and Technology, 3, 213-220 (2013).
23 Y.F. Jiang, Y.F. Bao and K. Yang, Journal of Iron Steel Research, 19, (11), 39-45 (2012).
24 A.R. Rastkar and B. Shokri, Surface and Interface Analysis, 44, 342-351 (2012).
25 H. Tavakoli, S.M. Mousavi Khoie, S.P. Marashi, O. Bolhasani, Journal of Materials Engineering and Performance, 22(8), 2351-2358 (2013).
26 H. Tavakoli, S.M. Mousavi Khoie, S.P.H. Marashi and S.A. Hosseini Mogadam, Journal of Alloys and Compounds, 583, 382-389 (2014).
27 H. Pang, G.-L. Zhang, X.Q. Wang, G.-H. Lv and H. Chen, S.-Z, Chinese Physics Letters, 28 (11), 103-118 (2011).
28 F. Mahzoon, S.A. Behgozin, M.E. Bahrololoom and S. Javadpour, Journal of Materials Engineering and Performance, 21 (8), 1751-1756 (2012).
29 L. Cenk Kumruoglu, A. Yerokhin, A. Ozel and A. Matthews, 1st ISTS International Surface Treatment Symposium, Istanbul, 295-310 (2011).
30 N. Lin, R. Xie, P. Zhou, Y. Ma, Z. Wang, P. Han, Z, Surface Review and Letters, 23 (4), 163-200 (2016).
