Today is Email Alert  RSS
更多内容请点击

Materials Protection >

2023 , Vol. 56 >Issue 3: 98 - 105

DOI: https://doi.org/10.16577/j.issn.1001-1560.2023.0065

Study on B/C Chemical Heat Treatment of 12Cr13 Martensitic Stainless Steel

Expand
  • School of Materials Science and Engineering,Jiangsu University,Zhenjiang 212013,China

Received date: 2022-09-15

  Revised date: 2022-10-05

  Accepted date: 2022-11-07

  Online published: 2023-03-15

Fold

Abstract

The effects of technological parameters of solid boroncarburizing and boron-carbon compound carburizing on the microstructure and properties of 12Cr13 martensitic stainless steel were studied.For the co-carburizing,12Cr13 steel was treated by solid borocarburizing heat treatment with different boron-carbon ratios;as for the boron-carbon compound carburizing,12Cr13 martensitic stainless steel was solid carburized first,then the boronizing treatment was carried out to get the optimal composite carburizing parameters.The microhardness,XRD phase structure,corrosion resistance under electrochemistry,friction and wear properties of 12Cr13 martensitic stainless steel samples under the optimum co-carburizing and compound carburizing parameters were tested and analyzed.Results showed that under the co-carburizing conditions of 950 ℃and 6 h,the optimum boron-carbon ratio of borocarburizing agent was 6:4;Under the condition of chemical compound carburizing for 6 h,the optimum parameters of boron-carbon compound carburizing were 950 ℃carburizing and 950 ℃boronizing.After the final heat treatment (quenching+low temperature tempering) of borocarburizing and compound carburizing test pieces,the hardness of the surface layer could reach 1 507.3 HV0.98 N, and the hardness of the core was 420.6 HV0.98 N.The thickness of the borocarburizing and compound carburizing layers under the optimum parameters was 976 μm and 1 125 μm,respectively.The electrochemical test showed that the corrosion resistance of the material was improved after borocarburizing and boron-carbon compound carburizing,and the corrosion potential was -0.578 V for borocarburizing and -0.582 V for boron-carbon compound carburizing.The wear test showed that the borocarburizing and boron-carbon compound carburizing could significantly improve the wear resistance of 12Cr13 martensitic stainless steel.

Key words: martensitic stainless steel; borocarburizing; boron-carbon compound carburizing; hardness; wear resistance

Cite this article

SHAO Hong-hong, LIU Fan, LI Cheng-long, ZHAO En-xu, YANG Liu, CHENG Xiao-nong . Study on B/C Chemical Heat Treatment of 12Cr13 Martensitic Stainless Steel[J]. Materials Protection, 2023 , 56(3) : 98 -105 . DOI: 10.16577/j.issn.1001-1560.2023.0065

References

[1] 戴起勋,程晓农.金属材料学[M].北京:化学工业出版社,2015.DAI Q X,CHENG X N.Metal Materials [M].Beijing:Chemical Industry Press,2015

[2] DALMAU A,RICHARD C,IGUAL-Muñoz A.Degradation mechanisms in martensitic stainless steels: Wear,corrosion and tribocorrosion appraisal [J].Tribology International,2018,121:167-179.

[3] 邵红红,纪嘉明.金属组织控制技术与设备[M].北京:北京大学出版社,2011.SHAO H H,JI J M.Metal tissue control technology and equipment[M].Beijing: Peking University Press,2011

[4] 刘同华,强文江,王 伟.不锈钢中合金元素的作用及其研究现状[J].热加工工艺,2018(4):17-21.LIU T H,QIANG W J,WANG W.Function and Research Status of Alloying Elements in Stainless Steel [J].Hot Working Process,2018(4): 17-21

[5] ISFAHANY A N,SAGHAFIAN H,BORHANI G.The effect of heat treatment on mechanical properties and corrosion behavior of AISI420 martensitic stainless steel[J].Journal of Alloys and Compounds,2011,509(9):3 931-3 936.

[6] 白 鹤,王伯健.马氏体不锈钢成分、工艺和耐蚀性的进展[J].特殊钢,2009,30(2):30-33.BAI H,WANG B J.Progress in Chemical Composition,Process and Corrosion Resistance of Martensite Stainless Steel [J].Special Steel,2009,30(2): 30-33

[7] 宗晓明,权超健,陈怀刚,等.9Cr18 马氏体不锈钢表面低温渗碳强化技术研究[J].热处理技术与装备,2017,38(3):29-32.ZONG X M,QUAN C J,CHEN H G,et al.Study on Low Temperature Surface Carburizing Technology of 9Cr18 Martensitic Stainless Steel [J].Heat Treatment Technology and Equipment,2017,38 (3): 29-32

[8] 王 浩,宗晓明.马氏体不锈钢表面强化技术研究[J].科技资讯,2017,15(17):94,96.WANG H,ZONG X M.Research on surface strengthening technology of martensitic stainless steel [J].Science and Technology Information,2017,15 (17): 94,96

[9] FRANDSEN R B,CHRISTIANSEN T,SOMERS M A J.Simultaneous surface engineering and bulk hardening of precipitation hardening stainless steel [J].Surface and Coatings Technology,2006,200(16/17): 5 160-5 169.

[10] 高 飞,宗晓明,权超健,等.低温渗碳处理对G95Cr18 马氏体不锈钢组织和性能的影响[J].轴承,2017(5):19-22.GAO F,ZONG X M,QUAN C J,et al.Effect of Low Temperature Carburizing on Microstructure and Properties of G95Cr18 Martensitic Stainless Steel [J].Bearing,2017(5): 19-22

[11] ROVANI A C,BREGANON R ,DE SOUZA G S,et al.Scratch resistance of low-temperature plasma nitrided and carburized martensitic stainless steel [J].Wear,2017,376-377:70-76.

[12] CASTELETTI L C,TAKEYA G S,MARIANI F E,et al.Effect of boronizing on precipitation hardened niobium stainless steel [J].Heat Treatment,2016,31 (4): 42-46

[13] DOKUMACI E,ÖZKAN I,ÖNAY B.Effect of Boronizing on the Cyclic Oxidation of Stainless Steel[J].Surface and Coatings Technology,2013,232:22-25.

[14] 吴晔康,杨海丽,徐 宏,等.熔盐电解法渗硼工艺的优化[J].电镀与精饰,2014,36(11):24-27.WU Y K,YANG H L,XU H,et al.Process Optimization of Boronizing by Molten Salt Electrolysis[J].Electroplating and Finishing,2014,36 (11): 24-27

[15] BINDAL C,UCISIK A H.Characterization of boriding of 0.3%C,0.02%P plain carbon steel[J].Vacuum,2008,82(1):90-94.

[16] 周子年,顾宗涛,王海青.不锈钢的镀铁渗硼[J].金属热处理,1986(5):35-39.ZHOU Z N,GU Z T,WANG H Q.Boronizatiom of ironplating stainless steel [J].Metal Heat Treatment,1986(5): 35-39.

Options
Outlines

/

Total visitors:  Visitors of today:  Now online:
Website Copyright © Editorial Department of Materials Protection
Powered by Beijing Magtech Co. Ltd,.