Microstructure and Performance of AISI304 /Mild Steel Vacuum Diffusion Bonded Joint

被引：1

作者：

Huang X.-Q. ^{[1
]}

Wang D.-W. ^{[1
]}

Xiu S.-C. ^{[1
]}

机构：

[1] School of Mechanical Engineering & Automation, Northeastern University, Shenyang

来源：

Dongbei Daxue Xuebao/Journal of Northeastern University | 2017年 / 38卷 / 12期

关键词：

Austenitic stainless steel; Microstructure; Mild steel; Property; Vacuum diffusion welding;

D O I：

10.12068/j.issn.1005-3026.2017.12.019

中图分类号：

学科分类号：

摘要：

The vacuum diffusion bonding technology is used to connect the AISI304 austenitic stainless steel and low carbon steel dissimilar materials. Under the condition of constant temperature and pressure, the influence of the bonding time on the microstructure and properties of the AISI 304 austenitic stainless steel and low carbon steel bonded joint was studied. The results show that a good diffusion bonding between the mentioned two materials can be acquired with 850℃ bonding temperature, 10 MPa bonding pressure, and 60 min bonding time. Also with these parameters, the strength and toughness are higher than the low carbon steel base material level, that the tensile strength reaches 440 MPa at the bonding joint, and the tensile fracture occurs at the low carbon steel side. In high temperature environment, carbide segregation phase (Cr23C6) appears at the interface, decreasing the interfacial toughness. Longer bonding time can effectively prevent the precipitation of harmful compounds Cr23C6, and enhance the impact toughness up to 120.5 J/cm2. With this condition, the impact fracture occurs in low carbon steel side. © 2017, Editorial Department of Journal of Northeastern University. All right reserved.

引用

页码：1759 / 1763

页数：4

共 10 条

[1] Atasoy E., Kahraman N., Diffusion bonding of commercially pure titanium to low carbon steel using a silver interlayer, Materials Characterization, 59, 10, pp. 1481-1490, (2008)
[2] Wang D.S., Ziyua Q., Cladding of stainless steel on aluminum and carbon steel by interlayer diffusion bonding, Scripta Materialia, 56, 1, pp. 369-372, (2007)
[3] Allabhakshi S., Madhusudhan R.G., Studies on weld overlaying of austenitic stainless steel with ferritic stainless steel, National Welding Conference, pp. 8-10, (2002)
[4] Omar A., Effects of welding parameters on hard zone formation at dissimilar metal welds, Welding Journal, 77, 2, pp. 86-89, (1988)
[5] Huang Y.L., Kinsella B., Becker T., Sensitization identification of stainless steel to intergranular stress corrosion cracking by atomic force microscopy, Materials Letters, 12, 13, pp. 1863-1866, (2007)
[6] Chowdhuary S.G., Singh R., The influence of recrystallized structure and texture on the sensitization behaviour of a stable austenitic stainless steel, Scripta Materialia, 58, 12, pp. 1102-1105, (2008)
[7] Kina A.Y., Souza V.M., Tavares S.S., Microstructure and intergranular corrosion resistance evaluation of AISI304 steel for high temperature services, Materials Characterization, 59, 5, pp. 651-655, (2008)
[8] Boeuf A., Caciuffo R.G.M., Coppola R., Et al., Study of the M<sub>23</sub>C<sub>6</sub> precipitation at 550℃ and 700℃ in AISI304 stainless steel by small angle neutron scattering, Journal of Nuclear Materials, 126, 3, pp. 276-284, (1984)
[9] Little R.E., Jebe E.H., Statistical Design of Fatigue Experiments, pp. 61-80, (1975)
[10] Bobet A., The initiation of secondary cracks in compression, Engineering Fracture Mechanics, 66, 2, pp. 187-219, (2000)

← 1 →