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The effects of postweld heat treatment and isothermal aging on T92 steel heat-affected zone mechanical properties of T92/TP316H dissimilar weldments

Published online by Cambridge University Press:  12 April 2016

Ladislav Falat*
Affiliation:
Institute of Materials Research, Slovak Academy of Sciences, SK 040 01 Košice, Slovak Republic
Ján Kepič
Affiliation:
Institute of Materials Research, Slovak Academy of Sciences, SK 040 01 Košice, Slovak Republic
Lucia Čiripová
Affiliation:
Institute of Materials Research, Slovak Academy of Sciences, SK 040 01 Košice, Slovak Republic
Peter Ševc
Affiliation:
Institute of Materials Research, Slovak Academy of Sciences, SK 040 01 Košice, Slovak Republic
Ivo Dlouhý
Affiliation:
Institute of Physics of Materials, Academy of Sciences of the Czech Republic, CZ 616 62 Brno, Czech Republic
*
a)Address all correspondence to this author. e-mail: [email protected]
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Abstract

Cross-weld hardness profile, notch-tensile strength, and impact toughness of T92 steel heat-affected zone (T92 HAZ) of dissimilar T92/TP316H welds were studied in dependence of their postweld heat treatment (PWHT) and subsequent long-term aging. Two weldments series were individually subjected to either “single-step” tempering PWHT or a modified “two-step” renormalizing and tempering PWHT. Subsequently, the welds were isothermally aged at 625 °C for durations from 500 up to 11,000 h. The “single-step” PWHT preserved sharp hardness gradient of T92 HAZ, whereas the “two-step” PWHT led to the hardness values equalization. The T92 HAZ of the weldment after the “two-step” PWHT exhibited initially lower strength and higher toughness, compared to the weldment after the “single-step” PWHT. However, after long-term aging a more suitable combination of T92 HAZ mechanical properties i.e., the higher toughness and acceptable strength exhibited the weldments processed by “single-step” PWHT.

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Articles
Copyright
Copyright © Materials Research Society 2016 

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References

REFERENCES

Anand, R., Sudha, C., Karthikeyan, T., Terrance, A.L.E., Saroja, S., and Vijayalakshmi, M.: Effectiveness of Ni-based diffusion barriers in preventing hard zone formation in ferritic steel joints. J. Mater. Sci. 44, 257 (2009).Google Scholar
Silwal, B., Li, L., Deceuster, A., and Griffiths, B.: Effect of postweld heat treatment on the toughness of heat-affected zone for grade 91 steel. Weld. J. 92, 80 (2013).Google Scholar
Zhao, L., Jing, H., Xu, L., An, J., Xiao, G., Xu, D., Chen, Y., and Han, Y.: Investigation on mechanism of type IV cracking in P92 steel at 650 °C. J. Mater. Res. 26, 934 (2011).Google Scholar
Abson, D.J. and Rothwell, J.S.: Review of type IV cracking of weldments in 9–12% Cr creep strength enhanced ferritic steels. Int. Mater. Rev. 58, 437 (2013).Google Scholar
Abe, F., Tabuchi, M., Tsukamoto, S., and Shirane, T.: Microstructure evolution in HAZ and suppression of Type IV fracture in advanced ferritic power plant steels. Int. J. Pressure Vessels Piping 87, 598 (2010).CrossRefGoogle Scholar
Dudova, N. and Kaibyshev, R.: Effect of boron on microstructure and impact toughness of a 10% Cr martensitic steel. Mater. Sci. Forum 706–709, 847 (2012).Google Scholar
Baumgartner, S., Posch, G., and Mayr, P.: Welding advanced martensitic creep-resistant steels with boron containing filler metal. Weld. J. 56, 2 (2012).Google Scholar
Widak, V., Dafferner, B., Heger, S., and Rieth, M.: Investigations of dissimilar welds of the high temperature steels P91 and PM2000. Fusion Eng. Des. 88, 2539 (2013).Google Scholar
Rieth, M. and Rey, J.: Specific welds for test blanket modules. J. Nucl. Mater. 386–388, 471 (2009).Google Scholar
Falat, L., Výrostková, A., Svoboda, M., and Milkovič, O.: The influence of PWHT regime on microstructure and creep rupture behaviour of dissimilar T92/TP316H ferritic/austenitic welded joints with Ni-based filler metal. Kovove Mater. 49, 417 (2011).Google Scholar
Falat, L., Čiripová, L., Kepič, J., Buršík, J., and Podstranská, I.: Correlation between microstructure and creep performance of martensitic/austenitic transition weldment in dependence of its post-weld heat treatment. Eng. Failure Anal. 40, 141 (2014).Google Scholar
Homolová, V., Kroupa, A., and Výrostková, A.: Calculation of Fe–B–V ternary phase diagram. J. Alloys Compd. 520, 30 (2012).Google Scholar
Stratil, L., Hadraba, H., Buršík, J., and Dlouhý, I.: Comparison of microstructural properties and Charpy impact behaviour between different plates of the eurofer97 steel and effect of isothermal ageing. J. Nucl. Mater. 416, 311 (2011).Google Scholar
Hald, J.: Microstructure and long-term creep properties of 9–12% Cr steels. Int. J. Pressure Vessels Piping 85, 30 (2008).Google Scholar
Cui, J., Kim, I-S., Kang, C-Y., and Miyahara, K.: Creep stress effect on the precipitation behavior of Laves-phase in Fe–10% Cr–6% W alloys. ISIJ Int. 41, 368 (2001).Google Scholar
Zhao, L., Jing, H., Xu, L., Han, Y., and Xiu, J.: Experimental study on creep damage evolution process of type IV cracking in 9Cr–0.5Mo–1.8W–VNb steel welded joint. Eng. Failure Anal. 19, 22 (2012).Google Scholar
Zhu, M-L., Wang, D-Q., and Xuan, F-Z.: Effect of long-term aging on microstructure and local behavior in the heat-affected zone of a Ni–Cr–Mo–V steel welded joint. Mater. Charact. 87, 45 (2014).Google Scholar
Abe, F., Horiuchi, T., Taneike, M., and Sawada, K.: Stabilization of martensitic microstructure in advanced 9Cr steel during creep at high temperature. Mater. Sci. Eng., A 378, 299 (2004).Google Scholar
Hu, X., Huang, L., Yan, W., Wang, W., Sha, W., Shan, Y., and Yang, K.: Evolution of microstructure and changes of mechanical properties of CLAM steel after long-term aging. Mater. Sci. Eng., A 586, 253 (2013).CrossRefGoogle Scholar
Kipelova, A., Belyakov, A., and Kaibyshev, R.: Laves phase evolution in a modified P911 heat resistant steel during creep at 923 K. Mater. Sci. Eng., A 532, 71 (2012).Google Scholar
Abe, F.: Effect of fine precipitation and subsequent coarsening of Fe2W Laves phase on the creep deformation behavior of tempered martensitic 9Cr–W steels. Metall. Mater. Trans. A 36, 321 (2005).Google Scholar
Dudova, N., Plotnikova, A., Molodov, D., Belyakov, A., and Kaibyshev, R.: Structural changes of tempered martensitic 9% Cr–2% W–3% Co steel during creep at 650 °C. Mater. Sci. Eng., A 534, 632 (2012).Google Scholar
Dimmler, G., Weinert, P., Kozeschnik, E., and Cerjak, H.: Quantification of the Laves phase in advanced 9–12% Cr steels using a standard SEM. Mater. Charact. 51, 341 (2003).Google Scholar
Ghassemi-Armaki, H., Chen, R.P., Maruyama, K., Yoshizawa, M., and Igarashi, M.: Static recovery of tempered lath martensite microstructures during long-term aging in 9–12% Cr heat resistant steels. Mater. Lett. 63, 2423 (2009).Google Scholar
Yan, P., Liu, Z., Bao, H., Weng, Y., and Liu, W.: Effect of microstructural evolution on high-temperature strength of 9Cr–3W–3Co martensitic heat resistant steel under different aging conditions. Mater. Sci. Eng., A 588, 22 (2013).Google Scholar
Cao, J., Gong, Y., Yang, Z-G., Luo, X-M., Gu, F-M., and Hu, Z-F.: Creep fracture behavior of dissimilar weld joints between T92 martensitic and HR3C austenitic steels. Int. J. Pressure Vessels Piping 88, 94 (2011).Google Scholar
Jiang, J., Zhu, L., and Wang, Y.: Hardness variation in P92 heat-resistant steel based on microstructural evolution during creep. Steel Res. Int. 84, 732 (2013).Google Scholar
Chen, G., Zhang, Q., Liu, J., Wang, J., Yu, X., Hua, J., Bai, X., Zhang, T., Zhang, J., and Tang, W.: Microstructures and mechanical properties of T92/super304H dissimilar steel weld joints after high-temperature ageing. Mater. Des. 44, 469 (2013).Google Scholar
Jang, J-I., Shim, S., Komazaki, S-I., and Honda, T.: A nanoindentation study on grain-boundary contributions to strengthening and aging degradation mechanisms in advanced 12Cr ferritic steel. J. Mater. Res. 22, 175 (2007).Google Scholar
Gao, Q., Liu, Y., Di, X., Yu, L., and Yan, Z.: Martensite transformation in the modified high Cr ferritic heat-resistant steel during continuous cooling. J. Mater. Res. 27, 2779 (2012).Google Scholar
Moitra, A., Parameswaran, P., Sreenivasan, P.R., and Mannan, S.L.: A toughness study of the weld heat-affected zone of a 9Cr–1Mo steel. Mater. Charact. 48, 55 (2002).Google Scholar
Lomozik, M., Zeman, M., and Jachym, R.: Cracking of welded joints made of steel X10CrMoVNb9-1 (T91)—Case study. Kovove Mater. 50, 285 (2012).Google Scholar
Meng, D., Lu, F., Cui, H., Ding, Y., Tang, X., and Huo, X.: Investigation on creep behavior of welded joint of advanced 9%Cr steels. J. Mater. Res. 30, 197 (2015).Google Scholar
Pluvinage, G., Azari, Z., Kadi, N., Dlouhý, I., and Kozak, V.: Effect of ferritic microstructure on local damage zone distance associated with fracture near notch. Theor. Appl. Fract. Mech. 31, 149 (1999).Google Scholar
Hadraba, H., Nemec, O., and Dlouhý, I.: Conversion of transgranular to intergranular fracture in NiCr steels. Eng. Frac. Mech. 75(12), 3677 (2008).CrossRefGoogle Scholar
Janovec, J.: Nature of Alloy Steel Intergranular Embrittlement (VEDA, Bratislava, Slovakia, 1999); p. 119.Google Scholar