Effect of High Temperature Ageing on Microstructure and Stress-Relief Cracking Susceptibility of Coarse Grain Heat Affected Zone in T23 steel

doi:10.11900/0412.1961.2020.00331

Acta Metall Sin

2021, Vol. 57

Issue (6): 736-748 DOI: 10.11900/0412.1961.2020.00331

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Effect of High Temperature Ageing on Microstructure and Stress-Relief Cracking Susceptibility of Coarse Grain Heat Affected Zone in T23 steel

WANG Xue¹^,²(

), LI Yong²^,³, WANG Jiaqing³, HU Lei¹

^1.Key Laboratory of Green Fabrication and Surface Technology of Advanced Metal Materials, Ministry of Education, Anhui University of Technology, Ma'anshan 243032, China
^2.School of Power and Mechanics, Wuhan University, Wuhan 430072, China
^3.Da Tang Boiler Pressure Vessel Inspection Center Co. , Ltd. , Hefei 230088, China

Cite this article:

WANG Xue, LI Yong, WANG Jiaqing, HU Lei. Effect of High Temperature Ageing on Microstructure and Stress-Relief Cracking Susceptibility of Coarse Grain Heat Affected Zone in T23 steel. Acta Metall Sin, 2021, 57(6): 736-748.

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Abstract

Owing to its high creep rupture strength, good weldability, and low costs, T23 steel is an ideal material for manufacturing the heating components of water walls, superheaters and reheaters in ultra-super critical plants. However, its coarse grain heat affected zone (CGHAZ) is prone to stress-relief cracking (SRC) during post-weld heat treatment or high-temperature service. The mechanism of SRC is controversial and an effective method for forecasting and preventing SRC in T23 components is currently lacking. Clarifying the mechanism of SRC in the CGHAZ of T23 steel, and developing a practical engineering technique for predicting and preventing SRC generation, are therefore essential. In this work, CGHAZ specimens of T23 steel were simulated in a thermo-mechanical simulator, and aged at 650^oC for 0-48 h. After simulating the microstructure evolution of the as-welded CGHAZ during service, the SRC susceptibility of the CGHAZ was evaluated. The microstructural changes and carbide precipitation were observed by OM, SEM, TEM, and EDS. The as-welded CGHAZ of T23 steel was composed of mixed martensite and bainite with high hardness. After ageing at 650^oC, the structure recovered and recrystallized with a lower dislocation density and larger sub-grains than the as-welded CGHAZ. Carbides such as M₂₃C₆, M₇C₃, and MX gradually precipitated inside the grains and grain boundaries, decreasing the hardness. The SRC susceptibility was high in the as-welded CGHAZ, but decreased with increasing ageing time. When the ageing time exceeded 24 h, the sample was SRC-resistant. The main cause of SRC in the CGHAZ was precipitation and growth of M₂₃C₆ on the grain boundaries, which induced the formation of softened zones in the matrix near the grain boundary, and promoted the formation of micro-voids. During ageing, the unstable microstructure in the as-welded CGHAZ transformed as carbides precipitated and the matrix recrystallized, thereby reducing the intragranular strength. Meanwhile, the depletion of alloy elements near the grain boundary was eliminated. The microstructural evolution decreased the difference between the intragranular and intergranular strengths in the CGHAZ. Finally, the CGHAZ showed significantly improved ductility and low SRC susceptibility. The hardness of the aged CGHAZ was positively related to the SRC susceptibility. At hardnesses above 250 HB, the CGHAZ was SRC-susceptible, but at hardnesses below 250 HB, the CGHAZ was SRC-resistant.

Key words: T23 steel coarse grain heat affected-zone ageing stress-relief cracking

Received: 27 August 2020

ZTFLH:

TG404

Fund: National Natural Science Foundation of China(51574181);Sichuan Science and Technology Program(2018JY0668)

About author: WANG Xue, professor, Tel: 13554693820, E-mail: wangxue2011@whu.edu.cn

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https://www.ams.org.cn/EN/10.11900/0412.1961.2020.00331 OR https://www.ams.org.cn/EN/Y2021/V57/I6/736

Fig.1 Schematic illustration of the sample (unit: mm) for stress-relief cracking susceptibility evaluation (a) and thermal cycle curves (b) (t_p/8—cooling time from peak temperature to 800^oC, t_8/5—cooling time from 800^oC to 500^oC, t_5/3—cooling time from 500^oC to 300^oC)

Fig.2 OM images of coarse grain heat affected zone (CGHAZ) in T23 steel samples in as-welded condition (a), aged at 650^oC for 6 h (b), 24 h (c), and 48 h (d)

Fig.3 SEM images of CGHAZ in T23 steel samples in as-welded condition (a), aged at 650^oC for 6 h (b), 24 h (c), and 48 h (d) (M-A—martensite-austenite)

Fig.4 TEM images of CGHAZ in T23 steel samples as aged at 650^oC for 6 h (a, b), 24 h (c, d), and 48 h (e, f) (Insets show the corresponding EDS results of the carbides in the circles)

Fig.5 Hardnesses of CGHAZ in T23 steel samples in as-welded condition and aged at 650^oC for different time

Fig.6 Reduction of area vs test temperature of CGHAZ in T23 steel samples

Fig.7 Fracture surfaces at 750^oC of CGHAZ in T23 steel samples in as-welded condition (a), aged at 650^oC for 6 h (b), 24 h (c), and 48 h (d) (Insets in Figs.7a and d are corresponding high magnified images of fracture surface)

Fig.8 Longitudinal section views of CGHAZ in T23 steel samples fractured at 750^oC (Insets in Figs.8b and d show the high magnified images of grain boundaries with void)

Fig.9 TEM images of CGHAZ in T23 steel samples fractured at 750^oC

Fig.10 TEM image (a) and typical EDS line scans (b) done across prior austenite grain boundaries in fracture samples of as-welded CGHAZ of T23 steel sample tested at 750^oC

Fig.11 TEM image (a) and typical EDS line scans (b) done across prior austenite grain boundaries in fracture samples of CGHAZ of T23 steel aged at 650^oC for 48 h tested at 750^oC

Fig.12 Illustration of fracture mechanism of as-welded (a) and aged (b) CGHAZ (PAGB—prior austenite grain boundary)

Table 1 Equivalent heat exposure conditions of CGHAZs of T23 steels aged at 650^oC for different time

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