Microstructure and Impact Toughness of Welding Heat-Affected Zones of a Fe-Cr-Ni-Mo High Strength Steel

doi:10.11900/0412.1961.2017.00331

Acta Metall Sin

2018, Vol. 54

Issue (4): 501-511 DOI: 10.11900/0412.1961.2017.00331

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Microstructure and Impact Toughness of Welding Heat-Affected Zones of a Fe-Cr-Ni-Mo High Strength Steel

Mingyue WEN^1,², Wenchao DONG¹, Huiyong PANG³, Shanping LU¹(

)

1 Key Laboratory of Nuclear Materials and Safety Assessment, Institute of Metal Research, Chinese Academy of Sciences, Shenyang 110016, China
2 School of Materials Science and Engineering, University of Science and Technology of China,Shenyang 110016, China
3 Wuyang Iron and Steel Co. Ltd., Pingdingshan 462500, China

Cite this article:

Mingyue WEN, Wenchao DONG, Huiyong PANG, Shanping LU. Microstructure and Impact Toughness of Welding Heat-Affected Zones of a Fe-Cr-Ni-Mo High Strength Steel. Acta Metall Sin, 2018, 54(4): 501-511.

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Abstract

Marine engineering steel is the key material for the construction of major marine infrastructure projects. Due to the harsh environment in the deep sea, the mechanical properties such as strength, low temperature toughness and so on of the marine steel are required to be higher. In this work, the weldability of a Fe-Cr-Ni-Mo high-strength steel was studied, and the microstructure and impact toughness of the steel after welding thermal cycling at different peak temperatures were analyzed. The results show that the average impact toughness of characteristic heat affected zone under different temperatures increases first and then decreases with the increase of peak temperature (T_p). The microstructures of coarse grain heat-affected zone (CGHAZ, T_p=1320 ℃) and fine grain heat-affected zone (FGHAZ, T_p=1020 ℃) are quenched martensite. Because of the coarse grain size, the impact toughness of CGHAZ is poor, which is lower than that of FGHAZ. The microstructure of inter-critical heat-affected zone (ICHAZ, T_p=830 ℃ and T_p=760 ℃) is composed of quenched martensite and tempered martensite. Due to the randomness of the proportion of the interfaces between the mixed microstructures near the V-notch, the impact energy values of ICHAZ fluctuates greatly. The homogeneous fine grain structure in ICHAZ (T_p=830 ℃) has a crack arrest effect during the impact deformation, which makes the characteristic zone have the best impact toughness. Although the grain size in ICHAZ (T_p=760 ℃) is also fine, the existence of the ultra-fine grain zones (the grain size in which is only 1~2 μm) benefits the formation of secondary voids under the impact load. The undissolved M₂C and MC precipitations in matrix promote the connecting of secondary voids and then form the secondary cracks. As a result, the impact toughness of the characteristic zone is poor, and becomes the weak region of HAZ.

Key words: Fe-Cr-Ni-Mo high strength steel welding heat affected zone impact toughness microstructure

Received: 02 August 2017

ZTFLH:

TG401

Fund: Supported by National Key Research and Development Program of China (No.2016YFB0300601) and Key Programs of Chinese Academy of Sciences (No.GFZD-125-15-003-1)

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	Mingyue WEN
	Wenchao DONG
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	Shanping LU

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https://www.ams.org.cn/EN/10.11900/0412.1961.2017.00331 OR https://www.ams.org.cn/EN/Y2018/V54/I4/501

Fig.1 Typical thermal cycle curves of characteristic regions in HAZs (HAZ—heat-affected zone, CGHAZ—coarse grain heat-affected zone, FGHAZ—fine grain heat-affected zone, ICHAZ—inter-critical heat-affected zone)

Fig.2 Charpy-V notch impact energy of characteristic regions in HAZs under different temperatures (T_p—peak temperature)

Fig.3 Impact load-displacement curves of ICHAZ at 0 ℃ (a) T_p=760 ℃ (b) T_p=830 ℃

Table 1 Iniation energy (E_i), propagation energy (E_p) and total energy (E_t) of ICHAZ samples during instrumental impact test at 0 ℃

Fig.4 Relationship between heating rate and austenite transition temperatures A₁ and A₃ under welding state (A₁—austenite transformation starting temperature, A₃—austenite transformation finishing temperature)

Fig.5 OM images of microstructures (a1~a4) and morphologies of primary austenite grain boundaries (b1~b4) for CGHAZ (a1, b1), FGHAZ (a2, b2), ICHAZ (T_p=830 ℃) (a3, b3) and ICHAZ (T_p=760 ℃) (a4, b4)

Fig.6 SEM images of CGHAZ (a), FGHAZ (b), ICHAZ (T_p=830 ℃) (c) and ICHAZ (T_p=760 ℃) (d)

Table 2 Vicker hardness of different microstructures in ICHAZ (HV_0.1)

Fig.7 EBSD image of ICHAZ (T_p=760 ℃, UFGs—ultra-fine grains, UFGs zone shows UFGs (with the grains size between 1~2 μm) density distribution in this zone)

Fig.8 Distributions of secondary cracks on the fracture longitudinal section of ICHAZ impact sample at -20 ℃ (A—type I crack propagating along the interior of the microstructure; B—type II crack propagating along the boundary of the microstructure)(a~c) T_p=760 ℃, impact absorbed energy 29 J(d~f) T_p=830 ℃, impact absorbed energy 121 J

Fig.9 Relationship between percentage of two types of secondary cracks and impact absorbed energy in ICHAZ impact sample at T_p=760 ℃ (a) and T_p=830 ℃ (b)

Fig.10 Impact fracture morphologies of ICHAZ samples at crack initiation zone (a1, b1) and crack propagation zone (a2, b2) (A—secondary crack formed by void coalescence; B—dimple formed by void coalescence; C—ductile tearing ridge)(a1, a2) T_p=830 ℃, impact absorbed energy 121 J(b1, b2) T_p=760 ℃, impact absorbed energy 29 J

Fig.11 Bright-field TEM images of ICHAZ samples at T_p=760 ℃ (a) and T_p=830 ℃ (b)

Fig.12 TEM image (a) and SAED patterns of M₂C (b) and MC (c) phases of ICHAZ (T_p=760 ℃) sample under HAADF-STEM mode

Fig.13 Schematics of propatation process of secondary void for ICHAZ samples(a1) secondary voids formed in ICHAZ (T_p=760 ℃)(a2) micro-cracks formed through the carbides between the secondary voids in ICHAZ (T_p=760 ℃)(a3) secondary void connect to the secondary cracks in ICHAZ (T_p=760 ℃)(a4) impact fracture morphology of ICHAZ (T_p=760 ℃)(b1) secondary voids formed in ICHAZ (T_p=830 ℃)(b2) secondary voids grown-up into voids in ICHAZ (T_p=830 ℃)(b3) dimples formed by the connect voids in ICHAZ (T_p=830 ℃)(b4) impact fracture morphology of ICHAZ (T_p=830 ℃)

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