Effects of Small Ni Addition on the Microstructure and Toughness of Coarse-Grained Heat-Affected Zone of High-Strength Low-Alloy Steel
by
Gang Huang
1, 
Xiangliang Wan
1,*, 
Kaiming Wu
1,*,
Huazhong Zhao
2 and
Raja Devesh Kumarmr Misra
3 
1
The State Key Laboratory of Refractories and Metallurgy, Hubei Province Key Laboratory of Systems Science in Metallurgical Process, International Research Institute for Steel Technology, Wuhan University of Science and Technology, Wuhan 430081, China
2
Wuhan Anchor Welding consumables Co., Ltd., Wuhan 430081, China
3
Department of Metallurgical and Materials Engineering, University of Texas at El Paso, El Paso, TX 79968, USA
*
Authors to whom correspondence should be addressed.
Metals 2018, 8(9), 718; https://doi.org/10.3390/met8090718
Submission received: 14 August 2018
/
Revised: 11 September 2018
/
Accepted: 11 September 2018
/
Published: 13 September 2018
Abstract
:The objective of the present study is to investigate the effects of nickel (Ni) on the microstructure and impact toughness of coarse-grained heat-affected zone (CGHAZ) of high-strength low-alloy steel. It was observed that the microstructure of CGHAZ predominantly consisted of bainite and a small proportion of martensite-austenite (M-A) constituents and acicular ferrite (AF). With increased Ni content, the percentage of M-A constituent decreased and AF increased; consequently, the impact toughness of CGHAZ increased. The study revealed that a small addition of nickel significantly affected the formation of M-A constituents and AF; however, no obvious influence was observed on the bainitic microstructure of high-strength low-alloy steel.
1. Introduction
High-strength low alloy steels (HSLA) are widely used in applications requiring welding because of their high toughness, high strength, cold formability, and good weldability. In recent years, several studies have been carried out using high heat input welding to reduce cost and improve welding efficiency. However, the high heat input welding thermal cycle results in a coarse-grained heat-affected zone (CGHAZ), as well as degradation in the toughness of steels [1]. Therefore, improvement in the toughness of HAZ is an important aspect when high heat input is used.
The toughness of HAZ is strongly influenced by the microstructural features of steels [2]. Coarse bainite in the HAZ of HSLA steel contains parallel bainitic ferrite and martensite-austenite (M-A) constituents [3]. Thus, it is difficult to obtain superior HAZ toughness because of the hard M-A constituents and the low-angle grain boundary between parallel bainitic ferrite, which facilitates nucleation and propagation of cracks. Previous studies have revealed that the microstructural features of HAZ greatly depend on the alloying elements in HSLA steels [4]. Deoxidizing alloying elements, such as titanium and zirconium, provide favorable nucleation sites at grain boundaries for AF during the welding thermal cycle [5]. Some studies have also proposed that niobium, aluminum, and silicon can modify the morphology of M-A constituents [6,7,8].
Nickel (Ni) is generally present as a solid solution strengthening element in ferrite and increases the strength of steel by solid solution strengthening. Ni also has a strong influence on the toughness of weld metals. Previous studies have indicated that with increasing Ni content, the microstructure of the weld metal can be refined [9]. However, when Ni content exceeds a certain value, the toughness of the weld metal is reduced because of the formation of martensite [10]. Superior low-temperature toughness in high-Ni steel can be obtained due to the retained austenite, which absorbs high energy by transformation of the retained austenite to strain-induced martensite during Charpy impact testing [11]. However, an understanding of the effect of Ni on microstructural transformation and impact toughness of CGHAZ of HSLA steels is relatively limited and requires in-depth study.
In the present study, the effect of Ni on microstructural transformation during the welding thermal cycles of HSLA steels was studied, and the underlying toughening mechanism of CGHAZ was also explored.
2. Experimental Procedure
Three steel samples, Ni-free, 0.23% Ni, and 0.43% Ni steel, were prepared in a 10 kg vacuum melt induction furnace (Jinzhou North Electric Furnace Factory, Jinzhou, Liaoning, China) (Table 1). The cylindrical ingots, 120 mm in diameter and 100 mm in length, were reheated to 1250 ± 20 °C and forged into rectangular billets with cross-sections 30 mm × 30 mm. The samples were then machined into dimensions of 11 mm × 11 mm × 100 mm. The simulation of CGHAZ was carried out using a Gleeble 3800 (Dynamic Systems Inc., Austin, TX, USA). A schematic diagram of simulated thermal cycles is presented in Figure 1.The peak temperature, heating rate, and holding time for thermal cycle simulation were 1350 °C, 300 °C/s, and 3 s, respectively. The cooling times from 800 °C to 500 °C (t8/5) were 10.6 s and 52.8 s, respectively, which were approximately equivalent to heat inputs of 20 kJ/cm and 100 kJ/cm, respectively [12,13].
After the simulation, standard Charpy v-notch specimens of dimensions 10 mm × 10 mm × 55 mm were machined for Charpy impact test at −20 °C. The microstructure and fracture surface of the samples were studied by optical microscope (OM, Olympus Corporation, Tokyo, Japan.) and scanning electron microscope (SEM, FEI, Boston, MA, USA). The crystallographic grain size and the grain boundary misorientation were analyzed by electron backscattered diffraction (EBSD, EDAX, New York, NJ, USA) technique. The M-A constituents and AF grains in the digital images of simulated CGHAZ were selected and painted black using Adobe Photoshop (version 6.0, San, Jose, CA, USA) (Figure 2). The length, width, density, and area percentage of M-A constituents and AF grains were estimated using Image-Pro Plus (version 6.0, MEDIA, Rockville, MD, USA). Thirty digital images were analyzed to obtain an average value of the above parameters [12,13].
3. Results
3.1. Microstructural Characteristics of Simulated CGHAZ
Figure 3 shows the optical micrographs of simulated CGHAZ for three steel samples. It was observed that the prior austenite grains became coarse in all the samples. The microstructure of all the samples predominantly consisted of bainite and a small percentage of AF and M-A constituents. The AF grains were scattered among prior austenite grains, and some of them were also associated with inclusions. The bainitic ferrite sheaves nucleated at the grain boundaries and grew into the interior of the grain. Furthermore, the M-A constituents were observed in bainite packets, as well as between the boundaries of bainite packets.
3.2. Quantitative Analysis of Microstructure of Simulated CGHAZ
Prior austenite grain size is crucial for microstructural evolution [14]. The size of prior austenite grains was measured by averaging the long and short axes of the grains. The mean equivalent diameters and standard deviation of prior austenite grains (taken from about 20 optical micrographs at 500× magnification) are presented in Figure 4a. The equivalent diameters of prior austenite grains were in the range of 55–60 μm at 20 kJ/cm heat input welding, and increased to 70–80 μm for 100 kJ/cm. However, no significant change was noticed with increased Ni content (Figure 4a).
AF is one of the most important constituents for improving the toughness of CGHAZ of HSLA steels [3]. The mean length, width, and area percentage of AF was measured (Figure 4b–d). The mean length and width of AF increased with increased Ni content (Figure 4b,c). The area percentage of AF also increased with increased Ni content and heat input (Figure 4d).
Figure 5 shows the SEM images of block-like and film-like M-A constituents in the simulated CGHAZ. It is noted that the size, density, and area percentage of M-A constituents varied with increased Ni content and heat input (Figure 6). The mean length of M-A constituents decreased with increased Ni content (Figure 6a); however, the density of M-A constituents did not change with increased Ni content (Figure 6b). It was observed that the area percentage of M-A constituents also decreased with increased Ni content (Figure 6c). Previous studies reported that M-A constituents with large length (>2 μm and small length/width ratio (<4) were regarded as block M-A constituents, and were detrimental to impact toughness [15]. It is evident from Figure 6d that the area percentage of block M-A constituents decreased with increased Ni content.
3.3. EBSD Analysis and Grain Size Determination of Simulated CGHAZ
Figure 7 presents the EBSD analysis of simulated CGHAZ for 100 kJ/cm heat input welding. Figure 7a–c is the corresponding EBSD orientation image maps of Ni-free, 0.23% Ni, and 0.43% Ni steel, respectively. Different bainite packets are represented by different colors and characterized by high-angle grain boundaries between the packets with large misorientations (50°–60°). The bainitic ferrite laths/plates (for low-angle grain boundaries) in the same bainite packet are represented by similar color. However, it was observed that AF grains grew in the interior of prior austenite grains and had different orientations with the neighboring ferrite plates.
Figure 8a, billustrates the distribution of grain boundary misorientation angles between adjacent grains. The frequency of high-angle grain boundaries (45°–62°) for Ni-free steel was smaller than for 0.23% Ni and 0.43% Ni steels (Figure 8b). In the present study, the high-angle grain boundary threshold was estimated at 15°; hence, grain boundaries with a misorientation larger than 15° were regarded as the boundary of two grains. Grains were assumed to be spherical to facilitate grain size measurement. Figure 8c displays the statistical distribution of crystallographic grain size. The mean crystallographic grain sizes in CGHAZ of Ni-free, 0.23% Ni, and 0.43% Ni steels were calculated as 9.4 μm, 4.9 μm, and 4.4 μm, respectively (Figure 8d), and these values were significantly smaller than those for the prior austenite grains (73 μm, 78 μm, and 80 μm for Ni-free, 0.23% Ni, and 0.43% Ni steels, respectively), implying grain refinement in Ni-containing steels. The percentages of grain refinement in prior austenite grains for 0.23% Ni, 0.43% Ni, and Ni-free steels were ~94% (15.9 times finer), ~95% (18.6 times finer), and ~87% (7.7 times finer), respectively.
3.4. Impact Toughness in the Simulated CGHAZ
The Charpy v-notch impact toughness of CGHAZ for samples with varying heat inputs is presented in Figure 9. It was observed that the average absorbed energy increased with increased Ni content for both heat input welding thermal cycles (20 kJ/cm and 100 kJ/cm). The average absorbed energy for the 20 kJ/cm thermal cycle increased gradually from 94 J to 252 J and from 297 J for 0.23% and 0.43% Ni steels, respectively.
Figure 10 displays the characteristics of impact fracture for all samples with varying Ni content and heat inputs. The fracture surfaces of Ni-free steel exhibited river pattern characteristic of quasi-cleavage fracture (Figure 10a,b). In contrast, the impact fracture surface of 0.23% Ni and 0.43% Ni steels consisted of dimples (Figure 10c–f). Therefore, the difference in the nature of the fracture surface can be attributed to transition in the fracture mechanism from quasi-cleavage to dimple fracture [16].
4. Discussion
4.1. The Effect of Ni Addition on AF Formation and Impact Toughness
AF, also known as intragranular bainite, is the predominant microstructure in the CGHAZ of HSLA steels [3]. The formation of AF is strongly affected by the chemical composition of steel, inclusions, isothermal temperature, continuous cooling rate, and austenite grain size [4]. In the present study, the inclusion content, cooling rate, and prior austenite grain size were similar for three steels. The frequencies of AF grains in 0.23% Ni and 0.43% Ni steels were relatively higher in comparison to Ni-free steel because of the different Ni content. Nickel can also decrease bainite start (Bs) and bainite finish (Bf) transformation temperature in steel [4]. Figure 11a–c shows the continuous cooling curves of three steels for different cooling rates, which were calculated using J-MatPro software. The Bs and Bf temperatures for the samples cooled at a cooling rate of 6 °C/s (similar to 100 kJ/cm heat input simulated welding) were selected (Figure 11d). It was discerned that Bs transformation temperature decreased from 596 °C to 589 °C with increased Ni content. Thus, the higher degree of supercooling induced an increase in Gibbs free energy and nucleation efficiency of AF. A previous study suggested that AF grains grow faster at lower temperatures [17]; hence, the percentage of AF increased with increased Ni content.
AF microstructure with high-angle boundaries can enhance the toughness of HSLA steels by deflecting the propagation of cleavage crack [18]. In the present study, the frequency of AF grains in 0.23% Ni and 0.43% Ni steels was observed to be relatively higher than in Ni-free steel. Moreover, AF effectively refined the prior austenite grains in the CGHAZ. Thus, the formation of high-density AF grains in 0.23% Ni and 0.43% Ni steels contributed to a higher percentage of grain refinement. In addition, the average diameter of crystallographic grains was lower in 0.23% Ni and 0.43% Ni steels than in Ni-free steel. Furthermore, because of the fine-grained microstructure of AF, the cracks were less mobile and their direction of propagation was able to change during the Charpy v-notch impact test [18]. It can therefore be inferred that 0.23% Ni and 0.43% Ni steels possessed higher impact toughness in comparison to Ni-free steel.
4.2. The Effect of Ni Addition on M-A Constituents and Impact Toughness
M-A constituents have a significant influence on the toughness of HAZ [15]. Carbon diffuses into the untransformed austenite in CGHAZ, and these untransformed austenite areas become carbon enriched and are transformed into hard and brittle M-A constituents during continuous cooling [4]. Subsequently, microcracks are easily nucleated at the boundaries between M-A constituents and ferrite matrix. These cracks further propagate into the matrix when the stress concentration exceeds the critical stress of M-A constituents [4]. In the present study, SEM analysis revealed the presence of M-A constituents in bainite matrix (Figure 5). Moreover, the area percentage of M-A constituents decreased with increased Ni content. This finding is not in agreement with the previous result that showed an increase in M-A constituents with increased Ni content in high-strength steel [4]. The calculation of continuous cooling transformation also demonstrated that the temperature gap between Bs and Bf increased from 67 °C to 77 °C (from Ni-free to 0.43% Ni steel) (Figure 11d). Thus, more austenite was transformed into bainitic ferrite and AF. Also, the amount of M-A constituents was lower in 0.23% Ni and 0.43% Ni steels, and thereby contributed to high impact toughness in CGHAZ.
5. Conclusions
- (1)
- The microstructure of simulated CGHAZ in the three steel samples with heat input of 20–100 kJ/cm predominantly consisted of bainite and a small proportion of AF and M-A constituents. Although the small addition of Ni showed no significant effect on bainitic microstructure, it significantly influenced the formation of AF and M-A constituents. The area percentage of AF and M-A constituents in the simulated CGHAZ increased and decreased with increased Ni content, respectively.
- (2)
- The impact toughness of simulated CGHAZ at −20 °C increased with increased Ni content because of the fine-grained microstructure with more AF and fewer M-A constituents.
Author Contributions
K.W. conceived, X.W. and G.H. designed the experiments; G.H. performed the experiments and wrote the manuscript; H.Z. supplied the raw materials and R.D.K.M. revised the grammar of the manuscript.
Funding
The Major Technology Innovation of Hubei Province under grant (No. 2016AAA022); the National Natural Science Foundation of China (No. 51501134); China Postdoctoral Science Foundation (No. 2014M550414).
Acknowledgments
The authors gratefully acknowledge the financial support from the Major Technology Innovation of Hubei Province under grant No. 2016AAA022 and the National Natural Science Foundation of China (No. 51501134) and China Postdoctoral Science Foundation (No. 2014M550414).
Conflicts of Interest
The authors declare no conflict of interest.
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Figure 1.
Schematic illustration of simulated thermal cycles of the CGHAZ.
Figure 2.
(a) Optical and (c) SEM images showing representative acicular ferrite and M-A constituents, respectively, in the simulated CGHAZ of Ni-free steel with 100 kJ/cm heat input welding thermal cycle. (b,d) are processed images of (a,c), respectively, using Adobe Photoshop.
Figure 2.
(a) Optical and (c) SEM images showing representative acicular ferrite and M-A constituents, respectively, in the simulated CGHAZ of Ni-free steel with 100 kJ/cm heat input welding thermal cycle. (b,d) are processed images of (a,c), respectively, using Adobe Photoshop.
Figure 3.
Optical micrographs of simulated CGHAZ in specimens (a,b) Ni-free, (c,d) 0.23% Ni, and (e,f) 0.43% Ni, with heat input of (a,c,e) 20 kJ/cm, and (b,d,f) 100 kJ/cm, respectively.
Figure 3.
Optical micrographs of simulated CGHAZ in specimens (a,b) Ni-free, (c,d) 0.23% Ni, and (e,f) 0.43% Ni, with heat input of (a,c,e) 20 kJ/cm, and (b,d,f) 100 kJ/cm, respectively.
Figure 4.
(a) Prior austenite grain size and (b) mean length, (c) width, and (d) area percentage of acicular ferrite in samples subjected to different heat inputs.
Figure 4.
(a) Prior austenite grain size and (b) mean length, (c) width, and (d) area percentage of acicular ferrite in samples subjected to different heat inputs.
Figure 5.
SEM images of the simulated CGHAZ in (a,b) Ni-free, (c,d) 0.23% Ni, and (e,f) 0.43% Ni steels subjected to the heat input of (a,c,e) 20 kJ/cm and (b,d,f) 100 kJ/cm.
Figure 5.
SEM images of the simulated CGHAZ in (a,b) Ni-free, (c,d) 0.23% Ni, and (e,f) 0.43% Ni steels subjected to the heat input of (a,c,e) 20 kJ/cm and (b,d,f) 100 kJ/cm.
Figure 6.
Effect of nickel content and simulated heat input on (a) mean length, (b) density, and (c) area percentage of M-A constituent, and (d) area percentage of block M-A in the CGHAZ.
Figure 6.
Effect of nickel content and simulated heat input on (a) mean length, (b) density, and (c) area percentage of M-A constituent, and (d) area percentage of block M-A in the CGHAZ.
Figure 7.
Orientation maps of bcc phase of steel samples. (a) Ni-free, (b) 0.23% Ni, and (c) 0.43% Ni; and (d) orientation color key. The simulated heat input for all samples is 100 kJ/cm.
Figure 7.
Orientation maps of bcc phase of steel samples. (a) Ni-free, (b) 0.23% Ni, and (c) 0.43% Ni; and (d) orientation color key. The simulated heat input for all samples is 100 kJ/cm.
Figure 8.
Statistical distribution of (a,b) misorientation between adjacent grains and (c) crystallographic grain size; and (d) mean crystallographic grain size of simulated CGHAZ.
Figure 8.
Statistical distribution of (a,b) misorientation between adjacent grains and (c) crystallographic grain size; and (d) mean crystallographic grain size of simulated CGHAZ.
Figure 9.
Effect of nickel content and simulated heat input on average impact energy at −20 °C in the simulated CGHAZ.
Figure 9.
Effect of nickel content and simulated heat input on average impact energy at −20 °C in the simulated CGHAZ.
Figure 10.
SEM images of impact fracture surface of simulated specimens. (a,b) Ni-free, (c,d) 0.23% Ni and (e,f) 0.43% Ni for heat input of (a,c,e) 20 kJ/cm and (b,d,f) 100 kJ/cm.
Figure 10.
SEM images of impact fracture surface of simulated specimens. (a,b) Ni-free, (c,d) 0.23% Ni and (e,f) 0.43% Ni for heat input of (a,c,e) 20 kJ/cm and (b,d,f) 100 kJ/cm.
Figure 11.
Calculated continuous cooling curves prepared by using J-MatPro for (a) Ni-free, (b) 0.23% Ni and (c) 0.43% Ni steels, and (d) Bs and Bf temperatures of three samples with acooling rate of 6 °C/s. The Fs, Bs, Bf, Ps, Pf, and Ms indicate ferrite start, bainite start, bainite finish, pearlite start, pearlite finish and martensite start transformation temperature, respectively.
Figure 11.
Calculated continuous cooling curves prepared by using J-MatPro for (a) Ni-free, (b) 0.23% Ni and (c) 0.43% Ni steels, and (d) Bs and Bf temperatures of three samples with acooling rate of 6 °C/s. The Fs, Bs, Bf, Ps, Pf, and Ms indicate ferrite start, bainite start, bainite finish, pearlite start, pearlite finish and martensite start transformation temperature, respectively.
Table 1.
The chemical composition of the investigated steels (wt.%).
| Sample | C | Si | Mn | Nb | Ni | Ti | Mo | Al | Fe |
|---|---|---|---|---|---|---|---|---|---|
| Ni-free | 0.054 | 0.19 | 1.56 | 0.038 | - | 0.012 | 0.020 | 0.022 | Bal. |
| 0.23% Ni | 0.056 | 0.20 | 1.58 | 0.036 | 0.23 | 0.015 | 0.019 | 0.025 | Bal. |
| 0.43% Ni | 0.052 | 0.22 | 1.55 | 0.037 | 0.43 | 0.014 | 0.018 | 0.024 | Bal. |
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Huang, G.; Wan, X.; Wu, K.; Zhao, H.; Misra, R.D.K. Effects of Small Ni Addition on the Microstructure and Toughness of Coarse-Grained Heat-Affected Zone of High-Strength Low-Alloy Steel. Metals 2018, 8, 718. https://doi.org/10.3390/met8090718
AMA Style
Huang G, Wan X, Wu K, Zhao H, Misra RDK. Effects of Small Ni Addition on the Microstructure and Toughness of Coarse-Grained Heat-Affected Zone of High-Strength Low-Alloy Steel. Metals. 2018; 8(9):718. https://doi.org/10.3390/met8090718
Chicago/Turabian StyleHuang, Gang, Xiangliang Wan, Kaiming Wu, Huazhong Zhao, and Raja Devesh Kumarmr Misra. 2018. "Effects of Small Ni Addition on the Microstructure and Toughness of Coarse-Grained Heat-Affected Zone of High-Strength Low-Alloy Steel" Metals 8, no. 9: 718. https://doi.org/10.3390/met8090718
APA StyleHuang, G., Wan, X., Wu, K., Zhao, H., & Misra, R. D. K. (2018). Effects of Small Ni Addition on the Microstructure and Toughness of Coarse-Grained Heat-Affected Zone of High-Strength Low-Alloy Steel. Metals, 8(9), 718. https://doi.org/10.3390/met8090718
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