Evolution Behavior of Inclusions in Rare Earth Metal Alloying Oil Casing Steel During Refining and Casting and Hot-Rolling Process

doi:10.11900/0412.1961.2024.00269

Acta Metall Sin

2026, Vol. 62

Issue (4): 611-626 DOI: 10.11900/0412.1961.2024.00269

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Evolution Behavior of Inclusions in Rare Earth Metal Alloying Oil Casing Steel During Refining and Casting and Hot-Rolling Process

LIANG Yuyu¹^,², NI Peiyuan¹^,²(

), LIU Qilin³, LI Ying¹^,²

^1.Key Laboratory for Ecological Metallurgy of MultiMetallic Mineral (Ministry of Education), School of Metallurgy, Northeastern University, Shenyang 110819, China
^2.Liaoning Key Laboratory of Metallurgical Sensor Materials and Technology, School of Metallurgy, Northeastern University, Shenyang 110819, China
^3.Baoshan Iron & Steel Co. Ltd. , Shanghai 201900, China

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LIANG Yuyu, NI Peiyuan, LIU Qilin, LI Ying. Evolution Behavior of Inclusions in Rare Earth Metal Alloying Oil Casing Steel During Refining and Casting and Hot-Rolling Process. Acta Metall Sin, 2026, 62(4): 611-626.

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Abstract

Oil casing steel plays a critical role in the oil and natural gas industry, and its performance is significantly influenced by non-metallic inclusions. Rare earth (RE) elements can effectively modify these inclusions. In this study, industrial experiments were conducted to investigate the effects of rare earth metal alloying on inclusion characteristics during the refining, continuous casting, and hot-rolling processes. The evolution of inclusion morphology, quantity, and size was analyzed using SEM-EDS, FactSage 8.3 thermodynamic software, and an OTS One Bond inclusion analysis system. Results show that when the rare earth content was 4 × 10^-6, the total oxygen content decreased to 7 × 10^-6. In addition, rare earth microalloying transformed Ca-Al-O inclusions into Ca-RE-Al-O inclusions. Following alloying, the inclusion number density in continuous casting billet samples increased from 44 mm^-2 to 46 mm^-2, with the number density of 0-2 μm inclusions rising from 13 mm^-2 to 18 mm^-2, while the number density of 5-30 μm inclusions fell from 7 mm^-2 to 5 mm^-2. Overall, the average inclusion size decreased after rare earth metal addition. XRD and XRF analyses revealed the formation of rare earth phases in the refined slag after vacuum degassing rare earth alloying. Thermodynamic calculations indicate that at 1600 ^oC, the Gibbs formation energies of CaO and CeAlO₃ in steel were -357088.82 and -86892.89 J/mol, respectively, supporting the formation of these inclusions upon rare earth addition. In RE-free furnaces, both thermodynamic calculations and experimental results showed that CaS inclusions formed during solidification, with CaS precipitating around the edges of Ca-Al-O/Ca-RE-Al-O inclusions. In RE-containing furnaces, the addition of rare earth reduced the precipitation of calcium aluminate inclusions, leading instead to the formation of CaO·REAlO₃ inclusions, which likely serve as nucleation sites for CaS precipitation during solidification. During hot-rolling, long strip inclusions were observed in steel without rare earth; however, rare earth alloying improved the deformation ability of inclusions, preventing the formation of long strips due to inclusion crushing. Notably, the modifications induced by rare earth were independent of the inclusions’ Ca content. In hot rolled tube samples without rare earth, only inclusions with moderate Ca content exhibited good deformability. The low yield of rare earth metal was primarily attributed to reactions between the molten steel and refining slag, as well as the removal of rare earth inclusions from the molten steel to the slag.

Key words: oil casing steel rare earth metal alloying non-metallic inclusion thermodynamic calculation

Received: 03 August 2024

ZTFLH:

TF769.9

Fund: National Natural Science Foundation of China(52374333);Fundamental Research Funds for the Central Universities(N2325010);Liaoning Revitalization Talents Program(XLYC2203169)

Corresponding Authors: NI Peiyuan, professor, Tel: 15640417628, E-mail: nipeiyuan@smm.neu.edu.cn

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https://www.ams.org.cn/EN/10.11900/0412.1961.2024.00269 OR https://www.ams.org.cn/EN/Y2026/V62/I4/611

Fig.1 Schematics of production process and sampling process of oil casing steel
(a) RE-free furnace (RE—rare earth, RF2—vacuum degassing (VD) calcium treatment of RE-free steel, RF5—casting billet of RE-free steel, RF6—hot rolled tube blank of RE-free steel)
(b) RE furnace (R1—ladle furnace (LF) RE alloying of RE steel, R2—VD calcium treatment of RE steel, R3—VD RE alloying of RE steel, R4—tundish sample of ladle with 80 t of RE steel, R5—casting billet of RE steel, R6—hot rolled tube blank of RE steel)

Fig.2 Schematic of sample processing in refining stage (unit: mm)

Table 1 Chemical compositions of oil casing steel without and with RE addition

Fig.3 Schematic of hot rolled tube blank sample (RD—rolling direction, ND—normal direction, TD—transverse direction. unit: mm)

Fig.4 Changes of element content in refining and casting processes

Fig.5 Typical SEM images, EDS analysis results, and schematics of morphology of inclusions in RE-free steel casting billet sample (w_t—mass fraction) (a-d) SEM images and corresponding EDS point scanning results (e-h) SEM images and corresponding EDS element mapping analyses of square regions, and corresponding schematics of inclusion morphologies

Fig.6 Typical SEM images, EDS analysis results, and schematics of morphology of inclusions in RE steel casting billet sample (a-d) SEM images and corresponding EDS point scanning results (e-h) SEM images and corresponding EDS element mapping analyses of square regions, and corresponding schematics of inclusion morphologies

Fig.7 Schematics of the distribution of inclusion type in refining and continuous casting process
(a) R1 (b) RF2 (c) R3 (d) R4 (e) R5 (f) RF5

Fig.8 Number densities of inclusions with different sizes
(a) inclusions of RE steel refining and casting sample
(b) inclusions of RE-free steel and RE steel at VD and ingot samples

Fig.9 Typical SEM images and EDS analysis results of inclusions along RD for RE-free steel (a-e) and RE steel (f-j) in the hot rolled tube blank samples
(a-c, f-h) SEM images and corresponding EDS point scanning results (d, e, i, j) SEM images and corresponding EDS element mapping analyses

Fig.10 Typical SEM images and EDS analysis results of inclusions along TD for RE-free steel (a-d) and RE steel (e-h) in the hot rolled tube blank samples
(a, b, e, f) SEM images and corresponding EDS point scanning results (c, d, g, h) SEM images and corresponding EDS element mapping analyses

Fig.11 Typical SEM images and EDS analysis results of inclusions along ND for RE-free steel (a-d) and RE steel (e-h) in the hot rolled tube blank samples
(a, b, e, f) SEM images and corresponding EDS point scanning results (c, d, g, h) SEM images and corresponding EDS element mapping analyses

Table 2 XRF results of LF slag sample before RE addition, LF slag sample after RE addition, and VD slag sample after RE addition

Fig.12 XRD patterns of LF slag sample before RE addition (a), LF slag sample after RE addition (b), and VD slag sample after RE addition (c)

Fig.13 Thermodynamic calculation results of inclusion precipitation during cooling process in RE-free steel (a) and RE steel (b)

Fig.14 Thermodynamic calculation results of inclusion equilibrium composition with different Ce contents at 1600 ^oC (Insets show the SEM images of Ca-Al-O and Ca-RE-Al-O inclusions)

Fig.15 SEM images showing the deformation behaviors of inclusions with different Ca contents and EDS analysis of hot rolled tube blank in RE-free steel and RE steel
(a1-a3) RE-free steel with low Ca content (< 12%), along RD (a1), TD (a2), and ND (a3) (b1-b3) RE-free steel with medium Ca content (12%-21%), along RD (b1), TD (b2), and ND (b3) (c1-c3) RE-free steel with high Ca content (> 21%), along RD (c1), TD (c2), and ND (c3) (d1-d3) RE steel with no Ca content limit, along RD (d1), TD (d2), and ND (d3)

Table 3 Physical and mechanical properties of matrix and oxide inclusions^[24,25]

Fig.16 Schematic of rare earth modified inclusions and inclusion formation during cooling and rolling process

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