Effect of Rare Earth and Cooling Process on Microstructure and Mechanical Properties of an Ultra-Cleaned X80 Pipeline Steel

doi:10.1007/s40195-020-01151-8

Abstract

Abstract:

In order to explore the effect of a small amount of rare earth addition in ultra-cleaned pipeline steel and the influence of the cooling process on the tensile and impact properties, three API X80 pipeline steels were fabricated by varying RE addition and the cooling process at the same time. Three microstructures with different features for a low C high Nb microalloyed high-strength pipeline steel and the corresponding mechanical properties were investigated. The results showed that even in the ultra-cleaned steel with O and S contents less than 10 ppm, the addition of RE would still cause an increase in the volume fraction of inclusions consisting of complicated RE oxysulfide and RE sulfide. More inclusions formed in the 112 ppm RE steel were harmful to the low temperature toughness, while few inclusions formed in the 47 ppm RE steel had almost no influence on the low temperature toughness. The two RE additions had no effect on strength of the steels. As the finishing cooling temperature was increased and the cooling rate was decreased within a certain range, the volume fractions of polygonal ferrite and quasi-polygonal ferrite as well as the number density and size of martensite-austenite islands were increased. Under such combined effect, the strength of the steels had almost no change. As the finishing cooling temperature was increased from 481 to 584 °C and the cooling rate was reduced from 20 to 13 °C/s, for the steel with 112 ppm addition of RE, there was an obvious decrease in the low temperature toughness. The reduced value (about 33 J) of the USE of steel consisted of two parts including the influence (about 18 J) of more inclusions formed due to 112 ppm addition of RE and the effect (about 15 J) of the lower high-angle grain boundaries.

Key words: Low temperature toughness, Cooling process, High-angle grain boundaries (HAGBs), Ductile-brittle transition temperature (DBTT), Rare earth, Inclusions

He Duan, Yi-Yin Shan, Ke Yang, Xian-Bo Shi, Wei Yan, Yi Ren. Effect of Rare Earth and Cooling Process on Microstructure and Mechanical Properties of an Ultra-Cleaned X80 Pipeline Steel[J]. Acta Metallurgica Sinica (English Letters), 2021, 34(5): 639-648.

Figures/Tables 14

Table 1 Chemical compositions of the experimental steels

No.	C (wt%)	Si (wt%)	Mn (wt%)	P (wt%)	O (ppm)	S (ppm)	Nb (wt%)	Ti (wt%)	Cu + Cr + Mo + Ni (wt%)	RE (La + Ce) (ppm)
R1	0.05	0.26	1.77	0.005	5	8	0.09	0.03	1.20-1.30	-
R2	0.05	0.25	1.74	0.005	6	7	0.09	0.03	1.20-1.30	47
R3	0.05	0.26	1.77	0.006	6	6	0.09	0.03	1.20-1.30	112

Table 2 TMCP parameters for the experimental steels

Steel	Recrystallization		Non-recrystallization			Accelerated cooling
	Start rolling temperature (°C)	Accumulated reduction (mm)	Start rolling temperature (°C)	Finishing rolling temperature (°C)	Accumulated reduction (mm)	Finishing cooling temperature (°C)	Cooling rate (°C/s)
R1	1059	50	920	745	22	481	20
R2	1051	50	921	740	22	534	16
R3	1051	50	919	750	22	584	13

Table 3 Room temperature tensile properties of the experimental steels

Steel	Yield strength, R_p0.2 (MPa)	Tensile strength, R_m (MPa)	Elongation after fracture, A (%)	Reduction of area, Z (%)
R1	613	790	23.5	76.0
R2	620	800	25.0	77.5
R3	613	800	23.8	78.0

Fig. 1 Charpy impact absorbed energy versus test temperature: a steel R1, b steel R2, c steel R3

Fig. 2 Optical micrographs of the experimental steels: a steel R1, b steel R2, c steel R3

Fig. 3 PF and QF grains in the experimental steels: a steel R2, b steel R3

Fig. 4 SEM micrographs of the experimental steels: a steel R1, b steel R2, c steel R3

Fig. 5 TEM micrographs of the experimental steels: GB a and BF b in steel R1, PF c and MA d in steel R2, PF e, MA f in steel R3

Fig. 6 Inclusions in the experimental steels: SEM micrographs a-c, EDS analyses of the inclusions in steel R2 and R3 d, e

Fig. 7 Inclusions on the fracture surfaces of the tested steels: a steel R1, b steel R2, c steel R3

Fig. 8 Optical micrographs of the experimental steels after heat-treatment: a steel R1, b steel R2, c steel R3

Table 4 Tensile properties and Charpy impact toughness of the experimental steels after heat-treatment

Steel	Yield strength, R_p0.2 (MPa)	Tensile strength, R_m (MPa)	Charpy impact absorbed energy, KV₈ (-20 °C) (J)
R1	545	652	120
R2	550	654	118
R3	546	648	102

Fig. 9 Crystallographic characteristics of the experimental steels by EBSD: misorientation maps of steels R1 a, R2 c, R3 e, distributions of grain boundary misorientation in steels R1 b, R2 d, R3 f

Fig. 10 Distributions of the effective grain sizes: a steel R1, b steel R2, c steel R3

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