Strain Aging Behavior of X70 Pipeline Steel

doi:10.11901/1005.3093.2015.325

Chinese Journal of Materials Research

2016, Vol. 30

Issue (10): 767-772 DOI: 10.11901/1005.3093.2015.325

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Strain Aging Behavior of X70 Pipeline Steel

Yongwen JIANG^1,^**(

),Tao NIU¹,Chenggang AN¹,Xinlang WU²,Caixia ZHANG²,Xiaoli DAI¹

1. Shougang Research Institute of Technology, Beijing 100043, China
2. Shougang Qian’an Iron &Steel Co.Ltd, Qian’an 064404, China;

Cite this article:

Yongwen JIANG,Tao NIU,Chenggang AN,Xinlang WU,Caixia ZHANG,Xiaoli DAI. Strain Aging Behavior of X70 Pipeline Steel. Chinese Journal of Materials Research, 2016, 30(10): 767-772.

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Abstract

Effect of pre-strain and aging temperature on mechanical property and microstructure of X70 pipeline steel was investigated by means of scanning electron microscope ( SEM ) and transmission electron microscope ( TEM ). The results indicate that the X70 steel shows a microstructure compopsed of granular bainite, acicular ferrite and M/A. The aging temperatures below 300℃, exhibit nearly no effect on the microstructure and the tensile strength of the steel. With the rising of aging temperature, the quantity of activated interstitial atoms, therewith, the pinning effect on dislocations increases, which leads to the gradual increase of the yield strength; However, when the temperature raises to above 200℃, the recovery of pinning effect occurs resulting in the decline of the yield strength. With the rising of aging temperature, the hardening of material induced by the increased cottrell atmosphere and precipitations leads to the decline of the impact toughness. With the increase of the pre-strain, the increment of dislocations may lead to the increase of yield strength, and the stress concentration will increase at boundries of the hard brittle phase M/A, therewith increase the probability of the formation micro-cracks, as a result, the impact toughness delines.

Key words: metal materials X70 pipeline steel strain aging mechanical properties microstructure

Received: 12 October 2015

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	Yongwen JIANG
	Tao NIU
	Chenggang AN
	Xinlang WU
	Caixia ZHANG
	Xiaoli DAI

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https://www.cjmr.org/EN/10.11901/1005.3093.2015.325 OR https://www.cjmr.org/EN/Y2016/V30/I10/767

Table 1 Chemical composition of experimental steel (%, mass fraction)

Table 2 Test scheme of different aging temperature

Table 3 Test scheme of different re-strain

Fig.1 Mechanical properties variation with different aging temperatures (a) strength; (b) Y/T; (c) elongation; (d) impact absorbing energy

Fig.2 Mechanical properties variation with different pre-strain (a) strength; (b) Y/T; (c) elongation; (d) impact absorbing energy

Fig.3 Partial enlarged detail of tensile curve with different pre-strain

Fig.4 Microstructure comparison at different aging temperatures (SEM) (a) Rolled; (b) 150℃; (c) 250℃; (d) 300℃

Fig.5 Impact fracture with different pre-strain (a) Rolled; (b) 3%/300℃

Fig.6 Dislocation of X70 with different aging temperature (a) Room temperature; (b) 300℃

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