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Abstract

In this study, controlled rolling involving a relaxation process followed by accelerating cooling was applied for producing a V–N microalloyed pipeline steel during the industrial production process. The main objective of the research is to study the influence of the relaxation process on the microstructure and mechanical properties. The microstructure consisted of polygonal ferrite (PF), acicular ferrite (AF) and granular bainite in the experimental steels, while the volume fraction of PF and precipitates increased with the increasing air-cooling relaxation time. The yield strength, tensile strength, yield ratio, −20°C average impact energy and ductile–brittle transition temperatures are 535 ± 9 MPa, 602 ± 11 MPa, 0.89 ± 0.01, 263 ± 8 J and −81°C when the volume fraction of PF is 15.1 ± 0.3%, and 503 ± 8 MPa, 590 ± 9 MPa, 0.85 ± 0.02, 221 ± 10 J and −70°C when the volume fraction of PF increases to 30.4 ± 0.6%. The mechanical properties including strength and low-temperature toughness of V–N microalloyed steels meet X70 pipeline steel standards. The main strengthening mechanisms are grain boundary strengthening, dislocation strengthening and precipitation strengthening in this steel. In the process of plastic deformation, the non-uniformly distributed strain concentration regions could cause uneven distribution of deformation, which forms the nucleation of microcracks. AF and high-angle grain boundaries played an important role in improving the strength and toughness.

Keywords

V–N microalloyed microstructure pipeline steel precipitates acicular ferrite

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References

Kim

Lee

Kim

. Transformation behavior and microstructural characteristics of acicular ferrite in linepipe steels. Mater Sci Eng A 2008; 478: 361–370.

Wang

Lian

. Effect of microstructure on low-temperature toughness of a low carbon Nb–V–Ti microalloyed pipeline steel. Mater Sci Eng A 2014; 592: 50–56.

Sanchez-Mourino

Petrov

Bae

, et al. Microstructural changes after control rolling and interrupted accelerated cooling simulations in pipeline steel. Steel Res Int 2011; 82: 352.

Guo

Misra

RDK

, et al. Ultrahigh strength and low yield ratio of niobium-microalloyed 900 MPa pipeline steel with nano/ultrafine bainitic lath. Mater Sci Eng A 2010; 527: 3886.

Sung

Shin

Cha

, et al. Effects of acicular ferrite on charpy impact properties in heat affected zones of oxide-containing API X80 linepipe steels. Mater Sci Eng A 2011; 528: 3350.

Shanmugam

Misra

RDK

Hartmann

, et al. Microstructure of high strength niobium-containing pipeline steel. Mater Sci Eng A 2006; 441: 215–229.

Zhao

Wang

, et al. A novel thermo-mechanical controlled processing for large-thickness microalloyed 560 MPa (X80) pipeline strip under ultra-fast cooling. Mater Sci Eng A 2016; 673: 373–377.

Goto

Kami

Kawamura

. Effect of alloying elements and hot-rolling conditions on microstructure of bainitic-ferrite/martensite dual phase steel with high toughness. Mater Sci Eng A 2015; 648: 436–442.

Krauss

Thompson

. Ferritic microstructures in continuously cooled low- and ultralow-carbon steels. ISIJ Int 1995; 35: 937–945.

10.

Cao

Bao

Xia

, et al. Toughening mechanisms of a high-strength acicular ferrite steel heavy plate. Int J Miner Metall Mater 2010; 17: 567–572.

11.

Wang

, et al. Influence of dual-phase microstructures on the properties of high strength grade line pipes. J Mater Eng Perform 2014; 23: 3867–3874.

12.

Cabo Rios

Arlazarov

Charbonnier

, et al. Characterization and modelling of microstructure evolution during partitioning in Q&P steels. Materia 2024; 33: 101981.

13.

Cao

Bao

Xia

, et al. Toughening mechanisms of a high-strength acicular ferrite steel heavy plate. Int J Miner Metall Mater 2010; 17: 572.

14.

Capdevila

García-Mateo

Chao

, et al. Effect of V and N precipitation on acicular ferrite formation in sulfur-lean vanadium steels. Metall Mater Trans A 2009; 40: 522–538.

15.

Lagneborg

Siwecki

Zajac

, et al. The role of vanadium in microalloyed steel. Scand J Metall 1999; 28: 186.

16.

Siwecki

Eliasson

Lagneborg

, et al. Vanadium microalloyed bainitic hot strip steels. ISIJ Int 2010; 50: 760–767.

17.

Asahi

Hirakami

Yamasaki

. Hydrogen trapping behavior in vanadium-added steel. ISIJ Int 2003; 43: 527–533.

18.

Capdevila

García-Mateo

Chao

, et al. Effect of V and N precipitation on acicular ferrite formation in Sulfur-lean vanadium steels. Metall Mater Trans A 2009; 40: 522–538.

19.

Wang

J-J

, et al. Structure–mechanical property relationship in low carbon microalloyed steel plate processed using controlled rolling and two-stage continuous cooling. Mater Sci Eng A 2013; 585: 197–204.

20.

Zheng

Kang

Meng

, et al. Effect of cooling start temperature on microstructure and mechanical properties of X80 high deformability pipeline steel. J Iron Steel Res Int 2011; 18: 42–46.

21.

Zajac

Siwecki

Hutchinson

, et al. Strengthening mechanisms in vanadium microalloyed steels intended for long products. ISIJ Int 1998; 38: 1130.

22.

Wei-jun

Han

Yu-qing

. Effect of heat treatment on delayed fracture resistance of high strength steel 30CrMnSi2NiNb. J Iron Steel Res Int 2003; 10: 63.

23.

Zang

, et al. On the determining role of acicular ferrite in V-N microalloyed steel in increasing strength-toughness combination. Mater Charact 2016; 118: 446–453.

24.

Mohtadi-Bonab

Eskandari

Rahman

KMM

, et al. An extensive study of hydrogen-induced cracking susceptibility in an API X60 sour service pipeline steel. Int J Hydrogen Energy 2016; 41: 4185.

25.

Lan

Tang

, et al. Unlocking the mechanisms behind austenite formation of cold-rolled ferrite–martensite dual-phase steels: the role of ferrite recrystallization. Steel Res Int 2024; 95: 2300595.

26.

Turk

San Martín

Rivera-Díaz-del-Castillo

PEJ

, et al. Correlation between vanadium carbide size and hydrogen trapping in ferritic steel. Scr Mater 2018; 152: 112–116.

27.

Takahashi

Kawakami

Tarui

. Direct observation of hydrogen-trapping sites in vanadium carbide precipitation steel by atom probe tomography. Scr Mater 2012; 67: 213–216.

28.

Baker

. Processes, microstructure and properties of vanadium microalloyed steels. Mater Sci Technol 2009; 25: 1083–1107.

29.

Williams

Carter

. Transmission electron microscopy – a textbook for materials science. 2nd ed. New York: Springer, 2009.

30.

Peng

Chen

, et al. Isothermal precipitation kinetics of carbides in undercooled austenite and ferrite of a titanium microalloyed steel. Mater Des 2016; 108: 289–297.

31.

Chen

Qiao

Han

, et al. Effects of Mo, Cr and Nb on microstructure and mechanical properties of heat affected zone for Nb-bearing X80 pipeline steels. Mater Des 2014; 53: 888–901.

32.

Zikry

. Microstructural modeling of transgranular and intergranular fracture in crystalline materials with coincident site lattice grain-boundaries: σ3 and Σ17b bicrystals. Mater Sci Eng A 2016; 661: 32–39.

33.

Wilson

Crowther

, et al. The effects of vanadium, niobium, titanium and zirconium on the microstructure and mechanical properties of thin slab cast steels. ISIJ Int 2004; 44: 1093–1102.

On the determining role of acicular ferrite and polygonal ferrite in V–N microalloyed X70 pipeline steel in optimising the strength-toughness combination

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