고강도 구조용 철강소재의 대입열 용접 시 열영향부의 조직 미세화 및 기계적 특성 향상에 미치는 TiN 및 B의 효과

박진성; 황중기; 조재영; 한일욱; 이만재; 김성진; Jin-seong Park; Joong-Ki Hwang; Jae Young Cho; Il Wook Han; Man Jae Lee; Sung Jin Kim

Korean Journal of Materials Research, Vol.29, No.2, 97-105, February, 2019

DOI10.3740/MRSK.2019.29.2.97 Export Citation

고강도 구조용 철강소재의 대입열 용접 시 열영향부의 조직 미세화 및 기계적 특성 향상에 미치는 TiN 및 B의 효과

Effects of TiN and B on Grain Refinement of HAZ Microstructure and Improvement of Mechanical Properties of High-strength Structural Steel Under High Heat Input Welding

박진성, 황중기¹, 조재영², 한일욱², 이만재³, 김성진^†

순천대학교 신소재공학과
¹동명대학교 기계공학부
²포스코 기술연구원
³포항산업과학연구원

Jin-seong Park, Joong-Ki Hwang¹, Jae Young Cho², Il Wook Han², Man Jae Lee³, and Sung Jin Kim^†

Department of Advanced Materials Engineering, Sunchon National University, Suncheon 57922, Republic of Korea
¹School of Mechanical Engineering, Tongmyong University, Busan 48520, Republic of Korea
²POSCO Technical Research Laboratories, Pohang 37673, Republic of Korea
³Analysis and Assessment Group, Research Institute of Industrial Science and Technology (RIST), Pohang 37673, Republic of Korea

E-mail:

In the current steel structures of high-rise buildings, high heat input welding techniques are used to improve productivity in the construction industry. Under the high heat input welding, however, the microstructures of the weld metal (WM) and heat-affected zone (HAZ) coarsen, resulting in the deterioration of impact toughness. This study focuses mainly on the effects of fine TiN precipitates dispersed in steel plates and B addition in welding materials on grain refinement of the HAZ microstructure under submerged arc welding (SAW) with a high heat input of 200 kJ/cm. The study reveals that, different from that in conventional steel, the γ grain coarsening is notably retarded in the coarse grain HAZ (CGHAZ) of a newly developed steel with TiN precipitates below 70 nm in size even under the high heat input welding, and the refinement of HAZ microstructure is confirmed to have improved impact toughness. Furthermore, energy dispersive spectroscopy (EDS) and secondary-ion mass spectrometry (SIMS) analyses demonstrate that B is was identified at the interface of TiN in CGHAZ. It is likely that B atoms in the WM are diffused to CGHAZ and are segregated at the outer part of undissolved TiN, which contributes partly to a further grain refinement, and consequently, improved mechanical properties are achieved.

Keywords:high heat input welding;coarse grain heat affected zone;TiN;B;secondary-ion mass spectrometry

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[2] An GB, Han IW, Park JG, Woo WC, J. Weld. Join., 35, 15 (2017)

[3] Park JU, An GB, Woo WC, J. Weld. Join., 34, 16 (2016)

[4] Zhang X, Mi G, Chen L, Jiang P, Shao X, Wang C, J. Mater. Process. Technol., 259, 312 (2018)

[5] Woo W, An GB, Kingston EJ, Dewald AT, Smith DJ, Hill MR, Acta. Mater., 61, 3564 (2013)

[6] Liu C, Yang J, Shi Y, Fu Q, Zhao Y, J. Mater. Process. Technol., 256, 239 (2018)

[7] Yanet M, Monica Z, Procedia Mater. Sci., 8, 904 (2015)

[8] Barbosa LHS, Modenesi PJ, Godefroid LB, Arias AR, Int. J. Fatig., 18, 30571 (2018)

[9] Shi M, Zhang P, Wang C, Zhu F, ISIJ. Int., 54, 932 (2014)

[10] Tomita Y, Saito N, Tsuzuki T, Tokunaga Y, Okamoto K, ISIJ. Int., 34, 829 (1994)

[11] Chai F, Yang C, Su H, Zhang Y, Xu Z, Yang Y, Acta. Metall. Sin., 21, 220 (2008)

[12] Kojima A, Kiyose A, Uemori R, Mingawa M, Hoshino M, Nakashima T, Ishida K, Yasui H, Nippon Steel Technical Report, 90, 2 (2004)

[13] Shim JH, Cho YW, Chung SH, Shim JD, Lee DN, Acta Mater., 47, 2751 (1999)

[14] Ishikawa F, Takahashi T, ISIJ. Int., 35, 1128 (1995)

[15] Ryu KM, Kim DW, Lee JW, Bang HC, J. Weld. Join., 35, 27 (2017)

[16] Jeong HC, Park YH, An YH, Lee JB, J. Weld. Join., 25, 57 (2007)

[17] Moon JO, Park SJ, J. Weld. Join., 33, 31 (2015)

[18] Saunders T, Tatarko P, Grasso S, Reece MJ, J. Euro. Cera. Soc., 38, 4198 (2018)

[19] Cai Y, Luo Z, Huang Z, Zeng Y, J. Mater. Process. Technol., 230, 80 (2016)

[20] Gao YL, Xue XX, Yang H, Crystlas, 5, 592 (2015)

[21] Kashif EE, Asakura K, Koseki T, Shibata K, ISIJ. Int., 44, 1568 (2004)

[22] Subramanian B, Jayachandran M, Mater. Lett., 62, 1727 (2008)

[23] Yamashita T, Shimamura J, Oi K, Nagoshi M, Oikawa K, Ishida K, ISIJ. Int., 55, 2018 (2015)

[24] Tamura H, J. Jpn. Weld. Soc., 35, 710 (1966)

[25] Fujiyama N, Nishibata T, Seki A, Hirata H, Kojima K, Ogawa K, Sci. Tech. Adv. Mater., 18, 88 (2016)

[26] Choi JK, Development of high strength and high performance steels at POSCO through hipers-21 Project, Phase Transformations Web. Retrieved 2005 from https://www.phase-trans.msm.cam.ac.uk.

[27] Kang J, Park GT, Jeong SH, Lee CH, J. Weld. Join., 35, 21 (2017)

[28] Kim JS, Park KT, Lee D, Lee CS, Korean J. Met. Mater., 45, 506 (2007)

[29] Park GT, Koh SU, Jung HG, Kim KY, Corrosion Sci., 50, 1865 (2008)

[30] Hagi H, Mater. Trans., 35, 168 (1994)

[31] Hong GW, Lee JY, J. Mater. Sci., 18, 271 (1983)

[32] Hong GW, Lee JY, Metall. Trans. A, 14, 156 (1983)

[33] Bahadeshia HKDH, ISIJ. Int., 56, 24 (2016)

[34] Enos DG, Scully JR, Metall. Mater. Trans. A-Phys. Metall. Mater. Sci., 33, 1151 (2002)