Reducing process of sinter in COREX shaft furnace and influence of sinter proportion on reduction properties of composite burden

Ben-jing Shi; De-qing Zhu; Jian Pan; Bing Hu; Zhao-cai Wang

doi:10.1007/s11771-021-4638-5

Journal of Central South University ›› 2021, Vol. 28 ›› Issue (3) : 690 -698. DOI: 10.1007/s11771-021-4638-5

Article

Reducing process of sinter in COREX shaft furnace and influence of sinter proportion on reduction properties of composite burden

Ben-jing Shi ¹^,²^,³^,^a
, De-qing Zhu ⁴^,^b
, Jian Pan ⁴
, Bing Hu ¹^,²^,³
, Zhao-cai Wang ¹^,²^,³

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Abstract

In order to reduce the materials cost of COREX ironmaking process, sinter has been introduced into the composite burden in China. This work explored the reducing process of sinter in COREX shaft furnace to clarify its reduction properties change and then the effect of sinter proportion on metallurgical performance of composite burden was investigated. The results show that the reducing process of sinter in COREX shaft furnace was basically same with that in blast furnace but sinter seems like breaking faster. Under reducing condition simulated COREX shaft furnace, sinter possessed the worst reduction degradation index (RDI) and undifferentiated reduction index (RI) compared with pellet and iron ore lumps. Macroscopic and microscopic mineralogy changes indicated that sinter presents integral cracking while pellet and lump ore present surface cracking, and no simple congruent relationship exists between cracks of the burden and its ultimate reduction degradation performance. The existence of partial metallurgical performance superposition between composite and single ferrous burden was confirmed. RDI_+6.3≥70% and RDI_+3.15≥80% were speculated as essential requirements for the composite burden containing sinter in COREX shaft furnace.

Keywords

sinter / COREX shaft furnace / reducing process / composite burden / reduction degradation index (RDI) / metallurgical performance

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Ben-jing Shi, De-qing Zhu, Jian Pan, Bing Hu, Zhao-cai Wang. Reducing process of sinter in COREX shaft furnace and influence of sinter proportion on reduction properties of composite burden. Journal of Central South University, 2021, 28(3): 690-698 DOI:10.1007/s11771-021-4638-5

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References

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[1]	YING Zi-wei, CHU Man-sheng, TANG Jue, LIU Zheng-gen, ZHOU Yu-sheng. Current situation and future adaptability analysis of non-blast furnace ironmaking process [J]. Hebei Metallurgy, 2019(6): 1–7. DOI: https://doi.org/10.13630/j.cnki.13-1172.2019.0601. (in Chinese)

[2]	YouY, LiY-y, LuoZ-g, LiH-f, ZouZ-s, YangR-yu. Investigating the effect of particle shape on the charging process in melter gasifiers in COREX s[J]. Powder Technology, 2019, 351: 305-313

[3]	KumarP P, GuptaD, NahaT K, GuptaS S. Factors affecting fuel rate in COREX process [J]. Ironmaking & Steelmaking, 2006, 33(4): 293-298

[4]	LiH-f, ZouZ-s, LuoZ-g L, ShaoL, LiuW-hui. Model study on burden distribution in COREX melter gasifier [J]. Processes, 2019, 7(12): 892-906

[5]	ZHU Ren-liang, ZHU Jin-ming, SONG Wen-gang. Present operation situation and development prospect of Baosteel COREX-3000 [J]. Baosteel Technology, 2011(6): 12–17. DOI: https://doi.org/10.3969/j.issn.1008-0716.2011.06.003. (in Chinese)

[6]	CHEN Ruo-ping, TAN Zhen. Analysis the production performance of Baosteel COREX-3000 to guide the COREX production of Bayi steel [J]. Xinjiang Iron Steel, 2014(2): 19–21. DOI: https://doi.org/10.3969/j.issn.1672-4224.2014.02.006. (in Chinese)

[7]	ZhuD-q, ChouJ-l, ShiB-j, PanJian. Influence of MgO on low temperature reduction and mineralogical changes of sinter in simulated COREX shaft furnace reducing conditions [J]. Minerals, 2019, 5(9): 272-282

[8]	TianB-s, LiW-hao. Production practice of blowing-in OY furnace of Bayi steel [J]. Xinjiang Iron Steel, 2015, 21(4): 18-20(in Chinese)

[9]	AsadaM, ShimaM, OmoriY. Measurement of macro strain in the course of reduction of the skeletal hematite in sinter [J]. Tetsu-to-Hagane, 1987, 73(15): 1901-1908

[10]	NakajimaR, SumigamaT, WakimotoK, NaganoS, KawataH, SakuraiM. Reduction degradation behavior of sinter in the blast furnace shaft [J]. Tetsu-to-Hagane, 1987, 73(15): 1964-1971

[11]	PimentaH P, SeshadriV. Characterisation of structure of iron ore sinter and its behaviour during reduction at low temperatures [J]. Ironmaking & Steelmaking, 2002, 29(3): 169-174

[12]	LooC E, BristowN J. Study on low temperature reduction degradation mechanism of sinter [J]. Sintering Pelletizing, 1995, 20(3): 25-29(in Chinese)

[13]	GuoH, GuoX-min. Mechanism of low-temperature reduction degradation of alumina-containing hematite solid solution below 550 °C [J]. Metallurgical and Materials Transactions B, 2018, 49(6): 3513-3521

[14]	MaJ-f, WangG-w, ZhangJ-l, LiX-y, LiuZ-j, JiaoK-x, GuoJian. Reduction behavior and kinetics of vanadium-titanium sinters under high potential oxygen enriched pulverized coal injection [J]. International Journal of Minerals, Metallurgy, and Materials, 2017, 24(5): 493-503

[15]	ChenX-l, XiaoY-x, FanX-h, GanM, HuangX-xian. Evolution law of mineral phase (mineralogical) structure during low temperature reduction of sinter [J]. Sintering Pelletizing, 2019, 44(5): 1-6(in Chinese)

[16]	LiJ, MaoX-m, PengXin. Effect of micro-characteristics on reduction degradation index of sinter [J]. Iron & Steel, 2018, 53(8): 15-20(in Chinese)

[17]	WuS-l, LiuX-q, ZhouQ, XuJ, LiuC-song. Low temperature reduction degradation characteristics of sinter, pellet and lump ore [J]. Journal of Iron and Steel Research, International, 2011, 18(8): 20-24

[18]	ZhaoG-g, FanX-h, ChenX-l, YuanL-s, GanMin. Metallurgical properties of ferrous burdens in blast furnace [J]. Journal of Central South University (Science and Technology), 2010, 41(6): 2053-2059(in Chinese)