Reduction behaviour of Odisha Sands Complex, India ilmenite-coke composite pellets

D. Nayak; N. Ray; N. Dash; S. S. Rath; S. K. Biswal

doi:10.1007/s11771-020-4399-6

Journal of Central South University ›› 2020, Vol. 27 ›› Issue (6) : 1678 -1690. DOI: 10.1007/s11771-020-4399-6

Article

Reduction behaviour of Odisha Sands Complex, India ilmenite-coke composite pellets

Author information +

History +

PDF

Abstract

Presently, ilmenite concentrates from Odisha Sands Complex at Chhatrapur, India are utilized to produce TiO₂ slag by direct smelting in an electric arc furnace. However, the process involves the consumption of excess electrical energy and difficulty in handling the arc furnace due to frothing effects. A more efficient process of pre-reducing the ilmenite before smelting has been proposed in the present communication. In particular, studies have been undertaken on the reduction process of ilmenite-coke composite pellets. The difference in the reduction behaviour of raw ilmenite and ilmenite-coke composite pellets has been established and compared with that of the pre-oxidized raw pellets. The effects of various processing parameters like temperature, residence time, and reductant percentage on the metallization of composite pellets in a static bed have been investigated. Metallization of about 90% has been achieved at 1250 °C for a reduction period of 360 min with a 4°% coke composition. Furthermore, the reduced pellets have been characterized through chemical analysis, optical microscopy, field emission scanning electron microscopy and X-ray diffraction analysis. The reduction behaviour of composite pellets has also been found better than that of pre-oxidized pellets indicating the former to be more efficient.

Keywords

ilmenite / composite pellet / pre-oxidation / reduction / metallization

Cite this article

Download citation ▾

D. Nayak, N. Ray, N. Dash, S. S. Rath, S. K. Biswal. Reduction behaviour of Odisha Sands Complex, India ilmenite-coke composite pellets. Journal of Central South University, 2020, 27(6): 1678-1690 DOI:10.1007/s11771-020-4399-6

登录浏览全文

4963

注册一个新账户忘记密码

References

Publishing order | Descend order by publishing year | Descend order by cited within

[1]	LiW B, YuanZ F, XuC, PanY F, WangX Q. Effect of temperature on carbothermic reduction of ilmenite [J]. Journal of Iron and Steel Research International, 2005, 12: 1-5

[2]	WangY-m, YuanZ-f. Reductive kinetics of the reaction between a natural ilmenite and carbon [J]. International Journal of Mineral Processing, 2006, 81(3): 133-140

[3]	HuangR, LiuP-s, YueY-h, ZhangJ-z. Vacuum carbothermic reduction of panzhihua ilmenite concentrate: A thermodynamic study [J]. Mineral Processing and Extractive Metallurgy Review, 2017, 38(3): 193-198

[4]	MahmoudM H H, AfifiA A I, IbrahimI A. Reductive leaching of ilmenite ore in hydrochloric acid for preparation of synthetic rutile [J]. Hydrometallurgy, 2004, 73(1): 99-109

[5]	DangJ, ZhangG-h, ChouK-c. Kinetics and mechanism of hydrogen reduction of ilmenite powders [J]. Journal of Alloys and Compounds, 2015, 619: 443-451

[6]	LvW, LvX-m, LvX-w, XiangJ-y, BaiC-g, SongB. Non-isothermal kinetic studies on the carbothermic reduction of Panzhihua ilmenite concentrate [J]. Mineral Processing and Extractive Metallurgy, 2018, 128(4): 1-9

[7]	KucukkaragozC S, EricR H. Solid state reduction of a natural ilmenite [J]. Minerals Engineering, 2006, 19(3): 334-337

[8]	FrancisA A, El-MidanyA A. An assessment of the carbothermic reduction of ilmenite ore by statistical design [J]. Journal of Materials Processing Technology, 2008, 199(1): 279-286

[9]	MukherjeeA, RajeN, KrishnamurthyN. Effect of carbon on the beneficiation of OSCOM ilmenite by carbonitrothermy [J]. Thermochimica Acta, 2014, 575: 206-211

[10]	ZhangG-q, OstrovskiO. Effect of preoxidation and sintering on properties of ilmenite concentrates [J]. International Journal of Mineral Processing, 2002, 64(4): 201-218

[11]	GouH-p, ZhangG-h, ChouK-c. Influence of pre-oxidation on carbothermic reduction process of ilmenite concentrate [J]. ISIJ International, 2015, 55(5): 928-933

[12]	KellyR M, RowsonN A. Microwave reduction of oxidised ilmenite concentrates [J]. Minerals Engineering, 1995, 8(11): 1427-1438

[13]	LiaoX-f, PengJ-h, ZhangL-b, HuT, LiJ. Enhanced carbothermic reduction of ilmenite placer by additional ferrosilicon [J]. Journal of Alloys and Compounds, 2017, 708: 1110-1116

[14]	GuoS-h, ChenG, PengJ-h, ChenJ, LiD-b, LiuL-j. Microwave assisted grinding of ilmenite ore [J]. Transactions of Nonferrous Metals Society of China, 2011, 21(9): 2122-2126

[15]	ChenM, TangA-t, XiaoX. Effect of milling time on carbothermic reduction of ilmenite [J]. Transactions of Nonferrous Metals Society of China, 2015, 25(12): 4201-4206

[16]	LeiY, LiY, PengJ-h, GuoS-h, LiW, ZhangL-b, WanR-d. Carbothermic reduction of panzhihua oxidized ilmenite in a microwave field [J]. ISIJ International, 2011, 51(3): 337-343

[17]	YuukiM, MegumiN, NaotoT, TomohiroA. Reduction behavior and crushing strength of carbon-containing pellet prepared from COG tar [J]. Fuel Processing Technology, 2016, 142: 287-295

[18]	HuangZ-c, ZhongR-h, YiL-y, JiangT, WenL-m, LiangZ-k. Reduction enhancement mechanisms of a low-grade iron ore-coal composite by NaCl [J]. Metallurgical and Materials Transactions B, 2018, 49(1): 411-422

[19]	NikaiI, Garbers-CraigA M. Use of iron ore fines in cold-bonded self-reducing composite pellets [J]. Mineral Processing and Extractive Metallurgy Review, 2016, 37(1): 42-48

[20]	SahR, DuttaS K. Kinetic studies of iron ore-coal composite pellet reduction by TG-DTA [J]. Transactions of the Indian Institute of Metals, 2011, 64(6): 583-591

[21]	MantovaniM C, TakanoC, BuchlerP M. Electric arc furnace dust-coal composite pellet: Effects of pellet size, dust composition, and additives on swelling and zinc removal [J]. Ironmaking and Steelmaking, 2002, 29(4): 257-265

[22]	YoshitakaS, TetsuyaY, KanjiT, HiroshiI. New coal-based process to produce high quality DRI for the EAF [J]. ISIJ International, 2001, 41: S17-S21(Suppl)

[23]	MatheisonJ G, SomervilleM A, DeevA, JahanshahiS. 19-Utilization of biomass as an alternative fuel in ironmaking [M]. Iron Ore, 2015, UK, Woodhead Publishing, 581613

[24]	LuW K. The search for an economical and environmentally friendly ironmaking process [J]. Metallurgical and Materials Transactions B, 2001, 32(5): 757-762

[25]	EiseleT C, KawatraS K. A review of binders in iron ore pelletization [J]. Mineral Processing and Extractive Metallurgy Review, 2003, 24(1): 1-90

[26]	ChizhikovaV M, VainshteinR M, ZorinS N, ZainetdinovT I, ZinyaginG A, ShevchenkoA A. Production of iron-ore pellets with an organic binder [J]. Metallurgist, 2003, 47(3): 141-146

[27]	de MoraesS L, KawatraS K. Laboratory study of an organic binder for pelletization of a magnetite concentrate [J]. Mining, Metallurgy & Exploration, 2010, 27(3): 148-153

[28]	AmmasiA, PalJ. Replacement of bentonite in hematite ore pelletisation using a combination of sodium lignosulphonate and copper smelting slag [J]. Ironmaking & Steelmaking, 2016, 43(3): 203-213

[29]	El-HussinyN A, ShalabiM E H. Studying the pelletization of rosseta ilmenite concentrate with coke breeze using molasses and reduction kinetics of produced pellets at 800–1150 °C [J]. Science of Sintering, 2012, 44(1): 113-126

[30]	DewanM A R, ZhangG-q, OstrovskiO. Phase development in carbothermal reduction of ilmenite concentrates and synthetic rutile [J]. ISIJ International, 2010, 50(5): 647-653

[31]	ZhangJ-l, ZhengC-l, TangY-t, ChaiY-f. Reduction of Panzhihua titanium-bearing oxidized pellets by CO-N₂-H₂ gas [J]. Journal of Central South University, 2016, 23(5): 1015-1022

[32]	LvW, BaiC-g, LvX-w, HuK, LvX-m, XiangJ-y, SongB. Carbothermic reduction of ilmenite concentrate in semi-molten state by adding sodium sulfate [J]. Powder Technology, 2018, 340: 354-361

[33]	AgrawalB B, PrasadK K, SarkarS B, RayH S. Cold bonded ore-coal composite pellets for sponge ironmaking. Part 1. Laboratory scale development [J]. Ironmaking & Steelmaking, 2000, 27(6): 421-425

[34]	RamdohrPThe ore minerals and their intergrowths [M], 1969, Germany, Pergamon Press

[35]	AhmedH M, ViswanathanN, BjorkmanB. Composite pellets-A potential raw material for iron-making [J]. Steel Research International, 2014, 85(3): 293-306

[36]	SheX F, SunH Y, DongX J, XueQ G, WangJ S. Reduction mechanism of titanomagnetite concentrate by carbon monoxide [J]. Journal of Mining and Metallurgy B: Metallurgy, 2013, 49(3): 263-270

[37]	HuT, LvX-w, BaiC-g, LunZ-g, QiuG-b. Reduction behavior of panzhihua titanomagnetite concentrates with coal [J]. Metallurgical and Materials Transactions B, 2013, 44(2): 252-260

[38]	GuptaS K, RajakumarV, GrievesonP. The influence of weathering on the reduction of llmenite with carbon [J]. Metallurgical Transactions B, 1989, 20(5): 735-745

[39]	KhattoiS C, RoyG G. Reduction efficiency of iron ore-coal composite pellets in tunnel kiln for sponge iron production [J]. Transactions of the Indian Institute of Metals, 2015, 68(5): 683-692

[40]	ChowdhuryG M, MurmuC S, RoyS K, RoyG G. Some studies to establish the reaction mechanism for the reduction of iron ore-graphite composite pellets in a packed bed reactor [J]. Steel Research International, 2010, 81(11): 925-931

[41]	YangJ, MoriT, KuwabaraM. Mechanism of carbothermic reduction of hematite in hematite-carbon composite pellets [J]. ISIJ International, 2007, 47(10): 1394-1400

[42]	SunK, LuW K. Mathematical modeling of the kinetics of carbothermic reduction of iron oxides in ore-coal composite pellets [J]. Metallurgical and Materials Transactions B, 2009, 40(1): 91-103

[43]	CoetseeT, PistoriusP C, de VilliersE E. Rate-determining steps for reduction in magnetite-coal pellets [J]. Minerals Engineering, 2002, 15(11): 919-929

[44]	WangZ-y, ZhangJ-l, JiaoK-x, LiuZ-j, BaratiM. Effect of pre-oxidation on the kinetics of reduction of ironsand [J]. Journal of Alloys and Compounds, 2017, 729: 874-883