Evolution of ferronickel particles during the reduction of low-grade saprolitic laterite nickel ore by coal in the temperature range of 900–1250°C with the addition of CaO-CaF2-H3BO3

Zulfiadi Zulhan; Windu Shalat

doi:10.1007/s12613-020-2025-0

International Journal of Minerals, Metallurgy, and Materials ›› 2021, Vol. 28 ›› Issue (4) :612 -620. DOI: 10.1007/s12613-020-2025-0

Article

Evolution of ferronickel particles during the reduction of low-grade saprolitic laterite nickel ore by coal in the temperature range of 900–1250°C with the addition of CaO-CaF₂-H₃BO₃

Zulfiadi Zulhan ¹^,^a
, Windu Shalat ¹

Author information +

History +

PDF

Abstract

The method of producing ferronickel at low temperature (1250–1400°C) has been applied since the 1950s at Nippon Yakin Kogyo, Oheyama Works, Japan. Limestone was used as an additive to adjust the slag composition for lowering the slag melting point. The ferronickel product was recovered by means of a magnetic separator from semi-molten slag and metal after water quenching. To increase the efficiency of magnetic separation, a large particle size of ferronickel is desired. Therefore, in this study, the influences of CaO, CaF₂, and H₃BO₃ additives on the evolution of ferronickel particle at ≤1250°C were investigated. The experiments were conducted at 900–1250°C with the addition of CaO, CaF₂, and H₃BO₃. The reduction processes were carried out in a horizontal tube furnace for 2 h under argon atmosphere. At 1250°C, with the CaO addition of 10wt% of the ore weight, ferronickel particles with size of 20 µm were obtained. The ferronickel particle size increased to 165 µm by adding 10wt% CaO and 10wt% CaF₂. The addition of boric acid further increased the ferronickel particle size to 376 µm, as shown by the experiments with the addition of 10wt% CaO, 10wt% CaF₂, and 10wt% H₃BO₃.

Keywords

saprolitic laterite nickel ore / ferronickel particle / lime / fluorite / boric acid

Cite this article

Download citation ▾

Zulfiadi Zulhan, Windu Shalat. Evolution of ferronickel particles during the reduction of low-grade saprolitic laterite nickel ore by coal in the temperature range of 900–1250°C with the addition of CaO-CaF₂-H₃BO₃. International Journal of Minerals, Metallurgy, and Materials, 2021, 28(4): 612-620 DOI:10.1007/s12613-020-2025-0

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]	Team Kalkine. How Is the Nickel Landscape Shaping Up, 2019, Sydney, Kalkine Media 11–13

[2]	U.S. Geological Survey. Mineral Commodity Summaries 2019, 2019, Washington, U.S. Geological Survey 02–28

[3]	Harris CT, Peacey JG, Pickles CA. Liu J, Peacey J, Barati M, Kashani-Nejad S, Davis B. Thermal upgrading of nickeliferous laterites—A review. Pyrometallurgy of Nickel and Cobalt 2009, 2009, Ontario, 48th Conference on Metallurgists, 51.

[4]	Dong JC, Wei YG, Zhou SW, Li B, Yang YD, McLean A. The effect of additives on Ni, Fe and Co from nickel laterite ores. JOM, 2018, 70(10): 2365.

[5]	Li GH, Shi TM, Rao MJ, Jiang T, Zhang YB. Beneficiation of nickeliferous laterite by reduction roasting in the presence of sodium sulfate. Miner. Eng., 2012, 32, 19.

[6]	Zhu DQ, Cui Y, Vining K, Hapugoda S, Douglas J, Pan J, Zheng GL. Upgrading low nickel content laterite ores using selective reduction followed by magnetic separation. Int. J. Miner. Process., 2012, 106–109, 1.

[7]	Zhu DQ, Pan LT, Guo ZQ, Pan J, Zhang F. Utilization of limonitic nickel laterite to produce ferronickel concentrate by the selective reduction-magnetic separation process. Adv. Powder Technol., 2019, 30(2): 451.

[8]	Elliott R, Pickles CA, Peacey J. Ferronickel particle formation during the carbothermic reduction of a limonitic laterite ore. Miner. Eng., 2017, 100, 166.

[9]	Jiang M, Sun TC, Liu ZG, Kou J, Liu N, Zhang SY. Mechanism of sodium sulfate in promoting selective reduction of nickel laterite ore during reduction roasting process. Int. J. Miner. Process., 2013, 123, 32.

[10]	Lu J, Liu SJ, Shangguan J, Du W, Pan F, Yang S. The effect of sodium sulphate on the hydrogen reduction process of nickel laterite ore. Miner. Eng., 2013, 49, 154.

[11]	Harris CT, Peacey JG, Pickles CA. Selective sulphidation and flotation of nickel from a nickeliferous laterite ore. Miner. Eng., 2013, 54, 21.

[12]	Rao MJ, Li GH, Zhang X, Luo J, Peng ZW, Jiang T. Reductive roasting of nickel laterite ore with sodium sulphate form Fe-Ni production. Part II: Phase transformation and grain growth. Sep. Sci. Technol., 2016, 51(10): 1727.

[13]	Wang XP, Sun TC, Chen C, Kou J. Effects of Na₂SO₄ on iron and nickel reduction in a high-iron and low-nickel laterite ore. Int. J. Miner. Metall. Mater., 2018, 25(4): 383.

[14]	Chen GJ, Shiau JS, Liu SH, Hwang WS. Optimal combination of calcination and reduction conditions as well as Na₂SO₄ additive for carbothermic reduction of limonite ore. Mater. Trans., 2016, 57(9): 1560.

[15]	Zhou SW, Wei YG, Li B, Wang H, Ma BZ, Wang CY. Chloridization and reduction roasting of high-magnesium low-nickel oxide ore followed by magnetic separation to enrich ferronickel concentrate. Metall. Mater. Trans. B, 2016, 47(1): 145.

[16]	Wang ZZ, Chu MS, Liu ZG, Wang HT, Zhao W, Gao LH. Preparing ferro-nickel alloy from low grade laterite nickel ore based on metallized reduction-magnetic separation. Metals, 2017, 7(8): 313.

[17]	Watanabe T, Ono S, Arai H, Matsumori T. Direct reduction of garnierite ore for production of ferro-nickel with a rotary kiln at Nippon Yakin Kogyo Co., Ltd., Oheyama Works. Int. J. Miner. Process., 1987, 19(1–4): 173.

[18]	Kobayashi Y, Todoroki H, Tsuji H. Melting behavior of siliceous nickel ore in a rotary kiln to produce ferronickel alloys. ISIJ Int., 2011, 51(1): 35.

[19]	Tsuji H. Behavior of reduction and growth of metal in smelting of saprolite Ni-ore in a rotary kiln for production of ferronickel alloy. ISIJ Int., 2012, 52(6): 1000.

[20]	Warner AEM, Díaz CM, Dalvi AD, Mackey PJ, Tarasov AV. JOM world nonferrous smelter survey, Part III: Nickel: Laterite. JOM, 2006, 58(4): 11.

[21]	Li B, Wang H, Wei YG. The reduction of nickel from low-grade nickel laterite ore using a solid-state deoxidisation method. Miner. Eng., 2011, 24(14): 1556.

[22]	X.M. Lv, L.W. Wang, Z.X. You, J. Dang, X.W. Lv, G.B. Qiu, and C.G. Bai, Preparation of Ferronickel from Nickel Laterite Ore via Semi-Molten Reduction Followed by Magnetic Separation, [in] Extraction 2018, Cham, 2018, p. 913

[23]	Ma XD, Cui ZX, Zhao BJ. Efficient utilization of nickel laterite to produce master alloy. JOM, 2016, 68(12): 3006.

[24]	Morcali MH, Khajavi LT, Dreisinger DB. Extraction of nickel and cobalt from nickeliferous limonitic laterite ore using borax containing slags. Int. J. Miner. Process., 2017, 167, 27.

[25]	Zhang X, Gu FQ, Peng ZW, Wang LC, Tang HM, Rao MJ, Zhang YB, Li GH, Jiang T, Wang Y. Recovering magnesium from ferronickel slag by vacuum reduction: Thermodynamic analysis and experimental verification. ACS Omega, 2019, 4(14): 16062.