Efficient Utilization of Limonite Nickel Laterite to Prepare Ferronickel by the Selective Reduction Smelting Process

Wang, Xin; Zhu, Deqing; Guo, Zhengqi; Pan, Jian; Lv, Tao; Chao, Yang; Li, Siwei

doi:10.3390/su15097147

Cited by 3 publications

(2 citation statements)

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“…The pyrometallurgical process has become the mainstream smelting process for treating these laterite nickel ores. In general, two methods are used: reduction smelting of ferronickel and reduction–sulfurization of nickel matte. , The reduction smelting of ferronickel is the most mature technology currently used in the industry . This typically uses a rotary kiln drying the prereduction electric furnace smelting process (RKEF); however, the first technology to realize industrial production of laterite was reduction–sulfurization of nickel matte, where the laterite nickel ore is crushed and screened to give a fine particle size distribution.…”

Section: Introductionmentioning

confidence: 99%

“… 7 , 8 The reduction smelting of ferronickel is the most mature technology currently used in the industry. 9 This typically uses a rotary kiln drying the prereduction electric furnace smelting process (RKEF); 10 however, the first technology to realize industrial production of laterite was reduction–sulfurization of nickel matte, where the laterite nickel ore is crushed and screened to give a fine particle size distribution. Then, a drying treatment is applied, after which the laterite nickel ore is smelted with sulfiding and reducing agents in a blast furnace or electric furnace at a temperature above 1500 °C to obtain low-grade nickel matte.…”

Section: Introductionmentioning

confidence: 99%

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Reduction–Sulfurization Smelting Process of Waste Hydrogenation Catalysts, Automotive Exhaust Purifier Waste Catalysts, and Laterite Nickel Ore

Wang,

Jie

et al. 2023

ACS Omega

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Reduction−sulfurization smelting is an effective method for treating solid hazardous waste and recovering valuable components from them. In this work, a waste hydrogenation catalyst (WHC), an automotive exhaust purifier waste catalyst (AEPWC), a vulcanizer, and laterite nickel ore were mixed, and the reduction smelting behavior of this solid waste was investigated. XRD (X-ray diffractometry), TG-DSC (thermogravimetric/differential scanning calorimetry), SEM-EDS (scanning electron microscopy-energy dispersive spectroscopy), OM (optical microscopy), and ICP-OES (inductively coupled plasma-optical emission spectrometry) methods were used to examine the chemical composition, thermal stability, structure, and morphology, as well as the metal content of the samples. Under the Al 2 O 3 -FeO-SiO 2 ternary slag system, at a smelting temperature of 1450 °C, smelting time of 2 h, mass ratio of coke, pyrite, and CaO to waste catalysts of 16, 25, and 0%, respectively, nickel (Ni) and molybdenum (Mo) recovery reached 91.1 and 92.9%, respectively, where average PGMs (platinum group metals, platinum (Pt), palladium (Pd), rhodium (Rh)) recovery reached 96%, although vanadium (V) recovery was only 25.1%. The characterization of the slag shows that Al, Si, and Fe are mainly bound in the form of chemical compounds, while V is intercalated with ferro-or aluminosilicate, which hinders the reduction and sulfurization of V. A series of tests using reduction smelting without sulfurization were also conducted, after which the Ni, Mo, and V recovery reached 96.8, 96.6, and 89.7%, respectively, while PGMs (Pt, Pd, Rh) recovery ranges from 90.2 to 98.0%. The collaborative disposal of primary ore and multisource solid waste has been achieved through two process paths: reducing smelting and reducing sulfurization smelting, which provide reference for the collaborative smelting of multisource secondary resources.

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