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Abstract
Gypsum sludge refers to a hazardous solid waste produced by the non-ferrous smelting industry, and its disposal and utilization are environmentally challenging. To investigate the feasibility of replacing limestone with gypsum sludge for smelting slagging, the effect of gypsum sludge and smelting conditions on high lead slag reduction smelting was studied through thermodynamic calculation and experiments. It was found that calcium sulfate in the gypsum sludge consumed the reducing agent and vulcanized the metal oxide, thus, controlling its dosage was necessary. The optimal conditions for comprehensive recovery of valuable metals were as follows: calcium silicon mass ratio, dosage of carbon powder, mole ratio of calcium sulfate to calcium oxide, smelting temperature, and holding time were 0.8, 3.5 wt%, 1: 5, 1200 °C, and 1.5 h, respectively. The direct recovery of lead and zinc under these conditions was 94.43% and 58.43% respectively. Meanwhile, toxicity leaching experiment of sulfuric acid and nitric acid method indicated that the collaborative melting process stabilized the reduced slag.
Keywords
high lead slag
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gypsum sludge
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calcium sulfate
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bath smelting
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metal distribution
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Bo-wen Ruan, Fen Jiao, Wei Liu, Zu-chao Pan, Wen-qing Qin.
Utilization and detoxification of gypsum sludge by replacing limestone in reduction smelting of high lead slag.
Journal of Central South University, 2023, 30(4): 1145-1157 DOI:10.1007/s11771-023-5274-z
| [1] |
MatyasA G, MackeyP J. Metallurgy of the direct smelting of lead [J]. JOM, 1976, 28(11): 10-15
|
| [2] |
JI Luo-jun, JIN Su-min. Environmental protection technical progress and outlook of China’s nonferrous metallurgy and metallurgical acid production [J]. Sulphuric Acid Industry, 2016(5): 1–9. (in Chinese)
|
| [3] |
LehmustoJ, LaurénT, LindgrenM. Catalytic role of process dust in SO2-to-SO3 conversion in flash smelting heat recovery boilers [J]. JOM, 2019, 71(9): 3305-3313
|
| [4] |
PAN Zu-chao, JIAO Fen, QIN Wen-qing, et al. Research progress on comprehensive utilization of flue gas desulfurization gypsum and gypsum slag in smelting industry [J]. The Chinese Journal of Nonferrous Metals, 2022(5): 1–13. (in Chinese)
|
| [5] |
FuF-l, WangQ. Removal of heavy metal ions from wastewaters: A review [J]. Journal of Environmental Management, 2011, 92(3): 407-418
|
| [6] |
XiaL-g, CaoS-h, LiQ-h, et al. . Co-treatment of copper smelting slag and gypsum residue for valuable metals and sulfur recovery [J]. Resources, Conservation and Recycling, 2022, 183: 106360
|
| [7] |
ZhangT-f, LiuW, HanJ-w, et al. . Selective separation of calcium from zinc-rich neutralization sludge by sulfidation roasting and HCl leaching [J]. Separation and Purification Technology, 2021, 259118064
|
| [8] |
LiY, LiuX-m, LiZ-p, et al. . Preparation, characterization and application of red mud, fly ash and desulfurized gypsum based eco-friendly road base materials [J]. Journal of Cleaner Production, 2021, 284124777
|
| [9] |
YuY, HuJ-h, LiY-k, et al. . A new method for simultaneous separation and solidification of arsenic from arsenic-bearing gypsum sludge using waste carbon cathodes [J]. Separation and Purification Technology, 2022, 291120656
|
| [10] |
YuY, LiY-k, HuJ-h, et al. . An all-in-one strategy for resource recovery and immobilization of arsenic from arsenic-bearing gypsum sludge [J]. Chemosphere, 2022, 296134078
|
| [11] |
YangD-z, SasakiA, EndoM. Reclamation of a waste arsenic-bearing gypsum as a soil conditioner via acid treatment and subsequent Fe(II)As stabilization [J]. Journal of Cleaner Production, 2019, 21722-31
|
| [12] |
MaX, YaoS-h, YuanZ-d, et al. . Detoxification and reclamation of hydrometallurgical arsenic- and trace metals-bearing gypsum via hydrothermal recrystallization in acid solution [J]. Chemosphere, 2020, 250: 126290
|
| [13] |
KeY, ChaiL-y, MinX-b, et al. . Sulfidation of heavy-metal-containing neutralization sludge using zinc leaching residue as the sulfur source for metal recovery and stabilization [J]. Minerals Engineering, 2014, 61105-112
|
| [14] |
LiangY-j, ChaiL-y, MinX-b, et al. . Hydrothermal sulfidation and floatation treatment of heavy-metal-containing sludge for recovery and stabilization [J]. Journal of Hazardous Materials, 2012, 217–218: 307-314
|
| [15] |
YANG G, ZHAO B, WANG Ji-kun, et al. Study of different behaviours between lead-rich slags and sinter during reduction [J]. Nonferrous Metals (Extractive Metallurgy), 2008(4): 5–7. (in Chinese)
|
| [16] |
WU Zhan-qiang. Production test of ausmelt furnace treating neutralization dregs [J]. Copper Engineering, 2018(1): 83–86. (in Chinese)
|
| [17] |
LiX, ZhuX, QiX-j, et al. . Pyrolysis of arsenic-bearing gypsum sludge being substituted for calcium flux in smelting process [J]. Journal of Analytical and Applied Pyrolysis, 2018, 130: 19-28
|
| [18] |
ZhangZ, LiW, ZhanJ. The effect of coal ratio on the high-lead slag reduction process [J]. Journal of Mining and Metallurgy, Section B: Metallurgy, 2018, 54(2): 179-184
|
| [19] |
LiW-f, ZhanJ, FanY-q, et al. . Research and industrial application of a process for direct reduction of molten high-lead smelting slag [J]. JOM, 2017, 69(4): 784-789
|
| [20] |
ZhangZ-t, LiW-f, ZhanJ, et al. . Phase transformation behavior of lead and zinc in the high-lead slag reduction process [J]. Russian Journal of Non-Ferrous Metals, 2021, 62(2): 139-146
|
| [21] |
JakE, HayesP C. Experimental study of phase equilibria in the PbO-ZnO- “Fe2O3” -CaO-SiO2 system in air for high lead smelting slags (CaO/SiO2=0.35 and PbO/(CaO + SiO2)= 5.0 by weight) [J]. Metallurgical and Materials Transactions B, 2002, 33(6): 817-825
|
| [22] |
LI Wei-feng, YANG An-guo, CHEN Hui-ceng, et al. Technology study on direct reduction of lead-rich slag [J]. Nonferrous Metals (Extractive Metallurgy), 2011(4): 10–13. (in Chinese)
|
| [23] |
ChenL, YangT-z, BinS, et al. . An efficient reactor for high-lead slag reduction process: Oxygen-rich side blow furnace [J]. JOM, 2014, 66(9): 1664-1669
|
| [24] |
ZhangM-x, LiJ-l, ZengQ, et al. . An experimental study on the reduction behavior of dust generated from electric arc furnace [J]. Applied Sciences, 2019, 9(17): 3604
|
| [25] |
Perez-LabraM, Romero-SerranoA, Hernandez-RamirezA, et al. . Effect of CaO/SiO2 and Fe/SiO2 ratios on phase equilibria in PbO-ZnO-CaO-SiO2- “Fe2O3” system in air [J]. Transactions of Nonferrous Metals Society of China, 2012, 223665-674
|
| [26] |
OuyangK, DouZ H, ZhangT A, et al. . Effect of ZnO/PbO and FeO/SiO2 ratio on the viscosity of lead smelting slags [J]. Journal of Mining and Metallurgy, Section B: Metallurgy, 2020, 56(1): 27-33
|
| [27] |
ZhangD-c, ZhangX-w, YangT-z, et al. . Reduction smelting on bismuth oxide residue in FeO-SiO2-CaO ternary slag system [J]. Journal of Central South University, 2016, 23(6): 1326-1331
|
| [28] |
CuiY-r, LiK-m, HeJ-s, et al. . Melting point of molten high-lead slag in direct reduction process [J]. Chinese Journal of Rare Metals, 2013, 37(3): 473-478(in Chinese)
|
| [29] |
ChenL, YangT-z, LiuW-f, et al. . Distribution of valuable metals in liquid high lead slag during reduction process [J]. The Chinese Journal of Nonferrous Metals, 2014, 24(4): 1056-1062(in Chinese)
|
| [30] |
HJ/T 299-2007. Solid waste-Extraction procedure for leaching toxicity-Sulphuric acid & nitric acid method [S]. (in Chinese)
|
| [31] |
GB 5085.3-2007. Identification standards for hazardous wastes identification for extraction toxicity [S]. (in Chinese)
|
