Ammonia chloride assisted air-chlorination recovery of tin from pyrometallurgical slag of spent lead-acid battery

TY - JOUR

T1 - Ammonia chloride assisted air-chlorination recovery of tin from pyrometallurgical slag of spent lead-acid battery

AU - Li, Mingyang

AU - Yang, Jiakuan

AU - Liang, Sha

AU - Hou, Huijie

AU - Wang, Junxiong

AU - Hu, Guang

AU - Li, Zhaoyang

AU - Hu, Jingping

AU - Xiao, Keke

AU - Liu, Bingchuan

N1 - Publisher Copyright: © 2021

PY - 2021/7

Y1 - 2021/7

N2 - Tin-containing slag from pyrometallurgical recovery process of spent lead-acid battery is a valuable secondary Sn resource. However, the low content of Sn (~4 wt%) in this slag with complex impurities (Fe, Al, Pb, Zn, and Cu, etc.) makes it challenging for efficient tin separation. In this study, a low-temperature chlorinating process is proposed for tin recovery from the tin-containing slag by using ammonium chloride as the chlorinating reagent. Under the optimized chlorinating conditions, tin volatilization ratios of above 96% under both air and vacuum atmospheres could be achieved. However, the discrepancy between the temperatures of tin chlorinating and impurity metal chlorinating is more dramatic under the air atmosphere than that under vacuum, which facilitates the separation of impurities. Meanwhile, the decomposition rate of NH4Cl in air is much lower than that under vacuum atmosphere, resulting in less consumption of NH4Cl. The obtained chlorinated condensation product in air is subjected to a subsequent water leaching-alkali smelting-leaching-crystallization process to effectively separate Fe impurity and obtain the final sodium stannate product with a total tin recovery ratio of 94%. This study provides a promising strategy for the recovery of tin, and significant environmental benefit could be generated simultaneously with solid waste recycling.

AB - Tin-containing slag from pyrometallurgical recovery process of spent lead-acid battery is a valuable secondary Sn resource. However, the low content of Sn (~4 wt%) in this slag with complex impurities (Fe, Al, Pb, Zn, and Cu, etc.) makes it challenging for efficient tin separation. In this study, a low-temperature chlorinating process is proposed for tin recovery from the tin-containing slag by using ammonium chloride as the chlorinating reagent. Under the optimized chlorinating conditions, tin volatilization ratios of above 96% under both air and vacuum atmospheres could be achieved. However, the discrepancy between the temperatures of tin chlorinating and impurity metal chlorinating is more dramatic under the air atmosphere than that under vacuum, which facilitates the separation of impurities. Meanwhile, the decomposition rate of NH4Cl in air is much lower than that under vacuum atmosphere, resulting in less consumption of NH4Cl. The obtained chlorinated condensation product in air is subjected to a subsequent water leaching-alkali smelting-leaching-crystallization process to effectively separate Fe impurity and obtain the final sodium stannate product with a total tin recovery ratio of 94%. This study provides a promising strategy for the recovery of tin, and significant environmental benefit could be generated simultaneously with solid waste recycling.

KW - Ammonium chloride

KW - Chlorinating process

KW - Sodium stannate

KW - Tin recovery

KW - Tin-containing slag

UR - http://www.scopus.com/inward/record.url?scp=85103766944&partnerID=8YFLogxK

U2 - 10.1016/j.resconrec.2021.105611

DO - 10.1016/j.resconrec.2021.105611

M3 - 文章

AN - SCOPUS:85103766944

SN - 0921-3449

VL - 170

JO - Resources, Conservation and Recycling

JF - Resources, Conservation and Recycling

M1 - 105611

ER -