A New Pyrometallurgical Recycling Technique for Lead Battery Paste without SO2 Generation: A Thermodynamic and Experimental Investigation

Research output: Chapter in Book/Report/Conference proceedingChapterScientificpeer-review

Standard

A New Pyrometallurgical Recycling Technique for Lead Battery Paste without SO2 Generation : A Thermodynamic and Experimental Investigation. / Li, Yun; Chen , Yongming ; Tang, Chaobo; Yang, Shenghai ; Klemettinen, Lassi; Rämä, Minna; Wan, Xingbang; Jokilaakso, Ari.

Extraction 2018: Proceedings of the First Global Conference on Extractive Metallurgy. Springer International Publishing, 2018. p. 1109-1120 (The Minerals, Metals & Materials Series).

Research output: Chapter in Book/Report/Conference proceedingChapterScientificpeer-review

Harvard

Li, Y, Chen , Y, Tang, C, Yang, S, Klemettinen, L, Rämä, M, Wan, X & Jokilaakso, A 2018, A New Pyrometallurgical Recycling Technique for Lead Battery Paste without SO2 Generation: A Thermodynamic and Experimental Investigation. in Extraction 2018: Proceedings of the First Global Conference on Extractive Metallurgy. The Minerals, Metals & Materials Series, Springer International Publishing, pp. 1109-1120, Global Conference on Extractive Metallurgy, Ottawa, Canada, 26/08/2018. https://doi.org/10.1007/978-3-319-95022-8_90

APA

Li, Y., Chen , Y., Tang, C., Yang, S., Klemettinen, L., Rämä, M., ... Jokilaakso, A. (2018). A New Pyrometallurgical Recycling Technique for Lead Battery Paste without SO2 Generation: A Thermodynamic and Experimental Investigation. In Extraction 2018: Proceedings of the First Global Conference on Extractive Metallurgy (pp. 1109-1120). (The Minerals, Metals & Materials Series). Springer International Publishing. https://doi.org/10.1007/978-3-319-95022-8_90

Vancouver

Li Y, Chen Y, Tang C, Yang S, Klemettinen L, Rämä M et al. A New Pyrometallurgical Recycling Technique for Lead Battery Paste without SO2 Generation: A Thermodynamic and Experimental Investigation. In Extraction 2018: Proceedings of the First Global Conference on Extractive Metallurgy. Springer International Publishing. 2018. p. 1109-1120. (The Minerals, Metals & Materials Series). https://doi.org/10.1007/978-3-319-95022-8_90

Author

Li, Yun ; Chen , Yongming ; Tang, Chaobo ; Yang, Shenghai ; Klemettinen, Lassi ; Rämä, Minna ; Wan, Xingbang ; Jokilaakso, Ari. / A New Pyrometallurgical Recycling Technique for Lead Battery Paste without SO2 Generation : A Thermodynamic and Experimental Investigation. Extraction 2018: Proceedings of the First Global Conference on Extractive Metallurgy. Springer International Publishing, 2018. pp. 1109-1120 (The Minerals, Metals & Materials Series).

Bibtex - Download

@inbook{44f22d0cb29e4b40a4f8ba111b1a4086,
title = "A New Pyrometallurgical Recycling Technique for Lead Battery Paste without SO2 Generation: A Thermodynamic and Experimental Investigation",
abstract = "An innovative lead recycling process from scrap lead-acid battery paste is presented. The novelty in the process is avoiding SO2 generation and emission by using reductive sulfur-fixing technique. Iron-bearing secondary wastes produced from metallurgical industry were utilized as sulfur-fixing agent to capture sulfur in the form of FeS (s) instead of generation of SO2 (g). Molten Na2CO3 salt was added to the smelting system to speed the reactions and improve valuable metals’ recovery and sulfur-fixation efficiency. Furthermore, this process can simultaneously co-treat various lead and iron-bearing wastes. At the same time, some precious metals, such as Au and Ag, contained in iron-bearing wastes can be recovered. The feasibility and reliability of this process was investigated thermodynamically and experimentally with the help of HSC 9.0 database and XRD and SEM-EDS analysis. A possible reaction mechanism and path in PbSO4-Fe2O3-Na2CO3-C smelting system was also clarified.",
author = "Yun Li and Yongming Chen and Chaobo Tang and Shenghai Yang and Lassi Klemettinen and Minna R{\"a}m{\"a} and Xingbang Wan and Ari Jokilaakso",
note = "https://www.springerprofessional.de/extraction-2018/16053724?tocPage=1",
year = "2018",
doi = "10.1007/978-3-319-95022-8_90",
language = "English",
isbn = "978-3-319-95021-1",
series = "The Minerals, Metals & Materials Series",
publisher = "Springer International Publishing",
pages = "1109--1120",
booktitle = "Extraction 2018",

}

RIS - Download

TY - CHAP

T1 - A New Pyrometallurgical Recycling Technique for Lead Battery Paste without SO2 Generation

T2 - A Thermodynamic and Experimental Investigation

AU - Li, Yun

AU - Chen , Yongming

AU - Tang, Chaobo

AU - Yang, Shenghai

AU - Klemettinen, Lassi

AU - Rämä, Minna

AU - Wan, Xingbang

AU - Jokilaakso, Ari

N1 - https://www.springerprofessional.de/extraction-2018/16053724?tocPage=1

PY - 2018

Y1 - 2018

N2 - An innovative lead recycling process from scrap lead-acid battery paste is presented. The novelty in the process is avoiding SO2 generation and emission by using reductive sulfur-fixing technique. Iron-bearing secondary wastes produced from metallurgical industry were utilized as sulfur-fixing agent to capture sulfur in the form of FeS (s) instead of generation of SO2 (g). Molten Na2CO3 salt was added to the smelting system to speed the reactions and improve valuable metals’ recovery and sulfur-fixation efficiency. Furthermore, this process can simultaneously co-treat various lead and iron-bearing wastes. At the same time, some precious metals, such as Au and Ag, contained in iron-bearing wastes can be recovered. The feasibility and reliability of this process was investigated thermodynamically and experimentally with the help of HSC 9.0 database and XRD and SEM-EDS analysis. A possible reaction mechanism and path in PbSO4-Fe2O3-Na2CO3-C smelting system was also clarified.

AB - An innovative lead recycling process from scrap lead-acid battery paste is presented. The novelty in the process is avoiding SO2 generation and emission by using reductive sulfur-fixing technique. Iron-bearing secondary wastes produced from metallurgical industry were utilized as sulfur-fixing agent to capture sulfur in the form of FeS (s) instead of generation of SO2 (g). Molten Na2CO3 salt was added to the smelting system to speed the reactions and improve valuable metals’ recovery and sulfur-fixation efficiency. Furthermore, this process can simultaneously co-treat various lead and iron-bearing wastes. At the same time, some precious metals, such as Au and Ag, contained in iron-bearing wastes can be recovered. The feasibility and reliability of this process was investigated thermodynamically and experimentally with the help of HSC 9.0 database and XRD and SEM-EDS analysis. A possible reaction mechanism and path in PbSO4-Fe2O3-Na2CO3-C smelting system was also clarified.

U2 - 10.1007/978-3-319-95022-8_90

DO - 10.1007/978-3-319-95022-8_90

M3 - Chapter

SN - 978-3-319-95021-1

T3 - The Minerals, Metals & Materials Series

SP - 1109

EP - 1120

BT - Extraction 2018

PB - Springer International Publishing

ER -

ID: 28008698