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2023 | OriginalPaper | Chapter

7. Waste Lead-Acid Battery Recycling Technologies

Authors : Mahmut Altiner, Soner Top, Sait Kursunoglu

Published in: Recycling Technologies for Secondary Zn-Pb Resources

Publisher: Springer International Publishing

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Abstract

The growing of collected waste lead-acid battery quantity means the growing demand for secondary lead (Pb) material for car batteries, both needed for increased cars’ production and for replacing of waste batteries for the increased number of automobiles in service. Pb recycling is critical to keep pace with growing energy storage needs. In recent years, tightening emission regulations have forced many developed country smelters to close. This has driven battery manufacturers and distributors to increasingly rely upon unregulated smelting operations in developing nations, negatively impacting the environment and human health. Therefore, finding a cleaner and more cost-efficient Pb recovery and recycling method is critical to the Pb recycling community.

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previous chapter Hydrometallurgical Recovery of Zinc from By-Products and Waste Materials of Hot-Dip Galvanizing Process

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Andrews D, Raychaudhuri A, Frias C (2000) Environmentally sound technologies for recycling secondary lead. J Power Sources 88(1):124–129CrossRef

Agrawal A, Sahu KK, Panday BC (2004) Recent trends and current practices for secondary processing of zinc and lead: part 1: lead recovery from secondary sources. Waste Manage Res 22:240–247CrossRef

Arai K, Toguri JM (1984) Hydrometallurgy 12:49–59CrossRef

Badanoıu G, Bazuta T, Bazuta M, Butu M (2013) Study concerning PbO solubility in NaOH solution for the treatment of sulfate-oxide pastes obtained from dismantling used lead-acid batteries. Rev Chim (Buchatest) 64(3):1004-1010

Badanoıu G et al (2014) Study of PbSO₄ solubilization in NaOH solution for the treatment of oxide-sulphite pastes obtained from dismembered lead-acid batteries. U.P.B. Sci Bul Ser B 26(1):209–218

Battery University (2016) BU-201: How does the Lead Acid Battery Work? http://batteryuniversity.comlearn/article/lead_based_batteries. Accessed 5 April 21

Bernardes AM, Espinosa DCR, Tenório JS (2004) Recycling of batteries: a review of current processes and technologies. J Power Sources 130(1–2):291–298CrossRef

Best Available Techniques (BAT) reference, 2014. Document for the non-ferrous metals industries final draft: 1242

Chen TT, Dutrizac JE (1996) The mineralogical characterization of lead-acid battery paste. Hydrometallurgy 40(1–2):223–245. https://doi.org/10.1016/0304-386X(94)00081-DCrossRef

Chen W, Tian Y, Bian K, Zheng Y (1996) Basic electrolytic method for recovery of lead from scrap batteries. Trans Nonferrous Metals Soc China (English Edition) 6(4):47–51

Chen W, Tian Y (1997) Recovery of lead from waste battery slimes. Nonfer. Met. 49–64:7 (in Chinese)

Chen CS, Shih YJ, Huang YH (2016) Recovery of lead from smelting fly ash of waste lead-acid battery by leaching and electrowinning. Waste Manage 52:212–220CrossRef

Directive 2006/66/EC of the European Parliament and of the Council of 6 September 2006 on batteries and accumulators and waste batteries and accumulators and repealing directive 91/157/EEC, Orkesterjournalen L 266 (2006)

DPT (2001) State planning organization, eighth five-year development plan, mining special expertise commission report, metal mines Sub-Commission Lead-Zınc-cadmium working group Report. 167 p

Dutrizac JE, Mounsey EN, Piret NL (Eds) (2000) Lead-Zinc, TMS, pp 149–169

Egan RC, Rao VM, Libsch EC (1980) Cigan JM, Mackey TS, O'Keefe TJ (Eds), Lead-Zinc-Tin ‘80, Metall. Soc. AIME, pp 953–973

EPA (2012) Federal register, Part II 77(3):559

Ferracin LC, Chácon-Sanhueza AE, Davoglio RA, Rocha LO, Caffeu DJ, Fontanetti AR, Bocchi N (2002) Lead recovery from a typical Brazilian sludge of exhausted lead-acid batteries using an electrohydrometallurgical process. Hydrometallurgy 65:137–144

Forrest H, Wilson JD (1990) Mackey TS, Prengaman RD (Eds), Lead-Zinc ‘90, TMS, pp 971–999

Gong Y, Dutrizac JE, Chen TT (1992) The conversion of lead sulphate to leadcarbonate in sodium carbonate media. Hydrometallurgy 28:399–421CrossRef

Kammer U, Schenker U, Wieden HD (1993) Hager JP (Ed), EPD congress, pp 917–926

Kumar et al (2006) Lead recycling. P. British Pat., GB0622249.1. 2006–08–11

Laubertova M, Piroskova J, Dociova S (2017) The technology of lead production from waste. Erzmetall 70:47–54

Li L, Zhu X, Yang D, Gao L, Liu J, Kumar RV, Yang J (2012) Preparation and characterization of nano-structured lead oxide from spent lead-acid battery paste. J. Hazard Mater 203:274–282CrossRef

Li et al (2013) Lead citrate precursor route to synthesize nano-structural lead oxide from spent lead-acid battery paste. J Mater Res Bull 48:1700–1708. https://doi.org/10.1016/j.materresbull.2013.01.031

Liu J et al (2018) Evaluation of ammonium citrate tribasic as a leaching reagent for a lead-bearing ore, Physicochem. Probl Miner Process 55(3):689–700. https://doi.org/10.5277/ppmp18183

Liu W, Deng X, Zhang D, Yang T, Chen L (2018) A clean process of lead recovery from spent lead paste on hydrothermal reduction. Trans Nonferrous Metals Soc China 28:2360–2367CrossRef

Lu X, Ning P-H, Lee K, Shih F, Wang EYZ (2017) Transformation of hazardous lead into lead ferrite ceramics: crystal structures and their role in lead leaching. J. Hazard Mater 336:139–145CrossRef

Lyakov N et al (2007) Desulphurization of damped battery paste by sodium carbonate and sodium hydroxide. J Power Sources 171(2):960–965. https://doi.org/10.1016/j.jpowsour.2007.06.014CrossRef

Ma Y, Qui K (2015) Recovery of lead from lead paste in spent lead-acid battery by hydrometallurgical desulfurization and vacuum thermal reduction. Waste Manage 40:151–156. https://doi.org/10.1016/j.wasman.2015.03.010CrossRef

Ma N (2016) Recycling of basic oxygen furnace steelmaking dust by in-process separation of zinc from dust. J Cleaner Prod 112:4497–4504. https://doi.org/10.1016/j.jclepro.2015.07.009CrossRef

Ma C, Shu Y, Chen H (2016a) Leaching of spent lead paste by oxalate and sodium oxalate solution and prepared leady oxide powder in nitrogen and air for lead-acid battery. J Electrochem Soc 163(10):A2240–A2247CrossRef

Ma C, Shu Y, Chen H (2016b) Preparation of high-purity lead oxide from the spent lead paste by low-temperature burning and hydrometallurgical processing with ammonium acetate solution. RSC Adv 6(25):21148–21155CrossRef

Matthew SP (1990) Mackey TS, Prengaman RD (Eds), Lead-Zinc ‘90, TMS, pp 889–901

Melin AE (1992) Annual Meeting 1992 of the European Tin and Lead Smelters Club. Munich, Germany, pp 1–13

Millotte D (2005). in: Fujisawa T, Dutrizac JE, Fuwa A, Piret NL, Siegmund A (Eds), Lead-Zinc ‘05, pp 885–898

Ning P, Pan J, Li X, Zhou Y, Chen, J, Wang J (2016) Accelerated desulphurization of waste lead battery paste in a high-gravity rotating packed bed. Chem Eng Proc Process Intensification 104:148–153

Prengaman RD (1995) Recovering lead from batteries. JOM 47(1):31–33CrossRef

Prengaman RD, Lam TM (2005) in Fujisawa T, Dutrizac JE, Fuwa A, Piret NL, Sigmund A (Eds), Lead-zinc’05, 1375–1389

Prengaman RD, Mirza AH (2017) Recycling concept for lead-acid batteries, Lead-acid batteries for future automobiles, Chapter 20, pp 575–598.https://doi.org/10.1016/B978-0-444-63700-0.00020-9

Queneau PB, Cregar DE, Mickey DR (1989) Jaeck ML (Ed), Primary and secondary lead processing, 28th conference of metallurgists, CIM, Halifax Pergamon Press, pp 145–178

Ramus K, Hawkins P (1993) Lead/acid battery recycling and the new Isasmelt process. J Power Sources 42(1–2):299–313CrossRef

Reyes NRR, Vargas LE, Perez SS (2018) Thermokinetics of lead leaching from recycled batteries. IngenieriaYdesarrollo Universidad Del North 36(1):155–171

Roberts H (2020) Evaluation of global secondary lead production. In: Siegmund A et al (eds) PbZn 2020: 9th international symposium on lead and zinc processing, TMS. Springer, p 3

Schwartz W, Haase W (1964) NML Tech. J. Jamshedpur India 6:42–44

Sonmez MS, Kumar RV (2009a). Leaching of waste battery paste components. Part 2: leaching and desulphurisation of PbSO₄ by citric acid and sodium citrate solution, Hydrometallurgy 95(1–2):82–86, https://doi.org/10.1016/j.hydromet.2008.04.019

Sonmez MS, Kumar RV (2009b) Hydrometallurgy 95:53–60

Sonmez MS, Kumar RV (2008a) Leaching of waste battery paste components. Part 2: leaching and desulphurisation of PbSO₄ by citric acid and sodium citrate solution. J Hydrometallurgy 95:82–86. https://doi.org/10.1016/j.hydromet.2008b.04.019

Sonmez K (2008b) Leaching of waste battery paste components. Part 1: lead citrate synthesis from PbO and PbO₂. J Hydrometall 95:53–60. https://doi.org/10.1016/j.hydromet.2008a.04.012

Sun X, Li H, Zhu X, Zhang W, Hu Y, Yang J (2013) Study on effects of complex desulfurizer on the desulfurization ratio of lead pastes from the used lead-acid battery. Chinese Labat Man 4:002

Sun X, Yang J, Zhang W, Zhu X, Hu Y, Yang D, Yuan X, Yu W, Dong H, Wang L, Li RVK, Liang S (2014) Lead acetate trihydrate precursor route to synthesize novel ultrafine lead oxide from spent lead-acid battery pastes. J Power Sources 269:565–576CrossRef

Sun Z, Cao H, Zhang X, Lin X, Zheng W, Cao G, Sun Y, Zhang Y (2017) Spent lead-acid battery recycling in China—a review and sustainable analyses on the mass flow of lead. Waste Manage 64:190–201CrossRef

Tan S-Y, Payne, Hallett JP, Kelsall GH (2019) Developments in electrochemical processes for recycling lead-acid batteries. Current Opinion Electrochemi 16:83-89, ISSN 2451-9103.https://doi.org/10.1016/j.coelec.2019.04.023

Tian X, Wu Y, Hou P, Liang S, Qu S, Xu M, Zuo T (2017) Environmental impact and economic assessment of secondary lead production: comparison of main spent lead-acid battery recycling processes in China. J Clean Prod 144:142–148CrossRef

Torabi F, Ahmadi P (2020) Simulation of battery systems. Academic Press, pp 1–54. https://doi.org/10.1016/B978-0-12-816212-5.00005-2

USGS (2021) Abundance (atom fraction) of the chemical elements in Earth's upper continental crust as a function of atomic number. https://pubs.usgs.gov/fs/2002/fs087-02/

Vest H (2002) Fundamentals of the recycling of lead-acid batteries. Eschborn, Germany. http://www.gtz.de/gate/

Weijma J, Hoop K, Bosma W, Dijkman H (2002) Biological conversion of anglesite and lead waste from spent car batteries to galena. Biotech Prog 18:770–775CrossRef

Wood J, Coveney J, Hoang J, Reuter MA (2009) Small-scale secondary lead processing using ausmelt TSL technology, small-scale secondary lead processing using ausmelt TSL technology, Secondary lead conference, Macau, 30–31st August 2009 (preprints)

Wu X (2020) Application of CSC technology in nonferrous metallurgy, PbZn 2020. In: Siegmund A et al. (eds) 9th international symposium on lead and zinc processing, TMS. Springer

Yanakieva VP, Haralampiev GA, Lyakov NK (2000) Desulphurization of the damped lead battery pastes with potassium carbonate. J Power Sources 85(1):178–180CrossRef

Ye L, Duan L, Liu W, Hu Y, Ouyang Z, Yang S,Xia Z (2020) A facile method for preparing a nano lead powder by vacuum decomposition from spent lead-acid battery paste: leaching and desulfuration in tartaric acid and sodium tartrate mixed lixivium, Hydrometallurgy, 197

Yi H, Yang Z, Yufeng W, Xi T, Xiaoqin J (2019)Tracking flows of secondary vehicle batteries in China, resources, conservation and recycling 142:34–36, ISSN 0921–3449, https://doi.org/10.1016/j.resconrec.2018.11.016

Yu W et al. (2019) A low emission strategy to recover lead compound products directly from spent lead-acid battery paste: key issue of impurities removal. J Cleaner Prod 210:1534–1544. https://doi.org/10.1016/j.jclepro.2018.11.133

Zhang Q (2013) The current status on the recycling of lead-acid batteries in China. Int J Electrochem Sci 8:6457–6466

Zhang W et al (2016) A critical review on secondary lead recycling technology and its prospects. Renew Sustain Energy Rev 61:108–122. https://doi.org/10.1016/j.rser.2016.03.046CrossRef

Zhang X, Sun Y, Pan J (2017) A clean and highly efficient leaching-electrodeposition lead recovery route in HClO₄ Solution. Int J Electrochem Sci 12:6966–6979CrossRef

Zhu X, Li L, Sun X, Yang D, Gao L, Liu J, Kumar RV, Yang J (2012) Preparation of basic lead oxide from spent lead-acid battery paste via chemical conversion. Hydrometallurgy 117–118:24–31CrossRef

Zhu X, He X, Yang J, Liu J, Yang D et al (2013a) Leaching of spent lead-acid battery paste components by sodium citrate and acetic acid. Journal of Hazardous Materials, Volumes 250–251:387–396. https://doi.org/10.1016/j.jhazmat.2013.02CrossRef

Zhu X, Li L, Liu J, Kumar RW Yang J (2013b) Leaching properties of lead paste in spent lead acid battery with a hydrometallurgical process at room temperature. Envitron Eng Manag J, 12

https://docplayer.net/21445749-Secondary-lead-smelting.html

http://www.engitec.com/en/lead/

https://www.engineering.com/story/battery-recycling-technologies-part-2-recycling-lead-acid-and-li-ion

https://ecobatgroup.com/ecobatgroup-wAssets/img/products/Supersoftultra.pdf

https://www.metal.com/Lead

www.mogroup.com

https://www.mogroup.com/portfolio/ausmelt-tsl-process/

https://www.statista.com/statistics/675876/average-prices-lead-worldwide/

www.aquametals.com

www.engitec.com

www.kudretmetal.com

Title: Waste Lead-Acid Battery Recycling Technologies
Authors: Mahmut Altiner
Soner Top
Sait Kursunoglu
Publisher: Springer International Publishing
Book: Recycling Technologies for Secondary Zn-Pb Resources
Print ISBN: 978-3-031-14684-8

Electronic ISBN: 978-3-031-14685-5

Copyright Year: 2023
DOI: https://doi.org/10.1007/978-3-031-14685-5_7

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