Abstract
The issue of e-waste is global and is a mini catastrophe which is a big threat to the whole anthropogenosphere. There has been a laudable amount of research activities going on around the world on e-waste management for the last two decades. The last decade saw acceleration in developing and/or modifying technologies for environmentally sound e-waste recycling. However, this anthropogenic stockpile can be used for resource recovery and circulation. This is the main concept of urban mining, which facilitates the recovery of material and energy from urban waste and brings them back into the economy. The term urban mining has become synonymous with e-waste recycling as it is the most potential candidate for urban mining. It is important to tap this huge resource and bring it back to the economy. In reality, the stakeholders of e-waste business work in silos. It is quite relevant to bring them under one umbrella and look at things more in a systems approach. Partnership with the several units working as elements of an efficient supply chain will pave the path towards industrial symbiosis. Under the current investigation, the opportunities for establishing industrial symbiosis in case of e-waste recycling have been explored. A conceptual framework has been proposed based on literature survey and further analysis. Two realistic scenarios have been conceptualised—Presence of the companies in (a) two or three neighbouring zones and (b) scattered zone. A generalised discussion from the perspectives of sustainability has been provided to evaluate the two scenarios. It is expected to serve as prima facie for development of decision support systems in the future.
This is a preview of subscription content, log in via an institution to check access.
Access this chapter
Tax calculation will be finalised at checkout
Purchases are for personal use only
References
Amoyaw-Osei Y, Agyekum OO, Pwamang JA, Mueller E, Fasko R, Schluep M (2011) Ghana e-waste country assessment: SBC E-waste Africa project. Coordinated by the Basel convention
Baccini P, Brunner P (2012) Metabolism of the antroposphere: analysis, evaluation, design. The MIT Press, ISBN 9780262016650
Baidya R, Debnath B, Ghosh SK (2019) Analysis of E-Waste supply chain framework in India using the analytic hierarchy process. In: Ghosh SK (ed) Waste management and resource efficiency. Springer, Singapore, p 867
Balde CP, Forti V, Gray V, Kuehr R, Stegmann P (2017) The global e-waste monitor 2017: quantities, flows and resources. United Nations University (UNU), International Telecommunication Union (ITU) & International Solid Waste Association (ISWA), Bonn/Geneva/Vienna. ISBN Electronic Version: 978-92-808-9054-9
Baldé CP, Wang F, Kuehr R (2015) The global e-waste monitor–2014. United Nation University
Basel Convention (2014) Basel convention on the control of transboundary movements of hazardous wastes and their disposal protocol on liability and compensation for damage resulting from transboundary movements of hazardous wastes and their disposal texts and annexes. UNEP
Businesswire (2019) E-waste recycling & reuse services, 2019 report: global market size & share, application analysis, growth trends, key players, and competitive strategies to 2026. https://www.businesswire.com/news/home/20190206005377/en/E-waste-Recycling-Reuse-Services-2019-Report-Global. Accessed 15 Feb 2019
Chandrasekaran SR, Avasarala S, Murali D, Rajagopalan N, Sharma BK (2018) Materials and energy recovery from e-waste plastics. ACS Sustain Chem Eng 6(4):4594–4602
Chen YJ, Sheu JB, Lirn TC (2012) Fault tolerance modeling for an e-waste recycling supply chain. Transp Res Part E: Logistics and Transp Rev 48(5):897–906.
Chertow MR, Ashton WS, Espinosa JC (2008) Industrial symbiosis in Puerto Rico: environmentally related agglomeration economies. Reg Stud 42(10):1299–1312
Cossu R, Williams ID (2015) Urban mining: concepts, terminology, challenges. Waste Manag 45:1–3
Debnath B (2019) Sustainability of WEEE recycling in India. In: Jibin KP, Karaikal N, Thomas S, Nzihou A (eds) Reuse and recycling of materials: new headways. River Publishers, Netherlands, p 15
Debnath B, Baidya R, Ghosh SK (2015) Simultaneous analysis of WEEE management system focusing on the supply chain in India, UK and Switzerland. Int J Manu and Ind Eng 2:16–20
Debnath B, Roychoudhuri R, Ghosh SK (2016) E-waste management–a potential route to green computing. Procedia Environ Sci 35:669–675
Debnath B, Chowdhury R, Ghosh SK (2018a) Studies on sustainable material recovery via pyrolysis of WEEE. In: Abstracts of the 70th annual session of Indian Institute of Chemical Engineers, CHEMCON 2017, Haldia, West Bengal, India, 27–30 Dec 2017
Debnath B, Chowdhury R, Ghosh SK (2018b) Sustainability of metal recovery from E-waste. Front Environ Sci Eng 12:2. https://doi.org/10.1007/s11783-018-1044-9
Debnath B, Chowdhury R, Ghosh SK (2018c) Towards circular economy in E-waste recycling via metal recovery from E-waste (MREW) facilities. In: Proceedings of ISWA 2018 world congress, Kuala Lumpur, Malaysia, 22–24 Oct 2018
Debnath B, Chowdhury R, Ghosh SK (2019) Urban mining and the metal recovery from E-waste (MREW) supply chain. In: Ghosh SK (ed) Waste valorisation and recycling. Springer Nature, Singapore, p 341
ETC/RWM (2003) European Topic Centre on Resource and Waste Management (Topic Centre of the European Environment Agency) part of the European Environment Information and Observation Network (EIONET). http://waste.eionet.eu.int/waste/6. Accessed 15 Feb 2019
Eurostat (2014) Statistics explained. http://ec.europa.eu/eurostat/statistics-explained/index.php/Main_Page. Accessed 15 Feb 2019
Gaikwad V, Ghose A, Cholake S, Rawal A, Iwato M, Sahajwalla V (2018) Transformation of E-waste plastics into sustainable filaments for 3D printing. ACS Sus Chem Eng 6(11):14432–14440
Gao R, Xu Z (2019) Pyrolysis and utilization of nonmetal materials in waste printed circuit boards: debromination pyrolysis, temperature-controlled condensation, and synthesis of oil-based resin. J Haz Mat 364:1–10
Ghodrat M, Rhamdhani MA, Brooks G, Rashidi M, Samali B (2017) A thermodynamic-based life cycle assessment of precious metal recycling out of waste printed circuit board through secondary copper smelting. Environ Dev 24:36–49
Ghosh SK, Agamuthu P (2018) Circular economy: the way forward. Waste Manag Res 36(6):481–482
Ghosh SK, Baidya R, Debnath B, Biswas NT, De D, Lokeswari M (2014a) E-waste supply chain issues and challenges in India using QFD as analytical tool. In: Proceedings of international conference on computing, communication and manufacturing, ICCCM 2014, 22–23 Nov 2014
Ghosh A, Debnath B, Ghosh SK, Das B, Sarkar JP (2018) Sustainability analysis of organic fraction of municipal solid waste conversion techniques for efficient resource recovery in India through case studies. J Mater Cycles and Waste Manage 20(4):1969–1985
Ghosh SK, Singh N, Debnath B, De D, Baidya R, Biswas NT, Ghosh SK, Lili L, Dey PK, Li J (2014b) E-waste supply chain management: findings from pilot studies in India, China, Taiwan (ROC) and the UK. In: Proceedings of the 9th international conference on waste management and technology, Beijing China, 29–31 Oct 2014
Ghosh SK, Debnath B, Baidya R, De D, Li J, Ghosh SK, Zheng L, Awasthi AK, Liubarskaia MA, Ogola JS, Tavares AN (2016) Waste electrical and electronic equipment management and Basel convention compliance in Brazil, Russia, India, China and South Africa (BRICS) nations. Waste Manag Res 34(8):693–707
Hadi P, Xu M, Lin CS, Hui CW, McKay G (2015) Waste printed circuit board recycling techniques and product utilization. J Haz Mat 283:234–243
Hall WJ, Williams PT (2007) Separation and recovery of materials from scrap printed circuit boards. Resour Conserv and Recycl 51(3):691–709
Hazra J, Sarkar A, Sharma S (2011) E-waste supply chain management in India: opportunities and challenges. Clean Ind J 7(12)
He Y, Ma E, Xu Z (2014) Recycling indium from waste liquid crystal display panel by vacuum carbon-reduction. J Haz Mat 268:185–190
Huang K, Guo J, Xu Z (2009) Recycling of waste printed circuit boards: a review of current technologies and treatment status in China. J Haz Mat 164(2–3):399–408
Iannicelli-Zubiani EM, Giani MI, Recanati F, Dotelli G, Puricelli S, Cristiani C (2017) Environmental impacts of a hydrometallurgical process for electronic waste treatment: a life cycle assessment case study. J Clean Prod 140:1204–1216
Ilankoon IMSK, Ghorbani Y, Chong MN, Herath G, Moyo T, Petersen J (2018) E-waste in the international context–a review of trade flows, regulations, hazards, waste management strategies and technologies for value recovery. Waste Manag 82:258–275
Jacobsen NB (2006) Industrial symbiosis in Kalundborg, Denmark: a quantitative assessment of economic and environmental aspects. J Ind Eco 10(1–2):239–255
Khaliq A, Rhamdhani M, Brooks G, Masood S (2014) Metal extraction processes for electronic waste and existing industrial routes: a review and Australian perspective. Resour 3(1):152–179
Kirby PW (2019) Materialities meet the mangle: electronic waste scavenging in Japan and China. Geoforum 102:48–56
Marconi M, Gregori F, Germani M, Papetti A, Favi C (2018) An approach to favour industrial symbiosis: the case of waste electrical and electronic equipment. Proced Manuf 21:502–509
Martins TAG, Gomes KE, Rosario CGA, Espinosa DCR, TenĂłrio JAS (2019) Characterization of printed circuit boards of obsolete (PCBs) aimed at the production of copper nanoparticles. In: Li B et al (eds) Characterization of minerals, metals, and materials 2019. The Minerals, Metals & Materials Series. Springer, Cham, p 543
Masud MH, Akram W, Ahmed A, Ananno AA, Mourshed M, Hasan M, Joardder MUH (2019) Towards the effective E-waste management in Bangladesh: a review. Environ Sci Pollut Res 26(2):1250–1276
Mathews JA, Tan H (2016) Circular economy: lessons from China. Nat News 531(7595):440
Menikpura SN, Santo A, Hotta Y (2014) Assessing the climate co-benefits from waste electrical and electronic equipment (WEEE) recycling in Japan. J Clean Prod 74:183–190
Mirata M, Emtairah T (2005) Industrial symbiosis networks and the contribution to environmental innovation: the case of the Landskrona industrial symbiosis programme. J Clean Prod 13(10–11):993–1002
Ning C, Lin CSK, Hui DCW, McKay G (2017) Waste printed circuit board (PCB) recycling techniques. Top Curr Chem (Z) 375:43. https://doi.org/10.1007/s41061-017-0118-7
Obaje SO (2013) Electronic waste scenario in Nigeria: Issues, problems and solutions. Int J Eng Sci Invent 2(11):31–36
Odeyingbo AO, Nnorom IC, Deubzer OK (2019) Used and waste electronics flows into Nigeria: assessment of the quantities, types, sources, and functionality status. Sci Tot Environ 666:103–113
Ogungbuyi O, Nnorom IC, Osibanjo O, Schluep M (2012) E-waste country assessment of Nigeria. E-Waste Africa Project of the Secretariat of the Basel convention. Retrieved from http://www.basel.int/Portals/4/Basel%20Convention/docs/eWaste/EwasteAfrica_Nigeria-Assessment.pdf
Park YK, Han TU, Jeong J, Kim YM (2019) Debrominated high quality oil production by the two-step catalytic pyrolysis of phenolic printed circuit boards (PPCB) using natural clays and HY. J Haz Mat 367:50–58
Sahajwalla V, Gaikwad V (2018) The present and future of e-waste plastics recycling. Curr Opin Green Sust Chem 13:102–107
Salbidegoitia JA, Fuentes-Ordóñez EG, González-Marcos MP, González-Velasco JR, Bhaskar T, Kamo T (2015) Steam gasification of printed circuit board from e-waste: effect of coexisting nickel to hydrogen production. Fuel Proc Tech 133:69–774
Shen Y, Zhao R, Wang J, Chen X, Ge X, Chen M (2016) Waste-to-energy: Dehalogenation of plastic-containing wastes. Waste Manag 49:287–303
Shen Y, Chen X, Ge X, Chen M (2018) Chemical pyrolysis of E-waste plastics: char characterization. J Environ Manag 214:94–103
Shi H, Chertow M, Song Y (2010) Developing country experience with eco-industrial parks: a case study of the Tianjin Economic-Technological Development Area in China. J Clean Prod 18(3):191–199
Shinkuma T, Thi Minh Huong N (2009) The flow of E-waste material in the Asian region and a reconsideration of international trade policies on E-waste. Environ Imp Assess Rev 29(1):25–31. https://doi.org/10.1016/j.eiar.2008.04.004
Slack RJ, Gronow JR, Voulvoulis N (2009) The management of household hazardous waste in the United Kingdom. J Environ Manag 90:153–165
Statistic (2019) Outlook on e-waste generation globally 2018. Retrieved from https://www.statista.com/statistics/499891/projection-ewaste-generation-worldwide/. Accessed 15 Feb 2019
Streicher-Porte M, Widmer R, Jain A, Bader HP, Scheidegger R, Kytzia S (2005) Key drivers of the e-waste recycling system: assessing and modelling e-waste processing in the informal sector in Delhi. Environ Imp Assess Rev 25(5):472–491
Tran CD, Salhofer SP (2018) Analysis of recycling structures for e-waste in Vietnam. J Mater Cycles Waste Manag 20(1):110–126
Vehlow J, Bergfeldt B, Jay K, Seifert H, Wanke T, Mark FE (2000) Thermal treatment of electrical and electronic waste plastics. Waste Manag Res 18(2):131–140
Wang F, Kuehr R, Ahlquist D, Li J (2013) E-waste in China: a country report. Tsinghua University
Wang J, Wang H, Yue D (2019) Optimization of surface treatment using sodium hypochlorite facilitates co-separation of ABS and PC from WEEE plastics by flotation. Environ Sci Tech 53(4):2086–2094
Wath SB, Vaidya AN, Dutt PS, Chakrabarti T (2010) A roadmap for development of sustainable E-waste management system in India. Sci Total Environ 409(1):19–32
Wen Z, Meng X (2015) Quantitative assessment of industrial symbiosis for the promotion of circular economy: a case study of the printed circuit boards industry in China’s Suzhou New District. J Clean Prod 90:211–219
Widmer R, Oswald-Krapf H, Sinha-Khetriwal D, Schnellmann M, Böni H (2005) Global perspectives on e-waste. Environ Imp Assess Rev 25(5):436–458
Yamawaki T (2003) The gasification recycling technology of plastics WEEE containing brominated flame retardants. Fire Mater 27(6):315–319
Yang J, Retegan T, Ekberg C (2013) Indium recovery from discarded LCD panel glass by solvent extraction. Hydrometallurgy 137:68–77
Zeng X, Mathews JA, Li J (2018) Urban mining of e-waste is becoming more cost-effective than virgin mining. Environ Sci Tech 52(8):4835–4841
Zhang S, Yoshikawa K, Nakagome H, Kamo T (2013) Kinetics of the steam gasification of a phenolic circuit board in the presence of carbonates. App Energy 101:815–821
Author information
Authors and Affiliations
Corresponding author
Editor information
Editors and Affiliations
Rights and permissions
Copyright information
© 2020 Springer Nature Switzerland AG
About this chapter
Cite this chapter
Debnath, B. (2020). Towards Sustainable E-Waste Management Through Industrial Symbiosis: A Supply Chain Perspective. In: Salomone, R., Cecchin, A., Deutz, P., Raggi, A., Cutaia, L. (eds) Industrial Symbiosis for the Circular Economy. Strategies for Sustainability. Springer, Cham. https://doi.org/10.1007/978-3-030-36660-5_6
Download citation
DOI: https://doi.org/10.1007/978-3-030-36660-5_6
Published:
Publisher Name: Springer, Cham
Print ISBN: 978-3-030-36659-9
Online ISBN: 978-3-030-36660-5
eBook Packages: Earth and Environmental ScienceEarth and Environmental Science (R0)