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Draft:Innovations and Solution in Electronic Waste Recycling

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  • Comment: this is an essay- please read WP:NOTESSAY. The subject of the article must be clear. Spiralwidget (talk) 16:42, 13 December 2024 (UTC)

New Methods for E-Waste Recycling

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There is a continuous innovation in the recycling industry in relation to electronic waste. These technologies and innovations enable the recovery of the precious metals such as aluminum , lithium, cobalt , copper etc. from recycling outdated and waste electronic products and devices . Previously, most of the times these procedures were executed by manual labors. Now, however, recycling machines and robotic arms have enabled efficient and faster separation of recyclable components, For instance, automated shredders and magnetic separators can remove metals from plastics and circuit boards minimizing the risk of exposure to toxic materials and accidents to the workers and improves the quality of work and efficiency of the whole process..[1]

The Role of Extended Producer Responsibility (EPR)

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One of the key elements in e-waste management is the concept of Extended producer responsibility(EPR), because holds manufacturers accountable for the lifecycle of their products, including disposal and recycling[2]. To promote recycling or the use of reusable parts, several countries have adopted this policy that promotes a move towards recyclable designs. Through EPR programs, companies are held accountable for the waste management generated by their products, theoretically relieving taxpayers by shifting the financial burden to the producers themselves.

The Importance of Consumer Education

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Although much attention in the management of e-waste is directed towards the recyclers and manufacturers, awareness of consumers is of great importance too. Many people are unaware of the proper ways to dispose of their old electronics. This often leads to electronics being thrown away, ending up in landfills or incinerators. Public awareness campaigns that highlight the importance of recycling and offer easy access to collection points can encourage responsible disposal[3] . These campaigns are helpful in addressing the issues of e-waste pollution and depletion of important resources.

Global E-Waste Challenges and Solutions

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Because of the global nature of the electronic waste crisis, many electronic devices have been sent out or imported to nations with less environmental regulations . The countries often lack the infrastructure to safely manage e-waste, leading to pollution and health hazards [4]. One potential solution is international cooperation to improve waste management systems in developing countries. It is possible that countries that heavily utilizes electronics can help develop improved waste recycling facilities in these areas to lessen the environmental damage caused by e-waste.

E-Waste and Circular Economy

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The concept of a circular economy is one of the most increasing and recently applied approaches in the management of e-waste; Instead of following the traditional linear model of "take, make, dispose," where products are used and then discarded, the circular economy promotes the idea of reusing, repairing, and recycling [5]. For electronics, this means creating devices that can be disassembled more easily, allowing components to be reused or recycled rather than sent to landfills. Companies are beginning to design products with longer lifespans and greater ease of repair, and some are even offering take-back programs where consumers can return old devices for recycling. Employing a circular economy approach to e-waste should make it possible to experience lower waste output, conserve natural resources, and lessen the negative effects of electronics on the environment .

Innovative E-Waste Disposal Solutions

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To address the growing global challenge of electrical waste, new disposal solutions are being developed. Hydrometallurgy is now being utilized by some companies as one of the efficient technologies for precious metal recovery from electronics[6]. The chemicals employed in these processes are environmentally safe and make use of less harmful compounds, such as replacing cyanide altogether. Furthermore, a few companies are into urban mining which is the recovery of valuable materials from old electronics, rather than the normal methods of mining [7]. The approach helps avoid the damaging of the environment that comes with mining activities and promotes the conservation of natural resources .

Notes

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  1. ^ Now, however, recycling machines and robotic arms have enabled efficient and faster separation of recyclable components, For instance, automated shredders and magnetic separators can remove metals from plastics and circuit boards minimizing the risk of exposure to toxic materials and accidents to the workers and improves the quality of work and efficiency of the whole process
  2. ^ One of the key elements in e-waste management is the concept of Extended producer responsibility(EPR), because holds manufacturers accountable for the lifecycle of their products, including disposal and recycling
  3. ^ Public awareness campaigns that highlight the importance of recycling and offer easy access to collection points can encourage responsible disposal
  4. ^ .The countries often lack the infrastructure to safely manage e-waste, leading to pollution and health hazards
  5. ^ The concept of a circular economy is one of the most increasing and recently applied approaches in the management of e-waste; Instead of following the traditional linear model of "take, make, dispose," where products are used and then discarded, the circular economy promotes the idea of reusing, repairing, and recycling
  6. ^ To address the growing global challenge of electrical waste, new disposal solutions are being developed. Hydrometallurgy is now being utilized by some companies as one of the efficient technologies for precious metal recovery from electronics
  7. ^ The chemicals employed in these processes are environmentally safe and make use of less harmful compounds, such as replacing cyanide altogether. Furthermore, a few companies are into urban mining which is the recovery of valuable materials from old electronics, rather than the normal methods of mining

References

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[1] [2] [3] [4] [5] [6] [7]

  1. ^ Kumar, A., Kumar, S., Kumar, U., Li, J., Li, K., Ma, C., Marra, A., Mishra, D., Naseri, T., Nayaka, G., Ongondo, F., Park, J., Petter, P., Prabaharan, G., Quan, S. and Rienzie, R. Author links open overlay panelEldon R. Rene a 1, a, 1, b, c, g, … Rienzie, R. (2021). Electronic waste generation, recycling and resource recovery: Technological perspectives and trends. Retrieved from https://www.sciencedirect.com/science/ar
  2. ^ Votechnik. (2023, June 19). The role of epr in shaping e-waste management strategies. For The Clean Future. https://forthecleanfuture.com/the-role-of-epr-in-shaping-e-waste-management-strategies/
  3. ^ Recycle, I. (2023, December 7). E-waste management: Challenges and solutions. Medium. https://itrecycle2020.medium.com/e-waste-management-challenges-and-solutions-98dc0a66c456
  4. ^ Elgarahy, A. M., Eloffy, M. G., Priya, A. K., Hammad, A., Zahran, M., Maged, A., & Elwakeel, K. Z. (2024). Revitalizing the circular economy: An exploration of e-waste recycling approaches in a technological epoch. Sustainable Chemistry for the Environment, 7, 100124. https://doi.org/10.1016/j.scenv.2024.100124 https://www.sciencedirect.com/science/article/pii/S2949839224000671
  5. ^ Ashiq, A., Kulkarni, J., & Vithanage, M. (2019). Hydrometallurgical recovery of metals from e-waste. In Electronic Waste Management and Treatment Technology (pp. 225–246). Elsevier. https://doi.org/10.1016/B978-0-12-816190-6.00010-8 https://research-repository.uwa.edu.au/en/publications/hydrometallurgical-recovery-of-metals-from-e-waste
  6. ^ Liu, K., Tan, Q., Yu, J., & Wang, M. (2023). A global perspective on e-waste recycling. Circular Economy, 2(1), 100028. https://doi.org/10.1016/j.cec.2023.100028 https://www.sciencedirect.com/science/article/pii/S2773167723000055
  7. ^ Ouro-Salim, O. (2024). Urban mining of e-waste management globally: Literature review. Cleaner Waste Systems, 9, 100162. https://doi.org/10.1016/j.clwas.2024.100162 https://www.sciencedirect.com/science/article/pii/S2772912524000344