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Emerging Technologies in E-Waste and Battery Recycling
Emerging Technologies in E-Waste and Battery Recycling
Innovative Technologies for the Recovery and Reuse of Heavy Metals and Rare Earth Elements from End-of-Life Electronics and Batteries
RELEASE DATE
27-Sep-2018
27-Sep-2018
REGION
Global
Global
Research Code: D80E-01-00-00-00
SKU: EN01095-GL-TR_22342
$4,950.00
In stock
SKU
EN01095-GL-TR_22342
Description
Electronic and battery waste should be considered as an important source for the recovery of crucial precious metals including Lead, Lithium, Nickel, Cadmium, Cobalt, and Copper. The recovery of rare earth metals from end-of-life electronics and batteries will reduce the burden on landfills and will also prevent leaching of hazardous compounds into the ground water which can reduce soil fertility and can also have serious implications on human health and the environment. Recovery of precious metals through conventional hydro and pyro metallurgical processes is a capital and time intensive process that results in lesser recovery rates. Recovery of precious metals by novel processes will also reduce the operational and maintenance costs and will also reduce emissions of greenhouse gases. The federal regulations of all countries should also consider stringent emission discharge permissible limits for hazardous gases in order to reduce the impact on the environment and human health.
The research study has identified the utilization of futuristic physiochemical processes that will enable the efficient recovery of precious metals from end-of-life batteries.
Table of Contents
1.1 Research Scope
1.2 Research Process and Methodology
1.3 Key Findings in Emerging E-Waste and Battery Recycling Technologies
2.1 E-Waste Contains Valuable Materials that Offer Opportunities for Recovery and Recycling
2.2 Recovery of Heavy Metals and Toxic Electrolytes from Batteries Results in Reduced Impact on the Environment and Human Health
2.3 The Consumer Segment Contributes the Highest Share of E-waste Generated
2.4 Highly Valuable Composition Necessitates E-Waste Recycling Technologies
2.5 Physical Separation Requires Low Capital but Suffers from High Metal Loss Percentage
2.6 Eco-friendly Metal Recycling Technologies are the Need of the Hour
2.7 Level of Contamination Impacts the Market Value of Outputs from E-Waste and Battery Recycling Technologies
2.8 Heavy Metals and Flame Retardants are the Most Polluting Materials in the E-Waste Stream
2.9 The Presence of Valuable Resources in E-Waste Streams is the Key Driver for Recycling Technologies
2.10 Drivers for E-Waste and Battery Recycling Technologies Explained
2.11 Complexity in the Composition of E-Waste Streams is the Key Restraint for Recycling Technologies
2.12 Restraints for E-Waste and Battery Recycling Explained
3.1.1 Novel Technologies Predominantly Focus on Improved Environmental Performance
3.1.2 Corona Electrostatic Separation is a Zero Polluting Separation Technology for e-Waste Recycling with Negligible Contamination
3.1.3 The Use of Organic Acids for Leaching of Metals from E-waste Makes Bioleaching Attractive
3.1.4 Chemolithoautotrophic Bacteria (Acidithiobacillus ferrooxidans and Acidithiobacillus thiooxidans) have been Widely used for Bioleaching
3.1.5 Chelation Chemistry Offers Promising Potential for Metal Extraction from E-waste
3.1.6 Ionic Liquids Enable Efficient Rare Earth Metals Extraction from E-Waste
3.1.7 Supercritical Fluid Treatment Offers Superior E-Waste Recycling Rates
3.1.8 Vacuum Metallurgy Has the Potential to Recover Metal Nanoparticles
3.1.9 Advancements in Improving the Metal Extraction Rate are Required
3.1.10 Extraction of Rare Earth Metals is the Key Focus Area for Innovators
3.1.11 Recyclers Offer Additional Services to Ensure Data Security of E-Waste from the ICT Sector
3.2.1 Novel Battery Recycling Technologies Will Be Required to Replace Conventional Processes
3.3.1 Conventional Technologies Used in Lithium-Ion Battery Recovery
3.3.2 Processes Based on Vacuum Thermal Recycling Consume Less Energy Compared to Conventional Processes
3.3.3 Patented Closed Loop Process Uses Leachants to Recover Lithium from end-of-Life Batteries
3.3.4 Integration of Mechanical and Chemical Processes for Battery Recycling Enhances the Recovery Rate of Lithium Ions
3.3.5 Promoting Lithium Ion Battery Recycling also Aids in Recovery of other Precious Metals
3.3.6 Proprietary Processes Implemented by Various Companies for Lithium Ion Battery Recycling Reduces the E-waste Burden on Landfills
4.1 Electrowinning Technique Reduces the Number of Recycling Processes and thus Reduces Operational Expenditure
4.2 Leaching Processes Make Recovery of Lead a More Self-Sustained Process
4.3 Iono-Metallurgical Processes have High Recovery Rates as Compared to Traditional Processes
4.4 Novel Processes Help in Adhering to Zero Liquid Discharge Norms and also Recovering Precious Metals
5.1 Distillation of Nickel Carbonyl from Mond Process also Recovers other Precious Metals Apart from Nickel
5.2 Non Toxic Super Critical Fluids Enhance Recovery of Nickel and other Metals from Spent Batteries
5.3 Bio-Metallurgical Processes Enhance Recovery Rates of Ni from Nickel-Cadmium Batteries
5.4 Companies Involved in Managing Rare Earth Metals are also Involved in Recovering Nickel from End-of-Life Batteries
6.1 China’s Recent Ban on E-Waste Imports has Disrupted the Global E-Waste Trade
6.2 Stringent Regulations and Support Programs Are Key for Formal E-waste Recycling
6.3 E-Waste Recycling Promotes Sustainability Development Goals
6.4 Metal Recovery Using E-Waste Recycling Technologies Results in Reduced GHG Emissions
6.5 Shorter Lifespan of Mobile Phones Necessitates the Need for E-Waste Recycling
6.6 Comparative Analysis for the Emerging Battery Recycling Technologies
7.1 Growth Opportunity 1- Business Models – Battery Recycling Technologies
7.2 Growth Opportunity 2- Geographic Expansion – Battery Recycling Technologies
8.1 Key Conclusions
8.1 Key Conclusions
9.1 Key Contacts
Legal Disclaimer
Popular Topics
Electronic and battery waste should be considered as an important source for the recovery of crucial precious metals including Lead, Lithium, Nickel, Cadmium, Cobalt, and Copper. The recovery of rare earth metals from end-of-life electronics and batteries will reduce the burden on landfills and will also prevent leaching of hazardous compounds into the ground water which can reduce soil fertility and can also have serious implications on human health and the environment. Recovery of precious metals through conventional hydro and pyro metallurgical processes is a capital and time intensive process that results in lesser recovery rates. Recovery of precious metals by novel processes will also reduce the operational and maintenance costs and will also reduce emissions of greenhouse gases. The federal regulations of all countries should also consider stringent emission discharge permissible limits for hazardous gases in order to reduce the impact on the environment and human health.
The research study has identified the utilization of futuristic physiochemical processes that will enable the efficient recovery of precious metals from end-of-life batteries.
| No Index | No |
|---|---|
| Podcast | No |
| Author | Sharath Thirumalai |
| Industries | Environment |
| WIP Number | D80E-01-00-00-00 |
| Is Prebook | No |
| Ti Codes | D902,D908,D90C,D90F,D910,D912,D917,D927 |