Enviropass Expertise Inc.

Recycling Electronic Equipment

Recycling electronic equipment is an increasingly challenging task. According to the Global E-Waste Monitor 2020, the world annually generates an overwhelming 53.6 million tons of electronic waste (e-waste). Shockingly, they also report only 17.4% of properly recycled e-waste (The Global E-Waste Monitor 2020: Quantities, Flows, and the Circular Economy Potential). This stark reality underscores the critical need for improved e-waste management. As technology rapidly evolves, millions of devices – including smartphones, laptops, and industrial machinery – become obsolete annually. This constant cycle of technological advancement demands efficient recycling systems to reduce environmental damage and recover valuable resources.

Recycling Electronic Equipment Process

The recycling process for electronic equipment involves several stages, each requiring precision and adherence to environmental standards:

1. Collection and Sorting:

Devices are gathered through dedicated e-waste recycling programs and sorted by type, such as mobile phones, computers, or industrial equipment. Sorting ensures the appropriate recycling pathway for each category.

2. Dismantling:

Technicians or automated systems disassemble equipment into components, like circuit boards, batteries, screens, and casings. Manual dismantling is typically favored for complex devices because it allows for greater precision.

3. After Shredding Material Separation:

Shredded components undergo advanced separation techniques:

Metal

• Magnetic Separation: Removes ferrous metals, like steel.

• Eddy Current Separation: Isolates non-ferrous metals like aluminum and copper.
This is a highly effective method used in recycling to sort non-ferrous metals from other materials. This process utilizes the principles of electromagnetic induction. When a rotating magnetic field applies to a conveyor belt carrying shredded waste, it induces eddy currents in conductive materials like aluminum and copper. These eddy currents generate their magnetic fields, which oppose the original magnetic field, causing the non-ferrous metals to be repelled and separated from the rest of the waste stream. Eddy current separators are particularly valuable in recovering materials from e-waste, municipal recycling facilities, and scrap metal operations. They enhance efficiency and precision in recycling processes, reducing reliance on manual sorting and maximizing material recovery.

• Chemical Processing: Extracts precious metals such as gold and palladium.
This recycling method involves using various chemicals to extract valuable materials from waste. Commonly used chemicals include acids like nitric acid, sulfuric acid, and aqua regia (a mixture of nitric and hydrochloric acids) to dissolve metals and bases like sodium hydroxide to break down organic compounds. Oxidizing agents like hydrogen peroxide and chlorine improve the extraction process, while chelating agents like EDTA selectively bind to metals. Toxic substances, such as cyanide, as well as safer alternatives like thiosulfate, are used for gold recovery. Proper waste management and safety protocols are crucial to mitigate the environmental and health risks associated with these chemicals.

- Plastic

• Type Separation:

Plastics are separated by type (e.g., PET, HDPE, PVC) using optical or density separation methods.
Optical Sorting: Near-infrared (NIR) technology detects and sorts plastics by polymer type.
Near-infrared (NIR) technology uses light just beyond the visible spectrum to identify materials based on how they reflect or absorb light. It’s widely used in recycling to quickly and accurately sort plastics, paper, and other materials by their unique spectral signatures. Consequently, this technology improves efficiency and precision in waste management.
Float-Sink Separation: Some plastics float in water (e.g., HDPE), while others sink (e.g., PET).

• Pelletizing or Reprocessing:

Sorted plastics are shredded further into small flakes or pellets.
They melt and reuse these to create new plastic products.

- Glass

• Screening and Sorting:
After shredding, screens separate glass fragments (cullets) to remove non-glass materials like metals, paper, or plastics.
• Color Sorting:
Optical sorting systems separate glass based on color (e.g., clear, green, brown) to maintain the quality of the recycled product.
• Contaminant Removal:
Magnets or vacuum systems remove ferrous and non-ferrous metals, ceramics, and other contaminants from the glass cullet.

4. Material Recovery:

Extracted materials are refined and prepared for reuse.

- Metal

Gold and Precious Metals:

• E-waste recycling often focuses on recovering precious metals like gold, silver, and palladium.
• Gold, for instance, is commonly purified through electrochemical processes like electrolysis or electrowinning. These processes involve dissolving gold in a solution (such as cyanide or acid) and then using electricity to precipitate pure gold onto a cathode.
• Other methods include aqua regia refining and smelting.

Other Metals

Metals like aluminum, copper, and steel are typically melted at high temperatures to remove impurities and cast into ingots or other forms for reuse.

- Plastic

• The cleaned plastics are either shredded into flakes or melted and reprocessed into granules or pellets.
• These granules help produce new plastic products, reduce reliance on virgin plastics, and conserve petroleum resources.
• Plastics that are heavily contaminated or non-recyclable may be incinerated to recover energy or converted into fuel through pyrolysis.

- Glass

• The glass is cleaned to remove impurities such as labels and caps and then crushed into cullet (small pieces of glass).
• The cullet is melted and reformed into new glass products, like bottles and jars.
• Lower-quality or contaminated glass may be used in construction materials, such as aggregate for roads or as an additive in asphalt or concrete.

- Electronic Components

• Printed circuit boards (PCBs) and other electronic components undergo thermal processing (incineration or pyrolysis) or chemical leaching to extract valuable metals like gold, silver, and copper.
• Reprocessors sometimes turn plastics in electronics into fillers for construction materials.
• Ceramics in components like capacitors pose a recycling challenge. These ceramics often contain metals like barium, titanium, or lead, and they typically require specialized processes for recovery. Unlike plastics, recyclers do not commonly reuse ceramics as construction fillers.

Energy Recovery

Non-recyclable materials or low-grade plastics sometimes undergo waste-to-energy processes, where incineration generates heat or electricity. However, this often serves as a last resort option due to environmental concerns.

Hazardous Waste Management:

Toxic elements are treated and stored according to strict environmental regulations to prevent contamination.