Separating NiCd batteries from small-format Li-ion batteries

Description of need

As the volume of small-format batteries from electronics and power tools increases, recyclers face a major challenge in effectively sorting lithium-ion (Li-ion) batteries from nickel-cadmium (NiCd) batteries. NiCd batteries can contaminate batches of Li-ion batteries, with cadmium (Cd) contamination severely diminishing the economic value and recyclability of Li-ion battery materials.

To ensure high recovery yields and economic viability, small-format battery recyclers and sorting companies need advanced sorting technologies that can accurately and non-invasively separate NiCd from Li-ion batteries without destructive testing or labor-intensive sorting.

Problem severity (1-10)

8

Who has this need

• Battery recyclers
• Battery sorting and collection companies processing large volumes of mixed battery types

Total addressable market (TAM)

The global battery recycling market, projected to exceed $20 billion by 2030, includes a significant market for sorting technologies. With the increasing regulatory and economic pressures for clean battery recovery, a robust NiCd-Li-ion sorting solution could address hundreds of millions in annual market demand among recyclers, sorting facilities, and battery collection services.

Solutions today, and their shortcomings

1. Manual sorting: While feasible for low volumes, manual sorting is time-consuming, error-prone, and increasingly impractical as battery volumes rise.
2. X-ray fluorescence (XRF): XRF can detect cadmium, but it is often slow, expensive, and may struggle with battery casings that obscure material identification.
3. Assay testing: Requires cutting and sampling the battery contents, which is labor-intensive, costly, and results in destroyed materials.
4. Electrochemical or visual sorting methods: Limited in accuracy and tend to be unreliable due to variability in battery size, shape, and labeling, especially for small-format batteries.

Potentially relevant capabilities

Uknown. Possibly:

• Non-destructive elemental analysis: Real-time scanning technologies, like enhanced XRF or laser-induced breakdown spectroscopy (LIBS), capable of detecting cadmium presence through the battery casing.
• Advanced AI and machine learning: Algorithms trained on battery characteristics (size, shape, weight, color, etc.) to automate identification and improve sorting accuracy.
• Electromagnetic or density-based sorting: Techniques leveraging subtle differences in material properties between NiCd and Li-ion batteries to separate them without opening.
• Imaging and computer vision: High-resolution imaging combined with machine learning to detect subtle differences in appearance between NiCd and Li-ion batteries in a fast, automated process.
• Automated sorting machinery: Development of modular sorting units that integrate identification technology and automated separation, capable of handling high volumes with minimal intervention.

References

• 2024-11-12 Tim Johnston
• ChatGPT
• Reports by the U.S. Environmental Protection Agency (EPA) on heavy metal contamination in battery recycling.
• Research by the International Association for Soils, Sediments, Water, and Energy on cadmium impacts in battery recycling.
• Publications from Circular Energy Storage on small-format battery recycling challenges.
• Industry analyses on advanced sorting technologies for mixed waste streams by Fraunhofer and other research institutes.