Any deviation can lead to poor fitment and performance issues in the final application, be it in batteries, capacitors, or other energy storage devices. Material Handling: Electrode materials can be delicate and prone to damage during the slitting process.
Poor edge quality can lead to issues such as uneven current distribution, which can degrade the performance and lifespan of the battery. Waste Management: Minimizing waste generated during the slitting process is essential for cost control and environmental sustainability.
By integrating all this technology into the electrode manufacturing process, companies can overcome the significant challenges associated with longitudinal slitting. The result is a more efficient, cost-effective, and high-quality production process that meets the rigorous demands of the energy storage industry.
In the second phase, the minimum levels for the utilisation of recycled materials become effective after 18th of August 2031 and the battery manufacturers are required to utilise at least 16%, 85%, 6%, and 6% of recycled cobalt, lead, lithium, and nickel, respectively, in the manufacturing process of new batteries.
Speed and Efficiency: In a high-volume manufacturing environment, the slitting process must be not only accurate but also fast. Balancing speed with precision requires advanced technology and fine-tuning to prevent bottlenecks in production. Edge Quality: The quality of the slit edges is crucial for the performance of the electrodes.
Edge detection and high precision measurement of coating width. Use the Qi<+>PRO software solution to adjust knife position in real-time. Improved shape and slit position accuracy for manufacturing of Li-ion batteries with Meander correction and efficient energy leveling.