Lithium Battery Manual Pouch Cell Cathode And Anode Stacking Machine

Basic Parameter:

lab manual stacking machine equipment

This pouch cell stacking machine for batteries is a desktop unit that can be conveniently placed on a regular table, featuring easy maintenance and operation, a wide range of applicable stacking sheet sizes, high work efficiency with a digital timer, cylinder control through a foot switch, and a small machine dimension with an attractive appearance.

Manual lamination stacking machine

This lab manual stacking machine equipment integrates the stacking machine and control box, allowing for space-saving, easy parameter setting, and operation. It is used for Z-shaped stacking of battery cores, including anode, cathode, and separator.

Q1. What is the stacking process in battery manufacturing?

The stacking process in battery manufacturing involves assembling the individual components of a battery cell in a specific order and sequence to form a complete battery stack. This process is critical for achieving the desired electrical and mechanical properties of the battery.

During the stacking process, electrode layers, separators, and electrolytes are carefully arranged and aligned to create a layered structure. The electrode layers consist of a cathode, an anode, and a separator in between to prevent direct contact. The layers are typically coated with active materials that enable electrochemical reactions during battery operation.

Once the layers are stacked, they are compressed or pressed together to ensure good contact and maximize the electrode's active area. This compression helps to improve the overall performance and energy density of the battery. The applied pressure also aids in the formation of solid interfaces between the electrode layers and the electrolyte, promoting efficient ion transport and reducing internal resistance.

Q2. How does the battery stacking machine work?

The battery stacking machine is used in the battery manufacturing process to assemble and stack the individual battery components, such as electrodes, separators, and current collectors, into a complete battery cell. Here's how the battery stacking machine typically works:

    Preparation: The machine is set up with the necessary components, including the electrodes, separators, and current collectors, which are usually supplied in rolls or sheets.

    Feeding: The machine feeds the electrodes, separators, and current collectors into the stacking area. They are usually guided and positioned accurately to ensure the correct alignment during the stacking process.

    Stacking: The machine uses precise robotic or automated mechanisms to stack the components in the desired sequence. This process may involve placing alternating layers of positive and negative electrodes with separators in between.

    Compression: Once the components are stacked, the machine applies pressure or compression to ensure proper contact between the layers. This compresses the electrodes, helps improve the overall cell performance, and ensures good electrical conductivity.

    Welding: In some cases, the battery stacking machine may also incorporate a welding or bonding mechanism to join the current collectors and electrodes together. This welding process helps establish electrical connections and strengthens the overall structure of the battery cell.

    Inspection: After the stacking and welding process is complete, the machine may include inspection stations to check for any defects or inconsistencies in the stacked battery cells. This ensures the quality and reliability of the finished battery products.

    Output: Once the stacking and inspection are done, the completed battery cells are discharged from the machine. They are then further processed, such as undergoing electrolyte filling, sealing, and additional testing, to create finished battery packs or modules.

Overall, the battery stacking machine automates the precise and efficient stacking of battery components, ensuring consistent and accurate assembly of battery cells in the manufacturing process.

Q3.The role of the battery stacker

Improve the level of automation: The battery laminator precisely stacks the positive and negative electrode sheets together through an automated process, reducing manual operation and improving production efficiency.

Improved product quality: The automated lamination process ensures accurate alignment of the positive and negative plates and uniform stacking, thereby improving the overall quality and performance of the battery.

Increase production efficiency: The laminator can quickly and continuously complete the lamination work, which significantly improves the production speed of the battery and reduces the production cost.

Adapt to diverse needs: The laminator can flexibly adjust the lamination parameters according to different battery specifications and design requirements to meet diverse market needs.