Pouch Cell Preparation

Table of Contents

Pouch cell preparation, also known as pouch lithium batteries, are a type of rechargeable battery widely used in lithium battery applications.

Compared to traditional cylindrical or prismatic lithium batteries, the main feature of soft pack lithium batteries is the flexible aluminum-plastic composite film used as the outer packaging, making the battery shape more flexible and versatile. This flexibility gives soft pack lithium batteries advantages in special applications such as curved electronic devices and electric vehicles.

Applications and Industries of Pouch cell

Electric Vehicles:

Pouch cells are extensively used in electric vehicles, including electric cars and electric bicycles. The flexible outer packaging adapts to the flexible structure of electric vehicles, providing a reliable power source with high energy density.

Mobile Electronic Devices:

Pouch cell find widespread use in mobile phones, tablets, laptops, and other portable electronic devices. Their lightweight design helps reduce device volume while providing relatively high energy density.

Energy Storage Systems:

Pouch cell play a crucial role as a key component in energy storage systems, storing the electricity generated from renewable sources such as solar and wind energy. This is essential for balancing grid loads and addressing energy fluctuations.

Medical Devices:

Due to their flexibility, pouch cells are suitable for portable medical devices, including portable medical monitoring equipment and electric wheelchairs.

Portable Electronic Products:

Portable electronic products like portable speakers, Bluetooth headphones, smart wristbands, etc., often use pouch cell to meet the requirements of lightweight and thin design.

Aerospace:

Pouch cells are employed in some aerospace applications where lightweight and flexibility are critical factors, such as in aircraft and satellites.

New Energy Vehicles:

In addition to electric vehicles, pouch cells are widely applied in new energy vehicles, including hybrid cars and fully electric vehicles.

Embedded Systems:

Pouch cells are used in various embedded systems, IoT devices, and sensors, meeting specific requirements for battery shape and weight.

Basic Process of Pouch Cell Preparation

Positive and Negative Electrode Material Preparation

Positive Electrode Material Preparation:

Material Selection: Choose positive electrode materials, commonly oxide materials such as lithium cobalt oxide (LiCoO2), nickel manganese cobalt oxide (NMC), lithium iron phosphate (LiFePO4), etc., with good electrochemical performance.

Mixing and Grinding: Mix positive electrode active materials with conductive additives (such as carbon black) and binders, then mechanically grind to ensure uniform mixing.

Coating: Apply the mixture onto a conductive current collector (usually aluminum foil) to form the positive electrode sheet. This step is typically done using a coating machine or a roll coating process.

Drying: Dry the positive electrode sheet to remove solvents from the coating process.

Cutting: Cut the positive electrode sheet into the desired size to meet the battery design requirements.

Negative Electrode Material Preparation:

Material Selection: Choose negative electrode materials, commonly using graphite or silicon, with good electrochemical performance and lithium-ion accommodation capacity.

Mixing and Grinding: Mix negative electrode active materials with conductive additives and binders, mechanically grind to ensure uniform mixing.

Coating: Apply the mixture onto a conductive current collector (usually copper foil) to form the negative electrode sheet.

Drying: Dry the negative electrode sheet to remove solvents from the coating process.

Cutting: Cut the negative electrode sheet into the desired size to meet the battery design requirements.

ZYLAB recommends experimental equipment for the preparation of positive and negative electrode materials:

Rotary Sintering Furnace
Laboratory Furnaces
Bottom Heat Film Coater
Coaters
Planetary Ball Mill
Ball Mill
25L Drying Oven (2)
Drying Ovens
Planetary Vacuum Mixer
Laboratory Mixer
Rolling Press
Lab Rollers

Electrolyte Preparation:

● Choose electrolyte materials, typically an organic solution containing lithium salt.

● Mix and process the electrolyte solution to ensure its quality and purity.

● Prepare the electrolyte liquid for impregnating between positive and negative electrode sheets.

Battery Assembly:

● Stack positive and negative electrode sheets with the electrolyte liquid in between.

● Place the electrode sheets and electrolyte into the soft pack material.

● Seal the soft pack to prevent electrolyte leakage.

● Optionally, add protection circuits and temperature control systems to the exterior of the soft pack.

Charging and Testing:

● Charge the prepared soft pack battery to activate it.

● Perform battery performance tests, including voltage stability, capacity testing, cycle life, etc.

● Check the safety of the battery to ensure no abnormal conditions occur.

Data Recording and Analysis:

● Record parameters for battery preparation and testing.

● Analyze test results to evaluate the battery’s performance and stability.

Role of High-Temperature Furnace in Positive and Negative Electrode Material Preparation

Heat Treatment of Positive and Negative Electrode Materials:

High-temperature furnaces are used for the heat treatment of positive and negative electrode materials. This process improves the crystalline structure and electrochemical performance of the materials. Controlled heat treatment adjusts parameters such as crystal structure and particle size, enhancing battery performance and cycle life.

Solvent Evaporation during Coating Process:

In the coating process of positive and negative electrode materials onto current collectors, high-temperature furnaces assist in solvent evaporation. The furnace provides a temperature-controlled environment, allowing solvents to evaporate quickly, ensuring uniformity and stability of the electrode sheets.

Graphitization Treatment (for Negative Electrode Materials):

For certain negative electrode materials like graphite, high-temperature furnaces are used for graphitization treatment. This thermal process transforms the non-crystalline carbon structure in graphite to a more stable crystalline structure, improving conductivity and cycle life.

Optimization of Material Properties:

High-temperature furnaces play a crucial role in optimizing the properties of positive and negative electrode materials, including crystal structure, particle size, and conductivity. Precise control of the high-temperature environment allows for the enhancement of electrochemical properties.

Removal of Organic Solvents:

In the preparation process, organic solvents are commonly used. High-temperature furnaces aid in removing residual organic solvents, ensuring that the electrodes do not contain impurities that could affect battery performance.

Here are several high-temperature furnaces recommended by ZYLAB for your reference:

1500.C Tube Furnace
Tube Furnaces
Chemical Vapor Deposition (CVD) System
CVD System
Chamber Muffle Furnace
Muffle Furnaces
Vibrating Rotary Sintering Furnace (2)
Rotary Furnace
Rapid Thermal Processing Furnace
Annealing Furnace

When selecting a high-temperature furnace, it is essential to consider the specific requirements of your experiments, such as sample size, temperature gradients, heating rates, etc. Additionally, ensure that the chosen high-temperature furnace complies with laboratory safety standards and meets the needs of experiments for the preparation of positive and negative electrode materials in soft pack batteries.

Feel free to contact our technical staff if you have any questions.

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