Aluminum silicate fiber cotton is an ideal raw material for textile production

Excellent Thermal Insulation

• Low Thermal Conductivity: Aluminum silicate fiber cotton has a porous structure with numerous tiny air pockets. These air pockets are poor conductors of heat, creating a barrier to heat transfer and giving the material its excellent thermal insulation properties. In textile production, this helps to maintain a stable temperature in the working environment, reducing energy consumption for heating or cooling.
• High-temperature Resistance: It can maintain its thermal insulation performance at high temperatures, making it suitable for textile processes that involve high temperatures, such as thermal bonding or heat setting. This helps to ensure the quality and efficiency of the production process.

Good Chemical Stability

• Resistant to Chemical Corrosion: Aluminum silicate fiber cotton is relatively inert chemically and can resist corrosion from many chemicals. In textile production, it can come into contact with various chemical substances like dyes, sizing agents, and finishing agents without undergoing significant chemical reactions. This ensures its performance and lifespan as a raw material.
• No Release of Harmful Substances: It does not release harmful chemicals during use, meeting the environmental and health requirements of the textile industry. This ensures a safe production environment for workers and produces textiles that are safe for consumers to use.

Outstanding Mechanical Properties

• High Tensile Strength: Despite its soft appearance, aluminum silicate fiber cotton has good tensile strength. During textile processing, it can withstand tension and friction forces, reducing breakage and ensuring smooth production.
• Good Flexibility and Drape: It has excellent flexibility and drape, allowing it to be easily woven, knitted, or sewn into various textile products. This provides flexibility in textile design and production, enabling the creation of textiles with different styles and functions.

Outstanding Sound-absorption and Noise Reduction

• Porosity and Fibrous Structure: The porous and fibrous structure of aluminum silicate fiber cotton can effectively absorb sound waves. In textile workshops, it can reduce noise from equipment and processes, improving the working environment for employees and helping to protect their hearing.
• Vibration Damping: It can absorb and dissipate vibration energy, providing some vibration damping effects. This helps to reduce equipment vibrations in textile production, improving the stability and precision of the production process.

Low Density and Lightweight

• Easy Handling and Transportation: Its low density makes it lightweight, facilitating handling and transportation in the textile production process. This reduces labor intensity and transportation costs.
• comfort: Textiles made from it are also lightweight, offering comfort when used in clothing, curtains, or other textile products. They do not cause discomfort or burden to the user.

Customizable

• Can be Processed into Different Forms: Aluminum silicate fiber cotton can be processed into various forms, such as fibers, yarns, fabrics, and felts, to meet the different requirements of textile production. For example, it can be spun into yarn for weaving into fabrics or made into non-woven felts for use in insulation and soundproofing materials.
• Adjustable Performance: By changing its composition, structure, and processing methods, its properties can be adjusted to produce textiles with specific characteristics, such as enhanced thermal insulation, improved strength, or increased flame retardancy.

Good Electrical Insulation

• High Electrical Resistivity: Aluminum silicate fiber cotton has good electrical insulation properties, with high electrical resistivity. In textile production, it can be used to manufacture insulating textiles for protecting electrical equipment and facilities, preventing electrical leakage and ensuring the safe operation of electrical systems.
• ** arc and spark resistance**: It can withstand the heat and impact of electric arcs and sparks, providing effective protection for electrical equipment and personnel safety in environments with electrical hazards.