4 Ways to Make Carbon Fiber
Introduction:
Carbon fiber is a versatile and lightweight material that has revolutionized industries all around the world. Its incredible strength-to-weight ratio makes it a popular choice for aerospace, automotive, and sports equipment manufacturing. Here are four different ways to make carbon fiber, each with its unique advantages and applications.
1. PAN-Based Carbon Fiber:
PAN-based carbon fiber is the most common method for producing carbon fibers, accounting for over 90% of the market share. It begins with polyacrylonitrile (PAN) as a precursor material, which is spun into filaments and then subjected to various stages of oxidation, stabilization, and carbonization. The result is high-quality fibers that have excellent tensile strength and stiffness.
2. Pitch-Based Carbon Fiber:
The pitch-based method starts with petroleum or coal tar pitch as the precursor material. The pitch is first purified and transformed into mesophase pitch- a liquid-crystalline phase. It is then processed by melt spinning or extrusion through spinnerets to create fine filaments before being subjected to heat treatment for carbonization and graphitization. This method produces high-modulus carbon fibers suitable for applications requiring extra stiffness or thermal conductivity.
3. Viscose Rayon-Based Carbon Fiber:
Viscose rayon-based carbon fiber production involves the use of regenerated cellulose fibers sourced from wood or plant pulp as the precursor materials. These cellulose fibers are chemically treated, transformed into viscose, and then spun into filaments before undergoing heat treatment in controlled atmospheres for carbonization. This method resulted in flexible but weaker fibers compared to other methods.
4. Gas-Phase Growth Carbon Fiber:
Gas-phase growth involves directly depositing carbon atoms onto a substrate instead of starting with filaments from precursor materials like PAN or pitch. The process uses chemical vapor deposition (CVD) technology where the carbon-containing gases, such as methane or acetylene, are introduced into a reaction chamber and decomposed at high temperatures. The freed carbon atoms then deposit onto a substrate, creating high-quality carbon fibers known for their excellent thermal conductivity and heat resistance.
Conclusion:
The production methods for manufacturing carbon fiber greatly affect the final properties and applications of the material. With further innovation and improvements in these processes, the potential for carbon fiber in various industries will continue to expand, providing even more creative solutions across different fields.