Fabricação de Fibra de Carbono a partir de Poliacrilonitrila
Embed This Widget
Add the script tag and a data attribute to embed this widget.
Embed via iframe for maximum compatibility.
<iframe src="https://chemfyi.com/iframe/entity//" width="420" height="400" frameborder="0" style="border:0;border-radius:10px;max-width:100%" loading="lazy"></iframe>
Paste this URL in WordPress, Medium, or any oEmbed-compatible platform.
https://chemfyi.com/entity//
Add a dynamic SVG badge to your README or docs.
[](https://chemfyi.com/entity//)
Use the native HTML custom element.
Material de grau aeroespacial dez vezes mais resistente que o aço
Visão geral
Carbon fiber is produced by the controlled thermal conversion of polyacrylonitrile (PAN) precursor fiber through oxidation, carbonization, and graphitization steps. The resulting fiber has a tensile strength 10 times that of steel at one-fifth the weight, making it essential for aerospace, automotive, wind turbine blades, and sporting goods. PAN accounts for over 90% of all carbon fiber precursor, with Toray, Teijin, and SGL as major producers.
Processo químico
PAN precursor fiber is stretched and stabilized in air at 200-300 degrees C (oxidation), forming a thermally stable ladder polymer. The stabilized fiber is carbonized at 1,000-1,500 degrees C in nitrogen, removing non-carbon elements. Optional graphitization at 2,000-3,000 degrees C further increases modulus. The fiber is surface-treated and sized for composite compatibility.
Stabilized fiber ->[1,000-1,500 degrees C, N2] Carbon fiber + HCN + H2O + N2 (carbonization, >95% C)
Matérias-primas
-
Polyacrylonitrile (PAN) precursor fiber — Wet or dry-jet spinning of PAN copolymer (Carbon fiber precursor (>90% of production))
-
Nitrogen gas (N2) — Air separation unit (cryogenic) (Inert atmosphere for carbonization)
Produtos finais
-
Carbon fiber tow — Aerospace composites, automotive, wind turbines, sporting goods (3K-48K filament count, tensile modulus 230-600 GPa)
Environmental Impact
Carbon fiber production is extremely energy-intensive (~200 GJ/ton) and generates HCN as a toxic byproduct during carbonization. CFRP waste is difficult to recycle, though pyrolysis-based recycling is emerging. The high cost and energy input limit adoption outside high-performance applications.
Considerações de segurança
- ⚠ HCN generation during stabilization and carbonization -- lethal gas
- ⚠ High-temperature furnaces (up to 3,000 degrees C)
- ⚠ Carbon fiber dust is electrically conductive -- short circuit risk in electronics
- ⚠ Fiber fragments cause skin irritation (mechanical, not chemical)
Inovações recentes
Microwave and plasma-assisted carbonization can reduce energy consumption by 50%.
Bio-based precursors (lignin, cellulose) are being developed as cheaper, renewable alternatives to PAN.
Recycled carbon fiber from pyrolysis of CFRP waste is entering the market for non-critical applications.
Escala de produção
120000
toneladas/ano
$5.8 billion
valor de mercado
Mais em Materials Science & Polymers
Fabricação de Compósitos de Fibra de Vidro
Global Industrial Scale
Fabricação de Silicone (PDMS) pelo Processo Direto
Global Industrial Scale
Produção de Fibra Kevlar (Poli-p-fenileno Tereftalamida)
Commercial Production
Produção de Nylon 6,6 via Policondensação
Global Industrial Scale
Produção de Resina Epóxi a partir de Bisfenol A
Global Industrial Scale
Síntese de Polietileno via Catálise Ziegler-Natta
Global Industrial Scale
Vulcanização da Borracha com Reticulação de Enxofre
Global Industrial Scale