Granular PA66 CF20 for Adjustable/Rotatable Phone Holders
Crucial Comparative Advantages of Granular PA66 CF20:
*40% lighter than metal mechanisms
*30% stronger than standard nylon
*50% longer lifespan than ABS alternatives
*Superior dimensional stability vs. unfilled polymers
- Manufacturer: Carbon New Material
- OEM/ODM: Acceptable
- Color: Black
- Free Samples: ≤25kgs
- MOQ: 100kgs
- Port: Xiamen
- Model: PA66-CF-BCA2
- Fillers: Short carbon fiber
This advanced 20% carbon fiber-reinforced PA66 compound (Granular PA66 CF20) delivers exceptional performance for adjustable and rotatable phone holders through its unique combination of mechanical properties and functional reliability:
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Precision Movement Performance
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Flexural modulus: 7-9 GPa (ensures stability during rotation)
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Coefficient of friction: 0.22-0.28 (enables smooth 360° rotation)
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Wear resistance: <0.01mm material loss after 100,000 rotations
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Fatigue strength: Maintains 95% performance after 50,000 adjustment cycles
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Structural Integrity
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Tensile strength: 85-110 MPa (withstands repeated adjustments)
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Impact strength: 45-55 kJ/m² (ISO 179, prevents cracking)
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Creep resistance: <0.2% deformation under continuous load
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Enhanced User Safety
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Surface resistivity: 10⁹-10¹¹ Ω/sq (prevents static damage)
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Heat resistance: 140-160°C HDT (safe for car interiors)
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Flame rating: UL94 V-2 compliant
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Manufacturing Advantages of Granular PA66 CF20
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Mold shrinkage: 0.4-0.6% (tight tolerance for moving parts)
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Cycle time: 22-28 seconds (production efficiency)
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Warpage control: <0.25mm on thin sections
The material’s balanced stiffness and lubricity enable precise yet smooth rotation, while its mechanical durability ensures reliable performance through years of adjustments. Granular PA66 CF20 maintains critical clearances in moving parts better than conventional plastics, preventing wobble or loosening over time.
Surface Resistivity Comparison
Conductors < 10⁵ Ω/sq. Antistatic Materials 10⁵ ~ 10¹² Ω/sq. Insulators > 10¹² Ω/sq. Static-Dissipative 10⁶ ~ 10¹¹ Ω/sq. *Key Influencing Factors Humidity: Increased moisture can reduce resistivity (e.g., in polymers). Temperature: Affects carrier mobility (↑ heat may lower semiconductor resistivity). Surface Contamination: Dust/oils alter readings significantly. Additives: Carbon black, metallic fillers can lower resistivity. *Applications Electronics: Antistatic materials (10⁶–10⁹ Ω/sq) prevent electrostatic discharge (ESD). Aerospace: Composites must control resistivity to avoid charge buildup. Medical Devices: Insulating materials (>10¹² Ω/sq) ensure patient safety. *Examples Polypropylene (PP): ~10¹⁶ Ω/sq (excellent insulator). Carbon Fiber Composites: 10³–10⁶ Ω/sq (static dissipation). ESD Flooring: 10⁶–10⁹ Ω/sq.
Get to Know Carbon Fibers
The table presents key performance data of carbon fiber grades. T300, with a tensile strength of 3530 MPa and a tensile modulus of 230 GPa, has a relatively low tensile elongation at break of 1.5% and a body density of 1.76 g/cm³. As the grade increases, for example, T700S shows an enhanced tensile strength of 4900 MPa compared to T300, while maintaining the same tensile modulus but with a higher elongation at break of 2.1%. T800S and T1000G both have a tensile modulus of 294 GPa, and their tensile strengths are 5880 MPa and 6370 MPa respectively. T1100G stands out with the highest tensile strength of 7000 MPa and a tensile modulus of 324 GPa. Generally, with the increase in product grade, the tensile strength and modulus tend to rise, while the density remains relatively stable around 1.8 g/cm³.
How to Buy?
If you want to obtain information such as product specifications, performance, and price, choose a suitable product according to your own needs. Meanwhile, you can ask the manufacturer to provide samples for testing to ensure that the material meets your usage requirements. If you are interested in purchasing this composite material, please contact the manufacturer Carbon (Xiamen) New Material directly.
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Frequently Asked Questions
Carbon (Xiamen) New Material Co., Ltd. aims to provide buyers with "one-stop" worry-free high-quality services. Here you can find all information about carbon fiber engineering plastics. If you still have questions, please send us an email for consultation!
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How can I contact the manufacturer of a product that interests me?
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Where will I find a buying guide?
Please contact our after-sales service directly and we will provide you with a comprehensive operating guide.
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What are CF Reinforced Thermoplastic Composites?
CF Reinforced Thermoplastic Composites are materials where carbon fibers are incorporated into a thermoplastic matrix. They combine the strength and stiffness of carbon fibers with the processability and recyclability of thermoplastics. For instance, they are used in automotive parts like bumper beams.
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What are the benefits of CF Reinforced Thermoplastic Composites over traditional composites?
The key benefits include faster production cycles, easier recyclability, and better impact resistance. They also offer design flexibility. An example is in the manufacturing of consumer electronics casings where complex shapes can be achieved more easily.
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How are CF Reinforced Thermoplastic Composites processed?
Common processing methods include injection molding, extrusion, and compression molding. Injection molding is widely used for mass production. For example, in the production of small components for the medical industry.
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What industries use CF Reinforced Thermoplastic Composites?
They are utilized in aerospace, automotive, medical, and sports equipment industries. In aerospace, they can be found in interior components. In the medical field, they might be used in prosthetics.
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How does the carbon fiber content affect the properties of the composites?
Higher carbon fiber content generally leads to increased strength and stiffness but may reduce ductility. A moderate content is often balanced for specific applications. For example, a higher content might be preferred in structural parts of a race car.
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What are the challenges in using CF Reinforced Thermoplastic Composites?
Challenges include higher material costs, complex processing equipment requirements, and ensuring uniform fiber dispersion. Issues with adhesion between the fibers and the matrix can also arise. An example is in achieving consistent quality in large-scale production.
