Transforming Industries through Advanced Nylon CF
Carbon fiber reinforced nylon composite material refers to a modified composite material prepared by a certain production process with nylon as the base material and carbon fiber as the filler. This material has excellent properties such as high strength, high hardness, light weight, wear resistance, conductivity, anti-static property, etc., and is widely used in aerospace, military equipment, rail vehicles, automotive industry, household goods and other fields.
Nylon CF Reinforced Composites have several common application areas. They are widely used in the automotive industry for manufacturing parts like engine covers and gears due to their high strength and heat resistance. In the aerospace field, they can be found in structural components for lightweight and durability. They are also employed in the production of sports equipment, such as tennis rackets and bicycle frames, where strength and weight reduction are essential. Additionally, they are utilized in the manufacturing of industrial machinery parts for enhanced performance and longevity.
Product By Features
High stress applications MXD6-CF60
MXD6-CF60 is a high-performance polyamide composite reinforced with 60% carbon fiber, providing maximum strength, stiffness, wear resistance, and thermal stability. With a heat deflection temperature of ~360°C, very low moisture absorption, and excellent chemical resistance, it is ideal for automotive, industrial, and extreme engineering applications. Suitable for injection molding and…
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MXD6-CF50 high stress applications
MXD6-CF50 is a high performance polyamide composite reinforced with 50% carbon fiber, delivering maximum strength, stiffness, wear resistance, and thermal stability. With a heat deflection temperature of ~340°C, very low moisture absorption, and excellent chemical resistance, it is ideal for automotive, industrial, and extreme engineering applications. Suitable for injection molding…
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High-strength MXD6-CF40
MXD6-CF40 is a high performance polyamide composite reinforced with 40% carbon fiber, offering maximum strength, stiffness, wear resistance, and thermal stability. With a heat deflection temperature of ~320°C, very low moisture absorption, and excellent chemical resistance, it is ideal for automotive, industrial, and extreme engineering applications. Suitable for injection molding…
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MXD6-CF30 for molding
MXD6-CF30 is a high performance polyamide composite reinforced with 30% carbon fiber, delivering exceptional strength, stiffness, wear resistance, and thermal stability. With a heat deflection temperature of ~300°C, very low moisture absorption, and excellent chemical resistance, it is ideal for automotive, industrial, and high-performance engineering applications. Suitable for injection molding…
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Composites for medical devices MXD6-CF20
MXD6-CF20 is a high performance polyamide composite reinforced with 20% carbon fiber, offering exceptional strength, stiffness, wear resistance, and thermal stability. With a heat deflection temperature of ~280°C, very low moisture absorption, and excellent chemical resistance, it is ideal for automotive, industrial, and high-performance engineering applications. Suitable for injection molding…
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MXD6-CF10 composites for medical devices
MXD6-CF10 is a high-performance polyamide composite reinforced with 10% carbon fiber, offering enhanced strength, stiffness, wear resistance, and thermal stability. With a heat deflection temperature of ~260°C, low moisture absorption, and excellent chemical resistance, it is ideal for automotive, industrial, and electronics applications. Suitable for injection molding and extrusion, it…
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Carbon fiber thermoplastic materials MXD6-CF5
MXD6-CF5 is a high performance polyamide composite reinforced with 5% carbon fiber, offering enhanced strength, stiffness, dimensional stability, and wear resistance. It features excellent thermal stability (HDT ~250°C), low moisture absorption, and superior chemical resistance, making it ideal for automotive, industrial, and electronics applications. Easily processable via injection molding and…
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High Strength PA6 CF30 Pellet Materials for Art...
High Strength PA6 CF30 Pellet Materials feature high tensile strength, excellent impact resistance, good chemical resistance, high rigidity, low friction coefficient, good thermal stability and dimensional stability for reliable performance.
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Wear-resistant CF60 PPA Composite Raw Materials...
Wear-resistant CF60 PPA Composite Raw Materials feature high wear resistance against long-term friction, excellent tensile strength for mechanical loads, lightness, heat resistance, fatigue endurance, chemical stability and dimensional stability.
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High Strength but Lightweight CF50 PPA for Dron...
High Strength but Lightweight CF50 PPA features high tensile strength for withstanding strong forces, lightness for better flight, abrasion & heat resistance, fatigue endurance and chemical stability.
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Heat Resistant CF40 PPA Compounds for Drone Tai...
Heat Resistant CF40 PPA Compounds, with features like heat resistance, strength and lightness, are ideal for drone tail wings, ensuring flight stability and durability.
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High Strength PPA CF30 Compounds for Drone Roto...
High Strength PPA CF30 Compounds are high in tensile strength, fatigue, abrasion, chemical, impact and heat resistance, lightweight and dimensionally stable for better drone performance.
Learn MoreProduct Feature Box
WEAR RESISTANCE
HIGH STRENGTH
LIGHT WEIGHT
SCRATCH RESISTANCE
ABRASION RESISTANCE
CONDUCTIVE MATERIALS
ANTI STATIC
ECO FRIENDLY
Exceptional Traits of CF Nylon Composites
1. Exceptional mechanical properties
It has high strength and hardness, capable of withstanding large loads and stresses.
2. Lightweight
Compared to traditional materials, it is lighter, helping to reduce the weight of the overall structure, which is of great significance in fields such as aerospace and automotive.
3. Good wear resistance
This enables it to perform well in components with frequent friction, prolonging the service life of the product.
4. Outstanding thermal stability
It can maintain stable performance in high-temperature environments and is suitable for high-temperature working components such as engines.
5. Conductivity and antistatic properties
This feature can prevent the accumulation of static electricity in the electronic and electrical fields, ensuring the safe operation of equipment.
6. Chemical resistance
It can resist the erosion of various chemicals and adapt to different working environments.
7. Design flexibility
It can be customized in shape and size according to specific needs to meet complex design requirements.
8. Cost-effectiveness
Although the initial cost may be higher, due to its long service life and high performance, it is cost-effective in the long run.
For example, in the aerospace field, its lightweight and high-strength characteristics help reduce the fuel consumption of aircraft. In electronic devices, conductivity and antistatic properties ensure the normal operation of the equipment without being affected by static electricity interference.
Company Advantage
Excellent After-sales Service
Carbon (Xiamen) New Material offers all-round, prompt, and professional after-sales support. A dedicated team responds within 24 hours. They solve problems remotely or on-site and provide installation and maintenance training. Feedback is used to improve service. The company also establishes long-term relationships with customers by providing regular maintenance checks and updates, ensuring the longevity and optimal performance of its products.
Stringent Quality Control System
Carbon (Xiamen) New Material has a comprehensive quality inspection process in place, from raw material selection to finished product delivery. In raw material procurement, high-precision tests are done. During production, each step is monitored and sampled. Non-destructive testing checks for defects in finished products. This meticulous approach, coupled with continuous improvement efforts based on quality data analysis, ensures that every product leaving the factory meets or exceeds the most stringent industry standards.
Modern Factory Facilities
In modern factory facilities, carbon fiber-reinforced thermoplastic composites are becoming increasingly important. They are precisely manufactured on highly automated production lines, combining the advantages of carbon fibers and thermoplastics. With strict quality checks and continuous R&D, they are delivered efficiently to customers worldwide, facilitating industrial development.
Advanced Laboratory Equipment
1. Performance Testing Equipment Equipped with universal material testing machines, dynamic mechanical analyzers (DMA), thermogravimetric analyzers (TGA), differential scanning calorimeters (DSC), thermal conductivity testers, electrical property testers, etc., to comprehensively evaluate various properties of the materials. 2. Microstructure Analysis Instruments Including scanning electron microscopes (SEM), transmission electron microscopes (TEM), X-ray diffraction analyzers (XRD), etc., for observing and analyzing the microstructure and phase distribution of the materials.
Customization Production Capacity
Carbon (Xiamen) New Material is flexible and can meet unique customer demands. For aerospace, it uses advanced design and simulation for complex, high-performance parts. For the automotive industry, it combines strength with aesthetic and surface treatment. By closely collaborating with customers at every stage of the production process and leveraging its technical expertise, the company ensures that the final product precisely aligns with the customer's specifications and expectations.
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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FAQ 1: What are the key properties of Nylon Fiber-Reinforced Composites?
Answer: These composites typically exhibit increased strength, stiffness, and improved heat resistance compared to plain nylon.
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FAQ 2: How are Nylon Carbon Fiber Reinforced Materials manufactured?
Answer: They are usually produced through processes such as injection molding or extrusion, where carbon fibers are incorporated into the nylon matrix.
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FAQ 3: In what applications are Nylon Fiber-Reinforced Composites commonly utilized?
Answer: They are frequently found in automotive components, aerospace parts, and industrial machinery due to their high performance.
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FAQ 4: What are the advantages of using Nylon Carbon Fiber Reinforced Materials over traditional metals?
Answer: They offer weight reduction, better corrosion resistance, and design flexibility.
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FAQ 5: How does the cost of Nylon Fiber-Reinforced Composites compare to other composites?
Answer: The cost can vary depending on the specific formulation and manufacturing process, but it may be higher than some common composites.
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FAQ 6: Are Nylon Carbon Fiber Reinforced Materials recyclable?
Answer: To some extent, but the recycling process can be challenging and may not be as straightforward as for some other materials.
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FAQ 7: What kind of maintenance is required for products made from Nylon Fiber-Reinforced Composites?
Answer: Generally, minimal maintenance is needed. Regular cleaning and inspection for damage are often sufficient.
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FAQ 8: Can the properties of Nylon Carbon Fiber Reinforced Materials be customized?
Answer: Yes, by adjusting the composition and processing parameters, the properties can be tailored to specific requirements.
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FAQ 9: How do environmental factors affect the performance of Nylon Fiber-Reinforced Composites?
Answer: Exposure to extreme temperatures, humidity, and UV radiation can have an impact, but they are designed to withstand certain environmental conditions.
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FAQ 10: What are the latest trends in the development of Nylon Carbon Fiber Reinforced Materials?
Answer: Current trends include the development of more efficient manufacturing methods, improved fiber-matrix adhesion, and enhanced material performance.
