Product Description
>> Carbon Fiber UD fabrics are usually obtained by carbonizing and graphitizing organic fibers6. During the manufacturing process, carbon fibers are woven or laid up in different ways to form fabrics with various structures and properties.
- | 0° | 90° |
(g/m²) | ||
Fiber | Density (g/m²) | Fiber | Density (g/m²) | ||
CUD200-12k | 12K | 200 | Other | -- | 200 |
CUD300-12k | 12K | 300 | Other | -- | 300 |
CUD320-6k | 6K | 320 | Other | -- | 320 |
CUD320-12k | 12K | 320 | Other | -- | 320 |
CUD500-6k | 6K | 500 | Other | -- | 500 |
Why choose CUD150-1650 over woven carbon fabrics for bridge reinforcement?
Its unidirectional design focuses strength along the bridge’s load axis (e.g., vertical weight), whereas woven fabrics spread strength evenly—wasting material on non-critical directions.
Can CUD150-1650 be used with hand lay-up processes?
Yes. Its hot-melt weft keeps fibers aligned during hand lay-up, and it absorbs resin quickly—ideal for small-batch projects like custom boat hulls.
What is the maximum weight customization for CUD150-1650?
We offer weights from 150g/m² (lightweight aerospace parts) to 1400g/m² (heavy-duty industrial structural reinforcement)—contact us for custom formulations.
Technical Sheet
Code | Warp | Weft | Density g/m2 | Thickness mm | ||
Fiber | Weight g/m2 | Fiber | Weight g/m2 | |||
CUD150 | 12K | 150 | Hot Melt | 8 | 150 | 0.15 |
| >> Suitable production process | >> Characteristics |
| Prepreg process, Vacuum Infusion Process, hand Lay-up, molding process, Holding pressure tank process | With high strength, high modulus, high temperature resistance, wear resistance, corrosion resistance, fatigue resistance, electrical conductivity, electric heating and infrared radiation and other excellent properties. |
UD Fiber Alignment: 12K carbon fibers are precisely laid in a single direction (0°) using computer-controlled machines, ensuring <1° deviation for consistent load distribution.
Hot-Melt Weft Integration: A thin hot-melt polymer weft is applied at 90° to secure fibers, with controlled heat (80–100°C) to avoid fiber damage.
Surface Treatment: Electrochemical oxidation introduces hydroxyl groups on fibers, improving adhesion with epoxy and vinyl ester resins.
Cutting & Packaging: Fabric is cut to custom lengths, with edge sealing to prevent fiber slippage; rolls are wrapped in moisture-proof film for storage.
Directional High Strength: Tensile strength of 3500MPa along the 0° axis, making it 5x stronger than steel for beam reinforcement and wind turbine blade spars.
Ultra-Thin Profile: 0.15mm thickness adds minimal bulk to reinforced structures (e.g., historic building columns), preserving architectural aesthetics.
Excellent Thermal Stability: Withstands temperatures up to 1000°C, suitable for high-heat applications like industrial furnace liners and rocket engine components.
Cost-Effective Reinforcement: Requires 30% less material than woven fabrics for equivalent load-bearing, reducing construction and manufacturing costs.
Main Application Area
Aerospace & Aviation, Military industry and wind power industry,
Transportation, Construction Industry, Medical equipment, Sports products.
>> Construction Projects Carbon fiber fabric is increasingly being used in the construction industry for structural reinforcement. It can be applied to existing buildings and structures, such as beams, columns, and walls, to enhance their load-bearing capacity and seismic resistance. In cases of structural damage or deterioration, carbon fiber fabric can be used as a repair and strengthening solution, providing a cost-effective and efficient alternative to traditional methods. It is also used in the construction of new infrastructure projects, such as bridges and tunnels, to improve their durability and performance over time. |  |
 | >> Automotive Industry Carbon fiber fabric has revolutionized the automotive industry. It is applied in the production of car bodies, engine hoods, bumpers, and drive shafts. By incorporating carbon fiber fabric, automakers can achieve substantial weight reduction in vehicles, which leads to improved fuel economy, better acceleration, and enhanced handling. Moreover, its high strength contributes to the safety of the vehicle by providing better protection in the event of a collision. Luxury and high-performance cars often utilize carbon fiber fabric extensively to optimize performance and aesthetics, such as in carbon fiber body kits and interior trim pieces. |
| >> Aerospace Field In the aerospace sector, carbon fiber fabric plays a crucial role. It is widely used in the manufacturing of aircraft wings, fuselages, and tail sections. The lightweight yet high-strength nature of carbon fiber fabric helps to significantly reduce the weight of aircraft, thereby improving fuel efficiency and increasing the range of flight. Additionally, it enhances the structural integrity and durability of the aircraft, making it more resistant to harsh environmental conditions and mechanical stresses during flight. Components like engine nacelles and interior structural parts also benefit from the use of carbon fiber fabric for their enhanced performance and reduced weight. |  |
Advantage
High Strength and High Modulus: Carbon fiber fabric has extremely high tensile strength, far exceeding that of ordinary steel. Its tensile strength generally reaches above 3500MPa or even higher, which is several times that of steel with the same cross-section. Meanwhile, it also has a high elastic modulus and can effectively bear tensile force when stressed, transferring the load to other parts of the structure, thus improving the bearing capacity of the structure. When reinforcing flexural members such as beams and slabs in buildings, carbon fiber fabric can fully exert its tensile performance, enhancing the flexural capacity of the members and effectively suppressing the development of cracks. |  |
Width And Weight Can Customized
 |  |  |  |  |
Maintenance
| Clean the surface of the carbon fiber Fabric. During use, dust and stains on the surface of carbon fiber Fabric should be cleaned in time, and special cleaners should be used to avoid acidic or alkaline cleaners. |
| Prevent carbon fiber Fabric From being exposed to sunlight for a long time. Long exposure to sunlight will make the surface of carbon fiber Fabric crack and fade, affecting the beauty and service life. |
 | When storing carbon fiber Fabric Attention should be paid to avoid humidity, high temperature and other environments. When storing carbon fiber Fabric, avoid humidity, high temperature and other environments, and keep dry and ventilated. |
Density
