XYH Epoxy Resin Carbon Fiber Panel uses aerospace-grade carbon fiber + epoxy resin, with tensile strength >3500MPa, -60℃ to +150℃ resistance, and 40% weight savings vs steel. Available in 1-12mm thickness, matte/glossy finish, it suits automotive parts, aerospace components, and Carbon Fiber Drone Frames, ensuring durability and performance.

Product Overview

Our Epoxy Resin Carbon Fiber Panel is a premium composite engineered for high-demand industries. Crafted with aerospace-grade fibers and epoxy resin, it delivers exceptional strength-to-weight ratio—critical for manufacturing lightweight, durable parts like Carbon Fiber Drone Frames, automotive components, and aerospace structures. As a core product, it integrates seamlessly with Carbon Fiber Cnc Cutting processes, making it a top choice for professional buyers like drone manufacturers and automotive OEMs.

Technical Specifications

Material: Aerospace-grade carbon fiber + high-performance epoxy resin

Tensile Strength: >3500MPa

Temperature Resistance: -60℃ to +150℃ (no delamination)

Thickness: 1mm-12mm (customizable)

Weave Patterns: Twill, plain, bidirectional

Surface Finish: Matte/glossy (optional)

Density: ~1.6g/cm³ (1/4 steel, 1/2 aluminum)

Corrosion Resistance: Resistant to fatigue, environmental degradation

Compatibility: Works with CNC routing, vacuum bag molding, autoclave curing

Product Features

Superior Strength & Lightweight: 40% weight savings vs steel, 2x strength vs aluminum—ideal for carbon fiber drone frames to boost endurance by 25%-30%.

Extreme Environmental Adaptability: -60℃ to +150℃ operation and corrosion resistance, suitable for automotive under-hood parts and aerospace components.

Versatile Customization: Multiple weave patterns, thicknesses, and finishes adapt to automotive (hoods), aerospace (wing skins), and sports (bicycle frames) needs.

Easy Machining: Compatible with carbon fiber CNC cutting for precise parts like carbon fiber fpv frame components, reducing post-processing time.

High Durability: Low thermal expansion and anti-delamination design ensure long service life (over 50 years for bridge reinforcement).

How to Use the Panel

Design & Cutting: Use carbon fiber CNC cutting to shape panels into desired parts (e.g., drone frame arms, automotive fenders) based on specs.

Surface Prep: Clean panels to remove dust; bond directly with epoxy adhesives or fasten mechanically (minimal fiber pull-out risk).

Molding (if needed): Use vacuum bag molding or autoclave curing for complex shapes like curved aerospace components.

Finishing: Sand edges for smoothness; apply UV-protective coating for outdoor parts like carbon fiber Racing Drone frames.

Application Scenarios

Automotive: Lightweight hoods, fenders, chassis reinforcements (40% weight savings, better fuel efficiency).

Aerospace: Wing skins, fuselage segments (FAA/EASA compliant).

Drones: Carbon fiber drone frames, carbon fiber fpv frames, drone bodies (boost endurance by 25%-30%).

Industrial: Bridge reinforcement, sports equipment (bicycle frames, tennis rackets), medical devices.

Value to Buyers

Cost Savings: Lightweight design cuts shipping costs; 50-year service life reduces maintenance (no rust vs steel).

Performance Boost: Drones gain longer endurance; cars improve handling; aerospace parts meet strict weight limits.

Efficiency: Easy machining and prepreg options shorten assembly time by 30%.

Certifications and Compliance

Complies with ISO 9001, CE, FAA/EASA standards, ensuring global market access for automotive, aerospace, and drone buyers.

Customization Options

Offers custom thicknesses (1-12mm+), weave patterns, finishes, and pre-cut shapes for Carbon Fiber Drone Frame Kits or automotive OEM orders.

Production Process

Panels undergo: 

1) Fiber-resin prepreg (aerospace-grade materials); 

2) Layup per design; 

3) Vacuum bag/autoclave curing;

4) CNC cutting; 

5) Quality testing (tensile strength, temperature resistance).

FAQ

Q: How does it compare to steel for building reinforcement?

A: 10x tensile strength, 1/4 weight, no large equipment needed—construction time cut to 2/5 of steel.

Q: Is it better than carbon fiber cloth for beams?

A: 4-8x bearing capacity (288,000N vs 56,780N), less delamination, faster construction.

Q: Can it make curved drone frames?

A: Yes, good flexibility—fits complex curves with >95% adhesion rate (vs 70% for steel).

Q: What’s the max thickness available?

A: Standard 1-12mm; custom thicker panels for industrial reinforcement.

Q: Does it need special tools for cutting?

A: No—works with standard carbon fiber CNC cutting equipment, common in drone manufacturing.