aviation cable factory

1. Structural Design‌ ‌Conductor Structure‌ ‌Stranded Conductors‌: Silver-plated copper or silver-plated alloy strands enhance conductivity and corrosion resistance‌1. ‌Aluminum Alloy Conductors‌: Some cables use 7 groups of aluminum alloy cores, each containing two conductors twisted to form a high mechanical strength structure‌3. ‌Flat Conductors‌: Extruded flat conductors (e.g., ribbon cables) save space, suitable for compact aviation equipment wiring‌58. ‌Insulation and Shielding Layers‌ ‌ePTFE Dielectric Sintering‌: Used for high-frequency signal transmission, reducing capacitance and signal loss (e.g., 12.0 pF/ft@100 MHz)‌1. ‌Dual Shielding‌: Combines silver-plated copper braiding (for high-frequency interference) with aluminum foil shielding (for low-frequency noise)‌13. ‌Collective Shielding‌: Category 5e aviation cables use collective shielding to wrap multiple pairs of inner conductors, ensuring signal integrity‌6. ‌Jacket and Armor‌ ‌Jacket Materials‌: Fluorinated ethylene propylene (FEP) or polytetrafluoroethylene (PTFE) jackets withstand extreme temperatures (-65°C to 200°C)‌14. ‌Armor Layer‌: Nickel tape armor enhances mechanical protection, while nitrile insulation provides flexibility‌3. ‌2. Key Characteristics‌ ‌Extreme Environmental Resistance‌ ‌Temperature Range‌: Operates from -65°C to 260°C, suitable for engine bays and high-altitude environments‌14. ‌Vibration and Flex Resistance‌: Stranded conductors and flexible jackets ensure long-term mechanical stability‌36. ‌Electrical Performance‌ ‌Low Attenuation and High Bandwidth‌: Attenuation values like 18.2 dB/30m@1 GHz support high-speed data transmission (e.g., LVDS signals)‌16. ‌EMI Shielding Effectiveness‌: Dual shielding suppresses electromagnetic interference, meeting aviation electronics requirements‌13. ‌Safety and Environmental Compliance‌ ‌Low Smoke Zero Halogen (LSZH) Jackets‌: Reduce toxic smoke during fires, complying with FAA FAR 25.853 standards‌34. ‌Fire Resistance‌: PTFE insulation remains functional under high temperatures, ensuring cable integrity during emergencies‌2. ‌3. Core Materials‌ ‌Conductor Materials‌ ‌Silver-Plated Copper/Alloys‌: Ideal for high-frequency signals, minimizing resistance and oxidation‌1. ‌Aluminum Alloys‌: Lightweight design (30% lighter than copper), used in drones and electric aircraft‌35. ‌Insulation and Shielding Materials‌ ‌PTFE/FEP‌: High-temperature and chemical resistance with stable dielectric properties‌12. ‌Aluminum/Nickel Tape‌: Lightweight metal tapes provide EMI shielding and mechanical protection‌36. ‌Jacket Materials‌ ‌Cross-Linked Polyethylene (XLPE)‌: Resists abrasion and oil, used for outer protection‌3. ‌Nitrile Rubber‌: Flexible and oil-resistant, ideal for wiring in moving parts‌3. ‌4. Typical Applications‌ ‌Avionics Systems‌: Flight control cables (MIL-DTL-27500 standard), engine sensor wiring‌13. ‌High-Frequency Communication‌: Category 5e cables for onboard LVDS signal transmission‌6. ‌High-Temperature Zones‌: PTFE-insulated cables in engine bays and auxiliary power units (APUs)‌12. ‌Future Trends‌ ‌Composite Conductors‌: Carbon fiber-reinforced conductors for lighter weight and higher strength‌58. ‌Smart Cables‌: Integrated sensors for real-time health monitoring (e.g., temperature, stress)‌68. Through optimized structures and materials, modern aviation cables continue to advance in performance, safety, and lightweight design, supporting next-generation green aviation and high-density electronic systems‌