Product code FW-3mN·m FW-1.4mN·m FW-15mN·m Fw-150mN·m
Envelope dimension 139mm × 100 mm × 73.5 mm Single wheel body:≤71 mm×71 mm×40 mm; Control board ≤94 mm×94 mm×15 mm 113 mm × 152 mm × 74 mm Φ 252 mm × 125 mm
Weight 0.83kg Single wheel: ≤160g Control board: ≤110g ≤1.29kg 9±0.3kg
Power consumption (Three flywheels) Steady state ≤1.8W(@2000rpm) Peak ≤7w(@5000rp-m/3mNm) Standby power consumption ≤1.2W Steady state power consumption ≤3.5w(@3000rmp) Peak power consumption ≤13.2W Standby power consumption ≤1.8W Steady state power consumption ≤4.1W(@3000rmp) Peak power consumption ≤23W ≤5W(@1000rpm) ≤75W
Working voltage 12±1V 9V-12.5V 12V±1.2V 30V±3V
Communication interface RS422 CAN RS422 RS422
Angular momentum ≥0.1Nms(@±6000rpm) ≥ 50mNms(@9000rpm) ≥ 0.5Nms(@6000rpm) 15Nms(@3100rpm)
0utput torque ≥3mNm (0~±6000rpm) ≥1.4mNm(0~±6000rpm) ≥15mNm(0~±5000rpm) 0.15Nm
Working modes Standby mode, speed mode Standby mode, speed mode Speed mode, current mode,standby mode Standby mode, current mode,speed mode
Precision ≤±1rpm ≤±1rpm ≤±0.2 rpm (0ver 500rpm) ≤±1rpm(500rpm~100rpm) ≤±5rpm (Below 100rpm) \
Supply cycle 3 months 3 months 3 months 3 months

Flywheel

Features

  • Energy Storage and Regulation:

    • Stores rotational energy to balance energy supply and demand.

    • Provides stability by maintaining consistent angular velocity in mechanical systems.

    • Efficiently stores and manages rotational energy to provide necessary torque for attitude control in satellites.

  • High Inertia and Efficiency:

    • Designed with high mass and optimized shape for maximum energy storage.

    • Ensures efficient energy transfer and minimal energy loss.

    • Helps maintain the satellite's orientation with minimal energy loss.

  • Durable and Reliable Construction:

    • Made from high-strength materials such as steel, carbon fiber, or composites.

    • Ensures long-term durability and resistance to wear and fatigue.

    • Built from high-strength materials such as titanium or advanced composites for space applications.

    • Reliable performance in harsh environments, including space.

  • Versatile Applications:

    • Used in automotive engines to smooth out power pulses.

    • Integral in industrial machinery for energy regulation and efficiency.

    • Essential in renewable energy systems for grid stability and energy storage.

    • Crucial for tasks such as pointing instruments, stabilizing satellites, and maneuvering in space.

  • Precision Engineering:

    • Manufactured with precise balancing and alignment to minimize vibrations.

    • Enhances the overall performance and longevity of mechanical systems.

    • Provides precise control over a satellite’s angular momentum.

  • Maintenance and Reliability:

    • Low maintenance requirements due to robust design.

    • Reliable performance under varying operational conditions.

    • Designed for long-duration missions with minimal maintenance needs in space.

    • Critical for satellite longevity.

  • Thermal Stability:

    • Engineered to withstand the extreme temperature variations in space.

    • Maintains performance and integrity despite thermal cycling.

  • Compact and Lightweight Design:

    • Optimized for minimal weight and volume, crucial for satellite payload considerations.

    • Easy integration into satellite platforms without compromising performance.

Advantage

  • Efficient Energy Storage and Management:

    • High inertia design for optimal rotational energy storage.

    • Efficiently stores and manages rotational energy to provide necessary torque for satellite attitude control.

    • Balances energy supply and demand to maintain consistent system performance.

    • Ensures optimal orientation and stability of the satellite during various mission phases.

  • High-Strength Construction:

    • Made from premium materials such as steel, carbon fiber, or advanced composites.

    • Constructed from high-strength materials like titanium and advanced composites.

    • Ensures durability and resistance to wear and fatigue for long-term use.

    • Provides reliable performance in the extreme conditions of space.

  • Versatile Applications:

    • Ideal for automotive engines, smoothing out power delivery and enhancing performance.

    • Essential for industrial machinery, providing stability and energy efficiency.

    • Crucial for renewable energy systems, contributing to grid stability and energy storage.

    • Essential for tasks such as instrument pointing, satellite stabilization, and maneuvering in space.

  • Precision Manufacturing:

    • Precisely balanced and aligned to minimize vibrations and ensure smooth operation.

    • Delivers precise angular momentum control for accurate pointing and stabilization.

    • Enhances the overall performance and longevity of mechanical systems.

  • Low Maintenance and High Reliability:

    • Designed for minimal maintenance requirements.

    • Provides reliable performance under a wide range of operational conditions.

    • Designed for long-duration space missions with minimal maintenance needs.

    • Enhances satellite longevity by providing reliable performance over extended periods.

  • Thermal Resilience:

    • Engineered to withstand extreme temperature fluctuations in space.

    • Maintains consistent performance and integrity despite thermal cycling.

  • Optimized for Space Applications:

    • Compact and lightweight design minimizes impact on satellite payload and launch weight.

    • Easy integration into various satellite platforms, ensuring seamless operation.

  • Customizable Solutions:

    • Available in various sizes and specifications to meet specific application needs.

    • Customizable to align with the unique needs of different satellite systems.

  • Quality Assurance:

    • Rigorously tested to ensure high performance and reliability.

    • Meets the highest industry standards for mechanical components.

    • Meets the highest standards of aerospace components for space environments.

Choose us

  • We have extensive experience in the research and development of satellite integration and platform;

  • We have extensive experience in the research and development of remote sensing, communication, and navigation electronic equipment;

  • We have extensive experience in establishing research and production conditions;

  • We have extensive experience in the development of numerical control, testing, and data processing systems;

  • We have a large number of satellites to name;