Manufactured by BEGE, a renowned Dutch provider of automation components known for their robust solutions, this encoder combines precision engineering and durable design for demanding industrial environments.

Incremental Encoder with High Resolution: The BEGE MIG Nova+ is designed for applications requiring higher accuracy, providing enhanced speed and position feedback compared to basic encoders. Perfect for precise regulation in automated systems.

Improved Signal Stability: The advanced electronics ensure stable and noise-resistant output signals (A90°B / A'90°B', HTL/TTL), supporting reliable data transmission even in harsh industrial settings.

Wide Voltage Input (5-24VDC): Tailored for compatibility with various automation controllers and PLCs, facilitating seamless integration into different system architectures.

Stainless Steel Construction: The use of corrosion-resistant stainless steel offers exceptional durability and makes the encoder suitable for demanding environments, such as food, chemical, and outdoor applications.

Flange Mounting with Precision: Features an 80mm outer flange (BCD 65mm, thickness 7mm), meeting IEC 56B14 standards for compatibility with a wide range of motors and gearboxes, simplifying retrofitting and upgrades.

Extended Cable Length: A standard 20-meter shielded cable allows convenient installation over longer distances, reducing the need for additional extension cables.

Ingress Protection (IP55/IP67): Ensures reliable operation under dusty or wet conditions, safeguarding the encoder for both indoor and outdoor use.

Low Pulse Rate (2 pulses/rev per channel): Suitable for applications focused on slow or moderate-speed feedback with maximum stability and clarity of measurement.

Versatile Use in Industrial Automation: Ideal for conveyor systems, packaging machinery, process control, and motion monitoring where precise speed regulation and robust feedback are required.

Also available as MIG Basic (for fundamental automation speed feedback) and MIG AST absolute variants (for position retention after power loss and advanced closed-loop position control).