The BEGE MIG Nova+ Flange Encoder is a high-quality incremental encoder, specially developed for precise control and stable feedback in advanced industrial automation applications.

Produced by BEGE Power Transmission, a leading Dutch manufacturer renowned across Europe for durable, precision-engineered motion control solutions in the automation industry.

Advanced incremental technology with superior signal stability, making it highly suitable for demanding tasks requiring accurate speed feedback and reliable control in modern drive systems.

High resolution and noise-resistant signal output ensure optimal performance in precision automation, positioning, and control processes.

Compatible with harsh industrial environments due to its robust stainless steel housing (outer diameter: 350mm, flange BCD: 300mm, flange thickness: 12mm) for maximum mechanical protection and corrosion resistance.

Supports IEC 180B5 motor interface and shaft diameter of 48mm, allowing easy integration with large-scale motors and machinery.

Wide input voltage range (5-24VDC) for flexible compatibility with diverse industrial control systems.

Output types: A90°B / A’90°B’ HTL/TTL supporting both single-ended and differential signal transmission, maximizing adaptability for existing and new installations.

Delivers 8 pulses per rotation per channel, optimized for slower-speed, heavy-duty feedback without sacrificing reliability.

Long 10-meter cable reduces wiring complexity and ensures flexibility for remote mounting or complex assemblies.

High ingress protection (IP55 / IP67) guarantees reliable operation against dust and powerful water jets, making it suitable for demanding or hygienic environments.

Typical applications include conveying systems, heavy process automation, motor feedback, packaging machinery, and other precision-driven industries that require stable incremental feedback.

Choose the MIG Basic version for standard speed feedback where basic incremental signals are sufficient, or the MIG AST absolute encoder for situations demanding loss-free position memory after power loss and advanced positioning needs.