FOXBORO FBM02 Cable Termination Module
The FOXBORO FBM02 Cable Termination Module is a high-performance interface designed for efficient cable termination in industrial control systems, ensuring seamless integration and enhanced system reliability.
The FOXBORO FBM02 Cable Termination Module is a high-performance interface designed for efficient cable termination in industrial control systems, ensuring seamless integration and enhanced system reliability.
Material:Stainless Steel
Operating Temperature Range:-40°C to +85°C
Current Capacity:10A
Voltage Rating:Up to 500V DC/AC
Insulation Resistance:1000MΩ @500VDC
Environmental Protection:IP67
The FOXBORO FBM02 cable termination module boasts a compact yet robust design, engineered to withstand harsh industrial conditions. Its high-performance capabilities make it suitable for a wide range of applications, from process control to machine automation.
Featuring a versatile communication protocol, the module facilitates seamless data exchange between various devices within your system. This ensures that your operations run smoothly and efficiently, reducing downtime and enhancing productivity.
With a maximum input current capacity of 20 mA, the FBM02 module is capable of handling high data demands without compromising performance. Its ability to support up to 10 kHz output frequency allows for precise control in real-time applications.
Designed with safety in mind, the module includes an IP65 enclosure rating, protecting against dust and water ingress. This ensures reliable operation in outdoor or dusty industrial environments.
The FOXBORO FBM02 cable termination module is not just about functionality; its compact size and modular design make installation and maintenance a breeze. It is compatible with most standard industrial interfaces, ensuring easy integration into existing systems.
The FOXBORO FBM02 Cable Termination Module is a high-performance interface designed for efficient cable termination in industrial control systems, ensuring seamless integration and enhanced system reliability.