Tinned flexible busbar ERIFLEX FLEXIBAR Advanced 2 m 3x50x1 534037

Flexible copper busbar for switchboards and installations

The ERIFLEX FLEXIBAR Advanced flexible busbar is an innovative solution for transmitting electrical energy, characterized by exceptional flexibility and ease of installation. Made of tinned copper, it provides excellent conductivity and corrosion resistance. The product is designed for use both in switchboards and directly in installations where flexibility and adaptability to unusual shapes are required.

This busbar is particularly useful in situations where traditional copper busbars are impractical or difficult to use – e.g., when connecting devices with complex geometries or in confined spaces. Its flexibility allows for free cable routing and minimizes the risk of mechanical damage.

Construction and properties

The ERIFLEX FLEXIBAR Advanced busbar consists of many thin copper lamellas, which gives it exceptional flexibility. The laminated construction increases mechanical strength and dimensional stability. Insulation made of halogen-free, flame-retardant and low-smoke material ensures safe use, even in the event of a fire. Tinning the copper provides additional protection against corrosion and oxidation, which translates into a long product life.

Thanks to its properties, this busbar works perfectly in applications requiring high reliability and safety, such as:

• Electrical switchboards
• Control cabinets
• Industrial installations
• Uninterruptible power supply systems
• Renewable energy sources (RES) applications

Specifications and user parameters

The ERIFLEX FLEXIBAR Advanced busbar, 2 meters long, consists of 3 lamellas with dimensions of 50x1 mm each. It provides a rated current of up to 500 A at ΔT 40 K (ambient temperature). The total thickness of the busbar is 3 mm, and the width is 50 mm. The busbar design allows for easy cutting to the required length and making holes for connectors and fasteners. The flexibility of the material makes it easy to route cables in tight spaces and adapt to unusual shapes of devices.