Description
RGL9 Twin Leg Elasticated Webbing Lanyard & Shock Absorber: Advanced Fall Protection
The RGL9 Twin Leg Elasticated Webbing Lanyard & Shock Absorber is a crucial safety device for professionals working at height. This innovative lanyard combines superior functionality with enhanced user comfort, making it an indispensable tool for various industries.
Key Features and Benefits
Elasticated Legs: The lanyard’s elasticated design significantly reduces hanging slack, minimizing trip hazards and entanglement risks. This feature enhances worker mobility and safety in confined spaces.
Twin Leg Design: With two legs, this lanyard allows for seamless progression between anchor points through double clipping. This ensures continuous connection, providing optimal safety during tower climbing, steel erecting, scaffolding work, and maintenance on open structures.
Integrated Shock Absorber: In the event of a fall, the built-in shock absorber deploys to limit the impact force on the user. This critical feature helps prevent severe injuries and enhances overall fall protection.
Industry Applications
The RGL9 Twin Leg Elasticated Webbing Lanyard & Shock Absorber is widely recognized as an industry standard for fall protection. It’s often the minimum required equipment issued alongside a safety harness for height work across various sectors.
Usage Guidelines
For maximum effectiveness, this lanyard must be used in conjunction with a safety harness. Users have the flexibility to choose from a range of EN 362 compliant fittings to suit specific work requirements.
Customization Options
While standard connectors are provided, the RGL9 offers customization options to meet diverse workplace needs. This adaptability ensures that workers can select the most appropriate configuration for their specific tasks and environments.
By incorporating the RGL9 Twin Leg Elasticated Webbing Lanyard & Shock Absorber into your fall protection system, you’re investing in a versatile, reliable, and high-performance safety solution that prioritizes worker safety and efficiency in demanding height-related work scenarios.
