BS EN 16750:2017+A1:2020 - Fixed Firefighting Systems: Oxygen Reduction Systems

Ensure the safety and security of your premises with the comprehensive guidelines provided by the BS EN 16750:2017+A1:2020 standard. This essential document is your go-to resource for the design, installation, planning, and maintenance of fixed firefighting systems, specifically focusing on oxygen reduction systems.

Overview

Released on August 28, 2020, this standard is a critical update in the field of firefighting systems. It provides detailed instructions and specifications to ensure that oxygen reduction systems are effectively integrated into your safety protocols. With 40 pages of in-depth information, this document is a must-have for professionals in the field of fire safety and building management.

Key Features

• Standard Number: BS EN 16750:2017+A1:2020
• ISBN: 978 0 539 03256 7
• Status: Standard

Why Choose BS EN 16750:2017+A1:2020?

The BS EN 16750:2017+A1:2020 standard is designed to provide a robust framework for the implementation of oxygen reduction systems. These systems are crucial in environments where traditional firefighting methods may not be feasible or effective. By reducing the oxygen concentration in a protected area, these systems help prevent the ignition and spread of fires, offering a proactive approach to fire safety.

Design and Installation

One of the core components of this standard is its focus on the design and installation of oxygen reduction systems. It provides detailed guidelines to ensure that these systems are tailored to the specific needs of your facility. Whether you are working in a warehouse, data center, or any other environment where fire risk is a concern, this standard will guide you through the process of designing a system that meets your unique requirements.

Planning and Maintenance

Effective planning and maintenance are critical to the long-term success of any firefighting system. The BS EN 16750:2017+A1:2020 standard offers comprehensive advice on how to plan for the integration of oxygen reduction systems into your existing safety protocols. Additionally, it provides maintenance guidelines to ensure that your systems remain operational and effective over time.

Benefits of Oxygen Reduction Systems

Oxygen reduction systems offer several advantages over traditional firefighting methods:

• Proactive Fire Prevention: By reducing the oxygen level, these systems prevent fires from starting, rather than just extinguishing them after they have begun.
• Minimal Water Damage: Unlike water-based systems, oxygen reduction systems do not cause water damage, making them ideal for environments with sensitive equipment or materials.
• Continuous Protection: These systems provide ongoing protection, ensuring that your facility is always safeguarded against fire risks.

Who Should Use This Standard?

The BS EN 16750:2017+A1:2020 standard is essential for a wide range of professionals, including:

• Fire safety engineers and consultants
• Building managers and facility operators
• Architects and designers involved in the construction of new facilities
• Maintenance personnel responsible for the upkeep of safety systems

Conclusion

Incorporating the BS EN 16750:2017+A1:2020 standard into your fire safety strategy is a proactive step towards ensuring the safety and security of your facility. With its comprehensive guidelines on the design, installation, planning, and maintenance of oxygen reduction systems, this standard is an invaluable resource for anyone involved in fire safety management.

Stay ahead of potential fire risks and protect your assets with the trusted guidance of the BS EN 16750:2017+A1:2020 standard. Equip yourself with the knowledge and tools necessary to implement effective oxygen reduction systems and safeguard your environment against the threat of fire.

BS EN 16750:2017+A1:2020

This standard BS EN 16750:2017+A1:2020 Fixed firefighting systems. Oxygen reduction systems. Design, installation, planning and maintenance is classified in these ICS categories:

• 13.220.20 Fire protection

This European standard specifies oxygen reduction systems that are used as fire prevention systems by creating an atmosphere in an area which is having a lower permanent oxygen concentration as in ambient conditions. The level of oxygen reduction is defined by the individual risks of these areas (see Annex A). Oxygen reduction is achieved by technical systems which are providing a flux of air containing a reduced concentration of oxygen. This European standard specifies minimum requirements and defines the specifications governing the design, installation and maintenance of fixed oxygen reduction systems with oxygen reduced air in buildings and industrial production plants. The standard also applies to the extension and modification of existing systems. This European standard applies to oxygen reduction systems using nitrogen which are designed for continual oxygen reduction in enclosed spaces. NOTE Nitrogen is today the most suitable gas to be used for oxygen reduction. For other gases this European standard can be used as basis. This European standard does not apply to oxygen reduction systems that use water mist or combustion gases. The European standard does not apply to: - explosion suppression systems; - explosion prevention systems; - fire extinguishing systems using gaseous extinguishing agents; - inertization of portable containers; - systems in which oxygen levels are reduced for reasons other than fire prevention (e.g. steel processing in the presence of inert gas to avoid the formation of oxide film); - inerting required during repair work on systems or equipment (e.g. welding) in order to eliminate the risk of fire or explosion. In addition to the conditions for the actual oxygen reduction system and its individual components this European standard also covers certain structural specifications for the protected area. The space protected by an oxygen reduction system is a controlled and continuously monitored indoor climate for extended occupation. This standard does not cover unventilated confined spaces that may contain hazardous gases.