Role of fire-resistant cables in critical firefighting systems

Understanding life-safety and firefighting &#;wiring systems&#; is essential, and several countries have now upgraded the testing of fire-resistant cables and wiring systems to adopt and harmonise with a more realistic standard time temperature curve. The logic behind this is that &#;essential&#; circuits must at least survive the same fire intensity as all the other fire-rated components, elements and systems of the building exposed to the same fire.

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The reliability of electric cables during a fire is crucial for life safety, firefighting and critical emergency systems. If these essential cable systems were to fail, the vital equipment they power would also fail, endangering the lives of occupants, emergency responders and property.

Building regulations frequently stipulate that emergency equipment must maintain operation for the duration necessary to fulfil its intended purpose. There is a widespread expectation that these &#;systems&#; should be both suitable for their intended function and in compliance with the minimum code requirements. This article explores how the current BS and IEC cable testing methods can satisfy this requirement.

Building codes and regulation

Numerous fire-code requirements concerning essential cables primarily revolve around the product&#;s testing and performance criteria, which are incorporated into Building Codes and upheld by regulatory authorities. Certification bodies in many countries audit, test and then certify companies and their fire-performance cable products to specific performance standards on a &#;component only&#; basis. This does not validate or imply any &#;installed system performance&#; or &#;fitness for purpose&#;. 

To ensure the validation of an entire system, including all its components and installation methods, it is essential not only to subject them to joint testing and certification but also to ensure that the whole system complies with local regulations during the installation phase with the continuing focus on building safety, fire-resistant cables &#; and their ability to service critical systems in the event of a fire. 

So, the cable shall be suitably chosen and installed; fire-resistant cables must comply with the following codes of practice:

• BS -1: Emergency lighting &#; Code of practice for emergency escape lighting in premises.
• BS -1: Fire detection and fire alarm systems for buildings &#; Code of practice for the design, installation, commissioning, and maintenance of systems in non-domestic premises.
• BS :: Code of practice for the selection and installation of fire-resistant power and control cable systems for life safety and fire-fighting applications.

Upgraded fire classification

We know that fire is a dynamic force, exhibiting movement, expansion and altering the shape, size and characteristics of everything it encounters. To simulate real fire scenarios accurately, it is essential for testing to encompass factors like the risk of flashover, falling debris during a fire (including potential impact on cables), and exposure to water, either from sprinkler systems or fire hoses.

British Standards offer exemplary test scenarios that illustrate this approach. For instance, BS (applied to cables exceeding 20mm) mandates direct impact testing and high-pressure water-jet tests on a single sample. Another example is BS CWZ (relevant for cables under 20mm), which requires a three-hour fire test, simulating situations where residents may be trapped in a tall building. In such scenarios, critical safety equipment might need to operate for extended periods, irrespective of size or construction. Each cable sample must pass a realistic fire scenario test to ensure reliability.

Many polymeric cable&#; insulation and sheath materials can deteriorate rapidly when exposed to high temperatures. Consequently, the enhanced classification of fire-rated cables is pivotal in the integrity of critical firefighting systems.

Types of fire and flammability testing  

• Flame spread: This test focuses on assessing a product or material&#;s reaction to fire in controlled environments, where specific parameters such as temperature, airflow, or pressure can influence the fire&#;s propagation. For instance, a cable may undergo testing to determine whether it emits particles that contribute to the fire&#;s spread.
• Fire resistance: This test concentrates on how effective the product is at enduring a fire and continuing to operate in a fire scenario. Products often tested for fire resistance are designed for withstanding fire for an extended period, such as 120 minutes for a fire-resistant cable.

Fire resistance performance (insulation integrity tests)

BS , BS , BS EN , BS -2 & IEC -1,2&3, IEC -21,23&25

Both British and IEC standards for fire-resistant cable testing do not necessitate the installation of cables on supports or with common fixing components, distances or methods used during typical installations. Test specimens are typically configured horizontally with short laboratory-scale cable lengths. The test flame source typically involves 500mm- or 600mm-long ribbon burners with a flame temperature specified in the test standard. Depending on the cable&#;s construction, the insulation is usually safeguarded by an outer sheath, which can be copper, steel wire-armoured, or a fire-resistant polymeric sheath, each responding differently to fire conditions.

To meet the requirements of a fire-resistant cable, the construction must align with the appropriate British Standard tailored to the specific type of fire-resistant cable. Several references for cable fire performance exist, including BS , BS , BS , BS , BS and IEC . These standards specify variations in time and temperature at which cables are tested under different fire conditions, ranging from a 30-minute rated cable tested at 830°C (e.g. PH30 cable as per BS EN ) to a three-hour rated cable tested at 940°C (BS category C). These standards collectively offer confidence to those specifying the cable that it will continue functioning in the event of a fire.

Fire propagation performance (fire spread & flame retardance)

This test ensures the fire behaviour of flame-retardant material prevents flame propagation during a fire emergency. When the material comes into contact with fire, the by-product from the endothermic reaction is gaseous water, which will help envelop the flame and thereby exclude oxygen from the fire.

The best flame-retardant cables are often halogenated because the insulation and outer jacket are flame-retardant. Still, when we need halogen-free cables, we often find only the flame-retardant outer jacket and the inner insulation, which are not. This has significance because cables with a flame-retardant outer jacket may pass flame retardance tests with an external flame source (BS EN -1, BS EN -3). Designers and users of cables claiming must meet to be flame retardant to IEC -3-22/23/24/25.

The primary importance of fire load

Many countries worldwide are moving to greater use of Halogen Free and Flame Retardant (HFFR) cables to increase building safety. To provide halogen-free cables, cable manufacturers often choose polymers like polyethylene (sometimes referred to as polyethene) (PE & XLPE) because it is easy to process and cheap; however, although PE is halogen-free, it has a naturally high fire load.

The table below compares the fire load in MJ/Kg for commonly used cable-insulating materials. While the Heat Release Rate and volatility in the air may vary among these materials, the amount of fuel introduced to a fire per kilogram and the resulting volume of heat produced and oxygen consumed can be assessed comparatively. For instance, the heat release for Petrol is 48MJ/Kg, Coal is 25MJ/Kg, and Wood is 18.5MJ/Kg.

Name of PolymerDescriptionCalorific Value (MJ/Kg)XLPECrosslinked Polyethylene46PPPolypropylene46Nylon 66Polyamide33EPREthylene Propylene Rubber28.5CSPCholorsulphonated Polyethylene28PCPPolychloroprene Rubber24PVCPolyvinyl Chloride18SIRSilicon Rubber15.5ETFEEthylene tetrafluoroethylene13.8HFFRHalogen Free Flame Retardant13PTFEPolytetrafluoroethylene5

Smoke emissions 

The first and most crucial aspect of smoke is how much smoke is released. Typically, the larger the fire, the more smoke is generated. So, whatever can be done to reduce the spread of fire will also correspondingly reduce the amount of smoke.

Most fire-resistant cables rely on polymers or tapes to increase their resistance to fire, yet these materials can burn away at as little as 80°C, exposing the critical conductors. To give some soft-skinned polymer cables flame-retardant properties, halogens such as chlorine, bromine and fluorine are added to the outer sheath. When exposed to a fire, these halogenated polymers will release extremely toxic halides. This smoke restricts breathing and increases the risk of inhaling when following the common rules during a fire. 

Low-smoke, zero-halogen (LSZH) flame retardant (FRT) cables comply with IEC , IEC and IEC , which ensure that the flame-retardant cables reduce flame propagation, prevent the release of toxic gases and control smoke emission under fire conditions.

Ensuring a safer and more sustainable future together

As the complexity of new buildings increases, decision-makers in the supply chain must ensure that specified products meet safety standards and compliance requirements, adhering to recognized governance and regulations. The rise in high-rise building fires globally has emphasized the importance of product quality, especially for fire performance circuits.

The latest generation of fire performance cabling guarantees the continued operation of critical fire-safety circuits for a minimum of 30 minutes, extending up to 120 minutes during a fire. In establishments like hospitals, schools, shopping malls and airports, which often feature intricate addressable-loop fire-alarm systems, the choice of cabling becomes crucial.

Recognizing this, industry experts and regulators are advocating for more rigorous testing standards. An upgraded classification of fire survival cables has been introduced for critical systems, enabling them to power essential circuits during a fire and withstand the challenges posed by safety systems, including falling debris, collapsing walls, fire hoses, high-pressure sprinklers and smoke extraction.

While fire survival cables play a crucial role in building safety, there is a lack of understanding about their significance, prompting local regulatory authorities to educate the market on the advantages of specifying these cables. There can be no compromise, and thorough fire-performance testing of cables is essential due to its numerous benefits. Equally important is understanding the correct installation procedures for these cables.

About the Author

Goto SUNUA to know more.

Manikandan Annadurai

Manikandan Annadurai is a Reaction-to-Fire Testing Engineer with Dubai Civil Defense&#;s Emirates Safety Laboratory. Manikandan is a Chemist and has 18+ years of various industrial experience including Fire Testing, specializing in designing and conducting comprehensive fire tests to evaluate the performance of materials under different conditions.

• Fire performance testing on electric cables/wires

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Related

What are Fire-Resistant Cables?

Unlike standard cables that melt and fail relatively quickly in high temperatures, fire-resistant cables are specially designed to withstand extreme heat and flames for a specified period. This allows them to continue transmitting power and signals even when engulfed in fire, providing critical support for life-saving operations.

Types of Fire-Resistant Cables

Several types of fire-resistant cables are available to suit various applications and requirements:

1. Mineral-Insulated Cables (MIC): MICs consist of copper conductors surrounded by magnesium oxide insulation and a copper sheath. These cables offer exceptional fire resistance and are commonly used in high-temperature environments, such as industrial plants and power generation facilities.

2. Fire-Rated Cables: Fire-rated cables are designed to maintain circuit integrity for a specified duration under fire conditions. They are often installed in buildings and structures where fire safety is a concern, such as hospitals, schools, and commercial complexes.

3. Fire Resistant Control Cables: These cables are specifically designed for control and instrumentation applications in fire-prone environments. They provide reliable signal transmission and control functions during fire emergencies.

4. Fire Alarm Cables: Fire alarm cables are used to connect fire detection and alarm systems, ensuring timely notification of fire incidents. These cables are engineered to withstand fire exposure and maintain communication between alarm devices.

Understanding the Need for Fire-Resistant Cables

Fire presents a complex and multifaceted threat. Standard cables, while crucial for everyday electrical operations, can quickly succumb to high temperatures, melting, and short circuits. This can have disastrous consequences:

• Loss of critical systems: Fire alarms, emergency lighting, communication systems, and life support equipment may fail, hindering evacuation and response efforts.
• Spread of fire: Burning cables can act as fuel sources, exacerbating the spread of flames and smoke.
• Toxic fumes: Certain cable materials release harmful toxins when burned, posing a significant health hazard.

Fire-resistant cables address these concerns by offering various levels of protection:

• Maintaining circuit integrity: They withstand high temperatures and flames for a specific duration, ensuring critical systems remain operational during a fire.
• Limiting fire spread: Fire-resistant materials and sheathing prevent flames from traveling along the cable path, potentially containing the fire to its origin.
• Reducing smoke and toxic fumes: Fire-resistant cables often use materials that produce minimal smoke and toxic fumes, improving visibility and air quality during evacuation.

Where Are They Used?

Fire-resistant cables are essential in various scenarios where maintaining circuit integrity during a fire is critical. They are commonly used in:

• Emergency systems: Fire alarm circuits, emergency lighting, public address systems, and elevator controls rely on these cables to function properly during an evacuation.
• Critical infrastructure: Hospitals, data centers, airports, and transportation hubs require uninterrupted power and communication, making fire-resistant cables vital for safety.
• Hazardous environments: Oil rigs, chemical plants, and other high-risk areas necessitate cables that can withstand extreme heat and harsh conditions.

Choosing the Right Cable: It&#;s All About Needs

With a variety of fire-resistant cables available, selecting the right one requires careful consideration:

• Fire resistance rating: Choose a cable that meets the required fire resistance duration based on local regulations and building codes.
• Application environment: Consider factors like moisture, chemical exposure, and mechanical stress impacting cable selection.
• Circuit requirements: Ensure the cable&#;s conductor size and type match the electrical load and voltage requirements of the application.
• Budget: While fire-resistant cables offer superior protection, they generally come at a higher cost than standard cables.
• Installation and maintenance: Opt for cables with proper flexibility and fire-resistant accessories for easier installation and future maintenance.

Consulting with a qualified electrician or fire safety professional is crucial to ensure you choose the appropriate fire-resistant cable for your specific needs.

Installation and Maintenance Considerations

Proper installation and maintenance practices are critical to maximizing the performance and longevity of fire-resistant cables. Key considerations include:

1. Proper Installation Techniques: Fire-resistant cables should be installed according to manufacturer guidelines and industry best practices to ensure optimal performance and safety.

2. Routine Inspection and Maintenance: Regular inspection and maintenance of fire-resistant cables are necessary to identify potential issues and ensure continued reliability.

3. Replacement and Upgrading: Fire-resistant cables should be periodically inspected for signs of wear, damage, or deterioration, and replaced or upgraded as needed to maintain optimal performance and compliance with regulations.

Benefits of Fire-Resistant Cables:

Fire-resistant cables offer a multitude of advantages, making them a valuable investment for various applications. Let&#;s explore some of the key benefits:

1. Enhanced Life Safety:

• Fire Alarm Systems: Fire-resistant cables ensure uninterrupted power and data transmission for fire alarm systems, allowing for early detection and rapid response to fire events. This can provide crucial time for occupants to evacuate safely.
• Emergency Lighting and Evacuation: By maintaining power supply for emergency lighting, fire-resistant cables illuminate escape routes and provide visual guidance during evacuation, even in smoke-filled conditions.
• Communication Systems: Continued functionality of communication systems facilitates clear communication and coordination between emergency personnel and building occupants during a fire event, contributing to efficient evacuation and rescue efforts.

2. Reduced Property Damage:

• Continued System Operation: By protecting critical systems like control panels and machinery from fire damage, fire-resistant cables can minimize equipment downtime and associated repair costs.
• Minimized Fire Spread: Cables failing during a fire can act as fuel sources, accelerating the spread of flames. Fire-resistant cables, with their flame-retardant properties, help contain the fire and minimize damage to building infrastructure.
• Reduced Business Disruption: Maintaining system functionality during a fire incident can minimize business downtime and associated economic losses.

3. Compliance and Regulatory Requirements:

Are you interested in learning more about fire resistant cable insulation material? Contact us today to secure an expert consultation!

• Building Codes and Fire Safety Regulations: Many countries and regions have regulations mandating the use of fire-resistant cables in specific buildings and applications. Choosing compliant cables demonstrates adherence to regulations and helps avoid potential legal ramifications.
• Insurance Requirements: Some insurance companies offer premium discounts for buildings utilizing fire-resistant cables, recognizing their contribution to improved fire safety.
• Provides peace of mind: Knowing that critical systems will function during a fire can offer significant peace of mind to building owners, managers, and occupants.