FR Technical
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EMEA
25 Oct 2024
Thirty years ago, it may have been considered “easy” to classify a fabric due to limited choices and technologies available – a full aramid or a full cotton fabric.
A full aramid FR fabric would contain inherent fibers, or fibers that incorporate flame retardants into the fiber formation process or where flame resistance is a property of the fiber itself.
Alternatively, a full cotton FR fabric would be treated, or contain fibers that in their natural state would support combustion but need the addition of a flame retardant to become flame resistant. This process typically occurs on the product in its fabric form – most likely after the dying stage.
With both types, the fabric they create ends up with characteristics of flame resistance.
The FR/AR fabric market (and associated technologies) have evolved. We’re routinely blending fibers to maximize characteristics…good for wearers, but more difficult for understanding. Classification is tough – what is a fabric that not only incorporates “inherent” fibers, but also has a flame retardant added? Is there a percentage of either fiber that’s absolutely necessary?
We know it’s not easy, and that there’s not guidance, and at this point it’s not event necessary to define or categorize a fabric.
With the true meaning of these terms growing less and less meaningful over time, the key to specifying exactly which fabric you need is in knowing the unique challenges your team might encounter. Understand that the fabric under evaluation has durable flame resistance, meaning it will last for the useful life of the garment. Make choices on three levels: protection, comfort and value. Pay attention to the industry standards the fabric meets, the level of FR/AR protection it offers, and how it feels on your employees.
Digging into these details for each option is much safer than relying on oversimplified marketing jargon that could lead you to a misinformed decision and loss of protection on the job. No matter how or where you’re evaluating fabrics, make sure your decision is based on standardized, scientific test results specific to your environment.
If you’ve got any questions on how your industry has changed regarding fiber classification or you want to learn more about how to select the most applicable PPE for your employees, contact us.
Have you ever wondered how protective flame resistant (FR) fabrics resist catching fire? We have your answers.
When a flame, spark or intense heat reaches a flammable substance, a chemical reaction occurs that produces heat and light. This reaction, termed “combustion,” is the basis of fire. Have you ever wondered how protective flame resistant (FR) fabrics resist catching fire?
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Arc flash, flash fire and combustible dust hazards are commonplace in many industrial settings, including the oil and gas and electric industries. Daily wear FR personal protective equipment (PPE) helps provide a final safeguard to those who may experience these short-term thermal hazards. Yet, to provide this critical protection, PPE must harness the science behind fire and FR fabrics.
To develop effective FR fabrics, textile manufacturers must first have a deep understanding of the science of fire. Manufacturers have developed different technologies to create FR textiles, each with their own merits. To help you understand how these approaches work to snuff out a flame, we explain the various technologies, explore their advantages and drawbacks, and provide some insight into how they work to provide flame resistance.
What is Fire?
We generally think of fire as requiring three separate components: oxygen, heat and fuel. Heat is required to break down the fuel in gaseous components, and then oxygen reacts with the gas that is formed. The heat produced then breaks down more fuel into gases, and this cycle continues until one of the three components—oxygen, heat or fuel—is removed or consumed.
However, the chemical reaction that results in combustion is actually very complex and requires another component that we cannot observe. In order to react with oxygen, the fuel must break apart into highly reactive molecules called “radicals”. These radicals react with oxygen and form more radicals in a chain reaction that results in fire. Therefore, scientifically, fire requires four components: fuel, oxygen, heat and this chain reaction.
The Science of Flame Resistance
By using a deep scientific understanding of fire, fabric manufacturers have developed strategies for flame resistance that are focused on removing one of the components required to sustain the fire. All of these technologies are designed to snuff out a flame and mitigate the risk of injury for the wearer, but each of them has their own set of advantages. Since each of the technologies can be made permanent for the life of the protective garment and will not wash out with laundering, the selection of the technology will depend on the specific hazard and the preference for other attributes.
This article originally appeared in the April 2020 issue of Occupational Health & Safety.
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