The team used fibres extracted from the textile reinforcement commonly embedded into tyres to guarantee their performance. Adding these fibres to the concrete mix was shown to reduce the concrete’s tendency to spall – where surface layers of concrete break off – explosively under the intense heat from a fire.
Using man-made polypropylene (PP) fibres to protect concrete structures from damage or collapse if a fire breaks out is a relatively well-known technique. Many modern structures, including large scale engineering projects such as Crossrail, have used concrete that includes PP fibres for protection against fire spalling.
This study is the first to show that these fibres do not have to be made from raw materials, but can instead be reclaimed from used tyres. The results are published in the journal Fire Technology.
We’ve shown that these recycled fibres do an equivalent job to ‘virgin’ PP fibres which require lots of energy and resources to produce. Using waste materials in this way is less expensive, and better for the planet.
Dr Shan-Shan Huang
Lead author
The fibres melt under the intense heat from a fire, leaving networks of tiny channels. This means that moisture trapped within the concrete can escape, rather than becoming trapped, which causes the concrete to break out explosively.
Protecting the concrete from fire spalling means that steel reinforcements running through the concrete are also protected. When the steel reinforcements are exposed to extreme heat they weaken very quickly, meaning a structure is much more likely to collapse.
The Liverpool Waterfront Car Park suffered this kind of damage during a fire in 2017, leading to the entire structure eventually having to be demolished.
Collaborating with Twincon, a Sheffield-based company that develops innovative solutions for the construction industry, the researchers have also developed technologies for reclaiming the fibres from the used tyres.
Because the fibres are so small, they don’t affect the strength or the stiffness of the concrete. Their only job is to melt when heat becomes intense. Concrete is a brittle material, so will break out relatively easily without having these fibres help to reduce the pressure within the concrete.
Dr Shan-Shan Huang
Lead author
This involved separating the fibres from the tyre rubber, untangling the fibres into strands, and then distributing them evenly into the concrete mixture.
The team plan to continue testing the material with different ratios of the fibres to concrete and also using different types of concrete. They also plan to find out more about how the materials react to heat at the microstructure level.
By scanning the concrete as it is heated, they will be able to see more precisely the structural changes taking place inside the material.