Researchers from Drexel University, Purdue University and Oregon State University have discovered that adding paraffin oil to the mix for road concrete can give it the ability to melt ice and snow when temperatures fall.
Image: Drexel University
Drexel University researchers have recently made a discovery that could create roads that deice themselves during winter storms. The secret? Adding a little paraffin wax to the road's concrete mix.
In a paper published for the journal Cement and Concrete Composites, researchers, led by Yaghoob Farnam, PhD., an assistant professor in Drexel's College of Engineering, explain how substances like paraffin oil—known in the chemistry world as "phase change materials”—can be used in concrete to store energy and release it as heat when a road needs a melt-off.
Keeping roads open to travel is a persistent challenge during winter months, but efforts to make them safely passable—including the constant use of snowplows, deicing chemicals and road salt—tend to deteriorate the surface. The chemicals and road salts currently used to melt snow and ice can also have a harmful environmental impact when surface runoff carries them into nearby ecosystems—which is pretty likely considering Drexel’s home state of Pennsylvania alone dumps more than 900,000 tons of it on roads each winter. So researchers have been searching for a better winter option than salting and plowing for some time.
Farnam's group, in collaboration with researchers from Purdue University and Oregon State University, is among the first to demonstrate that using phase change materials as an environmentally friendly alternative can be just as effective as the standard salting and scraping methods.
"Phase change materials can be incorporated into concrete using porous lightweight aggregate or embedded pipes, and when PCM transforms from liquid to solid during cooling events, it can release thermal heat that can be used to melt ice and snow," Farnam stated in a release. "By inhibiting the formation of ice and snow on the pavement or bridge surface, the use of PCM may reduce or eliminate the need for deicing chemicals/salts, snowplowing or both—thus saving money and positively influencing the environmental impact of such operations."
Paraffin oil, a common ingredient in candles, wax polishes, cosmetics and water-proofing compounds, was the researchers’ material of choice for this endeavor because it is organic, widely available, chemically stable and relatively inexpensive. Like all phase change materials, it releases thermal energy when it changes its physical state, which means as temperatures drop and the oil begins to solidify it releases energy through latent heat of fusion. This means paraffin oil can be tailored to embed deicing capabilities in a road surface so that it becomes thermally active during snow events or when deicing is needed.
To test its snow- and ice-melting ability, the team created a set of concrete slabs—one with paraffin-filled pipes inside, one containing porous lightweight aggregate that had been infused with paraffin, and a third reference slab without paraffin. Each was sealed in an insulated container and then covered with about 5 in. of lab-created "snow."
With temperatures inside the boxes held between 35-44° F, both of the paraffin-treated slabs were able to completely melt the snow within the first 25 hours of testing, while the snow on the reference sample remained frozen. The slab with the paraffin-filled tubes melted the snow slightly faster than the one composed of paraffin-treated aggregate. Farnam suggests that this is because the paraffin inside the tubes is able to solidify more quickly because of the regular diameter of the pipes, while the diameter of the pores of the aggregate vary in size.
But in the group's second experiment, in which the ambient air temperature in the box was lowered to freezing before the snow was added, the paraffin-treated aggregate was more effective than the embedded pipes. This is because the capillary pore pressure delayed the freezing of the paraffin, thus allowing it to release its heat energy over a longer period of time.
"The gradual heat release due to the different pore sizes in porous lightweight aggregate is more beneficial in melting snow when concrete is exposed to [a] variety of temperature changes when snow melting or deicing is needed," Farnam said. "We believe that using porous lightweight aggregate can be [a] potential way of incorporating phase change materials in concrete as it is easy to be implemented in practice and can cover environmental conditions of various locations in the U.S. dealing with snow, especially melting snow or deicing in roads and bridges in the Northeast."
One of the first uses of this infrastructure technology could be at airports, where keeping runways clear of snow and ice is crucial and a constant challenge in winter. The Federal Aviation Administration supported this research as part of its Heated Airport Pavements Project in its Partnership to Enhance General Aviation Safety, Accessibility and Sustainability program.
"Additional research is needed to further understand other factors influencing concrete constructability, including concrete fresh and hardened performance when the concrete contains phase change materials, and the phase change materials’ thermal performance in different locations in the U.S.," Farnam said. "Eventually this could be used to reduce the amount of deicing chemicals we use, or can be used as a new deicing method to improve the safety of roads and bridges. But before it can be incorporated, we will need to better understand how it affects durability of concrete pavement, skid resistance and long-term stability."
Article source: Drexel University