Nanotech for Nascar? Let's git'r done!

The United States may soon need to bid a sad farewell to the sand-barrel approach to highway crash protection. A new self-healing automotive crash-barrier material developed to add safety at NASCAR pit stops--it recaptures its original shape minutes after a car crashes into it--is now under evaluation for use on the nation's highways.

"If we put these in high-accident locations, it's immediately ready after an accident" to absorb a second crash, says Dean Focke, roadway standards engineer for the Ohio Department of Transportation, which, along with federal transportation officials, is currently evaluating the material, made by Battelle Science and Technology, of Columbus, OH.

The material is a type of polyurethane that Battelle developed through a proprietary process that removes brittleness no matter how hard or fast it's deformed. What's more, the deformed material doesn't "rebound" too quickly, which could cause a crashed car to bounce back into lanes of traffic. The materials can be arranged in several bays and modified for various applications.

"Most materials, as you impact it at faster and faster rates, they will have more brittleness," says Jay Sayre, a materials scientist at Battelle. "But this material doesn't go through a brittle failure. It's an energy-absorbing hyperelastic form of polyurethane. What's unique about it is the mechanical performance."

Battelle originally developed the system for NASCAR, which wanted something practical and safe for the leading edge of the concrete wall that separates pit row from the race lanes. A prototype was able to take head-on and 20-degree impacts at speeds up to 100 miles per hour and still regain its shape. Now Battelle is working on versions that could take the place of highway-crash barriers and even some military armor applications.

With most polyurethanes and other plastics, "if you hit it, it might go back to 95 percent the first time, 90 percent the second time, 85 percent, and eventually, it just doesn't go back," says Scott Versluis, vice president for technology development and commercialization at Battelle. "That's how a classical plastic behaves. Also, there is a point where you can stretch it far enough that it will break." click here to read on