Football players (and anyone else who takes hard hits) may want to breathe a sigh of relief.
In recent research, engineers at the University of 蜜糖直播 of Boulder and Sandia National Laboratories have developed a new design for padding that can withstand big impacts. The team鈥檚 innovations, which can be printed on commercially available 3D printers, could one day wind up in everything from shipping crates to football pads鈥攁nything that helps to protect fragile objects, or bodies, from the bumps of life.听
The team in the journal 鈥淎dvanced Materials Technologies.鈥
鈥淚mpact mitigation is something that鈥檚 important everywhere,鈥 said Robert MacCurdy, corresponding author of the study and assistant professor in the Paul M. Rady Department of Mechanical Engineering at 蜜糖直播 Boulder. 鈥淚t鈥檚 in highway crash barriers, knee pads and elbow pads, and in packaging equipment.鈥
The research takes a fresh look at something most people encounter all the time but rarely notice: foams. They鈥檙e squishy materials filled with countless tiny holes and channels. Picture packing peanuts or stress balls. MacCurdy said that foams can be good at absorbing blows, but they have a major drawback: If you squeeze a foam hard enough, it will eventually compress down into a rigid wad.
He and his colleagues think they can do better.
In the new study, the group wrote computer algorithms to meticulously redesign the interior of cushioning materials鈥攁llowing them to buckle under force, but only following a careful pattern. When the group put their designs to the test in the lab, they discovered that their padding could absorb as much as 25% more force than current state-of-the-art technologies.听
鈥淭he material you use for absorbing impacts matters,鈥 MacCurdy said. 鈥淏ut what really matters is the geometry.鈥
Zooming in
To understand why some cushions work well, and others don鈥檛, it helps to look deep inside. 听
What gives a foam its spring, for example, are all those little nooks and crannies. When you squeeze a sponge, MacCurdy explained, those empty spaces will begin to close up, which, in turn, absorbs energy.听
Some engineers have moved beyond that basic design. Instead, they make padding out of a network of towers, or 鈥減late lattices,鈥 that look a bit like honeycombs. If a linebacker, perhaps, crashes into this kind of cushion, the impact will cause the honeycombs to collapse in a wave-like pattern. That鈥檚 a more efficient way to absorb forces.
But, MacCurdy noted, researchers have long strived for padding that meets a gold standard鈥 technology that doesn鈥檛 just absorb a lot of force, but can also absorb many different kinds of forces with the same finesse.
鈥淚f you鈥檙e riding your bike and get into a crash, you don鈥檛 know if that鈥檚 going to be a low-speed impact or a high-speed impact. But regardless, you expect your helmet to perform well,鈥 he said. 鈥淲e鈥檙e trying to develop a geometry that performs well under all of those scenarios.鈥
Giving the squeeze
To make a more versatile cushion, the engineer and his colleagues opted to rearrange the interior of these objects, down to the scale of a millimeter or less.
The group first used custom software to lay out a network of honeycombs, then tweaked them to include a few kinks, a bit like the bellows in an accordion. Those kinks help to guide the honeycombs as they crunch down during an impact, allowing for a much smoother collapse.
鈥淭he moment you start to compress these structures, they absorb a certain amount of force,鈥 MacCurdy said. 鈥淭he best absorber designs maintain a constant force across the whole range of compression.鈥
In other words, unlike a foam, these cushions will behave the same no matter how much you squish them down鈥攐r, at least, up to a certain maximum.
The researchers also wanted to make sure their padding could stand up to bumps and bruises in the real world. They used a 3D printer to create blocks the size of a small brick out of a springy material called thermoplastic polyurethane. Then they squeezed them with an impact-testing machine.
The group discovered that its blocks could absorb roughly six times more energy than standard foams made out of the same material, and up to 25% more than other honeycomb designs. MacCurdy and his colleagues are currently working to improve on their structures听even further. He added that engineers can make these kinds of designs out of many different types of materials, from bouncy plastics to harder substances like aluminum.
The world, in other words, could soon be a much softer place.