A.Rahman
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Liquid Armor
Flexible full-body protection that could save our troops' lives and limbs is at the top of the list for many researchers and technology companies. One such product could soon make its way to Iraq. As this ScienCentral News video explains, the secret ingredient is a liquid that could turn lightweight material into full-body armor.
Full Liquid Jacket
The current war in Iraq is leaving behind a legacy of wounded soldiers. For every fatality there have been between seven or eight injured -- a number amounting to 18,356 as of June 11, 2006 (U.S. Department of Defense). That's a higher ratio of injured to dead than in any previous American war, a mixed blessing that can largely be attributed to advances in body armor and improved battlefield medical treatment.
A new "liquid armor" could be the solution for protecting the parts of the body that aren't currently covered by standard-issue ballistic vests ââ¬â arms and legs, where many of these devastating and life-threatening injuries occur. Co-developed by two research teams ââ¬â one led by Norman Wagner at the University of Delaware, and the other led by Eric Wetzel at the U.S. Army Research Lab in Aberdeen, MD ââ¬â the liquid technology will soon lead to light, flexible full-body armor.
The liquid - called shear thickening fluid is actually a mixture of hard nanoparticles and nonevaporating liquid. It flows normally under low-energy conditions, but when agitated or hit with an impact it stiffens and behaves like a solid. This temporary stiffening occurs less than a millisecond after impact, and is caused by the nanoparticles forming tiny clusters inside the fluid. "The particles jam up forming a log jam structure that prevents things from penetrating through them," Wagner explains.
Wagner and Wetzel developed a way to specially treat ballistic fabrics, such as Kevlar, with the liquid, making them dramatically more resistant to puncture and much better at reducing blunt trauma.
"We integrate those materials with the fabric itself, imbibe it in a way, such that the shear thickening fluid is not at all evident, it's not a coating on the outside. It's actually intercalated directly into the material," says Wagner.
The stiffening of the liquid allows the energy of an impact to be distributed over a much larger surface area ââ¬â so the force, rather than being focused on the area of a bullet head, is distributed over the area of the surrounding fabric. Ballistic tests have demonstrated that the treatment can actually prevent bullets from penetrating.
The treated Kevlar is even better at resisting puncture from sharp projectiles, such as knife stabs or shrapnel from roadside bombs. As Wagner explains, Kevlar was never designed to function against puncture.
Bullet proof vests and Kevlar are not very good against stab threats like puncture that you might see in correctional prison guards or from fragmentation threats on the battlefield," he says.
The treatment of the fabric prevents the fibers from spreading apart or "windowing," which keeps sharp objects from entering. That means that not only would materials treated with shear thickening fluids be better against conventional threats such as bullets, but would also resist puncture from shrapnel. The materials would also remain light ââ¬â only 20 percent heavier after treatment - and flexible, which means they could be used for much-needed protection of the limbs.
"We can make thin layers of material for use on the arms and legs that remain flexible under normal motion, but become rigid and absorb energy when impacted by a ballistic threat or a knife," Wagner says.
U.S. manufacturer Armor Holdings recently licensed the technology and plans to release its first products by the end of the year.
Wagner says there could also be many civilian applications ââ¬â like protecting people during car crashes, or making tires sturdier.
Some of Wagner's recent work was published in the May/June 2005 issue of the Journal of Rheology and was featured in the May 2006 issue of Scientific American. For a complete list of publications see Dr. Wagner's website. Some of the funding sources included IFPRI and the Army Research Laboratory CMT program through the Center for Composite Materials of the University of Delaware as well as the NASA Delaware Space Grant College and Fellowship Program.
Flexible full-body protection that could save our troops' lives and limbs is at the top of the list for many researchers and technology companies. One such product could soon make its way to Iraq. As this ScienCentral News video explains, the secret ingredient is a liquid that could turn lightweight material into full-body armor.
Full Liquid Jacket
The current war in Iraq is leaving behind a legacy of wounded soldiers. For every fatality there have been between seven or eight injured -- a number amounting to 18,356 as of June 11, 2006 (U.S. Department of Defense). That's a higher ratio of injured to dead than in any previous American war, a mixed blessing that can largely be attributed to advances in body armor and improved battlefield medical treatment.
A new "liquid armor" could be the solution for protecting the parts of the body that aren't currently covered by standard-issue ballistic vests ââ¬â arms and legs, where many of these devastating and life-threatening injuries occur. Co-developed by two research teams ââ¬â one led by Norman Wagner at the University of Delaware, and the other led by Eric Wetzel at the U.S. Army Research Lab in Aberdeen, MD ââ¬â the liquid technology will soon lead to light, flexible full-body armor.
The liquid - called shear thickening fluid is actually a mixture of hard nanoparticles and nonevaporating liquid. It flows normally under low-energy conditions, but when agitated or hit with an impact it stiffens and behaves like a solid. This temporary stiffening occurs less than a millisecond after impact, and is caused by the nanoparticles forming tiny clusters inside the fluid. "The particles jam up forming a log jam structure that prevents things from penetrating through them," Wagner explains.
Wagner and Wetzel developed a way to specially treat ballistic fabrics, such as Kevlar, with the liquid, making them dramatically more resistant to puncture and much better at reducing blunt trauma.
"We integrate those materials with the fabric itself, imbibe it in a way, such that the shear thickening fluid is not at all evident, it's not a coating on the outside. It's actually intercalated directly into the material," says Wagner.
The stiffening of the liquid allows the energy of an impact to be distributed over a much larger surface area ââ¬â so the force, rather than being focused on the area of a bullet head, is distributed over the area of the surrounding fabric. Ballistic tests have demonstrated that the treatment can actually prevent bullets from penetrating.
The treated Kevlar is even better at resisting puncture from sharp projectiles, such as knife stabs or shrapnel from roadside bombs. As Wagner explains, Kevlar was never designed to function against puncture.
Bullet proof vests and Kevlar are not very good against stab threats like puncture that you might see in correctional prison guards or from fragmentation threats on the battlefield," he says.
The treatment of the fabric prevents the fibers from spreading apart or "windowing," which keeps sharp objects from entering. That means that not only would materials treated with shear thickening fluids be better against conventional threats such as bullets, but would also resist puncture from shrapnel. The materials would also remain light ââ¬â only 20 percent heavier after treatment - and flexible, which means they could be used for much-needed protection of the limbs.
"We can make thin layers of material for use on the arms and legs that remain flexible under normal motion, but become rigid and absorb energy when impacted by a ballistic threat or a knife," Wagner says.
U.S. manufacturer Armor Holdings recently licensed the technology and plans to release its first products by the end of the year.
Wagner says there could also be many civilian applications ââ¬â like protecting people during car crashes, or making tires sturdier.
Some of Wagner's recent work was published in the May/June 2005 issue of the Journal of Rheology and was featured in the May 2006 issue of Scientific American. For a complete list of publications see Dr. Wagner's website. Some of the funding sources included IFPRI and the Army Research Laboratory CMT program through the Center for Composite Materials of the University of Delaware as well as the NASA Delaware Space Grant College and Fellowship Program.
