Liquid Body Armor

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Rheologists Apply Shear-Thickening Fluids to Protective Gear • August 1, 2006 (originally posted by DBIS - American Institute of Physics) • Rheologists have created a new way of bullet-proofing clothes using shear-thickening fluids. Fabric treated with shear-thickening granular suspensions can turn soft material into solid protective gear when struck by a projectile. The treatment can strengthen Kevlar to produce lighter, more comfortable bullet-proof vests, or it can be used to turn extend the bullet-proof protection to ordinary fabric. • NEWARK, Del. -- Hard, heavy, stiff and bulky is how most cops describe their bullet-proof vests, but relief could be in sight. One coat of this gooey liquid turns soft fabric into a tough, stab-proof, bullet-proof material. • It's not just in the movies. Our men and women in blue put their lives on the line every day, and this may be their next weapon against crime. It's no normal, flimsy piece of fabric after it's soaked in shear-thickening fluid, which turns soft material into solid protective gear. • The material becomes very hard and prevents the projectile from moving through the fabric, Norman Wagner, a rheologist at the University of Delaware in Newark, tells DBIS. • Rheologists, who study the unusual flow of materials, developed the liquid. Now, it's being tested on Kevlar to make bullet-proof vests as comfortable as regular clothing. • A normal vest is 30, 40 layers of Kevlar fabric tightly packed together, Wagner says. We can potentially reduce the number of layers, making the material lighter, more flexible, better -- easier to wear. • To prove the liquid's toughness, an ice pick goes right through untreated fabric, but it's stopped by fabric coated with the new liquid. Tiny, hard particles in the liquid cluster together and jam when struck by a sudden force. Fabric coated in the liquid becomes hard enough to stop a bullet, while remaining flexible. • Wagner says, We want to improve current body armor technology and make it resistant to many different threats -- not just ballistic, but also fragmentations such as bombs. • The military plans to use the liquid technology to improve Kevlar vests for troops, a must-have body armor that saves lives. Researchers will also test the liquid technology in fabric for pants and sleeves, areas that aren't covered by a traditional Kevlar vest. • SCIENCE INSIDER • BACKGROUND: Engineers have designed a way to make police officers and soldiers safer with better body armor. The secret is a new shear-thickening fluid. When fabric has been saturated in this new fluid, it becomes strong enough to stop a bullet, but strong enough to wear comfortably. • HOW IT WORKS: When a bullet strikes the fabric, it immediately becomes rigid and keeps the object from penetrating. Once the assault has stopped, the fabric returns to being flexible and lightweight. Material that has been soaked in the new fluid is slightly oily to the touch but otherwise feels and drapes like normal fabric. • ABOUT SMART MATERIALS: The shear-thickening fluid is an example of a smart material. Smart materials are a class of materials that can sense and respond to changes in the environment, either through the application of electricity or magnetism, or to changes in temperature. In the case of the new body armor, the material responds to a change in pressure. Under normal conditions, the fluid's molecules are weakly bonded and can move around with ease; that's why the material is so flexible. But the shock of an impact causes those chemical bonds to strengthen so the molecules lock into place; once the force from the impact dissipates, the bonds weaken again. That's why the fabric becomes rigid instantly when a bullet strikes, preventing that bullet from penetrating, and reverts to its more flexible state once that force has ceased. • WHAT IS ELASTICITY? Different materials can withstand different amounts of deformation, a property known as elasticity. Most materials are elastic to some degree: when they are deformed or bent by an infusion of incoming energy, they will bounce back to their original shape. But elastic materials all have their limits. Metal springs and rubber bands are very elastic. Plaster and glass are not very elastic; instead, they are brittle and snap with even a small deformation. Energy, like momentum, is conserved, but in a collision, it can turn into different forms of energy, such as heat or noise. How much of the energy is converted depends in part on both the relative toughness and elasticity of the materials involved in the impact. There is no such thing as a perfectly elastic collision, but if there were, all of the energy would be transferred to the target with nothing lost to heat or noise, for example. • Norman Wagner • Chemical Engineer • University of Delaware • Tel: 302-831-8079 • [email protected] • Materials Research Society • Warrendale, PA 15086-7573 • http://www.mrs.org

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