Piezo: Tough Plastic With a Sensitive Side : Technology: A high-tech super-polymer is tough, clear, able to withstand harsh environments--and it can sing. Scientists believe it may one day harness the ocean’s vast power.
“It’s tougher than weather, clear as crystal, flexible as paper and can even transform baby breaths or speeding stardust into tiny electrical signals that you can keep an eye on.” That’s what engineer Victor Chatigny of Penwalt Corp. in Valley Forge, Pa., might say if he made a television ad for a seemingly does-it-all plastic that his company sells as Kynar Piezo Film.
Penwalt designs the high-tech super-polymer into components that industrial buyers use to make singing balloons, paper-thin microphones and television screens, particle sensors on satellites, blood flow sensors, pressure sensors in underground nuclear test sites--even a so-called “smart” skin to damp vibrations on the proposed space station. Perhaps one day it will be used in platforms that convert the mechanical energy in ocean waves into electrical power.
Kynar, known generically as polyvinylidene difluoride, or PVDF, starts out as a higher version of plastic wrap or polyvinylidene dichloride. Because the sun’s ultraviolet radiation, which degrades most polymers, passes harmlessly through PVDF, the material makes for a lasting protective plastic.
In the late 1960s, a Japanese scientist figured out how to process the tough PVDF into a far more versatile form that has the curious ability to respond to physical deformations by generating electrical signals, a phenomenon called piezoelectricity.
It was not until the last few years, however, that the cost of making the material dropped enough--and researchers became expert enough with it--to make feasible the menagerie of devices and applications now on the market or under development. “Now it’s really beginning to take off,” Chatigny said.
Most of the world’s supply of piezoelectric PVDF comes from Penwalt, but other chemical companies, including Solvay of Belgium and Kureha of Japan, also make it.
Exposed metal parts of the famous Liberty Place skyscraper in Philadelphia and some buildings in Houston are coated with PVDF. The Whitford Corp. in Frazer, Pa., sells PVDF-based coatings for lining chemical vats and tanks. The “unleaded gasoline only” stickers by your car’s gas tank are made of it.
The great appeal of the piezoelectric material lies, however, in its versatility. A few processing steps turn the protective form of PVDF into a material suitable for a variety of applications, even in the unwelcoming environments of outer space and underground bomb-testing wells.
Getting the polymer into its piezoelectric form takes some doing. First you must take some PVDF resin and stretch it after it pushes through a sheet-shaping extruder. This causes otherwise randomly arranged carbon chains in the sheet to align like a stack of zigzagging pipes. Next, press electrodes against each face of the film and place the metal-PDVF-metal sandwich in a strong electric field. This step causes pairs of alternately arranged fluorine and hydrogen atoms to swivel to opposite sides of the polymer’s backbone.
The result: a form of PVDF that displays the intriguing property of piezoelectricity (from the Greek word piezein, meaning to press).
Piezoelectric PVDF works like an electric sponge. Push down on a saturated kitchen sponge and water comes out. Push a little or a lot, fast or slow, and different amounts of water come out at different rates. Release the pressure on the sponge and it draws water back in.
With the polymer, electric current is what moves in and out. And because electricity can easily be shunted through wires and then to nearby or remote circuitry, the new plastic forms the heart of increasingly more sensors, switches and other devices.
Scientists around the world use the piezopolymer for a huge and growing list of applications, ranging from robotic tactile sensors to sleep apnea monitors. The U.S. Olympic karate team uses piezoelectric sensors to measure the force of team members’ kicks and punches. Some football coaches use similar sensors on blocking dummies to measure the force of their linemen’s hits. Some high-speed impact printers have a strip of the film behind the target area to monitor whether an impact has occurred. For security, entire rooms and vaults have been lined with the film to detect penetration of the enclosure.
The film can also serve as a microphone. Talking into a postage-stamp-sized piece of the polymer creates a sequence of electrical signals clear enough for recording on tape or sending through an amplifier and speaker. “You can cut a ribbon of it a quarter of an inch wide, place it down the length of a hallway and listen to all the conversations along the way,” Chatigny said.
“We are making sheets of piezofilm that will cover entire structures and be able to detect the presence or absence of flaws,” Chatigny said.
One specific application might be for the increasingly important job of inspecting the structural integrity of the nation’s aging jet fleet. By “wall-papering” a plane with such a film and using it to monitor ultrasonic pulses sent through the plane’s “skin,” inspectors could detect flaws without having to remove and reassemble large sections of the craft.
The pulses’ echoes generally come from the signals bouncing off the back surface of a plane’s skin. Cracks or peeling in the skin cause the echoes to return sooner than they would from flawless skin. Moreover, because jolting the piezoplastic with electric pulses of differing frequencies drives it like a speaker, the same film can serve as both sender and receiver of sound and ultrasound.
Engineers George W. Taylor and Joseph R. Burns, co-founders of Ocean Power Technologies Inc., in Princeton, N.J., envision power-generating applications of piezoelectric polymers.
“The combination of the virtually unlimited amounts of mechanical energy available in ocean waves with piezoelectric polymers offers the possibility of the large-scale direct conversion of ocean wave power into electricity,” they suggest. They hold several patents for a new power-generating technology called hydropiezoelectricity, which in the most promising designs would use tons of piezoelectric polymer to convert some of the ocean’s vast and powerful motions into electrical power.
They envision building ocean-based platforms that hold piezoelectric plastic slabs, which ocean waves would indefatigably deform to produce a continuous current of electricity. Laboratory tests indicate that each pound of the material could generate more than two watts of electricity; a 1-megawatt facility would require about 220 tons of the material.
Although piezoelectric materials respond electrically to mechanical pressures, they also respond mechanically to electrical pressures. Apply a voltage across the film and the film gets longer or shorter. Send a pattern of changing voltages across a piece of film and you get a speaker. Store a song electronically on a chip, connect the chip to a piece of piezoelectric film glued inside a helium-filled balloon and you get a floating globe that appears to produce music of its own accord.
By gluing together two 1 1/2-inch-long strips of the film so that their respective fluorine and hydrogen atoms point in opposite directions, engineers have made what might be thought of as plastic muscles. Putting a voltage across the glued strips makes the short assembly curl in on itself.
Strahl Technologies Inc., in Vancouver, Canada, offers giant color-television-like screens made with millions of fiber-optic elements, each with its own individually controllable piezoelectric flap serving as a shutter. The Houston Astrodome will get two of these high-resolution systems next year, said Strahl President J. Rodney Gage.
An extremely sensitive version of the film has made an extraterrestrial appearance on a Soviet satellite. Vega II, a spacecraft with instruments and detectors from several nations, carried a square foot of 1-millimeter-thick piezoelectric film to count high-speed dust particles as it approached the tail of Halley’s comet in 1986. According to University of Chicago scientists who analyzed the resulting data, the dust detector at times sensed thousands of particles per second, some with a mass of one-tenth of a trillionth of a gram and some traveling at roughly 170,000 m.p.h.
Highlighting the huge range in mechanical stresses the film can detect, researchers at the federally funded Sandia National Laboratories in Albuquerque, N.M., use a piezofilm-based sensor, designed by a French scientist, for monitoring seismic and pressure waves generated during underground nuclear tests and other explosions.
The sensors can measure pressures equivalent to what 400,000 stacked Earth atmospheres would produce, according to Sandia research scientist Robert A. Graham. He said other piezoelectric materials, like quartz, cannot measure pressures that high and are far less versatile than the tough flexible film. “It’s clearly revolutionary,” Graham said.
Taylor and Burns of Ocean Power Technologies and other researchers are investigating polymers related to PVDF in a search for piezoelectric polymers even better suited for applications such as ocean power. By adding a couple of fluorine atoms to the molecular units of polymers and controlling the shapes of the polymer molecules, scientists could create materials that pack yet bigger punches, Taylor suggested. He said these would make hydropiezoelectric power even more promising for tapping ocean energy.
And beyond the world’s oceans, some researchers envision the more sensitive piezopolymers one day tracking even gentler baby breaths and finer stardust than those monitored today.
ELECTRICITY FROM THE OCEAN
Engineers George W. Taylor and Joseph R. Burns of Princeton, N.J., plan to use piezoelectric polymers to harness the ocean. The engineers suggest anchoring platforms of multi-ton slabs of piezoelectric plastic to the ocean floor. Waves would strike the slabs, producing a continuous current of electricity. Each pound of the polymer could generate more than two watts.
