Drucella Andersen Headquarters, Washington, D.C. November 5, 1991 (Phone: 202/453-8613) Don Haley Ames-Dryden Flight Research Facility, Edwards, Calif. (Phone: 805/258-3456) RELEASE: 91-183 PRESSURE-SENSITIVE PAINT PASSES TEST WITH FLYING COLORS NASA has successfully tested a new method to measure surface pressure on airplanes during flight that could replace the sensing devices traditionally used to gather such data. Pressure measurements give engineers information on the strength of an aircraft's wings and tail, knowledge that lets them certify or improve the plane's design. The NASA tests used paint that becomes luminescent under ultraviolet light. The intensity of the light radiated by the paint results from the pressure it receives in flight. Researchers use videotapes or photographs taken in ultraviolet light to study the pressure patterns. Data from the research flights on an F-l04 aircraft at NASA's Ames-Dryden Flight Research Facility, Edwards, Calif., shows that "surface pressure measurements from the luminescent paint are comparable to those collected the conventional way," said Dr. Blair McLachlan, Project Scientist at NASA's Ames Research Center, Mountain View, Calif. More laboratory work to improve the paint's characteristics will be done before the next series of flights. Aerospace experts hail the pressure-sensitive paint as revolutionary because it could lead to large areas of a test aircraft being studied at once. The light pink paint is quick and easy to apply and the entire test surface can be "mapped." An aircraft does not have to be modified with wires and tubing needed for a conventional data collection system, although video or photo cameras and ultraviolet light systems are required. - more - - 2 - Surface pressure is normally measured with sensors and small openings that are part of a data collection system on the aircraft. But this method produces data only from single, fixed points and the systems are expensive and time-consuming to install. To measure large areas such as an entire wing, hundreds of sensors are needed and the pressure readings still do not represent 100 percent of the test surface. The luminescent paint test is based on a concept called oxygen quenching. The paint "senses" the amount of oxygen on the surface and responds by varying the light it emits. As surface pressure increases, the oxygen concentration also rises and the light emitted by the luminescent molecules decreases. The resulting light pattern can be photographed and processed to produce a map of pressures across the test surface. The NASA F-104 carried the paint experiment in a belly-mounted flight test pylon where a video system recorded the pressure variations. The paint was tested on three flights in a varied flight environment in which the plane reached nearly 1,200 mph (1.6 times the speed of sound) and 30,000 feet. The luminescent paint development is a cooperative research program between the chemistry department at the University of Washington and the Fluid Mechanics Laboratory at Ames Research Center. The effort began in 1987, followed by wind tunnel tests at Ames in 1989. Ames Research Center manages the project. Lisa Bjarke is the Project Flight Test Engineer at Ames-Dryden. - end - Note To Editors: A photograph of computerized results from a luminescent paint test flight is available by calling 202/453-8375. Color: 91-HC-711 B&W: 91-H-810