Stepless control devices with flexible pressure sensors
Silicone is so soft and flexible that it is easily deformed by the pressure of a finger. Researchers at Fraunhofer have recently created sensors made from this flexible material, making it easier to steplessly control devices. At the Hannover Messe, they are presenting a glove that can measure pressure and a steering wheel that lets the driver control music, light and ventilation at the touch of a finger.
Multifunction steering wheels are standard in most automobiles today, and these days drivers can easily manipulate the cruise control and stereo without taking their hands of the wheel. However, the buttons are rather inflexible and the driver can often only switch something “on” and “off” or can only choose the “next” or “previous” song. “That is because they are made of rigid materials like hard plastic, metal or ceramics,” explains Dr. Holger Böse, technical and scientific manager of the Center Smart Materials (CeSMa) at the Fraunhofer Institute for Silicate Research ISC in Würzburg, Germany. In his work, Böse focuses on smart materials with mechanical features that can be controlled either electrically or magnetically.
These novel sensors invented at ISC can send out electrical impulses to control things. They have therefore been designed like an electrical capacitor — two electrode layers consisting of a conductive silicone above and below and one insulating film layer in between. However, if you press on the capacitor nothing happens at first. “The electrical capacitance — the electrical charge divided by the voltage applied — is the decisive factor. However, in a conventional capacitor structure the pressure effect is so small that it can barely be measured let alone be used for control purposes,”Böse explains. In order for the pressure to have an effect, the researchers applied additional layers of silicone on the film. Thus, for example, two more films press from above and below to put additional pressure on the film in the middle. The two films are not smooth but have a special pattern that was added by the researchers. Through their special capacitor design, the researchers were able to use a physical property of silicone, which so far has only been observed when stretching a silicone film coated with layers of electrodes — its geometry changes; the surface becomes larger and the silicone layer becomes thinner. The result is that the electrical capacitance increases. “We transferred it from tensile forces to compression forces,” explains Böse.
How the compression force acts strongly depends on how the pattern is applied to the film and how the electrodes are attached. The sensor’s electrical capacitance is different in each case. The researchers can use these differences and adapt the design of the sensors individually to different geometries and sensitivities. The scientists apply industrial intermediate silicone products or use their own formula. “Our chemical department can develop customized silicone for the sensors based on the customers’ needs. We can vary the chemical composition and technical shape of the sensors depending on the properties required,” says Böse.