Printable elastic conductors promise large-area stretchable sensor/actuator networks for healthcare, wearables and robotics, among other areas. Force pressure sensors are one of their most attractive applications, although their large-area integration has been limited by difficulties in their processability or bendability, and their use by their insufficient sensitivity or stability. In this work, we present a flexible screen-printed capacitive pressure sensor, able to be modularly integrated in large-area systems thanks to the substrate flexibility, bending within itself and not only at its intersections, and cuttability, allowing a range of modifications in size and shape for complex structures. We built the sensors with a micro-structured dielectric, whose hill radii were tuned (between 125 and 375 µm) until obtaining a measurement range of five orders of magnitude, with a logarithm sensitivity above 20%/dB at the maximum pressure peak of 750 kPa and of 80%/kPa at the lowest test value of 0.5 kPa. These results went along completely with the theoretical model that we also developed. Besides, while smaller pillars showed a significant hysteresis for decreasing pressures, we observed how large hills performed with a small hysteresis of down to 3%, way ahead of the published sensors to the best of our knowledge.
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Printable elastic conductors promise large-area stretchable sensor/actuator networks for healthcare, wearables and robotics, among other areas. Force pressure sensors are one of their most attractive applications, although their large-area integration has been limited by difficulties in their processability or bendability, and their use by their insufficient sensitivity or stability. In this work, we present a flexible screen-printed capacitive pressure sensor, able to be modularly integrated in...
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