posted on 2021-03-08, 14:07authored byKyubin Bae, Jinho Jeong, Jongeun Choi, Soonjae Pyo, Jongbaeg Kim
Tactile
sensor arrays have attracted considerable attention for
their use in diverse applications, such as advanced robotics and interactive
human–machine interfaces. However, conventional tactile sensor
arrays suffer from electrical crosstalk caused by current leakages
between the tactile cells. The approaches that have been proposed
thus far to overcome this issue require complex rectifier circuits
or a serial fabrication process. This article reports a flexible tactile
sensor array fabricated through a batch process using a mesh. A carbon
nanotube–polydimethylsiloxane composite is used to form an
array of sensing cells in the mesh through a simple “dip-coating”
process and is cured into a concave shape. The contact area between
the electrode and the composite changes significantly under pressure,
resulting in an excellent sensitivity (5.61 kPa–1) over a wide range of pressure up to 600 kPa. The mesh separates
the composite into the arranged sensing cells to prevent the electrical
connection between adjacent cells and simultaneously connects each
cell mechanically. Additionally, the sensor shows superior durability
compared with previously reported tactile sensors because the mesh
acts as a support beam. Furthermore, the tactile sensor array is successfully
utilized as a Braille reader via information processing based on machine
learning.