Abstract
This work presents a cost-effective shadow mask printing approach to fabricate flexible sensors. The liquid-state sensing material can be directly brushed on a flexible substrate through a shadow mask. The ink leakage issue which often occurs in printed electronics is addressed with a custom taping scheme. A simple thermal compression bonding approach is also proposed to package the functional area of the sensor. To verify the feasibility and robustness of the proposed fabrication approach, a prototyped strain gauge displacement sensor is fabricated using carbon ink as the sensing material and a flexible polyimide (PI) film as the substrate. Once the substrate is deformed, cracks in the solidified ink layer can cause an increased resistance in the conductive path, thus achieving function of stable displacement/strain sensing. As a demonstration for displacement sensing application, this sensor is evaluated by studying its real-time resistance response under both static and dynamic mechanical loading. The fabricated sensor shows a comparable performance (with a gauge factor of ~17.6) to those fabricated using costly lithography or inkjet printing schemes, while with a significantly lower production cost.
Highlights
Strain gauge is a device that can convert an applied force to changes in resistance, capacitance, or piezoelectricity [1,2,3]
The inkjet printing approach is capable of directly depositing functional sensing materials onto the substrate to form a variety of patterns, for example, a cantilever-type micro-electro-mechanical systems (MEMS) deflection sensor [18] and textile electronics [19]
Thematerial, sensing material, for example, the ink used this in work, is applied on the of the shadow mask and isissolidified carbon inkinused this work, is applied on top the top of the shadow mask and solidifiedon onthe the flexible flexible substrate after the drying process
Summary
Strain gauge is a device that can convert an applied force to changes in resistance, capacitance, or piezoelectricity [1,2,3]. The inkjet printing approach is capable of directly depositing functional sensing materials (in ink form) onto the substrate to form a variety of patterns, for example, a cantilever-type micro-electro-mechanical systems (MEMS) deflection sensor [18] and textile electronics [19]. This fabrication approach requires a dedicated inkjet printing machine. Thematerial, sensing material, for example, the ink used this in work, is applied on the of the shadow mask and isissolidified carbon inkinused this work, is applied on top the top of the shadow mask and solidifiedon onthe the flexible flexible substrate after the drying process
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