Litcius/Paper detail

Advancing Smart Textiles: Structural Evolution of Knitted Piezoresistive Strain Sensors for Enabling Precise Motion Capture

Mareen N. Warncke, Carola H. Böhmer, Carmen Sachse, Susanne Fischer, Eric Häntzsche, Andreas Nocke, Johannes Mersch, Chokri Cherif

2023Polymers12 citationsDOIOpen Access PDF

Abstract

Recently, there has been remarkable progress in the development of smart textiles, especially knitted strain sensors, to achieve reliable sensor signals. Stable and reliable electro-mechanical properties of sensors are essential for using textile-based sensors in medical applications. However, the challenges associated with significant hysteresis and low gauge factor (GF) values remain for using strain sensors for motion capture. To evaluate these issues, a comprehensive investigation of the cyclic electro-mechanical properties of weft-knitted strain sensors was conducted in the present study to develop a drift-free elastic strain sensor with a robust sensor signal for motion capture for medical devices. Several variables are considered in the study, including the variation of the basic knit pattern, the incorporation of the electrically conductive yarn, and the size of the strain sensor. The effectiveness and feasibility of the developed knitted strain sensors are demonstrated through an experimental evaluation, by determining the gauge factor, its nonlinearity, hysteresis, and drift. The developed knitted piezoresistive strain sensors have a GF of 2.4, a calculated drift of 50%, 12.5% hysteresis, and 0.3% nonlinearity in parts.

Topics & Concepts

Piezoresistive effectGauge factorStrain gaugeHysteresisMaterials scienceStrain (injury)Smart materialElectrical conductorSIGNAL (programming language)TextileNonlinear systemAcousticsComposite materialComputer sciencePhysicsFabricationAlternative medicineQuantum mechanicsInternal medicinePathologyMedicineProgramming languageAdvanced Sensor and Energy Harvesting MaterialsTactile and Sensory InteractionsConducting polymers and applications