Litcius/Paper detail

Three-Dimensional Braided Wearable Flexible Strain Sensors: Fabrication and Performance

Man Zhang, Ying Quan, Jinhui Xu, Yujing Zhang, Aiqin Zhang, Shuqiang Liu

2025ACS Applied Materials & Interfaces11 citationsDOI

Abstract

Flexible and stretchable strain sensors are highly desired in wearable electronics, with textile-based sensors standing out for their superior flexibility, comfort, and seamless integration into clothing. However, simultaneously achieving high sensitivity and wide operable strain ranges remains a critical challenge. This study presents a simple, scalable approach to fabricate three-dimensional (3-D) braided strain sensors with both high sensitivity and exceptional stretchability, with a representative performance of a 340 gauge factor at 280% strain and a peak sensitivity of 1152 at 180% strain. The sensors utilize polyurethane filaments (PUF) as an elastic matrix with carbon nanotubes (CNTs) and graphene nanoplatelets (GNPs) as conductive fillers. Fabrication involves a four-step 3-D braiding process, subsequently followed by hybrid dip-coating and spray deposition. Characterization results reveal that CNTs form long-range conductive pathways for electrical continuity and strain tolerance, while GNPs enhance sensitivity through rapid resistance changes caused by the interlayer sliding under strain. The asymmetric bilayer conductive network─comprising an inner GNP layer for fast resistance response and an outermost CNT layer for stable conduction─synergistically improves both properties. Additionally, the interlaced spatial architecture of 3-D braided fabrics significantly extends the detectable strain range. By adjustment of structural parameters such as braiding angle and yarn arrays, sensors with customizable geometries can be engineered. This work achieves a synergistic balance between stretchability and sensitivity through innovative structural design and process optimization, providing a promising solution for high-performance flexible strain sensors and the advancement of wearable health monitoring systems.

Topics & Concepts

Materials scienceGauge factorFabricationElectrical conductorSensitivity (control systems)Strain gaugeLayer (electronics)Wearable computerGrapheneCarbon nanotubeNanotechnologyComposite materialWearable technologyStrain (injury)YarnBilayerCharacterization (materials science)OptoelectronicsStructural health monitoringElectrical resistance and conductanceThermoplastic polyurethaneFlexible electronicsLinearityScalabilityProcess (computing)Advanced Sensor and Energy Harvesting MaterialsConducting polymers and applicationsCarbon Nanotubes in Composites