Thermoplastic elastomer composite strips with damage detection capabilities for self-healing elastomers

Antonia Georgopoulou, Henry Korhonen, Anton W. Bosman, Frank Clemens
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Abstract

Self-healing materials can increase the lifetime of products and improve their sustainability. However, the detection of damage in an early stage is essential to avoid damage progression and ensure a successful self-healing process. In this study, self-healing sensor composite strips were developed with the embedding of a thermoplastic styrene-based co-polymer (TPS) sensor in a self-healing matrix. Piezoresistive TPS sensor fibers composites (SFCs) and 3D printed sensor element composites (SECs) were fabricated and embedded in a self-healing matrix by lamination process to detect damage. In both cases, the value of the initial resistance was used to detect the presence of damage and monitor the efficiency of healing. A higher elongation at fracture could be achieved with the extruded sensor fibers. However, for the composite strips the SECs could achieve a higher elongation at fracture. Mechano-electrical analysis revealed that the strips maintained a monotonic, reproducible response after the healing of the matrix. The SFCs had significantly lower drift of the sensor signal during cyclic mechanical analysis. Nevertheless, on a tendon-based soft robotic actuator, the SECs obtained a drift below 1%. This was explained by the lower deformation (e.g.) strain in comparison to the tensile test experiments.

具有自修复弹性体损伤检测能力的热塑性弹性体复合条
自愈材料可以增加产品的使用寿命,提高产品的可持续性。然而,在早期阶段检测损伤对于避免损伤进展和确保成功的自我修复过程至关重要。在本研究中,将热塑性苯乙烯基共聚物(TPS)传感器嵌入自修复基质中,开发了自修复传感器复合条。制备了压阻式TPS传感器纤维复合材料(sfc)和3D打印传感器元件复合材料(SECs),并通过层压工艺将其嵌入自修复基质中以检测损伤。在这两种情况下,初始电阻的值被用来检测损伤的存在和监测愈合的效率。挤压后的传感器纤维具有较高的断裂伸长率。然而,对于复合带材来说,SECs可以获得更高的断裂伸长率。机电分析表明,在基质愈合后,条带保持单调,可重复的响应。在循环力学分析中,sfc具有明显较低的传感器信号漂移。然而,在基于肌腱的软机器人驱动器上,sec获得了低于1%的漂移。这是由于与拉伸试验相比,变形(例如)应变较低。
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