Designing formulation variables of extrusion-based manufacturing of carbon black conductive polymer composites for piezoresistive sensing

Lingyan Duan, Martin Spörk, Tom Wieme, Pieter Cornillie, Hesheng Xia, Jie Zhang, Ludwig Cardon, Dagmar R. D'hooge

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26 Citations (Scopus)

Abstract

Highly sensitive conductive polymer composites for piezoresistive sensing are developed by a design of the formulation variables of extrusion-based manufacturing (filler type/amount, polymer amount) and annealing (a), considering thermoplastic polyurethane (TPU) and/or olefin block copolymer (OBC) as polymer matrix and carbon black (CB) as conductive filler. With ternary composites - based on a CB type with stronger filler-matrix interactions and an appropriate OBC/TPU blend mass ratio (40/60 with CB amount of 5–10 m%; 50/50 with CB amount of 10 m%), the challenging region of both high sensitivity and static strain (maximal gauge factors (GFmax) > 50 and εmax > 100%) can be realized: GFmax >104 and εmax=20–240%. OBC binary composites with a high CB2 amount (e.g. 15 m%) are however needed for ultrahigh static strains (εmax > 600%). Welldesigned ternary composites (e.g. OBC40-CB/TPU60-7-a and OBC30-CB/TPU70-7-a) possess a large dynamic resistance change, negligible hysteresis and high stability and display strain sensor application potential. Highly CB2 loaded binary (≥12 m%) and ternary composites (10 m%) exhibit a more obvious strain-dependent dynamic hysteretic behavior, as they switch from a dual peak to single peak pattern toward the sensing strain limit, which is interesting for self-diagnose.
Original languageEnglish
Pages (from-to)78-85
Number of pages8
JournalComposites science and technology
Volume171.2019
Issue number8 February
DOIs
Publication statusPublished - 13 Dec 2018

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