Bio-Inspired Polyethylene-based Composite reinforced by Thermoplastic Polyurethane (TPU) Fiber for Aerogel Production Solmaz Karamikamkar, Sasan Rezaie, Hani E. Naguib, Chul B. Park*(reference author) Mechanical and Industrial Engineering department, University of Toronto Presenting author’s email:
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[email protected] Abstract. A nanocomposite strategy for the selective inclusion of viscoelastic silica modified polyethylene (SiPE) into thermoplastic polyurethane (TPU) fiber junctions is demonstrated to create effective stress-transfer pathways within three-dimensional (3-D) fiber-reinforced modified polyethylene-based composites with a phenomenal thermal insulation properties. Inspired by the bone architecture in the human body, large amounts of hard segments and small amounts of soft segments, the 3-D interconnected Si-PE w/25% TPU composite achieves synergistic strengthening. The composite is prepared by a wet chemical synthesis approach, a sol–gel reaction, with operation procedure of functional polyethylene while incorporating TPU fiber phase. The solution containing polyethylene precursor initiates network formation throughout the liquid to form a 3-D network (the gel) through chain polymerization. The obtained functional polyethylene-based gel reinforced with TPU fibers is then left to be aged stimulated by time and temperature for structure completion. By the end of aging process, the solvent is extracted from the gels through supercritical drying technique. The remained obtained solid structure is the Si-PE w/TPU composite nanocellular foam called aerogel. The resulting Si-PE w/25% TPU composite aerogel exhibited fully structural deformations and compressive mechanical strength (17.68 MPa at a compressive strain of 90%) at one compression cycle while showing an extremely great thermal stability up to 500 °C. Owing to the combination of excellent mechanical strength and thermal stability properties, the Si-PE w/25% TPU composite can be used as thermal insulation material for strain sensors, showing very short response and load bearing with reliable sensitivity and extreme durability. Such bio-inspired architecture opens the door to fabricate new 3-D-multifunctional and mechanically durable nanocomposite for thermal insulation products and strong partially-flexible devices. Keywords: Polyethylene, Thermoplastic Polyurethane, nanofiber, Thermal Insulation, Aerogel PACS: 62.20 mj Brittleness
INTRODUCTION Aerogels are ultralight porous solids made from a gel in which the liquid phase was replaced by air which was first produced by S. S. Kistler1 in the early 1930’s extracting the liquid phase from the gel at a very high temperature under applied pressure. They stand out by their very unusual properties such as a very low density, high porosity, high specific area, low thermal conductivity, low index of refraction and low dielectric constant. Unlike foams, aerogels have extremely small pores, on the nanometer scale with complex interconnectivity and branched structure of a few nanometer. This makes them 2-5 times more effective insulators than foams. Current foams made with Polyurethane (PU) and Polystyrene (PS) often have thermal conductivity of 0.03W/m.K. However; aerogels emerge as a super-insulator material (thermal conductivity
