Abstract
To analyze the effect of nano-solid particles on the mechanical properties of shear thickening fluid (STF) and its Kevlar composite fabric. In this study, nano-silica and polyethylene glycol (PEG 200) were used as dispersed and continuous phases. Nano-graphite and nano-diamond particles were used as additives to prepare STF and Kevlar composite fabric. Study the friction characteristics and rheological characteristics of STF at different temperatures. Explore the STF’s mechanical response under transient high-speed impact conditions through the split Hopkinson pressure bar experiment. The mechanical properties of STF-Kevlar fabric are studied through yarn pull-out test and burst experiments. The experimental results show that the intermolecular repulsive force of STF is enhanced under a high-temperature environment, and shear thickening effect is reduced. Nano-diamond particles strengthen the contact coupling force and contact probability between the particle clusters, so that the maximum viscosity of the system reaches 1679 Pa s, the thickening ratio reaches 318 times, and the rheological properties of the shear thickening fluid are improved. The results of the SHPB experiment show that the STF can complete a dynamic response within a 50–75 µs time range, and the maximum stress can reach 78 MPa. The bullet’s incident kinetic energy is not only transformed into thermal energy and phase change energy of solid-liquid conversion, but also into frictional energy between particles. The mechanical experiments of STF-Kevlar composite fabrics show that the tensile force value of STF5-Kevlar is the largest (10.3 N/13.5 N), and the tensile force of neat Kevlar was the smallest (4.3 N/4.9 N). The maximum bearing capacity (0.3 kN) and absorption energy (51.8 J) of Neat Kevlar are less than those of STF1-Kevlar (3.2 kN, 116.7 J) and STF3-Kevlar (1.9 kN, 88.2 J), and STF5-Kevlar (4.7 kN, 143.3 J). Fabric’s failure mode is converted from partial yarn extraction to overall deformation and rupture of the fabric. Therefore, by changing the solid additives’ parameters, the STF and the composite fabric’s mechanical properties can be effectively controlled, which provides a reference for preparing the STF and fabric composite materials.
Highlights
There are two common types of shear stiffening intelligent materials, shear thickening fluid (STF) systems and shear stiffening gel (SSG) systems
The results show that compared with pure STF, the initial viscosity, and shear thickening viscosity of STF with SiC nanowire particles increased by nearly 30%
It can be found that the maximum viscosity of STF-5 with 3% nano-diamond at 20°C reaches 1679 Pa s, and the maximum viscosity of STF-3 with 3% nano-graphite reaches 801 Pa s at 20°C
Summary
There are two common types of shear stiffening intelligent materials, shear thickening fluid (STF) systems and shear stiffening gel (SSG) systems. Shear thickening fluid causes pipeline blockage, turbine blade damage, and uneven surface coating.[4] With the continuous deepening of research, people realized that the phenomenon of shear thickening could positively affect the industrial field. As the most widely used shear thickening fluid fabric composite material, the specific mechanism of its impact resistance is still controversial. It is mainly divided into two viewpoints: shear thickening effect and friction enhancement between yarns. Researchers such as Majumdar[31,32] believe that the failure mode of STF fabric composites is directly related to the friction between the fabric yarns. The single-dispersed STF composite fabric can absorb stronger impact energy than the double-dispersed STF composite fabric, so the shear thickening phenomenon plays a dominant role in the energy absorption field of the composite fabric
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