Abstract
Meta-aramid fibrids (MAF) have attracted much attention. However, it is difficult for this high mechanical performance fiber to form sufficient interface adhesion between the MAF and polyurethane (PU) matrix due to the chemical inertness of its surface. Thus, the surface activity of MAF should be improved to obtain a high-performance MAF/PU composite. A novel methodology to modify the surface of MAF with a sodium dichloroisocyanurate solution (DCCNa) was developed to obtain chlorinated MAF (MAFC) in this study. A series of MAFC/PU composites was prepared by in situ polymerization processes. The results of Fourier-transform infrared spectroscopy (FTIR) and X-ray photoelectron spectroscopy (XPS) demonstrated that the chlorine-contained chemical groups were introduced onto the MAF surfaces after chlorination. Dynamic contact angle analysis (DCAA) revealed that the surface wettability and the surface free energy of the MAFC were significantly improved, which allowed for strong chemical bonding to PU. Scanning electron microscopy (SEM) showed a uniform distribution of MAFC and good interfacing bonding between the MAFC and PU. With the incorporation of 1.5 wt% MAFC into the polyurethane matrix, the tensile and tear strength values of MAFC/PU were 36.4 MPa and 80.1 kN·m−1 respectively, corresponding to improvements of approximately 43.3% and 21.1%, as compared to those of virgin PU as 25.4 MPa and 66.1 kN·m−1, respectively.
Highlights
It has been reported that polytetramethylene ether glycol/toluene diisocyanate (PTMEG/TDI)-based polyurethane (PU) elastomer is a block copolymer composed of alternating soft and hard segment phase, wherein the hard segment phase is composed of toluene diisocyanate (TDI) and a chain extender, and the soft segment phase is composed of polytetramethylene ether glycol (PTMEG) [1]
PTMEG/TDI-based PU elastomer cannot be used in high-load applications due to the insufficient mechanical strength of the PTMG2000/TDI polyurethane elastomer, here PTMEG2000 refers to the PTMEG with the average molecular weight of 2000
It can be concluded that a novel chlorination treatment of meta-aramid fibrids (MAF) was investigated in this study
Summary
It has been reported that polytetramethylene ether glycol/toluene diisocyanate (PTMEG/TDI)-based polyurethane (PU) elastomer is a block copolymer composed of alternating soft and hard segment phase, wherein the hard segment phase is composed of toluene diisocyanate (TDI) and a chain extender, and the soft segment phase is composed of polytetramethylene ether glycol (PTMEG) [1]. PTMEG/TDI-based PU elastomer cannot be used in high-load applications due to the insufficient mechanical strength of the PTMG2000/TDI polyurethane elastomer, here PTMEG2000 refers to the PTMEG with the average molecular weight of 2000. The mechanical properties of PTMEG/TDI-based PU elastomers should be improved. MAF possesses the inherent properties of meta-aramid fibers, such as higher strength, higher modulation, and excellent thermal and chemical stabilities. MAF possesses many excellent properties, due to the surface chemical inertness and the steric effect of the benzene rings in the molecular chains, the amide groups of MAF do not react readily with other atoms or groups, which results in poor interface adhesion between the MAF and polyurethane matrix [15,16]. The mechanical properties of the MAF/PU and MAFC/PU composites were characterized using tensile testing
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