二氧化硅颗粒增强聚合物复合材料的力学和热特性

Hassan K. Langat, J. K. Keraita, F. Mwema, E. T. Akinlabi
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摘要

聚合物基复合材料由于其高强度重量比和其他吸引人的特性,目前被应用于汽车、航空航天、生物医学和民用等多个领域。在目前的研究中,二氧化硅颗粒被评估为三种聚合物的增强剂,即高冲击聚苯乙烯(HIPS),通用聚苯乙烯(GPPS)和再生低密度聚乙烯(rLDPE)。通过改变二氧化硅颗粒相对于聚合物基体的重量来制备复合材料,然后分别使用万能拉伸试验机、Charpy冲击试验机和差示扫描量热仪(DSC)评估复合材料的拉伸、冲击和热性能。力学结果表明,随着二氧化硅含量的增加,HIPS- silica复合材料的抗拉强度从纯HIPS的13.6 MPa增加到5%二氧化硅时的13.9 MPa和31%二氧化硅时的14.8 GPa。GPPS-Silica的抗拉强度从纯的16.2 MPa略微增加到5%二氧化硅时的33.8 MPa, 31%时降低到21.5 MPa。rldpe -二氧化硅复合材料的抗拉强度从再生HDPE的10.4 MPa降低到含5%二氧化硅的10.2 MPa,在含31%二氧化硅的情况下提高到11.7 MPa。所有样品的弹性模量随二氧化硅含量的增加而增加。冲击强度从纯PS - GPPS的5.6 kJ/m2增加到5%二氧化硅的8.1 kJ/m2。当硅含量为31%时,PS-PPS的冲击强度没有显著提高。对于HIPS复合材料,影响从纯HIPS的47 kJ/m2减少到5%二氧化硅的37 kJ/m2和31%二氧化硅的11 kJ/m2。将复合材料在31%二氧化硅下的热结果与纯聚合物进行了比较。在热力学性能方面,通用聚苯乙烯具有最高的吸热能力和抗拉强度。弹性模量在通用聚苯乙烯复合材料中也有最高的报道。结果表明,在聚合物中加入二氧化硅后,玻璃化转变温度略有变化,吸热性能有所提高。研究结果表明,天然硅(硅藻土)基复合材料可作为绿色建筑材料。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Mechanical and Thermal Characterization of Silica Particle-Reinforced Polymer Composites
Polymer based composites are currently used in several fields including automobile, aerospace, biomedical, and domestic applications due to their high strength-to-weight ratio and other attractive properties. In the current study, silica particles are evaluated as reinforcement for three polymers namely, high impact polystyrene (HIPS), general purpose polystyrene (GPPS) and recycled low density polyethylene (rLDPE. The composites were prepared by varying the weight of silica particles in relation to the polymer matrix and then tensile, impact and thermal properties were evaluated using universal tensile testing machine, Charpy impact and differential scanning calorimeter (DSC) respectively. The mechanical results showed that for HIPS-Silica composite, the tensile strength increased with increased silica content from 13.6 MPa for pure HIPS to 13.9 MPa at 5% silica and 14.8 GPa at 31% Silica. GPPS-Silica showed slight increase in tensile strength from 16.2 MPa for pure to 33.8 MPa at 5% silica and reduced to 21.5 MPa at 31%. The rLDPE-silica composite showed reduced tensile strength from 10.4 MPa for recycled HDPE to 10.2 MPa at 5% silica and an increase at 31% silica to 11.7 MPa. The modulus of elasticity for all the samples increased with the increasing silica content. The impact strength was found to increase from 5.6 kJ/m2 for pure PS - GPPS to 8.1 kJ/m2 at 5% silica. There was no remarkable increase in impact strength at 31% silica for PS-PPS. For HIPS composite, the impact reduced from 47 kJ/m2 for pure HIPS to 37 kJ/m2 at 5% silica and 11 kJ/m2 at 31% silica. Thermal results of the composites at 31% silica were compared with pure respective polymers. In terms of thermal and mechanical properties, the general-purpose polystyrene had the highest heat absorption capacity and tensile strength. The modulus of elasticity was also reported highest in the general-purpose polystyrene composite. The results showed slight change in glass transition temperature and an increased heat absorption property when silica was added to respective polymers. Based on the results, natural silica (diatomite)-based composites may be used as green construction materials.
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