BN粒子改性PVDF电纺纤维膜插层增强碳纤维/环氧树脂复合材料层间韧性

针对纤维增强复合材料层压板的分层失效问题,本文提出了一种氮化硼(BN)粒子改性聚偏氟乙烯(PVDF)电纺纤维膜以插层方式增强碳纤维/环氧树脂(CF/EP)复合材料层间断裂韧性的方法。通过超声处理将BN均匀分散于PVDF溶液中,利用静电纺丝方法制备了BN改性PVDF纤维膜(BN&PVDF),作为插层材料被引入碳纤维的层间,采用手工铺设-真空热压法制备BN&PVDF增强CF/EP复合材料层压板(BN&PVDF-CF/EP)。重点研究了BN粒子含量对改性PVDF电纺纤维膜增强CF/EP层间断裂韧性的影响及相关增韧机理。研究结果显示:当BN含量为3.2wt%时,BN&PVDF电纺纤维膜的增韧效果最好,相对于CF/EP,BN&PVDF-CF/EP的Ⅰ型层间断裂韧性提高了129.6%,Ⅱ型层间断裂韧性提高了160.6%;BN粒子引入后,提高了PVDF的拉伸强度和模量;SEM分析显示,BN粒子被部分镶嵌于PVDF纤维上,提高了PVDF纤维表面的粗糙度,增强了PVDF纤维与基体的界面相互作用,引起了更加复杂的增韧形式并提高了PVDF纤维的增韧效果。

纳米菱方氮化硼对氰酸酯树脂的改性研究

将纳米菱方氮化硼粒子(RBN)经烘干预处理后,加入氰酸酯树脂(CE)基体,二月桂酸二丁基锡(BDTL)作为引发剂,制得CE/RBN系列浇铸体复合材料。对浇铸体复合材料的力学想能、玻璃化温度、热分解温度和热失重性能实测表明,RBN质量分数为4.0%时,复合材料冲击强度为15.02kJ/m^(2),较纯基体固化产物提高了71.65%;弯曲强度达到163.60MPa,较纯基体固化产物提高了93.60%;RBN加入质量为有机基体质量的4.0%时,复合材料玻璃化转变温度(Tg)为289.50℃,比纯基体固化产物提高了13.30%;热分解温度为458.30℃,提高了10.73%;质量保持率为72.40%,比纯基体固化产物提高了41.41%。综合各方面因素考虑,RBN加入的质量分数为有机基体质量的4.0%时,复合材料性能得到综合提升。

氮化硼对量子点光转化LED流明效率的影响

量子点光转化LED(QCLED)是LED发展中的一种新型器件,然而,QCLED的流明效率无法满足实际应用的要求。本文针对QCLED器件流明效率低的技术难题,在量子点光转化涂层中掺入六方氮化硼纳米粒子,利用其强散射效应,提高QCLED的流明效率。通过实验研究,得出氮化硼粒子的最优掺入浓度,当氮化硼粒子掺入浓度为0.25wt%时,QCLED的流明效率与传统QCLED相比增加了17.7%,达到了提升QCLED流明效率的目的。

In situ FTIR investigation on phase transformations in BN nanoparticles

Fourier transformation infrared spectrum (FTIR) was employed to investigate phase transformation of nanoparticle BN, containing eBN, rBN, wBN and cBN, in which eBN and rBN are the main components. We found that part of eBN was converted into rBN at 200―350℃. At and above 400℃, eBN transformed into wBN, and some of wBN were converted into cBN simultaneously. This conclusion is supported by the results from high- resolution transmission electron microscopic (HRTEM) and Raman spectroscopic measurements. In this work, the converting processes be- tween different BN phases were continuously monitored by in situ FTIR spectroscopy. The results will be helpful for synthesis of cBN at moderate conditions.