PAO8和45#变压器油基础油粘度调和及计算模型研究

采用高低温运动粘度测定仪测量PAO8(8#聚烯烃)合成基础油和45#变压器油基础油按不同比例调和后混合基础油的粘温性能,运用Arrhenius模型和Grunberg-Nissan模型计算混合基础油的理论粘度,研究粘度偏差率随测试温度的变化规律.实验结果表明:Arrhenius模型能准确预测混合基础油的高温运动粘度,粘度偏差率最大值不超过1%,而Grunberg-Nissan模型能精确计算混合基础油的低温运动粘度;PAO8和45#变压器油基础油调和能够获得高低温粘度的匹配.     

提高聚氨酯推进剂基体粘结强度的途径探索

聚氨酯的水解稳定性较差,粘结强度偏低。将端羟基聚丁二烯与聚氨酯进行共混改性,提高了聚氨酯基体的表观交联度及推进剂的拉伸强度。采用示差扫描量热法和红外光谱法分析基体共混物的微观结构,表明这是提高聚氨酯基体粘结强度的一条有效途径。     

基于预配装思想的物资混装配载优化策略

提出了一种基于预配载思想的装备物资混装配载策略,并应用模糊聚类和混合智能算法进行了实例仿真。研究对于组合优化策略在装备保障信息化系统建设中的应用具有积极意义。     

基于控制通道融合的瞄准线组合稳定技术

提出一种光电二级稳定粗、精控制通道融合新方案,并与现有粗、精控制通道相互独立二级稳定方案相比较。仿真结果表明,粗、精控制融合方案无论在成本、体积、性能和精度上,都优于现有二级稳定方案。新方案的可行性已通过原理样机得到验证。     

装备物资混装配载效益化特征聚类分析

提出了通过对物资聚类分组来分步解决混装配载问题的思想,分析了装备物资混装配载中物资分类的办法,讨论了使用聚类分析法研究分类问题的特点,给出了一种基于系统聚类法的物资效益化特征分组方法。     

Effect of nano powder (Al2O3-CaO) addition on the mechanical properties of the polymer blend matrix composite

This work describes the preparation and study of the properties of composite nanoparticles prepared by the sol-gel method which consists of two materials (Al₂O₃-CaO), and study the effect of these nanoparticles on the mechanical behavior of a polymer blend (EP 4% + 96% UPE). The powder was evaluated by X-ray diffraction analysis, scanning electron microscopy analysis (SEM), particle size analysis, and energy dispersive X-ray analysis (EDX). The mechanical behavior of the composite material was assessed by tensile test, bending test and hardness test. The evaluation results of the composite nanoparticles showed good distribution of the chemical composition between aluminum oxide and calcium oxide, smoothness in particles' size at calcination in high and low temperatures, formation of different shapes of nanoparticles and different (kappa and gamma) phases of the Al₂O₃ particles. The results of mechanical behavior tests showed marked improvement in the mechanical properties of the resulted composite material, especially at 1.5%, compared with polymer blend material without nano powder addition. The tensile properties improved about (24 and 14.9) % and bending resistance about (23.5 and 16.8) % and hardness by (25 and 22) % when adding particles of size (63.8 and 68.6) respectively. Therefore, this reflects the efficiency of the proposed method to manufacture the nanocomposite powder and the possibility of using this powder as a strengthening material for the composite materials and using these composite materials in bio applications, especially in the fabrication of artificial limbs.