三维编织复合材料的力学行为研究现状

关于三维编织复合材料的细观几何模型以及力学性能的研究进展进行了综述,着重阐述了近年来该研究领域的一些学术成果,其中包括三维编织复合材料力学性能的实验和理论研究.实验研究则多以测试各种编织参数和载荷对其力学性能参数的影响规律,而理论研究则侧重介绍细观结构力学模型.最后,总结了目前研究工作存在的问题,并对未来发展趋势做出展望.     

高效阴离子交换色谱-脉冲安培法测定W135群和Y群脑膜炎球菌多糖中半乳糖和葡萄糖含量

目的采用高效阴离子交换色谱-脉冲安培法(High-performance anion-exchange chromatography with pulsedamperometric detection,HPAEC-PAD)测定W135群和Y群脑膜炎球菌荚膜多糖中半乳糖和葡萄糖的含量,并对该方法进行验证及初步应用。方法多糖蛋白结合物原液的混合液经HCl水解处理后,进样CarboPac PA10柱,以氢氧化钠-醋酸钠梯度流洗,脉冲积分安培检测器检测。筛选样品的水解条件;对HPAEC-PAD法进行专属性、精密性及准确性验证,并进行初步应用。结果确定的样品水解条件为以2 mol/L HCl于85℃处理1 h。载体蛋白破伤风类毒素对检测结果无干扰;重复性、日内精密性和不同操作者之间精密性试验结果的RSD均小于5%;准确性试验中葡萄糖和半乳糖的回收率在90%～110%之间。HPAEC-PAD法测定多糖蛋白结合物原液的多糖含量与传统间苯二酚比色法测定结果相当;成品疫苗中的W135群和Y群多糖含量测定结果符合《A、C、W135、Y群脑膜炎球菌结合疫苗制造及检定规程草案》的规定(均≥4μg/剂)。结论 HPAEC-PAD法专属性、精密性和准确性良好,可用于A、C、W135、Y群脑膜炎球菌结合疫苗中W135群和Y群多糖含量的测定。     

纳米碳颗粒/碳化硅陶瓷基复合材料的氧化行为

以微米硅(Si)和纳米碳黑(Cp)粉体为主要原料,采用经机械化学法合成的碳化硅(SiC)和15%和25%的纳米碳颗粒与碳化硅(Cp-SiC)的复合粉体,并经无压烧结得到了Cp/SiC陶瓷基复合材料,分析了在不同温度条件下Cp/SiC烧结体的氧化行为。结果表明:当温度小于700℃时,Cp/SiC复合陶瓷在空气中的氧化受C—O2反应控制,致使其为均匀氧化;700℃时,氧化后的复合材料显气孔率最大,弯曲强度达极小值;大于700℃,氧化过程受O2的气相扩散控制,呈非均匀氧化;700~900℃之间,O2通过微裂纹的扩散控制着Cp/SiC的氧化过程;900~1 100℃之间,O2通过SiC缺陷的扩散控制着Cp/SiC的氧化过程,并在1 000℃时的最初的2 h内,复合材料弯曲强度增大,且达到了极大值。同时表明,纳米碳含量是影响复合材料强度及氧化行为的关键因素,添加纳米碳质量分数为15%的Cp/SiC复合陶瓷可以作为一种抗氧化性能优良的玻璃夹具材料。     

碳纳米管增强环氧／石墨复合材料的制备与性能研究

采用粉末冶金法制备了碳纳米管增强环氧／石墨复合材料,并研究了酸洗处理对复合材料弯曲强度、硬度和导电性能的影响。结果表明：与未处理碳纳米管相比,酸处理的碳纳米管增加了环氧／石墨复合材料的弯曲强度和硬度,降低了电阻率。酸处理的碳纳米管增强环氧／石墨复合材料的弯曲强度达到21．9MPa,比未添加碳纳米管时提高了近22％;同时复合材料的硬度达到最大值21．7HS,比未添加碳纳米管时提高了近10％;复合材料的电阻率达到了最小值45036μΩ·cm,比未添加碳纳米管时复合材料的电阻率降低了近17％。     

焦炭颗粒/热解炭复合材料的制备与压缩性能研究

分别以LJ1、LJ2、YJ、ZJ 4种焦炭颗粒作为增强体,CVD炭作为基体,利用TCVI设备制备出了焦炭颗粒增强热解炭基(焦炭颗粒/热解炭)复合材料。并从其力学性能着手,使用金相显微镜分析其显微结构,采用扫描电镜观察其断口微观形貌,并结合载荷-位移曲线综合分析其断裂方式及机理。结果表明:4种焦炭颗粒/热解炭复合材料中,LJ1和ZJ焦炭颗粒沉积前后密度与质量变化最大,其质量分别增加57.4%和64.3%;焦炭颗粒/热解炭复合材料微观组织结构为各向异性;LJ2焦炭颗粒/热解炭复合材料轴向和径向的压缩强度分别为203.7 MPa和176.3 MPa,在4种焦炭颗粒/热解炭复合材料中强度最高;4种焦炭颗粒/热解炭复合材料压缩断裂方式为脆性断裂,LJ2焦炭颗粒/热解炭复合材料和YJ焦炭颗粒/热解炭复合材料主要是因其内部焦炭颗粒孔洞的应力集中造成断裂,LJ1焦炭颗粒/热解炭复合材料和ZJ焦炭颗粒/热解炭复合材料主要沿其焦炭颗粒的层片断裂。     

聚氯乙烯/粉煤灰复合材料的制备与性能研究

制备了聚氯乙烯/粉煤灰复合材料,研究了粉煤灰的不同表面处理方式对共混物的力学性能和耐温性能的影响。结果表明:湿法处理粉煤灰的效果最好,不做处理的效果最差;粉煤灰会降低PVC材料的缺口冲击强度;添加5份处理过的粉煤灰可以提高PVC材料的拉伸强度;添加粉煤灰可以提高PVC材料的弯曲强度和弯曲模量,同时,耐温性也有一定的提高。     

Effect of Cryoprotectant and Freeze-Drying Process on the Stability of W/O/W Emulsions

In order to protect a hydrophilic drug and to prolong its further delivery, the formulation of multiple emulsions could be worthy. However, the double emulsions are not stable, their structure can change, leading to the formation of a single emulsion as the destruction of the system, and the drug can release easily from the globules in liquid state. The freeze-drying technology could be used to produce dry emulsion, the powder form being much more stable. The aim of this work was to study the influence of a cryoprotectant and a freeze-drying process on the stability of W/O/W emulsions. Samples were frozen at two different freezing rate (ν _f  = 0.55°C/min and 1.25°C/min) and successively dried at two different sublimation temperature (T _s  = ? 10°C and ? 20°C). The particle size distributions were measured by granulometer and UV spectrophotometer was performed to investigate the leakage of internal constituent. The glass transition temperature (T _g ) of the double emulsions was analyzed by DSC. The particle sizes became even smaller after freeze drying, except when κ-carrageenan is used as a cryoprotectant. In that case, the particles became aggregated after freeze drying, whatever the process conditions. The mean size is considerably reduced when the globules are diluted at low concentration in glucose and trehalose solution. When the concentration is increased, the size distribution is not significantly affected. The leakage of the internal aqueous phase to the external one during freeze drying was measured as an indicator of the structure stability. It is affected by the nature of the cryoprotectant and the conditions of the freeze-drying process. The leakage of the internal phase was smaller when cycle III (ν _f  = 1.25°C/min, T _s  = ? 10°C) was processed. From our experiments, we suppose that the water transfer from the inner phase to the outer aqueous phase results in the diminution of the globules size in double emulsion. The T _g of the double emulsions diluted with trehalose and glucose were determined at ? 33.8°C and ? 47.1°C. In contrast, the T _g of double emulsion with κ-carrageenan and HES did not appear.     

Effect on Mechanical Performance of UHMWPE/HDPE-Blend Reinforced with Kenaf,Basalt and Hybrid Kenaf/Basalt Fiber

The aim of this study was to investigate the performance of UHMWPE/HDPE-reinforced kenaf, basalt and hybrid kenaf/basalt composites. Mechanical testing of these samples was carried out such as tensile, flexural (three-point bending) and an impact test (Charpy). Pure resin (UHMWPE/HDPE) samples were tested and compare with reinforced 10% weight fraction of kenaf, basalt and hybrid kenaf/basalt samples to identifying their contribution and potential in this new composite material. UHMWPE/ HDPE sample was produced in constant ratio 60:40 respectively via extrusion process. Basalt reinforced UHMWPE/HDPE generates the highest elastic modulus result compared to kenaf and hybrid kenaf/basalt as a reinforcement material. The tensile results of kenaf reinforcement UHMWPE/HDPE samples are significantly higher (20%) than pure blend resin, which is an indication for good performance of kenaf, basalt and hybrid kenaf/basalt to be used in UHMWPE/HDPE-blend polymers. The flexural and Charpy strengths show the drawback results, where performance of polymer is reduced 5% with the absence of kenaf. It can be concluded that kenaf, basalt and hybrid kenaf/basalt fiber successfully increase the UHMWPE/HDPE blends performance especially under tensile loading.     

Characterization of Europium Complex-doped PMMA and PMMA-EVA Polymer Networks

Europium-β-diketone chelate doped poly(methyl methacrylate) and poly(methyl methacrylate)/poly(ethylene co-vinyl acetate) blends have been successfully prepared and characterized. The mechanical properties of the PMMA-EVA systems have been assessed in terms of tensile strength and impact strength. The thermal characteristics and the energy involved in thermal decomposition have been studied. The structural properties of the complex doped polymeric systems reveal that the complex exists in the same crystalline state in the doped systems as it does in the pure state. The orientations of the groups in the host matrix have been found to be affected by the complex loading. The optical properties of the system have been studied by photo luminescence spectroscopy. The fluorescence lifetime have been observed to decrease at greater loadings of the complex; an effect that has been attributed to concentration quenching. The complex doped PMMA/EVA polymer network developed is considered to be a potential candidate for the development of optoelectronic devices those possess superior mechanical properties.     

Progress in Carbon Fiber and Its Polypropylene- and Polyethylene-Based Composites

Due to their lightweight and excellent toughness, carbon fiber (CF) and its reinforced thermoplastic composites are suitable for high-performance applications such as aerospace, aviation, automotive and sport equipments. In this study, comprehensive detail is provided on the production of carbon fiber, its various forms and geometry and their corresponding effects on the mechanical properties of CF and its reinforced polypropylene (PP) and polyethylene (PE) composites. Here we discuss extensively various methods reported in literature on improving the interfacial fiber-matrix adhesion and dispersion in order to achieve better mechanical properties for such composites.