溴化十六烷基三甲基铵胶束高效液相色谱的研究和应用

研究了苯、苯胺、苯酚和甲苯在以溴化十六烷基三甲基铵(CTAB)水溶液为移动相,YWG-NH_2为固定相时的保留行为。当柱温为45℃、移动相组成为5%正丙醇(或9%乙醇)的0.03mol/L CTAB 时,苯、苯胺、苯酚和甲苯分离最佳。还计算了溶质传质过程的焓值及其在水、胶束、固定相间的分配系数。     

AA/AAm改性的PVF高速粘贴标签胶粘剂的研制

采用AA/AAm改性PVF的方法制备高速粘贴标签胶粘剂。对PVA用量、聚合反应温度、引发剂、pH值、AA/AAm等对胶粘剂性能的影响进行了研究。结果表明 ,这些因素对胶粘剂的粘度、稳定性、干燥速度和粘贴强度有很大的影响。该胶粘剂有较好的粘贴性能 ,适用于 14 0 0 0 -2 80 0 0支 /小时高速啤酒生产线粘贴标签     

大液相负荷下斜孔塔板的流体力学性能

针对大液相负荷气液传质操作 ,通过冷模实验 ,重新确定了普通斜孔塔板的液体力学性能 ,并给出了新的关联式。同时基于普通正排斜孔塔板在大液量操作条件下压降大 ,泄漏和雾沫夹带严重等缺点 ,沿用梯形导向浮阀的思想 ,提出了变正排为斜排的改进方案 ,并在相同条件下对两者的液体力学性能进行初步比较。证明了斜排斜孔塔板是一种适合大液体处理量且操作弹性较宽的塔板     

三石─堇青石匣钵的研制

引入“三石”改善堇青石质匣钵性能,提高匣钵使用寿命。     

微波促进有机反应原理及微波有机合成仪

论述了微波促进有机反应的原理和微波加热的特点.对目前使用的家用微波炉和专用微波有机合成仪的性能进行了评价.指出微波促进有机反应需要解决的问题及我国应加强对该领域的研究.     

Role of heat transfer and thermal conductivity in the crystallization behavior of polypropylene‐containing additives: A phenomenological model

The thermal conductivity of a filler and the thermal conductivity of a composite made from that filler influence the heat‐transfer process during melt processing. The heat‐transfer process from the melt to the mold wall becomes an important factor in developing the skin–core morphology. These aspects were examined in this study. The thermal conductivity of polypropylene–filler composites was estimated with a standard model for various fillers such as calcium carbonate, talc, silica, wollastonite, mica, and carbon fibers. The rate of cooling under given conditions, including the melting temperature, mold wall temperature, mass of the composite, and filler content, was estimated with standard heat‐transfer equations. The time to attain the crystallization temperature for polypropylene was evaluated with a regression method with differential temperature steps. The crystallization curves were experimentally determined for the different fillers, and from them, the induction period for the onset of crystallization was estimated. These observations were correlated with the expected trends from the aforementioned formalism. The excellent fit of the curves showed that in all these cases, the thermal conductivity of the filler and composite played a dominant role in controlling the onset of the crystallization process. However, the nucleation effects became important in the later stages after the crystallization temperature was attained. © 2003 Wiley Periodicals, Inc. J Appl Polym Sci 89: 2994–2999, 2003     

Development of new device for measuring thermal stresses

In recent years, numerous analytical and experimental researches have been performed on the prediction of thermal stresses in mass concrete structures. However, due to the difficulty of the problem, limitations still exist for both analytical and experimental methods of measuring thermal stresses in mass concrete. In this research, a new experimental device measuring thermal stresses directly in a laboratory setting is developed. The equipment is located in a temperature chamber that follows the temperature history, which has been previously obtained from temperature distribution analyses. Thermal forces are measured continuously by two load cells in the device. The results show that the thermal stresses estimated by the newly developed device agree well with general stress variations in actual structures.     

Thermal Shock Failure in Thick Epoxy Coatings

In this paper we describe an apparatus for reproducibly measuring thermal shock resistance of thick polymer layers bonded to metals. The thermal shock behavior is discussed in terms of epoxy samples bonded to an aluminum substrate. It was found that both high resin toughness and low resin thermal expansion coefficient improved thermal shock resistance of thick coatings, but only a sample containing 60wt. % glass beads did not develop a failure crack. Effects of sample thickness, temperature gradient, and resin composition on thermal shock behavior are discussed.     

莫来石及多孔莫来石的研究和应用

高温性能稳定,抗热震性能好的莫来石是一种重要的工程陶瓷材料。概述了莫来石的结构、性能,以及在工业上的应用,并对多孔莫来石陶瓷的研究进展和应用进行了介绍。针对莫来石室温力学性能较差的缺陷,讨论了氧化锆和颗粒增韧莫来石的方法。最后,对多孔ZTM陶瓷发展前景进行了展望。     

Processing-structure-multi-functional property relationship in carbon nanotube/epoxy composites

The novel properties of carbon nanotubes have generated scientific and technical interest in the development of nanotube-reinforced polymer composites. In order to utilize nanotubes in multi-functional material systems it is crucial to develop processing techniques that are amenable to scale-up for high volume, high rate production. In this research we investigate a scalable calendering approach for achieving dispersion of CVD-grown multi-walled carbon nanotubes through intense shear mixing. Electron microscopy was utilized to study the micro and nanoscale structure evolution during the manufacturing process and optimize the processing conditions for producing highly-dispersed nanocomposites. After processing protocols were established, nanotube/epoxy composites were processed with varying reinforcement fractions and the fracture toughness and electrical/thermal transport properties were evaluated. The as-processed nanocomposites exhibited significantly enhanced fracture toughness at low nanotube concentrations. The high aspect ratios of the carbon nanotubes in the as-processed composites enabled the formation of a conductive percolating network at concentrations below 0.1% by weight. The thermal conductivity increased linearly with nanotube concentration to a maximum increase of 60% at 5 wt.% carbon nanotubes.