柳树河油页岩微波干燥及其对热解特性的影响

在对家用微波炉改造基础上搭建了微波干燥实验台,研究了柳树河油页岩微波干燥特性及对热解特性的影响。结果表明,微波干燥所需的时间为传统干燥所需时间的20%;微波干燥速率要明显大于传统干燥速率;Page模型适用于描写柳树河油页岩微波干燥过程。微波干燥的油页岩同热风干燥后及原样油页岩的热解活化能随转化率的变化曲线基本一致,整体呈先上升后下降的趋势,在转化率为0.7时达到最大值;热解活化能在80~200 kJ/mol变动;微波干燥油页岩热解反应有机质分解段的活化能增加。     

柳树河油页岩微波干燥及其对热解特性的影响

在对家用微波炉改造基础上搭建了微波干燥实验台,研究了柳树河油页岩微波干燥特性及对热解特性的影响。结果表明,微波干燥所需的时间为传统干燥所需时间的20%;微波干燥速率要明显大于传统干燥速率;Page模型适用于描写柳树河油页岩微波干燥过程。微波干燥的油页岩同热风干燥后及原样油页岩的热解活化能随转化率的变化曲线基本一致,整体呈先上升后下降的趋势,在转化率为0.7时达到最大值;热解活化能在80~200 kJ/mol变动;微波干燥油页岩热解反应有机质分解段的活化能增加。     

干燥方法对纳米Sb2O5性能的影响

1前言 胶体Sb2O5及其超微粉末作为高效阻燃增效剂,其优异性能已得到公认[1,2].美、日等发达国家已进入实验应用阶段,我国在合成方法及阻燃性能评定方面也开展了一些工作.水溶胶合成方法较多,所得胶体性能相仿.由水溶胶制备干粉,文献报导中多采用喷雾干燥法,至于干燥过程对其组成及性能有无影响,未见文献报导.作者利用电子显微镜、X射线衍射、X光电子能谱及溶剂再分散实验等,对采用喷雾干燥法和直接蒸发法所得干胶粉,进行了对比测试和分析,结果表明,喷雾干燥法不但使其组成发生变化,且使其颗粒变大,再分散成溶胶的性能变差.直接蒸发法没这些问题,且设备简单,处理能力大,更经济实用.     

生物质微波干燥及其对热解的影响

通过与常规热风干燥方式比较,研究生物质微波干燥过程及其对热解的影响,以探索在生物质快速热解液化工艺中采用微波干燥技术进行原料预处理的可行性。干燥实验表明,微波炉的干燥速率明显大于烘箱（5倍以上）,同时在微波快速干燥过程中,原料内部的孔隙结构得到了改善。热天平上干燥样品的热解表明,微波干燥处理有利于生物质的热解,特别是纤维素和半纤维素的热解,并且能在一定程度上抑制生物油蒸汽的二次裂解反应,从而使实际流化床热解液化装置中的生物油产率有所提高。研究表明,将微波干燥技术用于生物质热解液化的原料预处理过程在技术上和经济上均具有可行性。     

草甘膦锆:干燥方法对微形貌的影响及甲醛吸附行为

本文运用扫描电子显微镜、X射线粉末衍射仪等手段对在不同干燥方法下得到的层状材料草甘膦锆分子聚集体的形貌及其对甲醛吸附性能进行了深入研究,探讨了干燥条件对材料形态的影响以及化合物形态对甲醛吸附不同的内在因素。研究结果表明:干燥方法不同,所得草甘膦锆的形貌有明显差别,应用超临界干燥技术得到的产物是具有大比表面(445m2·g-1)和大比孔容(5.32cm3·g-1)的三维网状结构,应用冷冻干燥技术得到的产物具有介孔结构,而使用喷雾干燥技术得到的产物为微孔与介孔共存微球。在对4种不同干燥产物对甲醛吸附性能的研究发现,甲醛分子在不同形态载体上的吸附能力差距很大,超临界干燥得到的草甘膦锆对甲醛吸附最大百分率(被吸附甲醛的质量占吸附组装体的百分含量)达到7.8%,且甲醛被吸附后热稳定性较好,具有较好的应用前景。     

污泥干燥预处理后与神府煤共成浆性的研究

以萘系阴离子表面活性剂为分散剂,考查了污泥干燥条件和粒径对神府煤成浆性的影响。结果表明,将污泥干燥后再制浆,明显提高了污泥煤浆的成浆浓度;升高干燥温度,有利于提高污泥煤浆的成浆浓度。干燥温度对污泥的可磨性影响较大。干燥温度越高,干燥污泥可磨性越好,球磨的污泥平均粒径越小,制得的污泥煤浆表观黏度越低;温度高于105℃,污泥的可磨性无明显差别,污泥煤浆的表观黏度亦无明显变化。污泥粒径越小,颗粒越细,一定程度上提高了煤粉的堆积效率,使污泥煤浆的表观黏度降低。     

表面活性剂浓度与表面张力-稀释倍数积分值的关系研究

比较了三阶段Hermit插值和二次多项式的表面张力-稀释倍数拟合曲线及其求积方式,得出由三阶段Hermit插值所得n 1个离散数据点的拟合曲线,及对其前n个离散数据点所在区间上进行求积较佳。在三阶段Hermit插值拟合及求积方式下,分析了十二烷基硫酸钠、十六烷基三甲基溴化铵、茶皂素和去菌体前后含鼠李糖脂发酵液溶液浓度与表面张力-稀释倍数积分值之间的线性回归方程F值和r值,结果显示:F值大小受积分区间、(生物)表面活性剂种类、溶液浓度与临界胶团浓度的比值大小及溶液中杂质的影响,但F值均大于F0.005。     

原位法常压干燥制备疏水SiO2气凝胶及其热稳定性

在正硅酸乙酯(TEOS)酸碱两步催化的溶胶-凝胶过程中, 加入干燥控制化学添加剂(DCCA)N,N-二甲基甲酰胺(DMF)和三甲基氯硅烷(TMCS)的混合溶液, 进行原位疏水改性处理, 并结合常压干燥工艺制备了高比表面积的疏水SiO2气凝胶. 利用N2物理吸附, 全自动X射线衍射仪(XRD), 傅立叶变换红外光谱仪(FTIR), 扫描电子显微镜(SEM)等对样品的形貌结构进行了表征. 实验结果表明, 原位疏水改性比非原位疏水改性制备的SiO2气凝胶具有更大的比表面积, 可达979 m2·g-1, 气凝胶表面存在憎水性基团—CH3, 有良好的疏水性. 500 ℃热处理后, 气凝胶因失去大量的—CH3基团, 由憎水性转为亲水性; 800 ℃高温热处理后, 疏水SiO2气凝胶仍处于非晶态, 具有良好的热稳定性能.     

添加环氧丙烷法常压干燥制备ZrO2气凝胶

以无机锆盐硝酸氧锆(ZrO(NO3)2·5H2O)为前驱体,1,2-环氧丙烷(PO)为凝胶促进剂,甲酰胺(FA)为干燥控制化学添加剂(DCCA),采用溶胶-凝胶法并通过常压干燥制备了轻质二氧化锆(ZrO2)气凝胶,利用差热分析(DTA)、扫描电镜(SEM)、N2吸附/脱附等测试技术对所制得的ZrO2气凝胶进行了表征.结果表明:添加环氧丙烷常压干燥制得的ZrO2气凝胶具有纳米尺寸的多孔网络结构,表观密度可低至202.08 kg·m-3,比表面积可高达645.0 m2·g-1,与超临界干燥效果相当.环氧丙烷因其环氧原子的强亲核性和不可逆的开环反应,可促进凝胶化,并通过环氧丙烷的量控制反应过程和凝胶状态.     

1-辛烯Ziegler-Natta聚合的活性中心多分散性——分子量分布及动力学的研究

本文通过对TiCl_3-Al(C_2H_5)_3聚合1-辛烯产物的双峰型分子量分布曲线用Schulz函数进行拟合、分峰处理,发现这种双峰型分布中的高分子量峰部分由一种活性中心生成,低分子量峰部分则由至少两种活性中心生成.将不同转化率时聚辛烯的分子量分布分峰拟合数据与聚合速率、活性中心数等测定数据相结合,得到了高分子量和低分子量两部分产物相应的活性中心上各自的动力学参数(增长速率常数、活性中心数、链转移常数等)及各自的聚合速率曲线,从而证实了多种活性中心的存在、它们催化特性的差异及与聚合物分子量分布增宽的关系.     

Drying Study of Siloxane-PPG Nanocomposites

This is a study of the structural transformations occurring in hybrid siloxane-polypropyleneglycol (PPG) nanocomposites, with different PPG molecular weight, along the drying process. The starting materials are wet gels obtained by the sol-gel procedure using as precursor the 3-(trietoxysilyl)propylisocyanate (IsoTrEOS) and polypropylenglycol bis(2-amino-propyl-ether) (NH₂-PPG-NH₂). The shrinkage and mass loss measurements were performed using a temperature-controlled chamber at 50°C. The nanostructural evolution of samples during drying was studied in situ by small angle x-ray scattering (SAXS). The experimental results demonstrate that the drying process is highly dependent on the molecular weight of polymer. After the initial drying stage, the progressive emptying of pores leads to the formation of a irregular drying front in gels prepared from PPG of high molecular weight, like 4000 g/mol. As a consequence, an increase of the SAXS intensity due to the increase of electronic density contrast between siloxane clusters and polymeric matrix is observed. For hybrids containing PPG of low molecular weight, the pore emptying process is fast, leading to a regular drying front, without isolated nanopockets of solvents. SAXS intensity curves exhibit a maximum, which was associated to the existence of spatial correlation of the silica clusters embedded in the polymeric matrix. The spatial correlation is preserved during drying. These results also reveal that the structural transformation during drying is governed by capillary forces and depends on the entanglement of polymer chains.     

不同干燥过程对超细TiO2粉体性质的影响

考察了采用不同干燥工艺制备的TiO2粉体在粒子形貌、颗粒大小与分布、晶相组成以及比表面积和孔结构等织构和结构性质方面的差异。结果表明，利用常规的干燥方法，由水凝胶脱水所得的颗粒，颗粒间严重团聚，颗粒粒径大且分布不均匀，比表面积和孔体积最小；由醇凝胶直接脱水，则可以显著提高粉体的织构性能．而采用超临界流体干燥法则可以进一步提高粉体的性能，比表面积由水凝胶的4．88m2·g－1增大到113．8m2·g－1，提高了近30倍；孔体积由0．027cm3·g－1增大到0．41cm3·g-1．大约提高了15倍；而且其能够有效地防止粒子间的团聚，较好地保持了湿凝胶的网络结构，使颗粒尺寸降低且分布均匀，可重复性好．     

超临界流体干燥过程的分析

以ZrOCl2•8H2O为原料，采用超临界流体干燥（SCFD）法，在短时间内制备出大孔体积高比表面ZrO2气凝胶超细粉．该法具有良好的稳定性和可靠性．建立了醇凝胶中液相含水量的分析方法，为产品质量控制及确认体系是否处于超临界状态提供了依据．对抽提后的溶剂分析表明，SCFD过程是一物理过程．对水的抽提干燥过程亦进行了初步的理论探讨．     

常压干燥法制备气凝胶的研究进展

气凝胶是一类轻质、低密度的三维纳米多孔固态材料,因其独特的高孔隙率、高比表面积和低导热系数等特性,使其在吸附、催化、保温隔热和隔音等诸多领域具有广泛的用途,目前其相关研究在材料科学领域受到了广泛的关注。气凝胶的制备主要包括溶胶-凝胶过程和湿凝胶干燥两个步骤,湿凝胶的干燥是制备气凝胶过程中至关重要而又较为困难的一步。传统的气凝胶通过超临界干燥制备,工艺复杂、成本高,而且由于干燥过程在高温高压条件下进行,有一定的危险性并且不适宜大规模生产,因此如何通过常压干燥获得高比表面积、高孔隙率、低密度的性能优异的气凝胶是其研究的重要方向之一。本文简要介绍了湿凝胶的制备以及凝胶干燥理论,详细介绍了近年来常压干燥方法气凝胶制备的研究进展,并对其未来发展前景做出了展望。     

不同干燥条件下壳聚糖膜表面的微观结构及微观力学性能

以自然风干(NW)、真空干燥(VD)及红外干燥(ID)三种干燥方式制备了壳聚糖膜.利用原子力显微镜(AFM)研究这三种壳聚糖膜的表面形貌及微观力学性能.实验结果表明VD和ID改善了膜材料的表面平整度,膜表面粗糙度分别为(5.47±1.34)和(2.79±0.93)nm,均显著低于NW膜((30.67±8.06)nm).干燥条件对壳聚糖膜的微观力学性能有较大影响:ID壳聚糖膜的粘附力((2595.0±68.5)pN)显著大于NW壳聚糖膜((982.6±149.3)pN)和VD壳聚糖膜((1817.9±279.2)pN);而ID壳聚糖膜的杨氏模量((158.8±15.2)MPa)则低于NW壳聚糖膜((204.3±22.7)MPa)和VD壳聚糖膜((195.8±14.6)MPa)的.     

Drying of alkoxide gels—Observation of an alternate phenomenology

The process of drying of a porous material as per the current phenomenological theory can be divided into two stages. At first the body shrinks by an amount equal to the volume of liquid that evaporates, and the liquid-vapor interface remains at the exterior surface of the body. The second stage begins when the body becomes too stiff to shrink and the liquid recedes into the interior, leaving air filled pores near the surface. We shall refer to this phenomenology as the drying front model. In our investigation of drying of alkoxide silica gels of less than 50 Angstroms pore radius, we have observed a different drying pattern, in which even after the gel body stops shrinking, drying continues to occur by evaporation on the exterior surface of the gel body, causing spontaneous nucleation of partially or fully dried opaque clusters, randomly distributed in the interior parts of the gel. These clusters than increase in number and size till they coalesce to form an opaque body. Upon further drying, the gel returns to its transparent form. We postulate that this is possible only if the rate of fluid flow in the pores by diffusion is faster than that by Darcy's flow, as well as the evaporation rate at the surface of the gel body. We shall refer to this as the cluster drying model. We shall present results of pin-hole drying experiments on cylindrical alkoxide gels showing that for identical gels the evaporation rate can be increased to change the phenomenology from cluster drying to one that exhibits both phenomenology simultaneously and finally to that of the drying front phenomenology. We shall also show the effect of gel pore size distribution on the phenomenology of drying under identical drying conditions. Finally, we will present evidence that for successful drying of large cylindrical alkoxide gels, drying conditions favoring cluster drying phenomenology is desirable.     

Physicochemical and Quality Properties of Dried Courgette Slices: Impact of Vacuum Impregnation and Drying Methods

The aim of this study was to determine the effects that the type of impregnating solution and drying method (freeze drying (FD) and vacuum drying (VD) at 45 °C and convective drying (CD) at 50, 60, and 70 °C) had on the physicochemical and quality properties of courgettes. Courgette slices were vacuum-impregnated (6 kPa) in freshly squeezed onion, kale, and onion and kale (50:50) juices with 3% NaCl solution (N). The application of vacuum impregnation (VI) with impregnating solutions from freshly squeezed onions and kale had a beneficial effect on the bioactive values of courgette. The highest contents of quercetin (41.84 μg/g d.m.) and carotenoids (276.04 μg/g d.m.) were found in courgette impregnated with onion juice after freeze drying. The highest values of lutein and zeaxanthin (216.42 μg/g d.m.) were recorded for courgette impregnated with kale juice and convective dried. By analysing the kinetics of convective drying, the best matching of the logistic model was found. Increasing the drying process temperature from 50 to 70 °C reduced the drying time from 15% to 36%, depending on the type of impregnating solution used. Water activity < 0.6 was recorded for courgette dried by freezing, vacuum, and convection at 60 and 70 °C. Conclusions: The vacuum impregnation process and the impregnation solutions from freshly squeezed vegetables can be used to develop new snacks with high levels of bioactive compounds. The FD method is the most appropriate considering both the bioactive compounds content and the obtained colour and water activity.     

Drying and Sintering of Bulk Silica Gels

Over the last few years, the feasibility of fabricating near net shape silica glass components, using a sub-critical drying process for pure alkoxide gels, has been demonstrated in our laboratories. Cracking during drying, due to capillary forces generated in the gel body, was overcome through two particular innovations. The first was the development and optimization of a dual-catalyzed high strength gel. The second was a controlled atmosphere drying process that allowed the gel to dry utilizing a newly observed phenomenology, postulated to be due to cavitation of the pore fluid. Contrary to conventional wisdom, in this drying approach the smallest pore size gels are the easiest to dry. Details of the types of gels and the drying process are reported. Gels of small size were sintered into crack-free glasses, utilizing conventional sintering approaches. However, large size gels always developed visible surface cracks that formed above 800°C. To successfully dry and sinter large monolithic gels then required re-optimization of the entire process. A great number of micron-range defects were initially detected in these sintered bodies. After analyzing the defects, further steps were taken to improve glass quality to the level of optical glass produced by vapor deposition processes. This included mixing and filtering of sols in a clean room, varying the pore size distribution, and optimizing the pre-sintering and sintering processes. Data of relevant glass quality parameters attained so far in the laboratory are reported.     

超临界干燥法制备SiO2气凝胶的研究

通过溶胶－凝胶法和超临界干燥技术制得了ＳｉＯ２气凝胶，研究了溶液的ｐＨ值对凝胶时间及气凝胶密度的影响，应用ＸＲＤ、ＳＡＸＳ、ＴＥＭ和等方面对气凝胶样品的结构进行了初步研究，结果表明，ＳｉＯ２气凝胶是连续网络的非晶态纳米多孔固体，其基本粒子的平均直径约１０ｎｍ．     

阳极氧化与超临界干燥结合制备多孔硅

多孔硅（PS）在室温下发射强可见光，这一发现在国际上引起极大关注，成为材料科学、半导体物理和化学以及信息科学领域研究的热点［1，2］．最近三、四年，国内外对PS制备工艺、影响PS发光的因素、PS发光机制、PS应用前景等方面进行了广泛的研究［2］，但有一些基本问题仍待解决，如关于PS发光机制尚存在分歧；PS电致发光效率低，离应用差距甚远；高多孔度PS微孔结构不稳定等．PS微孔内溶剂蒸发过程中，由于毛细管张力的存在，造成微孔骨架受力不匀．强的应力使PS骨架脆弱，甚至微孔结构坍缩，从而导致PS结构不稳定．对于高多孔度…