苯丙乳液的裂解气相色谱-质谱分析

苯乙烯一丙烯酸酯共聚乳液(简称苯丙乳液)是一种苯乙烯改性的丙烯酸酯系的共聚物乳液涂料.它用苯乙烯全部或部分代替纯丙乳液中的甲基丙烯酸甲酯,由于引入了苯乙烯链段,从而可提高涂膜的耐水性、耐候、耐碱性等,而且以水为介质,避免了传统油性涂料造成的环境污染和高成本,已广泛用于建筑涂料、地面涂料、粘合剂和胶粘剂等[1-2].     

硅丙微乳液共聚物胶膜的热性能

硅丙微乳液共聚物胶膜的热性能;硅氧烷; 丙烯酸酯; 微乳液热分析     

自交联型丙烯酸酯共聚物乳液的研究

以羟甲基丙烯酰胺、丙烯酸作为活性单体，采用种子乳液聚合法制得四元体系自交联型丙烯酸酯共聚物乳液。用透射电镜观察了乳胶粒的微观形态，并对共聚物乳液的流变性，稳定性等进行了测试，考察了羟甲基丙烯酰胺和丙烯酸的含量、聚合方式对共聚物乳液性能的影响。     

溶有增粘树脂的丙烯酸酯乳液共聚及压敏胶的性能

用一步法将溶有松香或氢化松香的丙烯酸酯单体进行乳液共聚合时，由于增粘树脂分子的自由基链转移作用使单体的转化率明显降低．先将大部分丙烯酸酯单体进行乳液共聚制得种子乳液，再将溶有增粘树脂的剩余丙烯酸酯单体加到种子乳液中进行第二步乳液共聚合，可显著提高单体的总转化率．用ＴＥＭ对分步聚合所得复合乳液的粒子形态进行了观察并对第二步乳液共聚合的机理进行了讨论．用分步乳液共聚合的方法制得的增粘树脂 丙烯酸酯复合乳液共聚物的压敏胶粘性能较一步法有很大的提高．     

含氟三元丙烯酸酯乳液共聚物的合成及性能

含氟三元丙烯酸酯乳液共聚物的合成及性能;甲基丙烯酸甲酯;丙烯酸丁酯;含氟甲基丙烯酸酯;β-环糊精     

含羧基/环氧树脂的丙烯酸酯共聚物乳液的制备和交联——1.含羧基丙烯酸酯共聚物乳液的分子设计和制备

以在低温下(<100℃)实现含羧基/环氧树脂的丙烯酸酯共聚物乳液的交联固化为目的,进行了分子设计;估算了共聚物的组成,用碱滴定法测定了乳胶粒表面的羧基数,并比较了不同单体配比所得乳液的成膜性能.     

优化含氟丙烯酸酯共聚物乳胶膜表面性能的方法研究

含氟丙烯酸酯乳液由于氟的引入具有优异的表面性能,在涂料、胶粘剂、纺织助剂等领域得到广泛应用.然而含氟单体成本较高,而且产物中乳化剂的存在影响了含氟丙烯酸酯乳液涂膜的抗污、疏水疏油等特性.如何采取有效措施提高含氟丙烯酸酯共聚物乳胶膜的表面性能,是其走向产业化急需解决的问题.针对这方面问题,本文主要从含氟单体的利用率、设计乳胶粒结构、共聚物链结构以及乳胶膜的后处理等方面对近年来的研究成果进行了综述.     

统计结构含氟丙烯酸酯共聚物的合成与表征

本文对含氟丙烯酸酯(FMA)与甲基丙烯酸丁酯(BMA)的RAFT细乳液共聚合及动力学进行了研究, 计算得到了FMA与BMA的竞聚率并制备出具有统计结构的含氟共聚物乳液.     

核壳乳液聚合法制备含氟硅丙烯酸酯乳液

以氟醇RfCH2CH2OH和乙烯基硅氧烷VTES为原料合成的氟硅单体,与甲基丙烯酸甲酯、丙烯酸丁酯在复合乳化体系中通过核壳乳液聚合制备了稳定的氟硅共聚乳液。对氟硅单体和氟硅丙烯酸酯共聚物的结构用红外光谱进行了表征,结果表明,得到了目标单体和共聚物。共聚物的TEM形态观察发现,乳胶粒子具有明显的核壳结构,平均粒径在125 nm左右。与丙烯酸酯共聚物相比,氟硅丙烯酸酯共聚物乳胶膜的吸水率降低至8.32%,热分解温度提高了23℃,耐溶剂性与氟硅单体的含量关系不大。     

含氟/硅丙烯酸酯乳液的合成进展

含氟丙烯酸酯聚合物具有良好的成膜性、光泽性、柔韧性、耐污性及耐腐蚀性,广泛应用于防腐耐候涂料。但其对基体的附着性差,对颜料、填料的润湿性差,不耐低温,加之含氟丙烯酸酯单体价格昂贵,大量使用受到限制。含氟/硅丙烯酸酯共聚物不仅兼备了含氟聚合物的诸多优良性能,而且能有效地提高与基体的附着力并降低聚合物成本。本文综述了氟/硅改性丙烯酸酯乳液常用单体;核壳型乳胶粒的结构及影响因素;氟/硅丙烯酸酯共聚物合成路线。     

磁性碳化硅陶瓷先驱体聚铁碳硅烷的研究

通过低分子量的聚硅烷与二茂铁反应合成了聚铁碳硅烷(PFCS).探索了反应温度、裂解温度、二茂铁含量等因素对合成PFCS的影响.元素分析、红外光谱、氢谱分析表明,铁被引入到PFCS中,PFCS与聚碳硅烷的结构相似.高温裂解聚铁碳硅烷所得碳化硅陶瓷具有一定的磁性.     

油剂混合区的工艺条件对催化裂化汽油改质的影响

利用连续式小型提升管催化裂化实验装置研究了原料预热温度、再生剂温度、油剂混合区温度和剂油比等油剂混合区的工艺条件对催化裂化汽油改质的影响规律。结果表明,降低再生剂温度、油剂混合区温度和剂油比均可以降低干气和焦炭的产率,同时也对催化裂化汽油改质的效果产生了影响。其中,再生剂温度对干气和焦炭产率影响最大;剂油比对催化裂化汽油改质的效果影响显著。降低再生剂温度、剂油比和油剂混合区温度一定程度上降低了烯烃转化率、异构烷烃增加率和芳烃增加率。提高原料预热温度可以一定程度上增加烯烃转化率、异构烷烃增加率和芳烃增加率。催化裂化汽油改质油剂混合区的最佳工艺条件为维持一定的反应温度和剂油比,并尽可能降低再生剂温度和提高原料预热温度。     

利用Py-GC/MS研究温度和时间对生物质热解的影响

以稻壳为原料,采用Py-GC/MS装置对其在不同热解条件下进行快速热解,并对热解气进行在线检测分析,考察了热解温度和时间对生物质热解性质的影响.结果表明,低于450 ℃,随着温度的升高,生物质热解产物种类及其产率均增加,但低温条件下产物种类较少,有利于产物的分离提纯;高于450 ℃,生物质热解产物种类基本稳定,仅在产率上有所变化,当550 ℃时,收率最大.随着热解温度的升高,其对应的最佳热解时间缩短,且生物质低温热解时间延长时热解比高温解热时间缩短时热解更充分.     

BN掺杂钛酸钡基NTC材料的研究

钛酸钡基材料在居里温度以下呈优异的NTC特性,围绕BN掺杂制备钛酸钡基NTC功能陶瓷材料,分别对不同掺杂量、烧结工艺过程进行了研究.结果表明,随着烧结温度的升高,NTC材料的致密化程度增强,其室温电阻率和NTC效应也会有一些变化,随着烧结温度的提高,NTC材料的居里温度也会有微小的变化;加入BN采用传统固相烧结法在烧结...     

Use of maximum temperature for correction of alanine dosimetry in electron beams

Alanine dosimetry is well characterized for irradiation temperature response. In use, alanine absorbed dose response is corrected for the irradiation temperature. The temperature used to correct alanine dosimetry absorbed dose response in electron beams has historically been the mean temperature occurring during irradiation (Sharpe and Miller, 2009). At lower absorbed doses, the change in temperature is relatively low; thus the absorbed dose response correction due to temperature is small. However, industrial electron beam processing often requires higher absorbed dose measurements where the change in temperature can be very large and the corresponding dose response correction for alanine becomes significant. This paper compares the impact of the temperature correction based on the use of a mean irradiation temperature (Sharpe and Miller, 2009) versus the use of a maximum irradiation temperature on the absorbed dose measurement. The results of this comparison indicate that the use of a mean temperature correction for higher absorbed doses measured with temperature corrected alanine dosimetry introduces a bias in the absorbed dose estimate.     

Reversed-phase retention thermodynamics of pure-water mobile phases at ambient and elevated temperature

The use of pure water at superheated temperatures, between 100 and 200 degrees C, as a mobile phase for reversed-phase separations is explored. The thermodynamics of the retention process at low temperature (15-55 degrees C) are compared to the thermodynamics at elevated temperature (125-175 degrees C). Significant differences in the enthalpy of the retention process are observed between the two temperature ranges. This is possibly due to changes in the hydrogen-bond network of the pure-water mobile phase, which would change the solvation, and therefore retention, of non-polar solutes. The change in thermodynamic values between the two temperature regions invalidates extrapolation of retention as a function of temperature between the two temperature regions for the prediction of room-temperature pure-water retention factors. The thermodynamic changes observed as the temperature is increased are similar to those seen when mobile phase composition is changed (by adding organic modifier) at constant temperature.     

The gas temperature in and the gas expulsion from a graphite furnace used for atomic absorption spectrometry

A simplified model for heat transfer based on thermal conduction is used to calculate the radial gas temperature distribution inside a semi-enclosed, commercial graphite tube furnace used for atomic absorption spectrometry. In the absence of a forced convective flow of a purge gas, the gas temperature inside the graphite furnace during its heating is lower than the wall temperature. After the wall temperature has attained a steady-state value, the gas temperature approaches the wall temperature and the radial temperature gradient in the gas decreases. The difference between the wall temperature and the gas temperature depends on the temperature program used, the thermal properties of the purge gas, and the atomizer geometry. The residence time of relatively volatile analyte elements is largely controlled by expulsion when wall atomization at high heating rates and high atomization temperatures are used. Analytical sensitivities are often enhanced by vaporizing the analyte into a gas having an approximately constant temperature.     

不同温度下炉内喷射氨水脱除NOx的模拟与试验研究

在一台小型沉降炉上进行了氨水喷射还原烟气中NOx的SNCR（Selective Non-Catalytic Reduction）实验研究，同时结合化学反应动力学模型研究了NH3还原NO过程中的关键影响因素，结果发现，过高的温度引起氨水的氧化，过低的温度不利于NO的还原，存在一个单一的温度区间，在该试验台上最佳的氨水喷射温度范围为850 ℃～1 100 ℃，最高达到了82％的NO还原率；采用均相反应模型与试验结果进行了对比，在高温区吻合情况较好；当温度高于950 ℃时，NH3残留量可以忽略；NH2的两类支链反应对于整个反应起重要作用。     

不同灰化温度下生物质混煤灰的烧结特性研究

选取晋城无烟煤和麦秆作为研究对象,利用压差法烧结温度测定装置测量不同灰化温度下煤和麦秆混合灰的烧结温度,再利用SEM-EDS以及XRD对灰样进行烧结特性分析。结果表明,不论灰化温度高低,随着麦秆的添加,煤和麦秆混合灰的烧结温度都呈现降低趋势,其降低幅度略有差别。灰化温度较低时,煤和麦秆混合灰的烧结温度低于灰化温度较高情况下混合灰的烧结温度。SEM-EDS分析表明,低温灰化得到的样品中出现较多不规则的纤维结构;较高温度下获得的灰样中出现较多致密的球状颗粒,这表明矿物质发生熔融形成球状颗粒。XRD分析表明,低温灰化烧结后的煤和麦秆混合灰样中因含有较多的含钾等碱金属系助融矿物质,导致混合灰样的烧结温度降低。然而,像钙长石等含钙矿物质本身具有较高的熔点,因此,在1 100℃时混合灰样具有较高的烧结温度。     

Thermally-regulated molecular selectivity of organosilica sol-gels

The feasibility of using temperature as a control mechanism for altering the selectivity of organosilica sol-gels for a specific molecule is demonstrated in this communication. The porous organosilica sol-gels act as reversible thermoresponsive materials which become hydrophobic at higher temperature and hydrophilic at lower temperature. When exposed to a mixture of molecules, the gels selectively intake the more hydrophobic species at higher temperature. A particularly remarkable feature of these gels is their ability to preferentially sequester the hydrophobic molecule at high temperature and the hydrophilic species at low temperature. Finally, these gels selectively intake hydrophobic molecules at high temperature and then preferentially release them when the temperature is lowered.