加速溶剂萃取/气相色谱-质谱法测定小麦中多环芳烃

建立了小麦中8种多环芳烃的分析方法.样品通过加速溶剂萃取,经全自动在线凝胶渗透色谱-浓缩联用系统和硅胶柱净化,最后用GC-MS测定.实验中优化了加速溶剂萃取条件和凝胶渗透色谱净化条件.结果表明,在120℃用正己烷-丙酮(V∶V=1∶1)提取8min,萃取3次的提取效果最好,1000～1800s是凝胶渗透色谱净化的最佳收...     

固相微萃取-气相色谱在水中有机污染物测定中的应用

固相微萃取技术是一种新型的无溶剂的样品前处理方法,集取样、萃取、富集、进样于一体,具有无溶剂、可直接进样、操作简便快捷、灵敏的特点。简述了固相微萃取技术原理,综述了SPME与GC联用在水中有机污染物测定中的应用。具体介绍了该技术在苯系物、酚类化合物、多环芳烃、有机氯化物及其它有机污染物分析中的应用,并提出了该技术的发展趋势及应用展望。     

吹扫捕集-气相色谱法同时测定水中的乙醛、丙烯醛和甲醛

研究了吹扫捕集-气相色谱法同时测定水中乙醛、丙烯醛和甲醛的方法并优化了实验条件.实验结果表明,该方法操作简便,灵敏高效,目标化合物的检出限分别为0.037、0.012、0.0006mg/L,相对标准偏差在3.9％ ～15.8％之间,实际水样的加标回收率在73.0％ ～118％之间,能很好满足《地表水环境质量标准》中相关项目的要求.     

上海市水灾风险分析

利用1949-1990年上海市郊水灾历史灾情资料,分析其时空分布特征显示,自1949年以来,水灾受灾指数和相应粮食减产率呈阶段性下降,尤其自1977年水利控制片贯彻实施后,二者呈大幅度下降。各区县中,综合考虑水灾频次和受灾面积两个因素,得出南汇灾情最为严峻。最终,针对历史灾情资料缺乏、小样本数据使用传统统计模型进行风险分析精度不高的特点,基于信息扩散原理,利用正态信息扩散技术将单一的样本观测值变为一模糊集的模糊数学方法,对各区县受灾指数进行了风险分析,结果显示:南汇、浦东在受灾指数较低时,超越概率较高,即风险较高;崇明、金山在任一受灾指数下,风险都显示最高,受灾指数达0.8的超越概率为0.03345和0.01243,分别达到30年一遇和100年一遇。     

针对C3H8／空气扩散火焰的PCA简化机理构筑

C3H8是液化石油气（LPG）的主要成分,其火焰结构的数值预测对于消防等相关行业具有重要意义。单步或总包反应过于简单,不能描述碳氢燃料的氧化机制,而耦合燃料详细机理的燃烧模拟计算量大,且描述反应的数学系统具有极强的“刚性”,限制了反应机理的实际应用,而去除冗余反应和组分的简化机理具有描述燃烧的全面性优点,且降低了数学系统的“刚性”,因此耦合简化机理的火焰结构数值预测具有优势。本文采用基于矩阵分析的主成分（PCA）分析技术,分析研究了wang等发展的469步C3H8详细反应动力学机理,获得了组分的重要性排序,基于此分别构筑了320步和214步两个简化机理,针对典型扩散火焰的计算,表明建立的两个简化机理具有较高的模拟可靠性,同时也提供了一种框架简化机理的构筑方法。     

居室天然气泄漏扩散过程仿真研究

随着我国城市环境保护的提高,城市燃料结构也在逐步改变。天然气作为一种清洁、高效的能源已经成为居民应用最广泛的燃料。随着天然气用户的不断增加,其事故次数也在不断上升。为了系统的研究居室内天然气泄漏扩散的过程和发展,预防居民家庭天然气火灾和爆炸事故以及发生事故后的应急提供依据。本文以普通的居民居室为研究对象,建立居室天然气泄漏扩散几何模型。并对室内天然气泄漏后的扩散状态进行仿真模拟,得到天然气泄漏后的室内扩散过程,以及在不同时间内存在爆炸极限的区域和达到爆炸极限的范围,并对爆炸后果进行了评估。结果显示：在设定条件下,泄漏发生后640 s,冰箱电源处达到爆炸下限,790 s时达到爆炸上限;其爆炸能量已达到使大型钢架结构破坏,大部分人员死亡的程度。泄漏1800 s后,可燃区域就扩散到厨房之外,存在于客厅之中了。     

风幕阻止飞机喷漆厂房内可燃气体扩散的数值模拟

应用FLUENT软件中的大涡模拟模型对飞机喷漆厂房内风幕的有效性进行了研究。以某一飞机喷漆厂房内的局部为原型构建网格模型,针对若干种工况,对甲苯蒸气的扩散过程进行了数值模拟,主要研究了甲苯量和风幕速度对甲苯扩散的影响规律。对计算结果进行分析,得到了不同工况下能有效阻止甲苯扩散的临界风幕速度,研究表明在飞机喷漆厂房内设置风幕,只要风幕速度不低于该种工况下的临界风幕速度,就可有效阻止甲苯扩散,降低厂房内可燃气体的爆炸危险性。     

Chemical absorption of carbon dioxide with asymmetrically heated polytetrafluoroethylene membranes

In this study, the absorption of carbon dioxide using an absorbent composed of 2-amino-2-methyl-L-propanol (AMP) + monoethanolamine (MEA) + piperazine (PZ) in asymmetric and symmetric polytetrafluoroethylene (PTFE) membrane contactors was investigated. Experiments were conducted using various gas flow rates, liquid flow rates, and absorbent blends. CO(2) recovery increased with increasing liquid flow rates. The mean pore size of PTFE membrane reduced via heating treatment. An asymmetric membrane had a better CO(2) recovery than a symmetric membrane. For the asymmetric membrane, placing the smaller pore-size side of the membrane in contact with the liquid phase, reduced the level of wetting of the membrane. The membrane mass transfer coefficient and durability of the PTFE membrane were enhanced by asymmetrically heating.     

榆林气田开发技术研究

针对榆林气田单井产能低、气田稳产能力差和生产中出现的低产低效气井难以正常生产等问题,进行了储层改造工艺技术优化研究.通过本项目的开展,有效地解决了影响气田正常生产和安全供气问题,为子洲-米脂气田的高效开发奠定了技术基础.     

Dispersion modeling approach for quantification of methane emission rates from natural gas fugitive leaks detected by infrared imaging technique

Recently, infrared optical imaging has been applied in the oil and gas industry as a method to detect potential leaks in pipelines, components and equipment. The EPA suggested that this impending technique is considered as a smart gas LDAR (leak detection, monitoring and repair) for its rapid recognition of leaks, accuracy and robustness. In addition, compared to the conventional method using Total Vapor Analyzer (TVA) or gas sniffer, it has several other advantages, such as the ability to perform real-time scanning and remote sensing, ability to provide area measurement instead of point measurement, and provide an image of the gas which is not visible to naked eye. However, there is still some limitation in the application of optical imaging techniques; it does not give any measurement of gas emissions rates or concentrations of the leaking gas. Infrared cameras can recognize a target gas and distinguish the gas from its surrounding up to a certain concentration, namely the minimum detectable concentration. The value of the minimum detectable concentration depends on the camera design, environmental conditions and surface characteristics when the measurement is taken. This paper proposed a methodology to predict gas emissions rates from the size of the dispersed gas plume or cloud to the minimum detectable concentration. The gas emissions rate is predicted from the downwind distance and the height of the cloud at the minimum detectable concentration for different meteorological conditions. Gas release and dispersion from leaks in natural gas pipeline systems is simulated, and the results are presented.