密闭舱内VOCs现场快速定量检测技术与装置研究

该文发展了可对压强变化的密封舱实现计量采样-富集的采样技术,基于薄壳金属筒式低功耗均温色谱柱组件,结合微池热导检测器/小型氢火焰离子化检测器,建立了一种对密闭舱内挥发性有机物(VOCs)进行现场快速定量检测的方法和装置。根据负压罐和密封舱的压强差值和绝压值以及温度,计算出有效采样体积(折算到标准大气压),进而计算出富集倍数。当有效采样体积为100 mL时,对甲苯的富集倍数大于400倍。所研制的色谱柱组件将色谱柱紧密排绕在薄壳式金属筒外层,加热丝紧密排绕在金属筒内侧,可实现小于0.4℃的均温效果和40℃/min的程序升温速率。在以10℃/min加热至300℃过程中,功耗低于35 W,300℃恒温加热功率仅需28 W。将色谱柱组件的分离性能(包括半峰宽、柱效、分离度和重复性)与实验室进口色谱仪炉箱得到的结果进行对比,发现两种加热方式得到的色谱分离性能相当。采用多种VOCs样品对采样-富集性能进行评价。在高速分离模式下,5 min内可实现53种VOCs的快速分离,半峰宽均小于0.8 s。研制出的整机已应用于烃类、苯系物、醇类、醛酮类等多种VOCs的快速分析,并与商品化便携式气相色谱或气相色谱-质谱的性能参数进行了对比,结果满意。     

应用裂解气相色谱对生物质快速裂解反应条件的研究

采用现代化学分析领域中重要的分析方法 -裂解气相色谱法 ,对生物质的快速裂解进行了探索性研究。以杨木木屑为研究对象 ,在裂解温度 40 0～ 80 0℃ ,升温速率 1 0 0℃ s、2 50℃ s、50 0℃ s,挥发性产物停留时间 0 6～4 0s的裂解条件下 ,考察了杨木木屑快速裂解气、液、固三种产物及气相组分的分布规律。实验结果表明 ,气、液、固三种产物所占比例及其组分含量取决于裂解条件 -裂解温度、挥发份停留时间和升温速率 ,杨木在升温速率50 0℃ s、挥发性产物停留时间 0 6s、裂解温度 50 0℃下快速裂解 ,可获得最大的产液率 80 % (含水 )。物料平衡的结果证明了裂解色谱研究方法的有效性和可行性。     

快速气相色谱控制系统的设计与应用

设计了一种用于快速气相色谱(Fast gas chromatography,FGC)的新型控制系统。该控制器主要由色谱柱温度控制系统、自动进样及气路压力控制系统组成。其温度控制范围为30~160℃,升温速度约为3℃/s,温度控制精度为±0.5℃,载气压力控制范围为0~0.5 MPa。将本控制器应用于自制快速色谱,并用色谱对由直链正构烷烃(C1~C8)以及甲苯9种物质组成的标准样品进行测试。结果显示,色谱能在100 s内将此9种物质完全分开。     

快速气相色谱法分析白酒中的香味组分

中国的传统白酒里含有多种香味组分,包括醇类、醛类、酸类和酯类,它们的比率决定着白酒的香型和品质。这些组分可以使用气相色谱仪进行很好的分析并定性和定量。为了缩短分析时间,建立了一种快速检测白酒中香味组分的气相色谱法。采用该方法,用20 m×0.1 mm×0.1 μm的熔融石英毛细管柱在12 min之内完成了对白酒中香味组分的分析,分析时间只是传统色谱方法的三分之一。该方法的重现性良好。     

垃圾衍生燃料等温快速热解和燃烧反应特性

利用热天平和管式炉对RDF(Refuse Derived Fuel)等温快速热解和燃烧反应特性进行了研究。实验发现，在等温快速升温的条件下，RDF热解和燃烧的反应速率都非常快，从受热开始到反应结束需60 s～80 s;从开始失重到完成反应为20 s。RDF热解和燃烧热重反应曲线非常类似，都只有一个反应失重区;RDF组成对其燃烧和热解反应性有重要影响，含有橡胶的RDF的热解和燃烧反应速率较小。在650 ℃～800 ℃RDF快速热解产物中气、液产物的产率可达80%～90%，而固体产物的产率只有10%～20%，热解气体的热值为20kJ/m3，RDF较适合进行热解处理。     

奥克托金(HMX)的T-Jump/FTIR快速热裂解研究

采用T-Jump/FTIR快速热裂解原位红外光谱联用技术研究了奥克托金(HMX)在0.1,0.2,0.3和0.4MPa的Ar气条件下,以1000℃·s-1的升温速率快速升温至设定的反应温度,用快速扫描傅立叶变换红外光谱跟踪分析分解产物的种类和相对摩尔浓度的变化,研究了温度及压力对初始检测产物的影响.结果表明,HMX在快速热裂解5s过程中红外所检测到的主要气相产物为CO,CO2,NO,NO2,N2O,HCONH2,CH2O,H2O,HNCO及HCN,并给出了这些产物相对摩尔浓度随时间变化的曲线.根据气体产物相对摩尔浓度的比率N2O/HCN,研究了压力和反应温度对HMX的快速热裂解过程及机理的影响,认为在低温HMX分解的C—N键断裂在两竞争反应中占优,通过压力的变化证明了气相产物之间存在二次反应.     

高分辨热裂解气相色谱/质谱法快速定性检测农产品中的单增李斯特菌

要在高分辨率热裂解气相色谱/质谱(HRPGC/MS)系统中采用选择离子检测法(SIM),建立了准确可靠、灵敏度高、快速简便的检测农产品中单增李斯特菌的方法.裂解条件:起始温度50℃;升温速率20℃/min,裂解室温度230℃;裂解温度650℃;裂解时间为10 s.气相色谱条件:载气为氦气;恒定流速0.9 mL/min;DB-WAXTER毛细管色谱柱;起始温度45℃;保持4min,以6℃/min的速率上升到100℃,然后以10℃/min上升到200℃,接着以12℃/min上升至250℃,并保持25 min.分流比为50∶1.EI离子源.选择色谱保留时间19.056 min,鉴别离子m/z 54,98,用于SIM检测.通过对单增李斯特菌、2种空白农产品和2种不同农产品污染单增李斯特菌的样品检测结果表明,HRPGC/MS方法检测不同黄瓜、牛肉农产品中单增李斯特菌,均能得到很好的反映.本方法分析时间缩短,用保留时间、质谱同时定性,消除了不同种类农产品杂质的干扰,结果准确可靠,选择性和重复性好,适于快速检测农产品中的单增李斯特菌.     

一种用于食品中二氧化硫快速测定的样品前处理方法

提出了一种采用半微量蒸馏-半导体制冷技术的食品中二氧化硫快速提取的新方法, 研制出了可在15 min内完成二氧化硫提取的食品检测快速蒸馏提取装置. 采用本装置,  无需冷凝水和含汞吸收剂即可实现对样品中二氧化硫的蒸馏提取. 考察了蒸馏液酸度、   蒸馏液体积、 馏分收集体积和蒸馏提取时间对二氧化硫提取效率的影响. 研究结果表明,  采用该方法在30 min内即可完成对食品中二氧化硫的快速定量测定.     

顶空-气相色谱-质谱法分析线叶旋覆花不同入药部位中挥发性成分的差异

将线叶旋覆花两个入药部位分开裁剪,用水洗净后干燥、粉碎,过孔径为0.25 mm筛网。分取0.02 g粗粉于20 mL顶空瓶中,于120℃加热30 min。所得挥发性成分进入气相色谱仪,以DB-5色谱柱在程序升温条件下分离,用配电子轰击离子源的质谱仪检测,以保留时间、碎片离子峰定性,以面积归一化法定量。结果显示：从线叶旋覆花中鉴定出的挥发性成分分别有46种(茎叶中)和30种(花中),其峰面积占总挥发性成分峰面积的71.11%,99.98%。花和茎叶中共有挥发性成分有8种,特有挥发性成分有22,38种;茎叶中挥发性成分包括烯烃类、酸类、醇类、醛类、烷烃类、芳香烃类、酯类、酮类和其他类化合物各13,5,4,9,7,2,3,2,1种,相对含量分别为18.11%,17.32%,12.16%,8.76%,4.05%,0.41%,0.80%,0.32%,9.18%;花中挥发性成分包括烯烃类、醇类、醛类、芳香烃类和其他类化合物各18,2,5,2,3种,相对含量分别为52.67%,29.35%,11.50%,2.07%,4.39%。不同入药部位中活性成分烯烃类化合物相对含量均较高,挥发性成分的种类和相对...     

利用快速定氮装置测定氮

一般化验室普遍使用的全量蒸馏装置 [1] (直接加热吸收 ) ,具有准确、重现性好的特点 ,但操作费时。半微量蒸馏装置 [2 ] (水蒸气加热吸收 )具有快速方便的特点 ,但对高含量的含氮样品 ,测定精密度稍差。以上两种装置需用冷凝管通水冷却 ,加热蒸馏吸收和滴定均分二步进行 ,比较麻烦和费时。作者装配的加热抽气吸收测定氮的装置 ,集加热蒸馏吸收滴定于一体 ,不用冷凝管 ,测定速度较快 ,但在操作过程中需经常更换反应瓶 ,而且 Na OH浓度过大 ,容易腐蚀玻璃瓶。本文将水蒸气加热蒸馏装置和抽气吸收滴定装置结合起来 ,组成一套快速可连续测定…     

Fast temperature programming on a stainless-steel narrow-bore capillary column by direct resistive heating for fast gas chromatography

A direct resistive-heating fast temperature programming device for fast gas chromatography was designed and evaluated. A stainless-steel (SS) capillary column acted both as a separation column and as a heating element. A fast temperature controller with the deviation derivative proportional-integral-derivative (DDPID) control algorithm, which was suitable for ramp control using ramp-to-setpoint function, was used to facilitate the fast pulse heating. The SS resistive-heating column can generate linear temperature ramps up to 10 degrees C/s and can re-equilibrium from 250 degrees C down to 50 degrees C within 30s. With n-alkanes as the test analytes, the relative standard deviations (RSDs) of retention time were between 0.19 and 0.59% and the RSDs of their peak areas were less than 4% for all but one. The results indicated that this technique could be used for both qualitative and quantitative analysis. Phenolic and nitroaromatic compounds were also analyzed by using the SS resistive-heated system. The combination of a short narrow-bore SS column and rapid heating rates provides sufficient separation efficiency for relatively simple mixtures at drastically reduced analysis time. The total analysis time including equilibration time was less than 2 min for all test mixtures in this study.     

A direct resistively heated gas chromatography column with heating and sensing on the same nickel element

Nickel clad or nickel wired fused silica column bundles were constructed and evaluated. The nickel sheathing or wire functions not only as the heating element for direct resistive heat, but also as the temperature sensor, since nickel has a large resistive temperature coefficient. With this method the temperature controller is able to apply power and measure the temperature simultaneously on the same nickel element, which can effectively avoid the temperature overshoot caused by any delayed response of the sensor to the heating element. This approach also eliminates the cool spot where a separate sensor touches the column. There are some other advantages to the column bundle structure: (1) the column can be heated quickly because of the direct heating and the column's low mass, shortening analysis time. We demonstrate a maximum heating rate of 13 °C/s (800 °C/min). (2) Cooling time is also short, increasing sample throughput. The column drops from 360 °C to 40 °C is less than 1 min. (3) Power consumption is very low – 1.7 W/m (8.5 W total) for a 5 m column and 0.69 W/m (10.4 W total) for a 15 m column when they are kept at 200 °C isothermally. With temperature programming, the power consumption for a 5 m column is less then 70 W for an 800 °C/min ramp to 350 °C. (4) The column bundle is small, with a diameter of only about 2.25 in. All these advantages make the column bundle ideal for fast GC analysis or portable instruments. Column efficiencies and retention time repeatability have been evaluated and compared with the conventional oven heating method in this study. For isothermal conditions, the column efficiencies are measured by effective theoretical plate number. It was found that the plate number with resistive heat is always less than with oven heat, due to uneven heat in the column bundle. However, the loss is not significant – an average of about 1.5% for the nickel clad column and 4.5% for the nickel wired column. Separation numbers are used for the comparison with temperature programming, with results similar to those observed for isothermal conditions. Retention time repeatability for direct heat were 0.010% RSD for isotheral and 0.037% RSD for temperature programming, which is similar to those obtained by oven heat. Applications have been demonstrated, including diesel and PAH analysis.     

Fast Temperature Programming in Gas Chromatography using Resistive Heating

The features of a resistive-heated capillary column for fast temperature-programmed gas chromatography (GC) have been evaluated. Experiments were carried out using a commercial available EZ Flash GC, an assembly which can be used to upgrade existing gas chromatographs. The capillary column is placed inside a metal tube which can be heated, and cooled, much more rapidly than any conventional GC oven. The EZ Flash assembly can generate temperature ramps up to 1200°/min and can be cooled down from 300 to 50°C in 30 s. Samples were injected via a conventional split/splitless injector and transferred to the GC column. The combination of a short column (5 m×0.25 mm i. d.), a high gas flow rate (up to 10 mL/min), and fast temperature programmes typically decreased analysis times from 30 min to about 2.5 min. Both the split and splitless injection mode could be used. With n-alkanes as test analytes, the standard deviations of the retention times with respect to the peak width were less than 15% (n = 7). First results on RSDs of peak areas of less than 3% for all but one n-alkane indicate that the technique can also be used for quantification. The combined use of a short GC column and fast temperature gradients does cause some loss of separation efficiency, but the approach is ideally suited for fast screening as illustrated for polycyclic aromatic hydrocarbons, organophosphorus pesticides, and triazine herbicides as test compounds. Total analysis times – which included injection, separation, and equilibration to initial conditions – were typically less than 3 min.     

Possibilities and Limitations of Fast Temperature Programming as a Route towards Fast GC

One possible way to speed up a gas chromatographic analysis is the application of fast temperature programming by using resistive heating techniques. With this heating technique programming rates up to 20° per second can be reached. A relative standard deviation of retention times better than 0.2% is obtained. Using fast temperature programming the analysis-times of a mineral oil sample, an industrial oligomer sample, and toxic compounds in diesel fuel have been reduced 5 to 20 times, compared to a standard temperature programmed analysis. In most cases resistive heating cannot be applied to reduce the analysis time of a complex sample. The use of fast temperature programming is preferable to the use of short columns and columns operated at above-optimum carrier gas velocities.     

Fast Capillary Gas Chromatography: Comparison of Different Approaches

Savings in analysis time in capillary GC have always been an important issue for chromatographers since the introduction of capillary columns by Golay in 1958. In laboratories where gas chromatographic techniques are routinely applied as an analytical technique, every reduction of analysis time, without significant loss of resolution, can be translated into a higher sample throughput and hence reduce the laboratory operating costs. In this contribution, three different approaches for obtaining fast GC separations are investigated. First, a narrow-bore column is used under conventional GC operating conditions. Secondly, the same narrow-bore column is used under typical fast GC conditions. Here, a high oven temperature programming rate is used. The third approach uses a recent new development in GC instrumentation: Flash-2D-GC. Here the column is placed inside a metal tube, which is resistively heated. With this system, a temperature programming rate of 100°/s is possible. The results obtained with each of these three approaches are compared with results obtained on a column with conventional dimensions. This comparison takes retention times as well as plate numbers and resolution into consideration.     

Determination of sulfonamides and trimethoprim using high temperature HPLC with simultaneous temperature and solvent gradient

A fast HPLC method for the analysis of eight selected sulfonamides (SA) and trimethoprim has been developed with the use of high temperature HPLC. The separation could be achieved in less than 1.5 min on a 50 mm sub 2 microm column with simultaneous solvent and temperature gradient programming. Due to the lower viscosity of the mobile phase and the increased mass transfer at higher temperatures, the separation could be performed on a conventional HPLC system obtaining peak widths at half height between 0.6 and 1.3 s.     

Fast HPLC method for the determination of glimepiride, glibenclamide, and related substances using monolithic column and flow program

This work presents a fast method for the simultaneous separation and determination of glimepiride, glibenclamide, and two related substances by RP LC. The separation was performed on a Chromolith Performance (RP-18e, 100 mm x 4.6 mm) column. As mobile phase, a mixture of phosphate buffer pH 3, 7.4 mM, and ACN (55:45 v/v) was used. Column oven temperature was set to 30 degrees C. The total chromatographic run time was 80 s. This was achieved using a flow program from 5 to 9.9 mL/min. Precisions of the interday and the intraday assay for both retention times and peak areas for the four analyzed compounds were less than 1.2%. The method showed good linearity and recovery. The short analysis time makes the method very valuable for quality control and stability testing of drugs and their pharmaceutical preparations.     

A low thermal mass fast gas chromatograph and its implementation in fast gas chromatography mass spectrometry with supersonic molecular beams

A new type of low thermal mass (LTM) fast gas chromatograph (GC) was designed and operated in combination with gas chromatography mass spectrometry (GC-MS) with supersonic molecular beams (SMB), including GC-MS-MS with SMB, thereby providing a novel combination with unique capabilities. The LTM fast GC is based on a short capillary column inserted inside a stainless steel tube that is resistively heated. It is located and mounted outside the standard GC oven on its available top detector port, while the capillary column is connected as usual to the standard GC injector and supersonic molecular beam interface transfer line. This new type of fast GC-MS with SMB enables less than 1 min full range temperature programming and cooling down analysis cycle time. The operation of the fast GC-MS with SMB was explored and 1 min full analysis cycle time of a mixture of 16 hydrocarbons in the C(10)H(22) up to C(44)H(90) range was achieved. The use of 35 mL/min high column flow rate enabled the elution of C(44)H(90) in less than 45 s while the SMB interface enabled splitless acceptance of this high flow rate and the provision of dominant molecular ions. A novel compound 9-benzylazidanthracene was analyzed for its purity and a synthetic chemistry process was monitored for the optimization of the chemical reaction yield. Biodiesel was analyzed in jet fuel (by both GC-MS and GC-MS-MS) in under 1 min as 5 ppm fatty acid methyl esters. Authentic iprodion and cypermethrin pesticides were analyzed in grapes extract in both full scan mode and fast GC-MS-MS mode in under 1 min cycle time and explosive mixture including TATP, TNT and RDX was analyzed in under 1 min combined with exhibiting dominant molecular ion for TATP. Fast GC-MS with SMB is based on trading GC separation for speed of analysis while enhancing the separation power of the MS via the enhancement of the molecular ion in the electron ionization of cold molecules in the SMB. This paper further discusses several features of fast GC and fast GC-MS and the various trade-offs involved in having powerful and practical fast GC-MS.     

Fast supercritical fluid chromatography using capillaries packed with nonporous particles

Summary Packed columns containing microparticles provide high column efficiency per unit time and strong retention characteristics compared with open tubular columns, and they are favored for fast separations. Nonporous particles eliminate the contribution of solute mass transfer resistance in the intraparticle void volume characteristic of porous particles, and they should be more suitable for fast separations. In this paper, the evaluation of nonporous silica particles of sizes ranging from 5 to 25 μm in packed capillary columns for fast supercritical fluid chromatography (SFC) using neat CO₂ is reported. These particles were first deactivated using polymethyl-hydrosiloxanes and then encapsulated with a methylphenylpolysiloxane stationary phase. The retention factors, column efficiencies, column efficiencies per unit time, separation resolution, and separation resolution per unit time for fast SFC were determined for various length capillaries packed with various sizes of polymerencapsulated nonporous particles. It was found that 15 μm nonporous particles provided the highest column efficiency per unit time and resolution per unit time for fast packed capillary SFC. Under certain conditions, separations were completed in less than 1 min. Several thermally labile silylation reagent samples were separated in times less than 5 min. Presented at the 21^st ISC held in Stuttgart, Germany, 15^th–20^th September, 1996