CN109507327B

CN109507327B - Quantitative determination of TNT content by GC-AED independent calibration curve method (CIC method)

Info

Publication number: CN109507327B
Application number: CN201811601520.2A
Authority: CN
Inventors: 刘红妮; 张皋; 苏鹏飞; 罗西; 王歌杨; 胡银; 杨彩宁; 陈曼; 温晓燕
Original assignee: Xian Modern Chemistry Research Institute
Current assignee: Xian Modern Chemistry Research Institute
Priority date: 2018-12-26
Filing date: 2018-12-26
Publication date: 2021-11-23
Anticipated expiration: 2038-12-26
Also published as: CN109507327A

Abstract

The invention discloses an irrelevant correction curve method (CIC method) for quantitatively determining TNT content of GC-AED. The chromatographic column used in the disclosed gas chromatographic analysis method is an HP-5 weak polarity capillary column, the temperature of a sample inlet is 200 ℃, the temperature of a column incubator is 180 ℃, the split ratio is 20:1, the sample injection amount is 0.5uL, and the column flow rate is 3 mL/min. The AED parameters were: the temperature of the transmission line is 220 ℃ and the temperature of the cavity is 250 ℃; the detection element used is C, the wavelength is C193 nm; the reaction gas used is O₂，H₂(ii) a The pressure of the supplementary gas He is 200 KPa. The quantitative detection method of TNT disclosed is to use chromatographic analysis method to respectively carry out 2 pairs^#Analysis of neutraceuticals and TNT, using AED Detector Pair 2^#Detection of the C elements of the mesogen and TNT at a detection wavelength of C193nm and 2^#Calculating the content of the C element of the TNT by taking the content of the C element of the medium reagent as a standard so as to obtain the content of the TNT compound. The element chromatographic analysis method has good peak shape, and the compound is quantitatively prepared from a non-self and non-energetic standard sample, so that the accuracy is high and the repeatability is strong.

Description

Quantitative determination of TNT content by GC-AED independent calibration curve method (CIC method)

Technical Field

The invention belongs to the technical field of explosives and powders, and particularly relates to a quantitative determination method of 2.4.6-trinitrotoluene (TNT) by using a gas chromatography-atomic emission spectrometry method (CIC method) through an irrelevant correction curve method.

Background

The qualitative and quantitative analysis of organic components in explosives and powders is one of the core work contents of physicochemical detection researchers, and comprises the qualitative and quantitative analysis of unknown substances in the synthesis process of energetic materials and the quantitative analysis of organic components in the formula of explosives and powders products. At present, the qualitative and quantitative determination of organic impurities in compounds mainly adopts Mass Spectrometry (MS), infrared spectroscopy (FTIR), Nuclear Magnetic Resonance (NMR), chromatography (GC/LC) and the like; the quantitative analysis of the components of the organic matters in the gunpowder generally adopts a solvent extraction method and then adopts a chromatographic external standard method or an internal standard method for quantitative analysis. However, the above techniques require a compound standard spectrum or a standard substance of the object to be detected as a support to achieve quantification, and accurate quantitative detection of the object cannot be achieved under the conditions that the chemical structure of impurities is unclear and a standard sample is difficult to prepare.

Therefore, a new quantitative detection method for energetic materials without a standard sample needs to be developed for solving the problem that the traditional detection method needs a standard substance per se. At present, no relevant technical report exists about quantitative detection of explosive components without self standard samples.

Gas chromatography-atomic emission spectrometry (GC-AED) uses an element-selective detector whose peak area of the element signal is proportional to the mass of the element in the composition, regardless of the molecular structure of the element, and a known standard compound containing the element being measured can be used in quantitative analysis to correct compounds containing the same element, a method that is unique to GC-AED, the CIC of compounds.

In addition, energetic compounds have the characteristics of flammability, explosiveness and high sensitivity, and if the energetic compounds are used as standard substances, certain potential safety hazards exist in the transportation process of the compounds, so that quantitative analysis of explosive components by using non-self and non-energetic compounds is a technical problem to be overcome in the field.

2^#The chemical name of the stabilizer is dimethyl diphenyl urea, which is an organic chemical and is commonly used as a gunpowder stabilizerOr as intermediates for fine chemicals, which do not contain C-NO in their structure₂、N-NO₂、O-NO₂、N₃N ═ N, and other energy-containing groups. The invention uses non-energetic material 2^#And the middle determination agent is a standard substance, GC-AED is adopted to carry out research on a TNT quantitative detection method without self standard sample, the research on the wavelength selection of C element, chromatographic separation condition and AED condition optimization is carried out, accurate quantitative experimental data of the element in the TNT is obtained, the content of the TNT compound is further measured, and a novel method for quantitatively detecting the TNT by adopting non self standard sample and non-energetic material is established.

Disclosure of Invention

One of the objects of the present invention is to provide a 2^#A GC-AED (gas chromatography-AED) C element chromatography method of a neutralizing agent and TNT (trinitrotoluene).

Therefore, the chromatographic column used in the chromatographic analysis method provided by the invention is HP-5, the temperature of a sample inlet is 200 ℃, the temperature of a column incubator is 180 ℃, the split ratio is 20:1, the sample injection amount is 0.5uL, and the flow rate of the column is 3 mL/min.

The AED parameters were: the transmission line temperature is 220 ℃ and the cavity temperature is 250 ℃. The detection element used is C, the wavelength is C193 nm; the reaction gas used is O₂，H₂(ii) a The pressure of the supplementary gas He is 200 KPa.

Another objective of the present invention is to provide a method for quantitatively detecting TNT.

The quantitative TNT detecting method includes the first analysis of two compounds with the chromatographic analysis method and the subsequent detection of C element content in two compounds with the chromatographic signal of C element channel of AED detector.

By 2^#The medium reagent is used as a standard substance, acetone is used as a solvent to prepare 2 solutions with the concentration of 26.5625ug/mL, 53.125ug/mL, 212.5ug/mL, 425ug/mL and 850ug/mL respectively^#Standard solutions of the medium, 2 for each concentration^#Repeat 6 injections of the standard solution of the mediator, determine the peak area of the chromatogram for each concentration using the C (193nm) channel of the GC-AED, and average the peak area of the C element to 2^#Linear fitting of the concentration of element C in the fixative, i.e. 2^#-independent calibration curves (CIC curves), curves and curves for the C element in the fixativeThe equations are shown in figure 1. In order to verify the accuracy and precision of the method, TNT standard solutions of 162ug/mL, 810ug/mL and 1620ug/mL were prepared, and each concentration was injected for 6 times, and 2 times was used^#Calculating the detection concentration of the C element by using a CIC curve equation of the C element in the neutralization reagent, and calculating the standard recovery rates of the method to be 94.6%, 99.7% and 101.3% respectively according to the detection concentration and the theoretical concentration of the C element, thereby showing that the method has good accuracy; the precision of the method is shown by Relative Standard Deviation (RSD) of the C element peak area, and RSD of the C element peak area under three concentration conditions is respectively 0.3%, 0.5% and 0.7%, which shows that the precision of the method is good.

GC-AED measurement of known concentrations of TNT formulated gave the peak area for element C, 2^#And calculating the peak area by using a CIC curve of the medium reagent to obtain the concentration of the C element of the TNT, further obtaining the concentration of the TNT compound, and comparing the calculated concentration of the TNT with the theoretical concentration to obtain a relative error. The TNT compound was quantitated and its relative error was calculated.

The TNT quantitative detection method provided by the invention has the advantages of good carbon element chromatographic peak shape, good separation degree, high accuracy and strong repeatability; in addition, the method adopts non-energetic materials and non-self-standard substances 2^#The quantitative determination of the C element is carried out by the medium-concentration reagent, so that the quantitative determination of the TNT component is completed, the problem of lack of standard substances in a laboratory is solved, a referable thought is provided for the subsequent quantitative determination of a plurality of organic matters containing the same element by using non-self and non-energy-containing standard substances, and the major safety risk existing in the transportation of energy-containing materials can be avoided.

Drawings

FIG. 12^#CIC plot of the C element in the fixative

FIG. 2C 193nm elemental analysis chart for TNT

FIG. 32^#Elemental analysis (C193 nm) plot of the intermediate reagent

FIG. 4 is a C193nm elemental analysis chart of TNT in an explosive formulation

Detailed Description

The separation and quantitative detection method of the invention is mainly carried out on a GC-AED instrument, and a sample passes through HP-5 weakly polar chromatography column, 2^#The median and TNT appeared separately and then according to 2^#-CIC curve equation for the median fixative and intensity of TNT flow through the detector signal to quantify TNT. The method can realize accurate quantification of TNT.

The following are examples provided by the inventors to further illustrate the technical solution of the present invention.

Example 1:

the experimental apparatus of this example:

an Agilent 7890A gas chromatograph, an autosampler with a 16-bit sample rotating stand, a JAS AED II Plus type multi-element detector and JAS multi-element detector software.

Test conditions for this example:

a chromatographic column: HP-5 chromatography column;

sample inlet temperature: 200 ℃;

column temperature: 180 ℃;

the split ratio is as follows: 20: 1;

sample introduction amount: 0.5 uL;

flow rate: 3 mL/min;

AED detector transmission line temperature: 220 ℃;

AED detector cavity temperature: 250 ℃;

detection wavelength of element C: c193 nm;

the reaction gas being O₂，H₂；

The pressure of the supplementary gas He is 200 KPa.

Preparing a TNT solution of 810ug/mL by using acetone as a solvent; sample introduction volume: 0.5 uL; after the instrument is stabilized, sample introduction is carried out for 6 times, and the average value of the peak area is obtained according to the reference 2^#And obtaining the concentration of the C element of the TNT by a CIC curve equation of the medium reagent, and further obtaining the concentration of the compound of the TNT.

TNT and 2 in this example^#The results of GC-AED elemental chromatography detection of the-fixative are shown in FIGS. 2 and 3.

The results of the quantitative determination of the sample to be tested in this example are as follows: the average value of the peak area of the C element in the TNT is 27239.03, the detection concentration of the C element in the TNT is 298.86ug/mL through calculation of a CIC curve equation, the detection concentration of the TNT can be 807.63ug/mL according to the detection concentration of the C element in the TNT, the known theoretical concentration of the TNT is 810ug/mL, and therefore the relative error is 0.29%.

Example 2:

the experimental equipment and test conditions used in this example were the same as in example 1.

The sample tested in this example was an explosive formulation of TNT, dinitrofurazan-based furazan (DNTF) and Benzotrifurannitroxide (BTF), where the conventional test method for TNT is a liquid chromatography external standard method requiring TNT standard materials. The method established by this study can be used with 2's of non-self, non-energetic materials^#-the intermediate reagent is used as a standard sample for the determination of the TNT content of the explosive formulation.

The pretreatment steps of the sample are as follows: weighing 0.2g of sample into a clean and dry 50mL volumetric flask, adding 30mL of acetone, plugging a bottle stopper, performing ultrasonic treatment until the solution is completely dissolved, performing constant volume to a scale mark by using the acetone, and uniformly mixing. Filtering with organic solvent filter, and analyzing by sample injection. The chromatographic separation pattern of the C element of the sample is shown in FIG. 4. Wherein peak No. 2 is the peak given by TNT. The peak areas of the two samples were measured in parallel and averaged to be 14400.44, 14202.34, respectively.

According to 2^#And (4) calculating the concentration of the C element of the TNT according to the CIC curve equation y of the median fixative 92.227x-323.570, and further obtaining the concentration of the compound of the TNT. And further calculating to obtain the mass percentage content of TNT in the explosive formula. The experimental data are shown in table 1. As can be seen from Table 1, the TNT content calculated by the method is substantially consistent with the theoretical dosage.

TABLE 1 determination of TNT content in certain explosive formulations

Claims

1. A method for quantitatively determining TNT content by a CIC method of a GC-AED irrelevant correction curve method is characterized in that a chromatographic column used in the method is an HP-5 weak polarity capillary column, the temperature of a sample inlet is 200 ℃, the temperature of a column incubator is 180 ℃, the split ratio is 20:1, the sample volume is 0.5 mu L, and the flow rate of the column is 3 mL/min;

the AED parameters were: the temperature of the transmission line is 220 ℃ and the temperature of the cavity is 250 ℃; the detection element used is C, the wavelength is C193 nm; the reaction gas used is O₂，H₂(ii) a The pressure of the supplementary gas He is 200KPa and 2^#-the fixative is a standard.

2. The method for measuring the TNT content of claim 1,

at different concentrations 2^#-the C content of the fixative is plotted against the corresponding C element chromatographic peak area, 2^#The linear equation for C in the fixative isy=92.227x-323.570，R²= 0.9998; the standard recovery rates of the C element concentration when the TNT concentration is 162 mu g/mL, 810 mu g/mL and 1620 mu g/mL are respectively 94.6%, 99.7% and 101.3%; the precision was expressed as relative standard deviation RSD, and RSD of the C element peak area was 0.3%, 0.5%, 0.7% for each of the three concentrations.

3. The method for determining the content of TNT according to claim 1, characterized in that the two components are analyzed separately:

is expressed by 2^#-a series of 2 with different concentrations prepared with a medium reagent as a standard and acetone as a solvent^#-a standard solution of a fixative, the elemental chromatographic peak area at the corresponding concentration being measured using the C193 channel of the GC-AED;

② by peak area pair 2^#C content of the median, plotted 2^#-an irrelevant correction curve CIC curve for the fixative;

③ GC-AED for measuring the area of peak obtained by formulating TNT with known concentration, 2^#And calculating the peak area by using a CIC curve of the medium reagent to obtain the C content of the TNT, further obtaining the content of the TNT compound, and comparing the TNT content obtained by calculation with the known concentration to obtain a relative error.