CN217007145U - Essence composition artificial sniffing device synchronous with instrument analysis - Google Patents

Abstract

The utility model discloses an artificial smell device for essence components synchronous with instrument analysis, belonging to the technical field of analysis and detection devices. The device has the characteristics of simple and convenient operation, flexible detection, accurate synchronization, easy verification, low cost and less manual smell interference, the double sample inlets of the gas chromatograph are respectively connected with two identical chromatographic columns, the tail end of one chromatographic column is connected with a mass spectrometer for mass spectrum analysis of essence components, the tail end of the other chromatographic column extends out of the external connection smell cover and synchronously heats the external part of the column box by a transmission pipe, and the synchronous push rod is used for realizing simultaneous sample introduction, thereby ensuring the synchronous separation of the essence components on the two chromatographic columns. The method effectively ensures that the same separated compounds obtained on the chromatographic column can reach the mass spectrum and the human nose at the same time, helps researchers to quickly and reliably determine the compounds and evaluate olfactory information, accurately identifies the odor active compounds of the essence and the spice, and provides a more stable, reliable and convenient technical means for the research of distinguishing, imitating and creating fragrance.

Description

Essence composition artificial sniffing device synchronous with instrument analysis

Technical Field

The utility model belongs to the technical field of analysis and detection devices, and particularly relates to an essence component artificial sniffing device synchronous with instrument analysis.

Background

The principle is that a shunt port is arranged at the tail end of a gas chromatographic column, one part of components separated by a capillary column enters a detector for detection and analysis according to a certain shunt ratio, the other part of the components enters an smelling end for on-line smelling, active ingredients of the odor are described by combining some analysis methods, and the odor intensity is recorded, so that the odor detector is a technical means for detecting effective flavor compounds.

Gas chromatography-olfactometry-mass spectrometry (GC-O-MS) is a typical representative of the above technology, and is a method for identifying aroma components by combining the separation ability of gas chromatography with human olfaction and determining characteristic aroma components. In recent years, GC-O-MS technology has been widely applied to the research of various food aroma components, blended fruit juice can be rapidly distinguished from natural fruit juice through aroma component identification, and aroma characteristics can be characterized by combining an odor activity value and sensory evaluation. Thus, the trend of identifying aroma components by using instrumental analysis is shown. The type and content of the aroma components are not only one of the important factors influencing the intrinsic quality of the essence, but also the basis of the evaluation and application of the essence.

The GC-O-MS technology is mainly characterized in that a branch port is additionally arranged at the tail end of a chromatographic column, so that a mass spectrum and an artificial smelling port can obtain a compound to be analyzed from the same chromatographic column, but under the condition of limited bearing capacity of the chromatographic column, the mass spectrum and the artificial smelling port can not completely obtain all the compounds, and the response intensity is reduced. Meanwhile, the shunt port additionally arranged in the column box can generate temperature change along with the temperature rise program of the column box, so that the actual shunt can be unstable, and further, system errors can be generated in the evaluation of mass spectrum response intensity and artificial smell intensity. Therefore, it is necessary to develop a more convenient and stable artificial smell device and a synchronous method for essence components synchronous with instrument analysis, so that the analyte can be separated and analyzed synchronously on two identical chromatographic columns, and the device and the method play an important role in the research of distinguishing and imitating the fragrance of the essence and the spice.

SUMMERY OF THE UTILITY MODEL

The utility model provides an artificial smell device and a synchronous method for essence components synchronous with instrument analysis.

The utility model aims to provide an essence component artificial smell device and a synchronization method, which are simple and convenient to operate, flexible to detect, accurate and synchronous, easy to verify, low in instrument modification cost and less in artificial smell interference.

The utility model aims to connect two identical chromatographic columns by using double sample inlets of a gas chromatograph respectively, wherein the tail end of one chromatographic column is connected with a mass spectrometer for performing mass spectrometry of essence components, and the tail end of the other chromatographic column extends out of a column box and is connected with a smell cover.

The utility model aims to synchronously heat the chromatographic columns outside the column box by using the transmission pipe and realize simultaneous sample injection by using the synchronous push rod, thereby ensuring the synchronous separation of essence components on the two chromatographic columns.

The utility model aims to debug and verify the synchronism of a mass spectrum detection signal and artificial olfaction information by using a synchronization method and ensure that the same compound separated on a chromatographic column can reach a mass spectrum and a human nose at the same time.

The utility model aims to utilize an artificial smelling device and a synchronization method to help researchers to quickly and reliably evaluate the smell information of a compound, accurately identify the smell active compound of essence and spice and provide a more stable, reliable and convenient technical means for the research of distinguishing, imitating and creating fragrance.

In order to achieve the purpose, the utility model adopts the following technical scheme:

an essence composition artificial smell device synchronous with instrumental analysis, includes: the device comprises a separation unit, a detection unit and an artificial sniffing unit;

the separation unit is a gas chromatograph used for separating essence components, and is provided with two chromatographic columns, a chromatographic column A and a chromatographic column B, the upper part of a column box is additionally provided with a column box outlet and is connected with a transmission pipe, and one end of the transmission pipe, which is arranged outside the column box, is communicated with a smell cover; the front end of the chromatographic column A is connected with a sample inlet A, and the tail end of the chromatographic column A is connected with an ionization chamber of a mass spectrometer through a mass spectrum transmission rod; the front end of the chromatographic column B is connected with a sample inlet B, and the tail end of the chromatographic column B extends out of the column box from the outlet of the column box and reaches the sniffing cover through a transmission pipe; the sample inlet A and the sample inlet B are independently injected by a sample injection needle A and a sample injection needle B respectively, and the sample injection operation is synchronously completed under the pushing of a synchronous push rod;

the detection unit is a detection instrument for combining a mass spectrometer and a gas chromatograph; for qualitative and quantitative detection of the compounds separated on the chromatographic column; an ionization chamber is arranged in the mass spectrometer

The manual sniffing unit comprises a transmission pipe, a controller, an air outlet, a fan, a fixing clamp, a bracket and a sniffing cover; the transmission pipe wraps the chromatographic column B, penetrates out of the column box from the outlet of the column box, extends to the sniffing cover and is fixedly connected with the sniffing cover and the bracket by a fixing clamp; the sniffing cover is conical and is provided with a circular opening so as to facilitate manual sniffing; the fan is positioned on the side surface of the smelling cover, the outer side of the fan is connected with the pipeline to the air outlet, and the fan is started in time to pump away residual substances in the smelling cover.

Further, 2 identical chromatographic columns selected need to have identical model, length, inner diameter, film thickness, stationary phase and column separation efficiency.

Further, in the detection parameters of the instrument, the injection port A and the injection port B need to be set with the same carrier gas flow, but not carrier gas pressure.

Further, when the length of the chromatographic column is adjusted, if the cut length exceeds 5% of the original length of the chromatographic column, the 2 chromatographic columns need to be replaced at the same time considering that the column efficiency of the 2 chromatographic columns has great difference.

A synchronization method of an essence component artificial sniffing device synchronized with instrument analysis comprises the following steps:

step 1, selecting chromatographic columns with proper stationary phases and types and specifications according to the characteristics and research purposes of essences and flavors, and connecting 2 same chromatographic columns into a gas chromatograph and a smelling device;

step 2, closing a box door of the column, opening the gas chromatograph and the mass spectrometer, and setting instrument detection parameters according to the characteristics of the essence and the spice, the research purpose and the performance of the chromatographic column when the instrument reaches a detection state;

step 3, starting the controller, setting the temperature program of the transmission pipe to be the same as that of the column box, and starting the fan;

step 4, selecting representative 2-4 essence monomer compounds with known olfactory information, and diluting the compounds to a concentration which can present a good peak shape in instrument detection by using a solvent to serve as a synchronous calibration solution;

step 5, extracting an equal amount of synchronous calibration solution by using the sample injection needle A, the sample injection needle B and the synchronous push rod;

step 6, completing simultaneous sample injection at the sample injection port A and the sample injection port B by using a synchronous push rod, and immediately starting a temperature program of a transmission pipe and a combined detection program of a gas chromatograph and a mass spectrometer;

step 7, detecting the real-time image by an observation instrument, closing a fan after the solvent peak is finished, enabling a smell cover to be close to the nose, artificially smelling smell information of a substance escaping from the tail end of the chromatographic column B, identifying and recording a compound, and recording the running time point of the instrument with the strongest smell feeling every time as the artificial smell time of the compound;

step 8, starting the fan for 10-30 s after each recording is finished, and emptying the sniffing cover to prepare for the next sniffing;

step 9, after the operation of the instrument is finished, determining the retention time of each essence monomer compound in the instrument detection image through mass spectrum database retrieval;

step 10, comparing the difference between the retention time of each compound and the artificial sniffing time, and if all the difference values are less than or equal to 10s, the length of a chromatographic column does not need to be adjusted; adjusting the length of the corresponding chromatographic column according to the time difference, and cutting off the front end of the chromatographic column A by 5-20 cm if the retention time exceeds the artificial sniffing time by more than 10 s; if the artificial sniffing time exceeds the retention time by more than 10s, cutting off the front end of the chromatographic column B by 5-20 cm;

step 11, repeating the steps 5-10 until all the difference values are less than or equal to 10s, namely the manual sniffing and the instrument detection are synchronous;

step 12, diluting and uniformly mixing the essence and spice samples to be detected according to a certain proportion to obtain a solution to be detected, and extracting the same amount of solution to be detected by using a sample injection needle A, a sample injection needle B and a synchronous push rod;

step 13, repeating the step 6, injecting the solution to be detected, starting detection, contrasting an instrument detection real-time chart, developing artificial sniffing according to the steps 7 and 8, and recording each time of the artificial sniffing time and the sensed olfactory information including odor description and odor intensity;

and 14, retrieving compounds corresponding to the spectrum peaks through a mass spectrum database after the detection of the instrument is finished, matching smell information according to the retention time and the correlation of the artificial smell time, and searching and identifying the smell active compounds of the essence and the spice by combining the integral smell information.

The gas chromatograph is provided with a control screen and two independent sample inlets.

The olfactory information of the selected essence monomer compounds should have certain difference, so that the olfactory information is convenient for olfactory identification.

The retention time of the selected essence monomer compound in the detection spectrogram of the instrument is represented by time, and the retention time covers the front and rear sections of the running time of the instrument as much as possible so as to calibrate and synchronize the time of the compound reaching the mass spectrum and the human nose more accurately.

The concentration of the essence monomer compounds in the synchronous calibration solution is not required to be uniformly fixed, the concentration is within the range of 0.1-5%, and the difference exists according to the response intensity of the compounds on detectors such as a mass spectrometer and the like.

Compared with the prior art, the utility model has the following advantages:

1. the utility model has the characteristics of simple and convenient operation and flexible detection, realizes synchronous sample injection at two independent sample injection ports of the gas chromatograph by utilizing the synchronous push rod, and can more flexibly set detection parameters without considering the influence of the split flow at the tail end of the chromatographic column.

2. The utility model has the characteristics of accurate synchronization and easy verification, and the synchronization of the mass spectrum detection signal and the artificial olfaction information is debugged and verified by using the synchronization method, thereby effectively ensuring that the same compound separated on the chromatographic column can reach the mass spectrum and the human nose at the same time.

3. The utility model has the characteristic of low instrument modification cost, and can be easily completed on a conventional gas chromatograph with double sample inlets.

4. The utility model has the characteristic of less interference of artificial smelling, and residual substances in the smelling cover are timely discharged by utilizing the fan which is positioned on the side surface of the smelling cover and is communicated with the external air outlet so as to prevent the interference of the next smelling.

Drawings

Fig. 1 is a schematic view of the artificial sniffing device of the present invention.

FIG. 2 is an instrument detection chromatogram of the synchronous calibration solution in the embodiment of the present invention.

Retention time: linalool 14.686min, vanillin 20.349min, and benzyl cinnamate 30.238 min.

1. A mass spectrometer; 2. an ionization chamber; 3. a post box door; 4. a gas chromatograph 5, a column box; 6. a mass spectrometry transmission rod; 7. a chromatographic column A; 8. a chromatographic column B; 9. a sample injection needle A; 10. a sample inlet A; 11. a synchronous push rod; 12. a sample injection needle B; 13. a sample inlet B; 14. an outlet of the column box; 15. a conveying pipe; 16. a controller; 17. an air outlet; 18. a fan; 19 a fixing clip; 20. a control screen; 21. a support; 22. sniffing the cover.

Detailed Description

In order to further illustrate the technical means and efficacy of the present invention, the following detailed description is provided with reference to the accompanying drawings and preferred embodiments of an apparatus and a method for artificially smelling essence components in synchronization with instrumental analysis, and the application and implementation of the method are provided in the present invention.

Example 1

An essence composition artificial smell device synchronous with instrumental analysis, includes: the device comprises a separation unit, a detection unit and an artificial sniffing unit;

the separation unit is a gas chromatograph 4 used for separating essence components, and is provided with two chromatographic columns, namely a chromatographic column A7 and a chromatographic column B8, a column box outlet 14 is additionally arranged at the upper part of a column box 5 and is connected with a transmission pipe 15, and one end of the transmission pipe 15 at the outer side of the column box 5 is communicated with a smell cover 22; the front end of the chromatographic column A7 is connected with a sample inlet A10, and the tail end of the chromatographic column A7 is connected with the ionization chamber 2 of the mass spectrometer 1 through a mass spectrum transmission rod 6; the front end of the chromatographic column B8 is connected with a sample inlet B13, and the tail end of the chromatographic column B8 extends out of the column box 5 from the column box outlet 14 to reach the sniffing cover 22 through a transmission pipe 15; the sample inlet A10 and the sample inlet B13 are independently injected by a sample injection needle A9 and a sample injection needle B12 respectively, and sample injection operation is synchronously completed under the pushing of the synchronous push rod 11;

the detection unit is a detection instrument used by the mass spectrometer 1 and the gas chromatograph 4; for qualitative and quantitative detection of the compounds separated on the chromatographic column; an ionization chamber 2 is provided in the mass spectrometer

The manual sniffing unit comprises a transmission pipe 15, a controller 16, an air outlet 17, a fan 18, a fixing clamp 19, a bracket 21 and a sniffing cover 22; the conveying pipe 15 wraps the chromatographic column B8, passes out of the column box 5 from the column box outlet 14 and extends to the sniffing cover 22, and is fixedly connected with the sniffing cover 22 and the bracket 21 by a fixing clamp 19; the sniffing cover 22 is conical and is provided with a circular opening for manual sniffing; the fan 18 is located on the side of the sniffing cover 22, and the outside thereof is connected with the pipeline to the air outlet 17, and is started in time to suck away the residual substances in the sniffing cover 22.

Further, 2 identical selected chromatographic columns need to have identical models, lengths, inner diameters, film thicknesses, stationary phases and column separation efficiencies.

Further, in the instrument detection parameters, the same carrier gas flow is required to be set at the sample inlet A10 and the sample inlet B13, not the carrier gas pressure.

Further, when the length of the chromatographic column is adjusted, if the cut length exceeds 5% of the original length of the chromatographic column, it is considered that 2 chromatographic columns have great difference in column efficiency, and 2 chromatographic columns need to be replaced at the same time.

Example 2

A synchronization method of an essence component artificial sniffing device synchronized with instrument analysis comprises the following steps:

step 1, selecting chromatographic columns with proper stationary phases and models according to the characteristics and research purposes of the essence and the spice, and connecting 2 same chromatographic columns into a gas chromatograph and a sniffing device;

step 2, closing a box door 3 of the column, opening the gas chromatograph 4 and the mass spectrometer 1, and setting instrument detection parameters according to the characteristics of the essence and the spice, the research purpose and the performance of the chromatographic column when the instrument reaches a detection state;

step 3, starting the controller 16, setting the temperature program of the transmission pipe 15 to be the same as that of the column box 5, and starting the fan 18;

step 4, selecting representative 2-4 essence monomer compounds with known smell information, and diluting the compounds to a concentration at which the compounds can present a good peak shape in instrument detection by using a solvent to serve as a synchronous calibration solution;

step 5, extracting an equal amount of synchronous calibration solution by using a sample injection needle A9, a sample injection needle B12 and a synchronous push rod 11;

step 6, completing simultaneous sample injection at a sample injection port A10 and a sample injection port B13 by using a synchronous push rod 11, and immediately starting a temperature program of a transmission pipe 15 and a combined detection program of a gas chromatograph 4 and a mass spectrometer 1 simultaneously;

step 7, detecting the real-time image by an observation instrument, closing the fan 18 after the solvent peak is finished, enabling the sniffing cover 22 to be close to the nose, manually sniffing the olfactory information of the substance escaping from the tail end of the chromatographic column B8, identifying and recording the compound, and recording the running time point of the instrument with the strongest olfactory sensation every time as the manual sniffing time of the compound;

step 8, starting the fan 1810-30 s after each recording is finished, and emptying the sniffing cover 22 to prepare for the next sniffing;

step 9, after the operation of the instrument is finished, determining the retention time of each essence monomer compound in the instrument detection image through mass spectrum database retrieval;

step 10, comparing the difference between the retention time of each compound and the artificial sniffing time, and if all the difference values are less than or equal to 10s, the length of a chromatographic column does not need to be adjusted; adjusting the length of the corresponding chromatographic column according to the time difference, and cutting off the front end of the chromatographic column A7 by 5-20 cm if the retention time exceeds the artificial sniffing time by more than 10 s; if the artificial smell time exceeds the retention time by more than 10s, cutting off the front end of the chromatographic column B8 by 5-20 cm;

step 11, repeating the steps 5-10 until all the difference values are less than or equal to 10s, namely the manual sniffing and the instrument detection are synchronous;

step 12, diluting and uniformly mixing the essence and spice samples to be detected according to a certain proportion to obtain a solution to be detected, and extracting the same amount of the solution to be detected by using a sample injection needle A9, a sample injection needle B12 and a synchronous push rod 11;

step 13, repeating the step 6, injecting the solution to be detected, starting detection, contrasting an instrument detection real-time chart, developing artificial sniffing according to the steps 7 and 8, and recording each time of the artificial sniffing time and the sensed olfactory information including odor description and odor intensity;

and 14, retrieving compounds corresponding to the spectrum peaks through a mass spectrum database after the detection of the instrument is finished, matching smell information according to the retention time and the correlation of the artificial smell time, and searching and identifying the smell active compounds of the essence and the spice by combining the integral smell information.

The gas chromatograph 4 is a gas chromatograph with a control panel 20 and two independent sample inlets.

The smell information of the selected essence monomer compound has certain difference, so that the smell identification is convenient.

The retention time of the selected essence monomer compound in an instrument detection spectrogram has time representativeness, and the retention time covers the front and the rear sections of the instrument operation time as much as possible so as to more accurately calibrate and synchronize the time of the compound reaching the mass spectrum and the human nose.

The concentration of the essence monomer compounds in the synchronous calibration solution is not required to be uniformly fixed, the concentration is within the range of 0.1-5%, and the difference exists according to the response intensity of the compounds on detectors such as a mass spectrometer and the like.

Example 3

The artificial sniffing device is applied to the identification of odor active compounds in a commercially available perfume sample

Step 1, selecting 2 DB-5MS chromatographic columns (60m multiplied by 0.25mm i.d. multiplied by 0.25 mu m d.f), and connecting the 2 same chromatographic columns into an instrument and a sniffing device;

step 2, closing the column box door 3, opening the gas chromatograph 4 and the mass spectrometer 1, and setting detection parameters: the temperature of the front and rear sample inlets is 250 ℃, the split ratio is 10: 1, and the sample injection amount is 1 mu L; carrying helium gas, and keeping the flow constant at 1 mL/min; keeping the temperature of the column box at 50 ℃ for 2min, and heating to 280 ℃ at 8 ℃/min for 5 min; the temperature of a transmission line is 280 ℃, the temperature of an ion source is 230 ℃, the ionization voltage is 70eV, the solvent delay is 4.8min, and the scanning range is 33-400 amu;

step 3, starting the controller 16, setting the temperature program of the transmission pipe 15 to be the same as the temperature of the column box 5, and starting the fan 18;

step 4, selecting 3 essence monomer compounds such as linalool, vanillin, benzyl cinnamate and the like, preparing 0.5% solvent by using ethanol as solvent, and uniformly mixing the solvent to obtain synchronous calibration solution;

step 5, respectively extracting 1 mu L of synchronous calibration solution by using a sample injection needle A9, a sample injection needle B12 and a synchronous push rod 11;

step 6, completing simultaneous sample injection at the sample injection port A10 and the sample injection port B13 by using the synchronous push rod 11, and immediately starting a temperature program of the transmission pipe 15 and a combined detection program of the gas chromatograph 4 and the mass spectrometer 1 at the same time;

step 7, detecting the real-time image by an observation instrument, closing the fan 18 after the solvent peak is finished, enabling the sniffing cover 22 to be close to the nose, manually sniffing the olfactory information of the substance escaping from the tail end of the chromatographic column B8, identifying and recording the compound, and recording the running time point of the instrument with the strongest olfactory sensation every time as the manual sniffing time of the compound;

step 8, starting the fan 1810-30 s after each recording is finished, and emptying the sniffing cover 22 to prepare for the next sniffing;

step 9, after the operation of the instrument is finished, determining the retention time of each essence monomer compound in the instrument detection image through mass spectrum database retrieval;

step 10, comparing the difference between the retention time and the artificial sniffing time of each compound, linalool (retention time 14.686min) is mainly embodied as floral, vanillin (20.349min) is mainly milky, and benzyl cinnamate (30.238min) is mainly pasty. The difference between the retention time of linalool and vanillin and the artificial sniffing time is less than 10s, and when the artificial sniffing time of vanillin exceeds the retention time of 12s, the front end of a chromatographic column B8 is cut by 11 cm;

step 11, repeating the steps 5-10, wherein the difference between the retention time of the 3 compounds and the artificial sniffing time is less than 10s, namely the artificial sniffing and the instrument detection are synchronous;

step 12, diluting and uniformly mixing a to-be-detected commercially available perfume sample with ethanol according to a proportion of 20% to obtain a to-be-detected solution, and extracting 1 mu L of the to-be-detected solution by using a sample injection needle A9, a sample injection needle B12 and a synchronous push rod 11;

step 13, repeating the step 6 to sample the solution to be detected and start detection, contrasting an instrument detection real-time chart, developing artificial sniffing according to the steps 7 and 8, and recording each time of the artificial sniffing time and the sensed olfactory information including odor description and odor intensity;

and 14, retrieving compounds corresponding to the spectrum peaks through a mass spectrum database after the detection of the instrument is finished, matching smell information according to the retention time and the correlation of the artificial smell time, and searching and identifying the smell active compounds by combining the integral smell information of the perfume sample.

While there have been shown and described what are at present considered to be the essential features and advantages of the utility model, it will be apparent to those skilled in the art that the utility model is not limited to the details of the foregoing exemplary embodiments, but is capable of other specific forms without departing from the spirit or essential characteristics thereof. The present embodiments are therefore to be considered in all respects as illustrative and not restrictive, the scope of the utility model being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein.

Furthermore, it should be understood that although the present description refers to embodiments, not every embodiment may contain only a single embodiment, and such description is for clarity only, and those skilled in the art should integrate the description, and the embodiments may be combined as appropriate to form other embodiments understood by those skilled in the art.

Claims (4)

1. The utility model provides an artifical device of smelling of essence composition synchronous with instrument analysis which characterized in that: the method comprises the following steps: the device comprises a separation unit, a detection unit and an artificial sniffing unit;

the separation unit is a gas chromatograph (4) which is provided with two chromatographic columns, a chromatographic column A (7) and a chromatographic column B (8), the upper part of the column box (5) is additionally provided with a column box outlet (14) and is connected with a transmission pipe (15), and one end of the transmission pipe (15) at the outer side of the column box (5) is communicated with a smell cover (22); the front end of the chromatographic column A (7) is connected with a sample inlet A (10), and the tail end of the chromatographic column A (7) is connected with an ionization chamber (2) of the mass spectrometer (1) through a mass spectrum transmission rod (6); the front end of the chromatographic column B (8) is connected with a sample inlet B (13), and the tail end of the chromatographic column B (8) extends out of the column box (5) from a column box outlet (14) and reaches a smell cover (22) through a transmission pipe (15); the sample inlet A (10) and the sample inlet B (13) are independently injected by a sample injection needle A (9) and a sample injection needle B (12) respectively, and the sample injection operation is synchronously completed under the pushing of a synchronous push rod (11);

the detection unit is a detection instrument used by combining a mass spectrometer (1) and a gas chromatograph (4); an ionization chamber (2) is arranged in the mass spectrometer

The artificial sniffing unit comprises a transmission pipe (15), a controller (16), an air outlet (17), a fan (18), a fixing clamp (19), a bracket (21) and a sniffing cover (22); the transmission pipe (15) wraps the chromatographic column B (8), penetrates out of the column box (5) from the column box outlet (14) and extends to the sniffing cover (22), and the chromatographic column B is fixedly connected with the sniffing cover (22) and the support (21) by a fixing clamp (19); the sniffing cover (22) is conical and is provided with a circular opening so as to facilitate manual sniffing; the fan (18) is positioned on the side surface of the sniffing cover (22), the outer side of the fan is connected with the pipeline to the air outlet (17), and the fan is started at proper time to pump away residual substances in the sniffing cover (22) in time.

2. The device for artificially smelling essence components synchronously with instrumental analysis according to claim 1, characterized in that: the 2 selected same chromatographic columns need to have the same model, length, inner diameter, film thickness, stationary phase and column separation efficiency.

3. The device for artificially smelling essence components synchronously with instrumental analysis according to claim 2, characterized in that: in the detection parameters of the instrument, the sample inlet A (10) and the sample inlet B (13) need to be set with the same carrier gas flow rate instead of carrier gas pressure.

4. The device for artificially smelling essence components synchronously with instrumental analysis according to claim 3, characterized in that: when the length of the chromatographic column is adjusted, if the cut length exceeds 5 percent of the original length of the chromatographic column, the 2 chromatographic columns need to be replaced at the same time considering that the column efficiency of the 2 chromatographic columns has great difference.

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