JPH0666701A - Odor identifying apparatus - Google Patents

Abstract

PURPOSE:To obtain an odor identifying apparatus, which can identify many samples automatically and readily at an excellent identifying rate. CONSTITUTION:An odor identifying apparatus sends carrier gas into an odor- pattern identifying means together with odor material in a sample tube through the sample tube 21. Thus, the odor pattern is identified. An odor-material sampling means in the sample tube can be freely moved in two dimensions or three dimensions. A carrier-gas passage in the odor-pattern identifying means is covered with fluoride resin.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an odor identifying device. More specifically, the present invention relates to an odor automatic identification device capable of continuously and automatically identifying a large number of specimens, and an odor identification device capable of accurately identifying odors.

[0002]

BACKGROUND OF THE INVENTION In living organisms, there are many receptors with different characteristics,
That is, it is said that the odor is identified by pattern recognition of the response pattern from the olfactory cell. An artificial odor identifying device simulating such a biological olfactory mechanism has been proposed (Japanese Patent Laid-Open No. 1-244335). The odor identification device proposed here combines detection information obtained from different sensitivities when a plurality of types of receptors (receptors) exhibiting mutually different sensitivities to substances exhibiting a predetermined odor are combined. Is a device developed by focusing on the fact that it differs from receptor to receptor and shows a constant pattern as a whole.

The proposed odor identifying device is shown in FIG. The sensor cell 10 is an array of a large number of crystal oscillators coated with various adsorption films that adsorb odor molecules, which serve as olfactory cells. When a gas containing an odor from the sample 1 is passed through the sensor cell 10, the adsorption film coated on the surfaces of the crystal oscillator sensors 10a, 10b, ..., 10h of the sensor cell 10 adsorbs the odor substance, and The surface load mass is changed to change the oscillation frequency of the oscillation circuit corresponding to each crystal oscillator sensor. The adsorption films coated on the crystal oscillator sensor have different adsorption characteristics with respect to the odor substance, which changes the surface-loaded mass of each sensor, and each sensor has a different response, that is, frequency change (Δf _a , Δ f _b , ..., Δf _h ). The response from each sensor is recognized as a pattern to identify the odor. As the electronic identification means for identifying the odor by performing the pattern processing, specifically, a neuromimetic circuit using the computer 11 is used. This neuromimetic circuit has a learning function and gains experience to improve the odor discrimination rate.

[0004]

SUMMARY OF THE INVENTION The above-mentioned conventional odor discriminating apparatus is used to identify the odor of the electromagnetic valves 17, 18 such as the sample 1 from the air from the air cylinder 14 through the mass flow controller 15. a, 18-a
The electromagnetic valve was opened and the odorous substance was sent to the sensor cell 10 together with the air for the purpose of identifying the odor. In such an apparatus, the number of samples that can be continuously measured depends on the number of electromagnetic valves, and it has been difficult to measure a large number of samples easily and quickly. An object of the present invention is to provide an odor identification device that can automatically and easily identify a large number of samples with a favorable identification rate. Another object of the present invention is to provide an odor identifying device that can identify odors with higher accuracy.

[0005]

According to the present invention, there is provided a carrier gas supply means, a means for supplying the carrier gas to a sample tube, and a means for identifying an odor pattern contained in the carrier gas. In the apparatus, the means for supplying to the sample tube is composed of means for feeding and collecting carrier gas to the sample tube and bypass means, and the means for feeding and collecting are carrier gas supply side control valve and carrier connected to the control valve. It comprises a gas feeding needle, a carrier gas identifying means side control valve and a carrier gas collecting needle containing odor connected to the control valve, and the bypass means is provided between the feeding and collecting means and the supply side control valve. It is a means for branching in front, connecting after the control valve on the identification means side, and having a control valve in the position after branching and before connection, wherein the feeding needle and the collecting needle are two-dimensional. To provide an automatic identification system odor, characterized in that is movable in three dimensional directions. Furthermore, the present invention provides a carrier gas supply means, a means for supplying the carrier gas to a sample tube, and a means for supplying an odor contained in the carrier gas to a sensor cell to identify outputs from a plurality of sensors as a pattern. An odor identifying device comprising: a carrier gas passage part of a sensor cell coated with a fluororesin.

The present invention will be described below with reference to the drawings. FIG. 1 is a block diagram showing an odor identifying device of the present invention.
14 is a reservoir of carrier gas for feeding the gas sample into the sensor cell. The carrier gas may be any gas that is inert to the odor substance, and examples thereof include air, nitrogen, and helium. Reference numeral 15 is a mass flow controller for controlling the flow rate of the carrier gas. Fluctuations in the flow rate of the carrier gas cause fluctuations in the sample concentration in the carrier gas fed into the sensor cell, and thus fluctuations in the pattern obtained from each quartz crystal resonator sensor. Therefore, the flow rate of the carrier gas is accurately controlled.

Reference numerals 17, 18 and 19 are automatic control valves. The automatic control valve only needs to be remotely controllable, and an electromagnetic valve is exemplified. The valve 19 is
It is provided as a bypass means for the carrier gas and is controlled so as to be opened when the carrier gas is sent to the sensor cell 10 and closed when the valves 17 and 18 are opened. When the valves 17 and 18 are opened, the carrier gas is fed into the sample tube 21 through the feeding needle 22, and then, together with the sample vapor in the sample tube, passes through the collecting needle 23 and the sensor cell 10.
Sent to. The needles 22 and 23 move to the top of the sample tube 21 by an automatic stage that moves in two dimensions (XY axis direction) or three dimensions (XYZ axis direction), and the rubber stopper 24
It is installed so that it can be inserted into and removed from the sample tube through the. In a preferred embodiment, the valves 17, 18 and the needles 22, 23 are integrated, and in a more preferred embodiment, the valves 17, 18, 19 and the needles 22, 2 are integrated.
It is preferable to install the unit 3 so that it can move in the XY-axis direction or the XYZ-axis direction as a unit.

The sensor cell 10 houses a plurality of crystal oscillator sensors 10a, 10b, ..., 10h. The crystal oscillator sensor is disclosed in JP-A-1-244335, and a surface acoustic wave element (SAW) may be used instead of the crystal oscillator sensor. For example, a crystal oscillator sensor is manufactured by applying an adsorption film such as a stationary phase material used for gas chromatography or the like, a cellulosic material, or a lipid bilayer film on electrodes provided on both sides of the crystal oscillator. The electrodes provided on both sides of the crystal unit are
It is connected to each oscillating circuit of the Kolwitz oscillating circuit 12.

Crystal oscillator sensors 10a, 10b, ..., 1
When the number of 0h is eight, each is connected to each circuit of the Kollwitz type oscillation circuit 12. The oscillation output of each circuit is
Each is input to each channel of the 8-channel frequency counter 13. The frequency counter 13 simultaneously measures the frequency change of each crystal oscillator sensor in parallel and performs sampling, for example, at an interval of 1 second. The computer 11
The odor is identified by pattern-processing the combination of the plurality of detected electrical signals, eight in the above case. Figure 2
FIG. 3A is a partially enlarged schematic view of the sensor cell 10. The carrier gas supplied from the supply pipe 30 for the carrier gas containing odor passes through the surface of the sensor 10a or the like in the sensor cell, and the other end side of the sensor cell (the opposite side of the pipe 30).
Emitted from. The pipe 31 is a cooling pipe for keeping the inside of the sensor cell at an appropriate temperature. The sensor 10a provided with the electrode 32 is held in the sensor cell and sealed with a sealing material 33 and a sealing plate 34. The sealing plate 34 is fixed to the sensor cell 10 with screws 35. FIG. 2B is a sectional view of the sensor cell. Reference numeral 36 indicates a carrier gas passage portion.

[0010]

The operation of the apparatus shown in FIG. 2 (a) will be described below. The control valves 17 and 18 are opened, the carrier gas is sent from the needle 22 into the sample tube 21, and the sample gas in the sample tube is sent into the sensor cell 10 through the needle 23 and the control valve 18. Measure the change. After the measurement is completed, the needles 22 and 23 extracted from the sample tube are inserted into the sample tube not containing the sample, and a carrier gas is caused to flow to clean the needle and the sensor in the sensor cell. Then, the needle is inserted into the sample tube containing the sample, and the above operation is repeated.

According to the present invention, the needles 22 and 23, or the needles 22 and 23 and the valves 17 and 18, or the needles 22 and 23 and the valves 17, 18 and 19 are integrally movable in the XY axis direction or the XYZ axis direction. The valves 17-a, 17-b, etc. and 18-a, 1
A large number of samples can be automatically measured without being affected by the number of 8-b or the like. Further, since the sample vapor can be sent to the sensor cell without moving the sample tube, it is possible to prevent the concentration variation of the sample vapor in the sample tube due to the movement vibration, and thereby prevent the frequency variation due to the concentration variation. can do.

FIG. 3 and FIG. 4 are diagrams showing examples of discrimination in the odor discriminating apparatus of the present invention. The sensitive film coated on the surface of the crystal oscillator sensor has different adsorption characteristics for the odor substance, which changes the surface adsorption mass of each sensor, and each sensor shows different response, that is, frequency change. Figure 3 shows the frequency change of Clove Oil. Figure 4 shows Clove Oil, Peppermint Oil, Ginger Oil Valen
The results of applying the data obtained when four types of cia Oil were identified to principal component analysis, which is a type of multivariate analysis, are shown. From the scatter diagram in FIG. 4, it can be seen that the four types of essential oils are well separated. The symbols 1 to 8 in FIG.
Means the same as.

Further, according to the present invention, the carrier gas passage portion in the sensor cell is coated with a fluororesin to prevent the condensation of the odor substance having a small vapor pressure. This makes it possible to more accurately identify odors. FIG. 5 shows a sensor cell in which a fluororesin is applied to a carrier gas passage portion in a thickness of μm and each sensor 10a
Dioleyl phosphatidylserin,
Cholesterol, Perfluorinated bilayer, Lecith
in (egg), Diethyleneglycol Succinate (DEGS), Sp
hingomyelin (egg), Acetyl cellulose, Ethyl cel
It is a graph which shows the frequency change when lulose is applied and propylene glycol is supplied to this together with dry air. FIG. 6 shows a sensor 10a not coated with fluororesin.
It is a graph which shows the frequency change at the time of apply | coating to 10h each similarly to the above, and supplying propylene glycol with dry air to this. FIG. 5 has a deeper valley of frequency change than that of FIG. 6, and shows the superiority of the odor discrimination device in which the fluororesin is applied to the carrier gas passage portion.

[0014]

According to the present invention, there is provided an odor identifying device capable of automatically identifying the odors of a large number of samples. Further, according to the present invention, there is provided an odor identifying device capable of identifying an odor at a favorable identification rate.

[Brief description of drawings]

FIG. 1 is a block diagram showing an odor automatic identification device of the present invention.

FIG. 2 is a schematic diagram of a sensor cell in which a fluororesin coating is provided on a carrier gas passage portion.

FIG. 3 is a graph showing a frequency change of Clove Oil by the odor identifying device of the present invention.

FIG. 4 is a graph showing the results of identifying four types of odor substances.

FIG. 5 is a graph showing frequency changes of propylene glycol showing the effects of the present invention.

FIG. 6 is a graph showing a frequency change of propylene glycol by a conventional method.

FIG. 7 is a block diagram showing a conventional odor identifying device.

[Explanation of symbols]

 10 Sensor Cell 17 Control Valve 18 Control Valve 21 Sample Tube 22 Needle 23 Needle

Claims (4)

[Claims] 1. An odor identifying device comprising a carrier gas supply means, a means for supplying the carrier gas to a sample tube, and a means for identifying an odor pattern contained in the carrier gas. The means comprises a carrier gas feeding / collecting means for the sample tube and a bypass means, and the feeding / collecting means is a carrier gas supply side control valve, a carrier gas feeding needle connected to the control valve, and a carrier. A control valve on the gas identification means side and a carrier gas recovery needle connected to the control valve that contains odor, and the bypass means branches in front of the feed-in recovery means and the supply side control valve, and the identification means side A means for connecting after the control valve and having the control valve at a position after branching and before connection, wherein the feeding needle and the collecting needle are two-dimensional or three-dimensional.
An odor automatic identification device characterized by being movable in the dimensional direction. 2. The automatic odor identifying device according to claim 1, wherein the supply-side control valve and the identifying-means-side control valve are two-dimensional or three-dimensional together with a feeding needle and a collecting needle.
An odor automatic identification device characterized by being movable in the dimensional direction. 3. The automatic odor identifying device according to claim 2, wherein the control valve of the bypass means is movable in two-dimensional or three-dimensional directions together with the feeding needle and the collecting needle. Automatic identification device. 4. A carrier gas supply means, a means for supplying the carrier gas to a sample tube, and a means for supplying an odor contained in the carrier gas to a sensor cell to identify outputs from a plurality of sensors as a pattern. An odor identifying device having a carrier gas passage portion of a sensor cell coated with a fluororesin.