JPH08220043A - Odor measuring instrument - Google Patents

Abstract

PURPOSE: To provide an odor measuring instrument which is used for effectively analyzing an odor generated in a container. CONSTITUTION: An odor measuring instrument is provided with a container 20 equipped with sheet-like heaters 21h and 22h in each wall of the container 20, sample stage 7 which is provided in the container 20 for mounting a sample 11, temperature controlling means equipped with a ceramic heater 10 which is connected to the stage 7 so as to heat the sample 11 mounted on the stage 7 to produce an odor, and odor sensor 14 which measures the amount of the odor generated in the container 20. Since the odor generated in the container 20 can be measured without allowing the odor to be adsorbed to the wall surfaces of the container 20, the odor can be measured accurately.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an apparatus for measuring odor generated when heating various substances (hereinafter referred to as samples).

[0002]

2. Description of the Related Art For example, there is an odor measuring device as disclosed in Japanese Patent Application Laid-Open No. 3-235047. The operation of the device disclosed in that publication will be briefly described below. When the sample is placed on the heater in the container and the start button of the control device is pressed, the control device starts the intake fan and starts ventilation, When the data of the temperature controller, the odor sensor, etc. are read into the control device and the test becomes possible, the heating of the heater is started. As a result, it is possible to measure the output of the odor sensor at predetermined time intervals.

[0003]

The odor generated in the container of the odor measuring device as described above diffuses in the container, and is particularly remarkable in the odorant having a large molecular weight.
The absolute amount of odor may be diluted by being adsorbed on the wall surface of the container until it reaches the odor sensor.

An object of the present invention is to provide an odor measuring device for effectively measuring odor generated in a container.

[0005]

SUMMARY OF THE INVENTION According to the present invention, a container having a heater for heating each surface, a sample table for mounting a sample in the container, and a heating control connected to the sample table are provided. The temperature control means for generating odor from the mounted sample and the detecting means for measuring the odor generated from the sample are characterized by the above-mentioned.

The container is composed of a container body and a lid of the container body. The container has an introduction pipe provided in the container body, a supply means capable of introducing a specific gas from the outside, and The temperature control means is provided with a stirrer for equalizing the generated odor, and the temperature control means includes a heater for directly heating the sample, a thermocouple for detecting the temperature of the sample, and an electrical connection between these heater and thermocouple. A temperature controller that is connected to the temperature controller and can control the temperature of the sample, and a constant temperature that keeps the sample at a constant temperature by a heater that heats the sample and a linear rise heating that heats the sample at a constant temperature. It is for heating. Further, the detection means is an odor sensor having a thin film of stannic oxide arranged inside the container, or an analysis device arranged outside the container and introduced through a sampling tube.

[0007]

Function Since the odor generated by heating the sample placed on the sample table is not adsorbed on the wall surface of the container, the odor in the container can be applied to the detection means without being diluted, and the odor generated is generated. A measurement corresponding to the amount of can be made.

The container comprises a container body and a lid for the container body. The container is provided with an introduction pipe provided in the container body, a supply means capable of introducing a specific gas from the outside, The stirring means for uniformizing the generated odor is provided, and the atmosphere can be adjusted when the sample is heated. The temperature control means comprises a heater that directly heats the sample, a thermocouple that detects the temperature of the sample, and a temperature controller that is electrically connected to the heater and the thermocouple to control the temperature of the sample. The linear heating is performed to raise the sample at a constant temperature by the heater that heats the sample, and the constant temperature heating is performed to keep the sample at a constant temperature by the heater that heats the sample. The heating method of the sample can be controlled. Further, the detection means, the odor of the odor by the odor sensor having a thin film of stannic oxide placed in the container, qualitative of the odor by the analyzer placed outside the container and introduced through the sampling tube,
Quantification and identification are possible.

[0009]

The structure of one embodiment of the present invention will be described below.

FIG. 1 is a schematic diagram showing the odor measuring device of the present invention. In the figure, 20 is a sealable container, which is composed of a container body 21 and a lid 22 thereof. An inlet pipe 23 for introducing a specific gas such as dry air is provided inside the side surface of the container body 21. A sample table 7 is provided on the inner wall of the container body 21, a ceramic heater 10 is placed on the sample table 7, and a sample 11, for example, cellulose powder, cotton or filter paper is placed on the ceramic heater 10. Adjacent to the thermocouple 1
2 is placed. The ceramic heater 10 and the thermocouple 12 are connected to the temperature controller 13. A container body 21 and a lid 22 that form the container 20
Is a sheet-shaped heater 21 that heats each of these surfaces.
h and 22h are provided respectively and are heated to a predetermined temperature. Even if the odorant has a relatively high molecular weight, it is prevented from being adsorbed on the inner wall of the container 20.

Reference numeral 30 denotes an analyzer into which the odor in the container 20 is introduced via a sampling tube 31, which can identify and quantify the odor substance. As the analyzer 30, a mass spectrometer, a gas chromatograph, an infrared spectrophotometer, an ultraviolet spectrophotometer, an X-ray analyzer, an electron beam analyzer and the like can be used.
The mass spectrometer can separate the odorants by their molecular weights, and can perform the molecular weights of the odorants and their quantification. The gas chromatograph device can separate odorants based on their mobility, and can perform quantification for each odorant. Other spectrophotometers and the like can detect the absorption of infrared wavelengths based on the molecular shape of the odorant, and identify or quantify the odorant.

A sampling tube 31 for this analyzer 30
Is provided with a coiled heater 32 for heating the entire inner wall thereof. Even if the odorant has a relatively high molecular weight, it is possible to prevent the odorant from adsorbing to the inner wall of the sampling tube 31 and to reliably introduce the odor in the container 20 into the analyzer 30. Similarly, the inner wall of the container 20 can also be heated, but the heating temperature of the heater is preferably about 60 to 150 ° C., though it depends on the odor substance, and if it is overheated, the odor substance may be thermally decomposed. is there. Furthermore, it is preferable that the inside of the container 20 and the inside of the sampling pipe 31 are subjected to Teflon processing that does not easily adsorb odorous substances.

On the inner wall of the container body 21 facing the sample table 7, a fan 24 that can be turned on and off is provided as a stirring means. Furthermore, an odor sensor 14 as a detection means is arranged in the container body 21. The odor sensor 14 detects the presence of odor by, for example, a odor sensor having stannic oxide as a main material.
Although it is not possible to discriminate the detailed odor substance, it is possible to detect the presence or absence of the odor and its strength. Then, from the output of the odor sensor 14 and the analysis result of the analysis device 30, it is possible to relatively examine the relationship between the amount and property of the odor substance and the odor intensity.

The temperature controller 13 to which the ceramic heater 10 and the thermocouple 12 are connected is the thermocouple 12
The heating of the heater 10 is controlled based on the output of 1) and is connected to a control device (not shown) together with the odor sensor 14.

Next, the operation of this odor measuring device will be briefly described. First, the lid 22 is opened, the sample 11 is placed on the ceramic heater 10 of the sample table 7, the lid 22 is closed, and the container 2 is closed.
After setting the inside of 0 to a predetermined atmosphere, the controller outputs a start signal to the temperature controller, the ceramic heater 10 heats the sample 11, and the odor peculiar to the sample 11 is generated. By rotating the fan 24 with the start of heating, the generated odor can be made uniform in the container 20.

The atmosphere in the container 20 can be adjusted by introducing, for example, dry air or nitrogen gas supplied from a cylinder (not shown) through the introduction pipe 23, and in order to adjust environmental conditions such as humidity. Can also be used. It is also possible to supply the atmosphere sequentially from the introduction pipe 23.

The heating method of the sample 11 is controlled by the temperature controller 13 based on the setting in the controller.
The temperature of the sample 11 is detected by the thermocouple 12, and the heating condition by the heater is adjusted. This heating method can perform linear rising heating that raises the temperature at a constant rate, such as 5 ° C. per minute, or low temperature heating that maintains a predetermined temperature, such as 200 ° C. It is possible to set the heating method for a certain period of time. These heating methods and atmospheres are configured so that various settings can be made when investigating the generation process of odor from the sample 11.

Furthermore, the odor sensor 14 and the analysis device 30
The measurement may be started sequentially by manual operation, but may be automatically measured by the control device.

2 shows a simple structure of a mass spectrometer as an analyzer, it basically comprises an ionization section 14, a mass separation section 15, and an ion detection section 16.

The odor drawn by the two-stage oil rotary pump 48 and drawn from the sampling tube 31 is introduced from the capillary 42 through the filter 43 into the apparatus of about 10 ^-6 Torr, and first, the ionization section by the EI ion source. 44
Are ionized by the electric field due to the high voltage. The ionized odor is separated by the molecular weight of the component in the odor flow by the magnetic field of 45 of the mass separation section by the quadrupole,
The separated components reach the ion detector 46 by the electron multiplier, and the odor caused by combustion is separated and detected for each molecular weight. Then, for example, when benzene is produced, a peak appears at the position of ionic strength 78 (m / e = 78), at the position of 50 (m / e = 50) for butadiene and at the position of 92 (m / e) for toluene. A peak appears at the position of e = 92).

Filter 43 from this capillary 42
Is provided in order to reduce the pressure in the apparatus from atmospheric pressure to a reduced pressure state by the turbo pump 47, but there is an influence that large molecules in the component are adsorbed by the filter 43. Considering the formation process of soot, it is considered that high molecular weight odors such as xylene, naphthalene, and anthracene are generated. Therefore, when measuring even large molecules, this filter 4
A plate or skimmer having holes (for example, about 1 μm) without 3 is provided with a through hole at the top of a cone, and stacking a plurality of them has the effect of repelling and concentrating light molecules such as nitrogen and oxygen. ) Or the like may be used. Further, the ionization section 44 may be an ion source using a radioactive element other than the EI ion source, and the mass separation section 45.
May be a magnetic source other than the quadrupole, and may use the TOF method.

As an analyzer other than the mass spectrometer, FIG. 3 shows a simple structure of an infrared spectrophotometer. Basically, an infrared light source 56, a measuring cell 55, and a spectroscope 6 are provided.
0, an infrared detector 52.

The air flow sent from the sampling tube 31 to the measuring cell 55 through the inlet port 53 continuing from the sampling pipe 31 is exhausted from the exhaust port 54.
It is exhausted from, and a new air flow is always taken in. On the other hand, the compensation cell 57 communicates with the measurement cell 55, but since the shielding plates 61 and 62 are provided, the compensation cell 57 is provided.
The atmosphere inside the container 20 can be left as it is in the initial state. It is preferable that the shield plates 61 and 62 be removed during the preparation for measurement and mounted in a state where the atmosphere in the container 20 starts the measurement. And these shield plates 6
A small through hole may be provided in each of the parts 1 and 62 so as to follow a slight change in the atmosphere, or may not be provided.

Light from an infrared light source 56 capable of emitting light in the infrared wavelength band is applied to the measuring cell 55 and the compensating cell 57 by the separator 51. The two lights that have passed through the measurement cell 55 and the compensation cell 57 are alternately shielded by the sector part 58, are separated into respective wavelengths by the spectroscope 60, and are condensed on the infrared detection part 52. In the spectroscope 60, although not shown in detail, the light from the sector section 58 passing through the slit for introduction is split by a prism and emitted toward the infrared detecting section 52 for each wavelength through the slit for emission. To be done. A silicon carbide rod, a Nernst lamp, or the like is used for the light source 56, and a thermocouple, a bolometer, or the like is used for the infrared detection unit 52.

Then, the measurement cell 55 and the compensation cell 57
The absorption due to the odor of each wavelength is measured from the intensity difference of the passing light of. Here, the odor in the container 20 is introduced into the measurement cell 55, but the atmosphere in the initial state of the container 20 remains in the compensation cell 57, and the intensity difference of each wavelength of the passing light is odor. It represents the characteristics of the molecular structure of a substance. For example, when benzene is produced, the absorption due to the = CH stretching vibration of the aromatic ring is around 3000 cm ^-1 , and
200 peculiar small wave absorption based on C-H out-of-plane bending vibration
At ⁰ to 1660 cm ⁻¹ , strong absorption due to ring vibration including C═C stretching vibration of aromatic ring is at 1600 to 1450 cm ⁻¹ , and slightly strong absorption due to ═C—H in-plane bending vibration of aromatic ring is 1.
The 250~1000cm ^-1, strong absorption based on = C-H out-of-plane deformation vibration of aromatic rings in 1000~650cm ^-1, infrared absorption spectrum having a large number of specific absorption bands are obtained.

In addition to the mass spectrometer and infrared spectrophotometer as described above, a gas chromatograph, an ultraviolet spectrophotometer, an X-ray analyzer or an electron beam analyzer can be used as an analyzer. , A combination thereof, for example, GC-MS separated by a gas chromatograph and introduced into a mass spectrometer, G separated by a gas chromatograph and introduced into an infrared spectrophotometer.
It may be C-IR, UV-IR or the like that simultaneously performs an infrared spectrophotometer and an ultraviolet spectrophotometer, and by using these instruments, it is possible to qualitatively, quantitatively, and identify odors in a multifaceted manner. is there.

[0027]

As described above, according to the present invention, a container having a heater for heating each surface, a sample table for mounting a sample in the container, and a sample table connected to the sample table to control heating. By having a temperature control means for generating odor from the mounted sample by this, and a detection means for measuring the odor generated from the sample, the odor generated by heating the sample mounted on the sample stage of the container The odor in the container can be allowed to act on the detection means without being adsorbed on the wall surface, and the odor in the container can be measured, and the amount of odor generated can be measured.

The container is composed of a container body and a lid of the container body. The container has an introducing pipe provided in the container body, a supply means capable of introducing a specific gas from the outside, and The stirring means for uniformizing the generated odor is provided, and the atmosphere can be adjusted when the sample is heated. The temperature control means, a heater for directly heating the sample, a thermocouple for detecting the temperature of the sample,
Consisting of a temperature controller capable of controlling the temperature of the sample electrically connected to these heaters and thermocouples,
The heater for heating the sample performs linear rising heating to raise the sample constantly, and the heater for heating the sample performs constant temperature heating to keep the sample at a constant temperature, and the heating method of the sample can be controlled. Further, the detection means is the odor intensity by a odor sensor having a thin film of stannic oxide arranged in the container, and the qualitative and quantitative odor of the odor by an analyzer arranged outside the container and introduced through a sampling tube. , And can be identified.

[Brief description of drawings]

FIG. 1 is a schematic configuration diagram showing an embodiment of the present invention.

FIG. 2 is a block diagram of the mass spectrometer used in FIG.

FIG. 3 is a configuration diagram of an infrared spectrophotometer used in FIG.

[Explanation of reference numerals] 7 sample stage 10 ceramic heater 11 sample 20 container 30 analyzer 31 sampling tube 32 heater

Claims (9)

[Claims] 1. A container having a heater for heating each surface, a sample table for mounting a sample provided in the container, and an odor generated from the sample mounted on the sample table by controlling heating. An odor measuring device comprising: a temperature control means for controlling the temperature and a detecting means for measuring the odor generated from the sample. 2. The odor measuring device according to claim 1, wherein the container comprises a container body and a lid of the container body. 3. The odor measuring device according to claim 1, wherein the container is provided with an introduction pipe provided in the container body and a supply means capable of introducing a specific gas from the outside. 4. The temperature control means comprises a heater for directly heating the sample, a thermocouple for detecting the temperature of the sample, and a temperature for electrically controlling the heater and the thermocouple to control the temperature of the sample. The odor measuring device according to claim 1, comprising a controller. 5. The odor measuring device according to claim 1, wherein the temperature control means performs linear ascending heating in which the sample is constantly heated by a heater for heating the sample. 6. The odor measuring device according to claim 1, wherein the temperature control means performs constant temperature heating for keeping the sample at a constant temperature by a heater for heating the sample. 7. The odor measuring device according to claim 1, wherein the container is provided with a stirring means for making the generated odor uniform. 8. The odor measuring device according to claim 1, wherein the detecting means is an odor sensor arranged in the container and having a thin film of stannic oxide. 9. The odor measuring device according to claim 1, wherein the detecting means is an analyzer which is arranged outside the container and into which odor is introduced through a sampling tube.