JP6538998B1 - Airborne asbestos inspection device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an airborne asbestos inspection apparatus capable of inspecting with high accuracy the presence or absence of asbestos floating in the air in a short time and in a small scale configuration, a method thereof, and a filter used therefor. SOLUTION: The asbestos adsorption filter 21 is a filter provided with a hole having a hole diameter which does not allow asbestos to pass through. The asbestos adsorption filter 21 is attached with an infrared non-absorbing material of metal such as tin. While irradiating the predetermined area of the asbestos adsorption filter 21 with infrared rays from the infrared irradiation unit 23, the spectrum analysis unit 25 performs the predetermined spectrum analysis. Then, based on the spectrum analysis result, it is determined whether asbestos is suspended in the air. [Selected figure] Figure 1

Description

The present invention relates to a method for identifying asbestos, and more particularly to an airborne asbestos inspection apparatus for inspecting asbestos suspended in the atmosphere, a method thereof, and a filter for asbestos used therefor.

In conventional asbestos analysis methods, dispersion dyeing using a phase contrast microscope that makes use of the difference in refractive index between asbestos particles and other substance particles, and dispersion dyeing using a phase contrast microscope that incorporates a method that can also confirm birefringence ( Patent Document 1), an extinction angle method by a polarization microscope utilizing birefringence of asbestos, and the like.
Such microscopy is large scale and time consuming.

JP, 2013-029442, A

By the way, there is a demand to inspect the asbestos particles suspended in the work site etc. on the site in a short time.
However, in the conventional asbestos analysis method, an inspection target is collected and inspected with a microscope in another place, and there is a problem that the inspection can not be performed in a short time in the field.

The present invention has been made in view of such circumstances, and an object in a short time, and provides airborne asbestos inspection equipment to the presence of asbestos floating in the air it can be inspected with high accuracy in a small configuration It is to do.

In order to solve the problems of the prior art mentioned above and to achieve the above-mentioned purpose, the airborne asbestos inspection apparatus of the present invention has a hole with a pore diameter which does not allow asbestos to pass through, and a sheet on which an infrared non-absorbing member is deposited. and Jo filter, and suction means for the air to be tested is sucked through the suction passage toward the filter, an infrared irradiation unit for irradiating infrared rays to the predetermined region of the filter, from the predetermined area of the filter Spectral analysis means for analyzing the absorption spectrum of infrared light, the filter is located between the infrared light irradiation means, the spectral analysis means, and the suction path, and the infrared light irradiation means and the spectral analysis means Are arranged at positions not overlapping with each other in a direction orthogonal to the filter with respect to a region facing the mouth of the suction path of the filter It is, the filter, the suction means, the infrared ray irradiation means and the spectral analysis means are provided in one casing.

Preferably, the suction path is disposed so as to be located between the infrared irradiation means and the spectrum analysis means as viewed in a direction orthogonal to the filter .

Preferably, the filter after irradiating the air to be inspected is irradiated with infrared rays, and asbestos adhered to the filter contains asbestos in the air to be inspected based on the spectrum of the infrared light absorbed by the filter. And determining means for determining whether or not it is determined .

Preferably, the infrared non-absorbing member is metal .

Preferably, the infrared non-absorbing member is tin .

Preferably, the hole diameter of the filter is 0.3 to 2.5 μm .

Preferably, the filter is made of polycarbonate or cellulose ester .

Preferably, the infrared non-sucking member does not block the pores of the filter, and metal is attached by vapor deposition over the entire area of the filter on which the air flows .

Preferably, the apparatus further comprises control means for controlling the suction means to perform the suction for a predetermined period, and to repeat the operation of the determination means to perform the determination after the suction is completed .

According to the present invention, a short time, and can provide airborne asbestos inspection equipment to the presence of asbestos floating in the air it can be inspected with high accuracy in a small configuration.

FIG. 1 is a block diagram of an airborne asbestos inspection apparatus according to an embodiment of the present invention. FIG. 2 is a flowchart for explaining the asbestos inspection method using the airborne asbestos inspection device according to the embodiment of the present invention.

Hereinafter, an airborne asbestos inspection apparatus and method according to an embodiment of the present invention will be described.
FIG. 1 is a block diagram of an airborne asbestos inspection apparatus 1 according to an embodiment of the present invention.
As shown in FIG. 1, the airborne asbestos inspection apparatus 1 includes, for example, an asbestos adsorption filter 21 (filter for asbestos), an infrared irradiation unit 23, a spectrum analysis unit 25, an asbestos determination unit 27, a suction unit 31 and a control unit 41. Have.
The airborne asbestos examination apparatus 1 accommodates, for example, all the components shown in FIG. 1 in one case.

The asbestos adsorption filter 21 is a filter provided with a hole having a hole diameter that does not allow asbestos to pass through.
An infrared non-absorbing member is attached to the asbestos adsorption filter 21.
The said infrared non-adsorption member does not block the hole of the asbestos adsorption filter 21, for example, And it vapor-deposits in the whole area of the part into which the air of the structural member (porous film part) which comprises the asbestos adsorption filter 21 flows in. It is attached.

The infrared non-absorbing member is a metal that absorbs infrared radiation, for example, tin.
As described above, since the asbestos adsorption filter 21 is formed with the infrared non-absorbing member, the infrared rays are not absorbed by the portions other than asbestos when the infrared rays are irradiated as described later. Thereby, it can be discriminate | determined with high precision whether asbestos is adhering to the asbestos adsorption filter 21. As shown in FIG.
Further, by forming the infrared non-absorbing member in this way, the infrared non-absorbing member can reflect infrared rays, and asbestos adhered can be irradiated, and infrared light can be absorbed more efficiently.

Moreover, the hole diameter formed of the structural member of the asbestos adsorption filter 21 is 0.3-2.5 micrometers.
Moreover, the said structural member is formed with a polycarbonate and a cellulose ester.
The asbestos adsorption filter 21 is, for example, circular white with a diameter of 47 mm and an average pore diameter of 0.8 μm. Use grids that are not printed so as not to interfere with fiber counting.

The infrared irradiation part 23 is arrange | positioned from the asbestos adsorption filter 21 at the fixed distance in the side which the air of the asbestos adsorption filter 21 flows in.
The infrared irradiation unit 23 irradiates infrared rays to a predetermined area of the asbestos adsorption filter 21.
When the asbestos adsorption filter 21 is irradiated with infrared rays, the asbestos absorbs the infrared rays if asbestos adheres to the asbestos adsorption filter 21.

The spectrum analysis unit 25 analyzes the infrared absorption spectrum from the predetermined area of the asbestos adsorption filter 21.
The spectrum analysis unit 25 detects, for example, an absorption spectrum of near-infrared light near 1400 nanometers.

The asbestos discrimination unit 27 determines whether asbestos is suspended in the air to be inspected based on the spectrum analysis result of the spectrum analysis unit 25.
More specifically, if the asbestos discrimination unit 27 absorbs infrared light according to the spectrum analysis result of the spectrum analysis unit 25 (if the light from the asbestos adsorption filter 21 does not have an infrared spectrum), the asbestos discrimination unit 27 is in the air to be inspected. It is determined that asbestos is suspended, otherwise it is determined that asbestos is not suspended.
In addition, the asbestos discrimination unit 27 may identify and display the floating amount of asbestos according to the asbestos absorption degree (level) based on the spectrum analysis result.

  As described above, the asbestos adsorption filter 21 is irradiated with infrared rays from the infrared ray irradiation unit 23, and the spectrum of asbestos absorbed is analyzed to perform inspection in a short time with a configuration smaller than that of microscopy. be able to.

  The suction unit 31 generates a suction force in the asbestos suction filter 21 via the suction passage 33, and causes the air to be inspected outside the case 41 to flow into the asbestos suction filter 21. For example, air is collected (sucked) continuously for 4 hours at a suction flow rate of 10 L / min.

The control unit 41 generally controls the operation of the airborne asbestos inspection apparatus 1.
For example, the control unit 41 controls the suction unit 31 to perform suction for a predetermined period, and to repeat the operation in which the asbestos discrimination unit 27 performs the above-described discrimination after the suction is completed.

Hereinafter, an asbestos inspection method using the airborne asbestos inspection apparatus 1 will be described.
FIG. 2 is a flowchart for explaining an asbestos inspection method using the airborne asbestos inspection device 1 according to the embodiment of the present invention.

Step ST1:
The suction unit 31 is driven to cause the asbestos suction filter 21 to generate a suction force via the suction passage 33.
From this, the air to be inspected outside the airborne asbestos inspection apparatus 1 flows into the asbestos adsorption filter 21, and asbestos adheres to the asbestos adsorption filter 21 when asbestos floats in the air.

Step ST2:
While irradiating the predetermined area of the asbestos adsorption filter 21 with infrared rays from the infrared irradiation unit 23, the spectrum analysis unit 25 analyzes the spectrum of the predetermined area.
At this time, as described above, the asbestos adsorption filter 21 is attached by vapor deposition over the entire area of the side on which the air flows. Therefore, only asbestos that floats in the air to be inspected and adheres to the asbestos adsorption filter 21 absorbs infrared rays.

Step ST3:
The asbestos discrimination unit 27 determines whether asbestos is suspended in the air to be inspected based on the spectrum analysis result of the spectrum analysis unit 25.

Step ST4:
The discrimination result of the asbestos discrimination unit 27 is displayed.

  As described above, according to the airborne asbestos inspection apparatus 1, the asbestos adsorption filter 21 is irradiated with infrared light from the infrared irradiation unit 23, and the spectrum of asbestos absorbed by it is analyzed, as compared with the microscopic method, With a small scale configuration, inspection can be performed in a short time.

  Moreover, since the asbestos adsorption filter 21 of the airborne asbestos inspection device 1 is formed with the infrared non-absorbing member, when the infrared is irradiated, the infrared is not absorbed by the portions other than asbestos. Thereby, it can be discriminate | determined with high precision whether asbestos is adhering to the asbestos adsorption filter 21. As shown in FIG.

  Further, by forming the infrared non-absorbing member in this way, the infrared non-absorbing member can reflect the infrared ray, and the attached asbestos can be irradiated, and the asbestos can absorb the infrared ray more efficiently.

The present invention is not limited to the embodiments described above.
That is, those skilled in the art may make various modifications, combinations, subcombinations, and substitutions within the technical scope of the present invention or equivalent components thereof regarding the components of the embodiments described above.

  In the embodiment mentioned above, the case where the asbestos adsorption filter 21 (filter for asbestos), the infrared irradiation part 23, the spectrum analysis part 25, the asbestos discrimination part 27, the suction part 31 and the control part 41 were accommodated in one case was illustrated. However, all or part of these may be individually provided in a separate housing or the like.

  The present invention is applicable to a system for inspecting asbestos suspended in the air.

1 ... airborne asbestos inspection device 21 ... asbestos adsorption filter 23 ... infrared irradiation unit 25 ... spectrum analysis unit 27 ... asbestos determination unit 31 ... suction unit 41 ... control unit

Claims (9)

A sheet-like filter having pores with a pore size that does not pass through asbestos, and the infrared non-absorbing member is vapor-deposited ;
Suction means for suctioning air to be inspected toward the filter via a suction path;
Infrared irradiation means for irradiating an infrared ray to a predetermined area of the filter ;
Spectrum analysis means for analyzing the absorption spectrum of infrared radiation from the predetermined region of the filter ;
The filter is located between the infrared irradiation means and the spectrum analysis means, and the suction path .
The infrared irradiation means and the spectrum analysis means are arranged at positions where they do not overlap with respect to a region facing the mouth of the suction path of the filter, as viewed from the direction orthogonal to the filter.
An airborne asbestos examination apparatus , wherein the filter, the suction means, the infrared irradiation means and the spectrum analysis means are provided in one case . The airborne asbestos inspection apparatus according to claim 1, wherein the suction path is located between the infrared irradiation unit and the spectrum analysis unit as viewed in a direction orthogonal to the filter. Irradiating the infrared ray to the filter after sucking the air to be inspected, and whether asbestos is contained in the air to be inspected based on the spectrum in which the asbestos attached to the filter absorbed the infrared light The airborne asbestos examination apparatus according to claim 1 or 2, further comprising: discrimination means for discriminating. The airborne asbestos inspection apparatus according to any one of claims 1 to 3 , wherein the infrared non-absorbing member is a metal. The airborne asbestos inspection device according to claim 4, wherein the infrared non-absorbing member is tin. The airborne asbestos inspection device according to any one of claims 1 to 5 , wherein a hole diameter of the filter is 0.3 to 2.5 μm. The airborne asbestos inspection device according to any one of claims 1 to 6 , wherein the filter is made of polycarbonate or cellulose ester. The metal according to any one of claims 1 to 7 , wherein the infrared non-sucking member does not block the pores of the filter, and metal is attached by vapor deposition over the entire area of the filter on which the air flows. Airborne asbestos inspection device. The air floating asbestos according to any one of claims 1 to 8 , further comprising: control means for performing control so that the suction means performs the suction for a predetermined period, and the discrimination means repeats the operation of performing the discrimination after the suction is completed. Inspection device.

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