JP2009162576A - Evaluation device, evaluation method, and computer program - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To determine quickly a countermeasure to an asbestos inclusion to be executed in a space having the asbestos inclusion. <P>SOLUTION: A method includes: a step of blowing an air current to the asbestos inclusion in the space having the asbestos inclusion, to thereby collect asbestos scattered by the air current, and receiving input of the number of fibers of the collected asbestos; a step of acquiring a risk degree by the asbestos in the space based on the number of fibers of the asbestos; and a step of outputting the acquired risk degree. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to an evaluation apparatus, an evaluation method, and a computer program for evaluating the risk level of asbestos in a space having asbestos-containing material.

As is well known, asbestos (asbestos) has been widely used in various fields including building materials since it has excellent physical properties. However, in recent years, it has become clear that the dust causes serious health damage, which is a serious social problem.
In order to take measures against asbestos dust, it is essential to know the concentration of asbestos dust in the ambient air. Therefore, an “asbestos monitoring manual” has been formulated as a technical guideline for measuring the concentration of asbestos dust in the ambient air (see Non-Patent Document 1).
“Asbestos Monitoring Manual (Revised Version)”, Air Quality Control Division, Air Quality Control Bureau, December 1993, p.1-6

The measurement method of asbestos dust concentration specified in Non-Patent Document 1 is the amount of asbestos dust in the atmosphere by continuously sampling the atmosphere over a long period of time at a measurement target point and passing it through a filter paper for collection (membrane filter). It is based on measuring.
Certainly, the average concentration in the atmosphere near the measurement target point can be measured by such a measurement technique. However, even with this measurement method, it is not possible to directly measure the amount of dust generated from a specific building material or to specify the dust generation location.

In order to take more advanced measures, the measurement method should be able to grasp not only the average concentration in the ambient air but also the possibility of asbestos dust generation and the degree of deterioration of building materials. Establishment is needed. And after establishing such a measuring method, it is necessary to determine quickly what kind of measures should be taken based on the measured result.
In view of the above circumstances, an object of the present invention is to provide an apparatus, a method, and a computer program that can quickly determine a countermeasure for the asbestos-containing material to be implemented in a space having the asbestos-containing material.

The present invention is an evaluation apparatus, and includes an input unit, an evaluation unit, and an output unit. The input means receives an input of the number of asbestos fibers. The number of asbestos fibers is the number of asbestos fibers that are scattered and collected by the air current applied to the asbestos-containing material in the space containing the asbestos-containing material. An evaluation means acquires the risk degree by the asbestos in space based on the fiber number of the input asbestos. The output means outputs the acquired risk degree.
According to the evaluation apparatus configured as described above, the asbestos risk degree in this space can be evaluated based on the number of asbestos fibers scattered from the measurement target site by the airflow. For this reason, it is possible to obtain a degree of risk that reflects the possibility of asbestos dust generation and the degree of deterioration of building materials leading to it, not just the average concentration in the ambient air. Therefore, it is possible to select a more reliable countermeasure method using this degree of risk.

Moreover, the evaluation apparatus of this invention may be comprised so that the memory | storage means which memorize | stores the coping method which should be taken with respect to the asbestos-containing material in space according to a risk degree may be comprised further. In this case, the evaluation unit is configured to read out a coping method corresponding to the acquired risk degree. The output means is configured to output the coping method read by the evaluation means.
According to the evaluation apparatus configured as described above, a coping method according to the degree of risk is output. Therefore, it becomes possible for a user who does not have knowledge about a coping method corresponding to the degree of risk to easily select a coping method to be taken.

Moreover, the evaluation means in the evaluation apparatus of this invention may be comprised so that the density | concentration of asbestos in space may be calculated and a risk degree may be acquired based on the value of this density | concentration. More specifically, this process is performed as follows. The evaluation means calculates the asbestos concentration (asbestos concentration in the space) in this space based on the input number of asbestos fibers and the parameters relating to the space in which the asbestos collection process and the collection process are performed. And an evaluation means acquires a risk degree based on this calculation result.
The present invention may be specified as a computer program for operating a computer as the above-described evaluation apparatus. Further, the present invention may be specified as an evaluation method performed by a computer that functions as the above-described evaluation apparatus. In addition, the present invention may be specified as a risk degree evaluation method.

  According to the present invention, it is possible to quickly determine a countermeasure against the asbestos-containing material to be implemented in a space having the asbestos-containing material.

[First embodiment]
When the evaluation apparatus according to the present invention operates, the scattering amount measurement is performed in advance, and the measurement result is input to the evaluation apparatus. And based on this input, the evaluation apparatus by this invention acquires and outputs the parameter | index regarding the countermeasure with respect to an asbestos containing material. First, the scattering amount measurement for obtaining the measurement result input to the evaluation apparatus according to the present invention will be described.
In the operation of the evaluation apparatus according to the present invention, the scattering amount measurement performed in advance is performed by blowing an air flow having a predetermined flow rate and a predetermined flow rate on the asbestos-containing material, and filtering the air containing the asbestos dust generated by the filter. Asbestos dust is collected on the filter by suction through the filter, and the number of fibers of the asbestos dust is measured. Hereinafter, a specific example of such scattering amount measurement will be described.

  FIG. 1 is a schematic configuration diagram of a measuring apparatus used for the scattering amount measurement. This measuring apparatus measures various asbestos-containing materials, for example, structural members such as steel beams whose surface is covered with fireproof asbestos as shown in the illustrated example. Hereinafter, such an object to be measured is referred to as a measurement object 1. The measuring device is a device for directly measuring the amount of asbestos dust from a specific part of the surface of the measuring object 1. The measurement apparatus is configured to cover the periphery of the measurement target region, the collection mechanism 3 attached to the cover 2, and be connected to the collection mechanism 3 to suck the air in the cover 2 through the collection mechanism 3. An intake pipe 4, an intake pump 5 connected to the proximal end of the intake pipe 4, a flow meter 6 built in the intake pump 5 for measuring the intake air amount, and a cover 2 provided through the intake pipe 5. An injection pipe 7 that blows air outside the cover 2 from the tip of the cover 2 to the measurement target site in an injection state by the suction force of the pump 5 and a collection mechanism 8 attached to the base end of the injection pipe 7 are provided.

The measurer uses the measuring apparatus having the above-described configuration to attach the cover 2 to the site to be measured, cover the periphery of the cover 2 in an airtight state, operate the intake pump 5 and suck the air in the cover 2. .
By this operation, the jet air flow from the jet pipe 7 is blown to the measurement target site at a predetermined wind speed, and the asbestos in the surface layer portion is blown off, so that a very small amount of dust is generated in the cover 2. Asbestos dust scattered in the cover 2 is sucked together with the air in the cover 2 by the collecting mechanism 3. Then, the entire amount sucked is collected by the membrane filter 3a. Only clean air after the asbestos dust is collected is sucked into the intake pump 5 through the intake pipe 4 and exhausted out of the system.

  The measurer performs such a collection operation for a predetermined time, then stops the operation of the measurement apparatus, and removes the collection mechanism 3 from the cover 2. The measurer further takes out the membrane filter 3a from the collection mechanism 3, and measures the number of fibers of the asbestos dust that has been forcedly generated. This measurement may be performed visually using a microscope, or may be automatically performed by image processing using an enlarged image by a microscope. The measurement result is input to the evaluation apparatus according to the present invention. The evaluation device performs evaluation based on this measurement result. The method for measuring the amount of scattering described above and the measuring apparatus used for measuring the amount of scattering are one specific example. Therefore, the method for measuring the amount of scattering performed when using the evaluation apparatus according to the present invention and the apparatus used for this measurement need not be limited to those described above.

Next, the evaluation apparatus according to the present invention will be described. FIG. 2 is a functional block diagram showing a functional configuration of the evaluation apparatus 100a which is the first embodiment of the evaluation apparatus according to the present invention. The evaluation device 100a includes an input unit 10, an output unit 20, and an evaluation unit 30a. The evaluation device 100a can be configured using an information processing device that is connected to a computing device or a storage device via a bus and operates based on a program stored in the storage device. Each functional unit or part of the evaluation device 100a may be configured using dedicated hardware. Hereinafter, each function part with which the evaluation apparatus 100a is provided is demonstrated using FIG.
The input unit 10 receives a command or numerical value input from a user via an input device (not shown) connected to the evaluation device 100a. The input device may be configured using, for example, a keyboard, a pointing device (mouse, trackball, tablet, etc.), a dial-type input device, a touch panel, a numeric keypad, various buttons, a voice input device, or the like. The input device may be configured using any other device as long as the user of the evaluation device 100a can input an instruction or a numerical value to the evaluation device 100a.
The input unit 10 accepts input of data related to measurement results and measurement conditions in the scattering amount measurement performed in advance. Details of data relating to measurement results and measurement conditions will be described later.

  The output unit 20 outputs data to the user of the evaluation device 100a via an output device (not shown) connected to the evaluation device 100a. The output device may be configured using, for example, a device that outputs images and characters on a screen. For example, the output device can be configured using a CRT (Cathode Ray Tube), a liquid crystal display, an organic EL (Electro-Luminescent) display, or the like. The output device may be configured using a device that prints (prints) an image or a character on a sheet. For example, the output device can be configured using an ink jet printer, a laser printer, or the like. In addition, the output device may be configured using a device that converts characters into speech and outputs the speech. In this case, the output device can be configured using a voice synthesizer and a voice output device (speaker). Hereinafter, a case where the output device is configured using an image display device will be described.

式１において、Ｆ．Ｅ．は、単位面積アスベスト繊維飛散数を示す。単位は、本／ｍ^２・分である。Ｎ_ｆは、予め実施された飛散量測定によって得られた捕集繊維のうち、プレパラート上の所定範囲（以下、「視野」という。）内、所定視野数で計数された総繊維数（以下、「計数分析繊維数」という。）を示し、単位は本である。Ａ_Ｆは、飛散量測定において石綿粉塵の捕集の際に使用されたフィルタ（上述した測定装置においては捕集機構３のメンブレンフィルター３ａが相当する）の有効面積を示し、単位はｍｍ^２である。Ａ_Ｌは、飛散量測定において、石綿含有物に対して空気流を吹き付けるために使用されたノズル（上述した測定装置においては噴射管７が相当する）の面積を示し、単位はｍ^２である。ａは、顕微鏡で計数分析繊維数を計数分析する際の一の視野の面積を示し、単位はｍｍ^２である。ｎは、計数分析を行った視野の数を示す。例えば、捕集された石綿粉塵を含むプレパラート上の５０視野において計数分析を行った場合は、この５０という数字がｎに相当する。Ｔは、飛散量測定を行った時間を示し、単位は分である。例えば、上述した測定装置において、測定対象部位にカバー２を装着して吸気ポンプ５によって吸気を行った時間がＴに相当する。 The evaluation unit 30a uses the measurement result of the scattering amount measurement input via the input unit 10 to evaluate the risk level (risk level) of the asbestos-containing material in the space where the measurement is performed. The evaluation unit 30a calculates the asbestos concentration in the space to be measured, and acquires the risk level based on this value. First, a specific example is shown about the calculation method of the asbestos concentration by the evaluation part 30a.
The evaluation unit 30a calculates the number of asbestos fibers generated from the unit area per unit time (hereinafter referred to as “unit area asbestos fiber scattering number”). Formula 1 is a formula for calculating the number of unit area asbestos fibers scattered.

In Formula 1, F. E. Indicates the number of scattered asbestos fibers per unit area. The unit is book / m ² · min. N _f is the total number of fibers (hereinafter referred to as the following) counted within the predetermined range (hereinafter referred to as “field of view”) on the slide of the collected fibers obtained by the scattering amount measurement performed in advance. "The number of fibers to be analyzed"), and the unit is book. A _F represents the effective area of the filter used for collecting asbestos dust in the scattering amount measurement (in the measurement apparatus described above, the membrane filter 3a of the collection mechanism 3 corresponds), and the unit is mm ² . is there. A _L indicates the area of a nozzle (corresponding to the injection pipe 7 in the above-described measuring apparatus) used to blow an air flow against the asbestos-containing material in the scattering amount measurement, and the unit is m ² . . a shows the area of one visual field when counting and analyzing the number of fibers for counting analysis with a microscope, and the unit is mm ² . n indicates the number of visual fields subjected to counting analysis. For example, when the count analysis is performed in 50 visual fields on the preparation containing the collected asbestos dust, the number 50 corresponds to n. T represents the time when the scattering amount measurement was performed, and the unit is minutes. For example, in the measurement apparatus described above, the time when the cover 2 is attached to the measurement target portion and the intake pump 5 performs intake is equivalent to T.

式２において、Ｔ．Ｆ．Ｅ．は、全アスベスト繊維飛散速度を示し、単位は本／分である。Ｆ．Ｅ．_ｔは、ｔ種類目の石綿含有物から飛散する単位面積アスベスト繊維飛散数を示し、単位は本／ｍ^２・分である。Ａ_ｔは、ｔ種類目の石綿含有物が、評価対象空間内においてそれぞれ使用されている面積を示し、単位はｍ^２である。式２においては、石綿含有物の種類毎にＦ．Ｅ．_ｔ及びＡ_ｔが算出され、それを乗じたものを石綿含有物全種類分加算することにより、全アスベスト繊維飛散速度が算出される。 Next, the evaluation unit 30a calculates the number of asbestos fibers (hereinafter referred to as “total asbestos fiber scattering speed”) scattered in the space to be evaluated in one minute. Formula 2 is a formula for calculating the total asbestos fiber scattering rate.

In Equation 2, T.I. F. E. Indicates the total asbestos fiber scattering rate, and the unit is book / minute. F. E. _t represents the number of unit area asbestos fibers scattered from the asbestos-containing material of the t type, and the unit is book / m ² · min. A _t the asbestos-containing product of t kind th, shows the area that is being used respectively in evaluation space, the unit is m ^2. In Formula 2, F.F. for each type of asbestos-containing material. E. _t and A _t are calculated, by those multiplied it adds all kinds min asbestos-containing material, the total asbestos fiber scattering rate is calculated.

式３において、Ａ．Ａ．Ａ．Ｃ．は、空間内アスベスト濃度を示し、単位は本／リットルである。Ｃ_Ｏは、外気アスベスト濃度を示し、単位は本／リットルである。なお、外気アスベスト濃度はゼロに近い値であると仮定することにより、評価部３０ａの動作において、ゼロが代入されても良い。Ｎ_Ｖは、評価の対象となっている空間における一時間当たりの換気回数を示す。Ｖは、評価の対象となっている空間の気積を示し、単位はｍ^３である。 Next, the evaluation unit 30a calculates an asbestos concentration in the space to be evaluated (hereinafter referred to as “in-space asbestos concentration”). Expression 3 is an expression for calculating the in-space asbestos concentration.

In Equation 3, A. A. A. C. Indicates the asbestos concentration in the space, and the unit is book / liter. _CO represents the outdoor asbestos concentration, and the unit is book / liter. Note that by assuming that the outdoor air asbestos concentration is a value close to zero, zero may be substituted in the operation of the evaluation unit 30a. N _V shows the ventilation rate per hour in the space that is the target of evaluation. V represents the volume of the space to be evaluated, and its unit is m ³ .

When the evaluation unit 30a receives the measurement result of the scattering amount and the data regarding the measurement condition (hereinafter, each numerical value is collectively referred to as “parameter”) via the input unit 10, the above-described Equation 1 to Equation 3 are used. Is used to calculate the asbestos concentration in the space for the space to be evaluated. Then, the calculated in-space asbestos concentration is output to the user via the output unit 20.
Next, an operation example of the evaluation apparatus 100a will be described. FIG. 3 is a flowchart illustrating an operation example of the evaluation apparatus 100a. First, the evaluation unit 30a displays an input screen on the image display device via the output unit 20 (S01).

FIG. 4 is a diagram illustrating an example of the input screen. Hereinafter, the input screen will be described with reference to FIG. The input screen is provided with an input field for inputting each parameter. In the case of FIG. 4, in order to input the sampling time, the filter effective area, the nozzle area, the number of fibers to be analyzed, the number of fields of view, and the field diameter as parameters, respective input fields (columns represented by horizontally long rectangles) Is provided. Here, the input fields for entering the number of ventilations, the use area of the asbestos-containing material in the space, and the volume of the space as values required in the calculation using the equations 1 to 3 are on the input screen. It is not displayed. This is because these values are evaluated by the evaluation unit 30a using hypothetical values instead of actual numerical values as assumption conditions. The assumption conditions are set as appropriate by the designer or user of the evaluation apparatus 100a. For example, all asbestos-containing materials are blown at a wind speed of about 1.8 meters per second, and ventilation is performed at 0.5 times / hour, which is the minimum required ventilation rate set by the Building Standards Act and the Enforcement Ordinance. The assumption is that the use area of the asbestos-containing material in the space is 1000 m ² and the volume of the space is 3000 m ³ . Note that the evaluation unit 30a may be configured to perform the evaluation using the input values without using the assumption conditions for these values. In this case, an input field for inputting these values is provided on the input screen. Moreover, among the assumption conditions mentioned above, the condition that the wind hits the asbestos-containing material at a wind speed of about 1.8 meters per second is the wind speed of the air flow injected from the injection pipe 7 when performing the scattering amount measurement. Used.

  In addition, although the visual field area is used in the above-described formula 1, this value can be calculated by the evaluation unit 30a squaring the half of the visual field diameter and multiplying by the circumference. In addition, in the case of FIG. 4, in order to improve the accuracy of evaluation, an input column is provided so that the number of fibers for counting analysis, the number of fields of view, and the field of view diameter can be entered when the scattering amount measurement is performed three times by the user. Is provided. The number of count analysis fibers, the number of fields of view, and the field of view diameter that can be input can be freely designed by the designer or user of the evaluation apparatus 100a. The sampling time, the effective filter area, the nozzle area, the number of fields, and / or the field diameter may be configured so as to omit input by using fixed numbers in the implementation of the scattering amount measurement. .

  Returning to the description of the operation example of the evaluation apparatus 100a. When the user inputs each parameter to the input screen using the input device, the input result is accepted by the input unit 10 and passed to the evaluation unit 30a (S02). The evaluation unit 30a calculates the asbestos concentration in the space based on Expressions 1 to 3 using each input parameter (S03). The evaluation unit 30a acquires the risk level of the asbestos-containing material in the space to be evaluated based on the calculated asbestos concentration in the space (S04). Any method may be applied as the method of acquiring the risk level. For example, the evaluation unit 30a may calculate a common logarithm of the calculated in-space asbestos concentration and acquire this value as the risk degree. In addition, the evaluation unit 30a may obtain the degree of risk as a positive number that is easier for the user to understand by calculating the common logarithm of the asbestos concentration in the space and truncating the fractional part. Further, the evaluation unit 30a may acquire the calculated asbestos concentration itself as the risk degree. Also, a plurality of threshold values and risk levels corresponding thereto may be provided, and the risk levels may be acquired from the relationship between the calculated asbestos concentration in the space and the threshold values. Then, the evaluation unit 30a displays the acquired risk degree on the image display device via the output unit 20 (S05). For example, the evaluation unit 30a outputs the risk degree in the “determination” column below the input screen shown in FIG.

By using the evaluation apparatus 100a configured as described above, the asbestos dust generation amount that is forcibly generated from the measurement target portion by the injection air flow is directly related to the intake air amount (= the injection air amount). It is possible to determine quantitatively and easily determine the degree of risk based on this value. By acquiring the risk level using this method, the risk level that reflects the possibility of asbestos dust generation and the deterioration of building materials that leads to it, not just the average concentration in the ambient air, is acquired. It becomes possible to do. Therefore, it is possible to take more advanced measures using this degree of risk.
In addition, the evaluation unit 30a is configured to acquire and output the degree of risk by a method using a common logarithm or a threshold value, so that the user does not have specialized knowledge about the asbestos concentration in the space. It is possible to understand the degree of risk sensuously. Therefore, it is possible to easily determine whether the risk of scattering due to the asbestos-containing material is low or high in the space to be evaluated.

[Second Embodiment]
The evaluation apparatus 100a according to the first embodiment outputs a risk level, but it is determined for a user who does not have specialized knowledge what countermeasures should be taken based on the risk level. It was difficult. The second embodiment is an invention proposed in view of such problems.

FIG. 5 is a functional block diagram showing a functional configuration of the evaluation apparatus 100b which is the second embodiment of the evaluation apparatus according to the present invention. The evaluation device 100b differs from the evaluation device 100a in that it includes an evaluation unit 30b instead of the evaluation unit 30a and further includes a storage unit 40. Hereinafter, differences between the evaluation apparatus 100b and the evaluation apparatus 100a will be described.
The evaluation unit 30b differs from the evaluation unit 30a in that output is performed based on the contents of the risk degree database stored in the storage unit 40. When the evaluation unit 30b obtains the risk level by the same process as the evaluation unit 30a, the evaluation unit 30b reads out information about the comment and the coping method corresponding to the risk level from the storage unit 40. And the information regarding a risk degree, a comment, and a coping method is output via the output part 20. FIG.

The storage unit 40 is configured using a so-called nonvolatile storage device such as a hard disk or a semiconductor storage device. The storage unit 40 stores a risk degree database. FIG. 6 is a diagram showing the contents of the risk degree database. The risk level database has a risk level and information on a coping method required according to each risk level in association with each other.
A coping method is a coping method with respect to the asbestos-containing material in the evaluation target space. Specific examples of such countermeasures include follow-up observation, containment, enclosure and removal. Each coping method has different effects and required costs. Generally, cost and effectiveness increase in the order of follow-up, containment, enclosure and removal. In the risk degree database, for each risk degree, it is indicated whether or not it is sufficient to implement a plurality of types of countermeasures. If it is enough, it will be given a double circle or ○, if not enough, but if it is temporary, it will be given a triangle, otherwise it will be given a cross. Furthermore, a comment is also given for each risk level.

FIG. 7 is a diagram illustrating an example of a screen output by the evaluation apparatus 100b of the second embodiment. Information read from the risk degree database is output to the screen according to the second embodiment in accordance with the risk degree acquired by the evaluation unit 30b. In other words, information related to the coping method is output according to the risk degree acquired by the evaluation unit 30b.
According to the evaluation apparatus 100b configured as described above, not only the risk level but also information related to a countermeasure to be taken according to the risk level is output. For this reason, even a user who does not have knowledge about a coping method according to the degree of risk can easily determine the coping method to be taken. For example, by outputting the information of risk level 4 shown in FIG. 7, it is possible for those who do not have enough funds to take effective measures while reducing costs by enclosing instead of removing them. Become.

In addition, you may make it implement | achieve the function of some evaluation apparatuses 100a and 100b in the embodiment mentioned above, for example, the evaluation parts 30a and 30b. In that case, a program for realizing the information management function may be recorded on a computer-readable recording medium, and the program recorded on the recording medium may be read into a computer system and executed. The “computer system” here includes an OS and hardware such as peripheral devices. The “computer-readable recording medium” refers to a portable medium such as a flexible disk, a magneto-optical disk, a ROM, and a CD-ROM, and a storage device such as a hard disk built in the computer system. Further, the “computer-readable recording medium” dynamically holds a program for a short time, like a communication line when transmitting a program via a network such as the Internet or a communication line such as a telephone line. It is also possible to include those that hold a program for a certain time, such as a volatile memory inside a computer system serving as a server or client in that case. The program may be a program for realizing a part of the functions described above, and may be a program capable of realizing the functions described above in combination with a program already recorded in a computer system.
The embodiment of the present invention has been described in detail with reference to the drawings. However, the specific configuration is not limited to this embodiment, and includes designs and the like that do not depart from the gist of the present invention.

  INDUSTRIAL APPLICABILITY The present invention can be used in a scene where an asbestos-containing material is determined in a space having asbestos-containing material.

It is a schematic block diagram of the measuring apparatus used for scattering amount measurement. It is a functional block diagram which shows the function structure of 1st embodiment of the evaluation apparatus by this invention. It is a flowchart which shows the operation example of 1st embodiment of the evaluation apparatus by this invention. It is a figure which shows the example of the input screen output by 1st embodiment of the evaluation apparatus by this invention. It is a functional block diagram which shows the function structure of 2nd embodiment of the evaluation apparatus by this invention. It is a figure which shows the content of a risk degree database. It is a figure which shows the example of the input screen output by 2nd embodiment of the evaluation apparatus by this invention.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 ... Measuring object 2 ... Cover 3 ... Collection mechanism 3a ... Membrane filter 4 ... Intake pipe 5 ... Intake pump 6 ... Flow meter 7 ... Injection pipe 8 ... Collection mechanism 10 ... Input part 20 ... Output part 30a, 30b ... Evaluation unit 40 ... Storage unit 100a, 100b ... Evaluation device

Claims (5)

An air flow is applied to the asbestos-containing material in the space having the asbestos-containing material, the asbestos scattered by the air current is collected, and input means for receiving an input of the number of fibers of the collected asbestos,
Based on the number of asbestos fibers input, the evaluation means for obtaining the degree of risk due to asbestos in the space;
An output means for outputting the acquired degree of risk;
An evaluation apparatus comprising: According to the degree of risk, further comprising storage means for storing a coping method to be taken for the asbestos-containing material in the space,
The evaluation means reads the coping method according to the acquired risk degree,
The output means outputs a coping method read by the evaluation means;
The evaluation apparatus according to claim 1. An air current is applied to the asbestos-containing material in a space having the asbestos-containing material, the asbestos scattered by the air current is collected, and the computer receives an input of the number of fibers of the collected asbestos; and
A computer obtaining a risk level of asbestos in the space based on the number of fibers of the asbestos;
A step in which the computer outputs the obtained degree of risk;
Evaluation method including Against the computer
An airflow is applied to the asbestos-containing material in the space having the asbestos-containing material, the asbestos scattered by the airflow is collected, and the step of accepting the input of the number of fibers of the collected asbestos;
Based on the number of fibers of the asbestos, obtaining a risk level due to asbestos in the space;
Outputting the obtained risk level; and
A computer program for running. In the space having the asbestos-containing material, applying an airflow to the asbestos-containing material, collecting the asbestos scattered by the airflow;
Counting the number of asbestos fibers collected;
Based on the number of fibers of the asbestos, obtaining a risk level due to asbestos in the space;
Evaluation method including

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