KR101754020B1 - Method for cleanse slit of image data acquisition unit of airborne asbestos concentration - Google Patents

Abstract

The present invention relates to a slit cleaning method for an image data acquisition apparatus for measuring a non-asbestos surface concentration, and a cleaning agent is sprayed to the slit through an injection path provided in an inlet block to be measured to remove residual material remaining on the slit. In the present invention, the cleaning agent injected from the residual material removing unit flows into the first inlet through the injection flow path of the object to be measured, moves along the ramp, and is injected through the second inlet into the slit at an inclined angle to clean the slit , Time and manpower for slit cleaning are not consumed, the ash ash concentration can be measured efficiently, and the measurement reliability can be improved.

Description

TECHNICAL FIELD [0001] The present invention relates to a slit cleaning method for an image data acquisition device for measuring asbestos ash concentration,

The present invention relates to a slit cleaning method for an image data acquisition apparatus for measuring a non-asbestos surface concentration, and more particularly, to an image data acquisition apparatus for acquiring an asbestos aspheric surface concentration, Slit cleaning method.

Recently, interest in asbestos has increased as dismantling and repair work has been increasingly applied to buildings containing asbestos, and the legal regulations on dismantling and repairing asbestos-containing buildings have been strengthened, thus necessitating cost-effective asbestos analysis .

Asbestos (asbestos) is a group of minerals produced from natural stone, and has a high tensile strength and flexibility. Asbestos is easily split into long, thin and strong fibers and can be woven with cloth. In addition, it has heat resistance, inertness, and insulating properties and is commonly used where nonflammability, electrical conductivity, and chemical inertness are required.

Most asbestos is consumed in building materials, automobile parts, and textiles. Since asbestos is highly preserved in the body and is highly toxic to humans, only very limited operators can handle it. If asbestos is inhaled for a long time, it is known that diseases such as lung cancer, malignant mesothelioma, and asbestosis may occur. Due to the harmful effects of asbestos mentioned above, the removal of asbestos and the measurement of asbestos concentration are frequently performed in public subway sections, schools, and infrastructure facilities.

In order to measure asbestos, asbestos measuring device is introduced in overseas or domestic. A common asbestos measuring device should be repeatedly operated by an operator when the asbestos is being measured, such as by replacing and recovering the filter. Therefore, there is a problem that it takes a lot of manpower and time to measure the asbestos, which is inefficient and the measurement reliability is lowered.

It is an object of the present invention to provide an image data acquisition device for measuring the concentration of non-asbestos aspheric surface, Slit cleaning method.

The problems of the present invention are not limited to those mentioned above, and other problems not mentioned can be clearly understood by those skilled in the art from the following description.

According to another aspect of the present invention, there is provided a slit cleaning method of an image data acquisition apparatus for measuring a non-asbestos surface concentration, comprising: injecting a cleaning agent into a slit through an injection path provided in an inlet block to be measured, .

In addition, the measurement target inflow block is provided with an air injection path for allowing the measurement air to flow into the accommodation space side, and when the image data acquisition is required, the first storage room And the air injection path are communicated with each other so that measurement air passing through the first storage chamber flows into the air injection path side and when cleaning of the slit is required after acquisition of image data by the slit, It is preferable that the second storage chamber in which air is stored and the air inlet passage communicate with each other so that the cleaning air passing through the second storage chamber flows into the air inlet passage.

Further, the present invention includes heating the cleaning air before the cleaning air flows into the air injection path, thereby removing the residual material remaining on the slit with the heated cleaning air desirable.

In addition, it is preferable that the cleaning agent sprayed on the slit side is a liquid material containing an alcohol component, and the accommodation space of the measurement target inflow block is heated so that the liquid material can be smoothly removed in the accommodation space.

A slit cleaning method for an image data acquisition apparatus for measuring a non-asbestos surface concentration according to the present invention having the above-described structure comprises the steps of: injecting a cleaning agent sprayed from a residual material removal unit into a first inlet through an injection flow path of an object- And the slit is sprayed on the slit through the second inlet to form an inclined angle with the slit through the slit so that clear image data for measurement of the non-asbestos surface concentration can be obtained, measurement reliability can be improved, Slit replacement and replacement work for slit cleaning is not wasted and asbestos concentration can be measured efficiently.

The effects of the present invention are not limited to those mentioned above, and other solutions not mentioned may be clearly understood by those skilled in the art from the following description.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a cross-sectional view of an image data acquisition apparatus for measuring a non-asbestos surface concentration according to an embodiment of the present invention; FIG.
2 is a partially enlarged view of an image data acquisition device for measuring a non-asbestos surface concentration according to an embodiment of the present invention;
3 is a block diagram for explaining a slit cleaning method of an image data acquisition apparatus for measuring a non-asbestos surface concentration according to an embodiment of the present invention.

Hereinafter, a slit cleaning method of an image data acquisition apparatus for measuring a non-asbestos surface density according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

However, for convenience of explanation, before describing the slit cleaning method of the image data acquisition device for measuring the non-asbestos surface concentration of the present invention, the configuration of the cleaning device employed to implement the cleaning method will be described first do.

FIG. 2 is a partially enlarged view of an image data acquisition device for measuring a non-asbestos surface density according to an embodiment of the present invention. FIG. 3 is a block diagram for explaining a slit cleaning method of an image data acquisition apparatus for measuring a non-asbestos surface density according to an embodiment of the present invention.

As shown in these figures, for the slit cleaning method implementation of the image data acquisition device for the non-asbestos concentration measurement, a measurement target inlet block 400 and a residual material removal unit 10 are included.

The measurement object inlet block 400 is coupled with the optical block 100 to form a receiving space. And accommodates the slit (300) in the accommodating space. The measurement target inflow block 400 includes an air injection path 401 and an injection path 402. The air injection path 401 of the measurement target inflow block 400 allows the measurement air containing the measurement object to be injected into the accommodation space. The inlet block 400 includes an injection path 402 for injecting a cleaning agent for cleaning the slit 300 into the slit 300.

The air injection path 401 of the measurement target inflow block 400 includes a first inlet 401a, a second inlet 401b, a ramp 401c, and a guide passage 401d. The first inlet 401a is formed at a position eccentric to the central axis of the slit 300 accommodated in the inlet block 400 and communicated with the guide passage 401d. The second inlet 401b is formed on the same axis of the slit 300 and is connected to the first inlet 401a. The ramp 401c is provided between the first inlet 401a and the second inlet 401b and is inclined from the first inlet 401a to the second inlet 401b.

The air injection unit 20 is preferably a 3-way valve. When it is required to acquire image data of the measurement object, the air storage unit 30 (see FIG. 3) in which measurement air is stored and the guide passage 401d ). When the cleaning of the slit 300 is required after acquiring the image data, the second storage chamber 40 (see FIG. 3) storing the cleaning air communicates with the guide passage 401d.

The residual material removing unit 10 (see FIG. 3) injects the cleaning agent toward the slit 300 through the injection path 402 formed in the measurement target inflow block 400.

On the other hand, the present embodiment may further include an air heating unit 50 (see Fig. 3). The air heating unit (50) heats the measurement air and the cleaning air. The air heating unit 50 enables the slit 300 for image data acquisition to prevent the temperature from dropping due to the measurement air and the cleaning air.

The remnant material removing unit 10 described above may include a cleaning pump unit (not shown). The cleaning pump unit is pumped driven, allowing the residual material removal unit 10 to inject the cleaning agent. Further, it may further include a vacuum pump unit 70 for discharging the measurement air and the cleaning air.

The present embodiment (see FIG. 3) may further include a discharge filter 80 to prevent air contamination due to the discharge of the measurement air and the cleaning air. The apparatus may further include a flow sensor (S) for measuring the amount of the measurement air and the amount of the cleaning air. The apparatus may further include a micro-material passage unit (not shown) disposed between the first storage chamber 30 and the air injection unit 20 for filtering substances other than the measurement object.

The apparatus may further include a foreign matter filter unit (not shown) disposed between the second storage chamber 40 and the air injection unit 20 for filtering the foreign substances contained in the cleaning air. The present embodiment further includes a block heating unit 60 for heating (heating) the interior of the measurement target inflow block 400 for evaporation of the cleaning agent injected into the measurement target inflow block 400 It is possible. The apparatus may further include an alcohol evaporation vessel 90 for evaporating the alcohol component remaining in the cleaning air when the cleaning air is discharged.

Hereinafter, a slit cleaning method of the image data acquisition device for measuring the non-asbestos surface concentration will be described in detail with reference to FIG.

In order to acquire image data of the measurement object, the measurement air is injected into the measurement target inflow block 400 through the air injection path 401. At this time, residual material remains in the slit (300). In order to remove the residual material, a cleaning agent is sprayed to the slit 300 side through the injection path 402 provided in the measurement target inflow block 400 to remove the residual material remaining in the slit image 300 .

The measurement air to be injected into the slit 300 is discharged through an outlet 403 provided in the measurement target inflow block 400 after acquiring image data. The measurement target material in the measurement air that has not been discharged remains in the slit 300. Residual materials (non-discharged measurement object and foreign matter, etc.) remaining in the slit 300 are removed by the cleaning agent injected by the residual material removal unit 10.

The detergent sprayed from the residual material removing unit 10 flows into the first inlet 401a through the injection path 402 (see FIG. 2) of the measurement target inflow block 400. Thereafter, the cleaning agent moves along the ramp 401c and is injected into the slit 300 through the second inlet 401b. The cleaning agent is injected toward the slit 300 in a slant angle with the slit 300 due to the inclined structure of the slant path 401c formed in the air injection path 401 (see FIG. 2).

The slit 300 is cleaned by the material properties of the cleaning agent. In addition, the slit 300 is washed away by the spray angle of the cleaning agent according to the structural characteristics of the air injection path 401, while the residual material is desorbed. In this embodiment, it is preferable that the cleaning agent is composed of a liquid phase containing an alcohol component.

Meanwhile, the present embodiment may include a cleaning agent storage unit (not shown) for repeated cleaning of the slit 300. The residual material removing unit 10 for cleaning the slit 300 may inject the cleaning agent stored in the cleaning agent storage unit toward the injection path 402 by driving the cleaning pump unit.

In this embodiment, when image data acquisition is required, the air injection unit 20 makes the first storage chamber 30 and the air injection path 401 communicate with each other. Therefore, the measurement air is introduced into the guide passage 401d in the first storage chamber 30. [ The introduced measurement air is injected into the measurement target inflow block 400 through the first inlet 401a, the ramp 401c, and the second inlet 401b.

When the cleaning of the slit 300 is required after the image data is acquired, the air injection unit 20 communicates the second storage chamber 40, in which the cleaning air is stored, The cleaning air stored in the second storage chamber 401 flows into the air injection path 401. [ Therefore, the cleaning air is injected into the measurement target inflow block 400 via the first inlet 401a, the ramp 401c, and the second inlet 401b.

Since the cleaning air passes through the inclined path 401c of the air injection path 401, the cleaning air is injected onto the slit 300 at an angle of inclination with respect to the slit 300. Accordingly, the cleaning air desorbs the residual material remaining in the slit 300, and the slit 300 is cleaned. On the other hand, when the slit 300 is cleaned by the cleaning agent, the cleaning air evaporates the cleaning agent remaining in the slit 300 and cleans the slit 300 again.

The cleaning air may be injected into the measurement target inflow block 400 together with the cleaning agent. Therefore, the slit 300 can be effectively cleaned by the cleaning air and the cleaning agent.

Since the cleaning material and cleaning agent are removed from the slit 300, sharp image data can be obtained through the slit 300. Therefore, it is possible to increase the measurement reliability in the measurement of the non-asbestos surface concentration. In addition, since the replacement of the slit 300 is not required for cleaning the slit 300, it is possible to measure the ash ash concentration efficiently.

Meanwhile, the present embodiment can heat the cleaning air before flowing into the air injection path 401 side. The heated cleaning air evaporates the cleaning agent remaining in the slit (300). In addition, the heated cleaning air is injected into the measurement target inflow block 400 together with the cleaning agent, thereby enhancing the cleaning effect of the slit 300.

The present embodiment has the effect of first cleaning the slit 300 with a cleaning agent and secondly cleaning the slit 300 using heated cleaning air when cleaning of the slit 300 is required.

In this embodiment, after cleaning the slit 300, the inside of the measurement target inflow block 400 may be heated by the block heating unit 60. Therefore, the cleaning agent remaining in the measurement target inflow block 400 can be evaporated. Accordingly, the inside of the measurement target inflow block 400 and the slit 300 can be maintained in a state before image data acquisition.

Furthermore, the present embodiment can heat the measuring air to the air heating unit 50 even when image data acquisition is required. The heated measuring air is injected through the first inlet 401a and the ramp 401c into the inlet block 400 through the second inlet 401b. Therefore, when the measurement air is injected into the measurement target inflow block 400, the temperature of the slit 300 can be prevented from being lowered due to the temperature difference.

On the other hand, after acquiring the image data, the measurement air in the measurement target inflow block 400 is discharged to the discharge port 403 by the vacuum pump unit 70. The present embodiment can filter the measurement air with the discharge filter 80 before the measurement air is discharged to prevent secondary air contamination due to the measurement air discharge.

Also, before the cleaning air is discharged, the cleaning agent may be evaporated again in the alcohol evaporation vessel 90 to prevent the cleaning air from flowing into the flow sensor S after cleaning with the cleaning agent.

In addition, the present embodiment filters the measurement air moving from the first storage chamber 30 to the air injection path 401 to prevent a substance other than the measurement target from being injected into the measurement target inflow block 400 can do.

When the cleaning of the slit 300 is required, the cleaning air flowing from the second storage chamber 40 to the air injection path 401 is filtered to introduce foreign matter into the measurement target inflow block 400 .

It is to be understood that both the foregoing general description and the following detailed description of the present invention are exemplary and explanatory and are intended to provide further explanation of the invention as claimed. It will be understood that variations and specific embodiments which may occur to those skilled in the art are included within the scope of the present invention.

10: Residual material removal unit 20: Air injection unit
30: first storage room 40: second storage room
50: air heating unit 60: block heating unit
70: Vacuum pump unit

Claims (4)

For removing the residues remaining on the slit for image acquisition disposed in the accommodation space when the measurement air containing the measurement object is made into the accommodation space side of the inflow block to be measured,
A cleaning agent is sprayed to the slit through an injection path provided in the inflow block to be measured to remove residual material remaining on the slit,
Wherein the measurement target inflow block is provided with an air injection path for allowing the measurement air to flow into the accommodation space side,
When the image data acquisition is required, the measurement air passing through the first storage chamber is allowed to flow into the air injection path by communicating the first storage chamber storing the measurement air and the air injection path,
When the slit is required to be cleaned after the image data is acquired by the slit, the cleaning air communicated through the second storage chamber is communicated with the second storage chamber in which the cleaning air is stored, Wherein the slit cleaning method comprises the steps of: (a) removing the slit from the slit, delete The method according to claim 1,
And heating the cleaning air before the cleaning air flows into the air injection path side to remove residual material remaining on the slit with the heated cleaning air. A slit cleaning method of an image data acquisition device for density measurement. The method according to claim 1,
The cleaning agent sprayed on the slit side is a liquid material containing an alcohol component,
And heating the accommodation space of the measurement target inflow block so that the liquid material can be smoothly removed in the accommodation space.

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