KR101458853B1 - Real Time Asbestos Fiber Counting Apparatus Using Light Scattering and Image Patten Recognition - Google Patents

Abstract

A real-time fugitive asbestos measurement apparatus based on light scattering and image pattern recognition includes: a static elimination device which neutralizes and removes electrostatic particles in the air flowing from an inlet; a chamber which is a path connected to an output terminal of the static elimination device, forming a predetermined space therein, and allowing air passing through the static elimination device to pass therethroough; and an image pattern recognition device which is installed on one side of the chamber, and which includes a pattern image detection unit determining asbestos fibers with reference to image data, obtained from a camera module which photographs particles in the air passing through the chamber, and the characteristics information of asbestos, stored in a database unit, by connecting the image data with the database unit, and a control unit counting the number of asbestos fibers and transmitting the counted number to the outside through a transmitting unit. The apparatus for counting the number of asbestos fibers is installed on the field to measure and monitor the concentration of asbestos in real time, and thus damage due to the harmful asbestos can be prevented.

Description

TECHNICAL FIELD [0001] The present invention relates to a real time asbestos asbestos measuring apparatus based on light scattering and image pattern recognition,

The present invention relates to an asbestos measuring apparatus, and more particularly, to a real-time scattered asbestos measuring apparatus based on light scattering and image pattern recognition that automatically counts asbestos using image recognition technology.

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

Asbestos is a term used to refer to a group of fibrous assemblages representing the specific luster of silkworms with high tensile strength and flexibility among the minerals produced by natural stone. They are easily broken into long, thin and strong fibers. It can be woven with a large cloth, and it is commonly used where heat resistance, inertness, insulation, nonflammability, electric conductivity, and chemical inertness are required.

Asbestos has more than 30 kinds of asbestos, but it is commercially important that three kinds of white surface such as serpentine system, amphibole system, and gallstone are commercially important, and more than 95% of world production is occupied by white stone.

Most asbestos is consumed in building materials, automobile parts, and textiles.

However, as described above, asbestos fibers are thin and sharp, very stiff, and especially because they are highly conserved in the body and are highly hazardous to the human body, so that only very limited handling can be handled.

Asbestos has been strictly regulated in terms of its use and removal and waste disposal. It is known that long-term inhalation of such asbestos causes occupational diseases such as lung cancer, malignant mesothelioma, and asbestosis.

Therefore, since these asbestos was designated as toxic designated waste by the ordinance, it is true that the majority of asbestos-related workers and people have been threatened with life because there is almost no crackdown by organizations and institutions at present.

In particular, the removal of asbestos that has been sprayed with the amount of asbestos floating in subway sections, schools, and infrastructure used by the public, which is several tens times the specified value, has been frequently performed.

Dismantling and dismantling Even in the construction of the building, the asbestos-sprayed architectural waste should be strictly classified as general construction waste and landfill separately. However, since most of the construction sites are dismantled along with general buildings, the second pollution is caused and the site workers There was a problem that it was a fatal threat to the health of the residents.

Therefore, the Ministry of Labor regulates or controls the use of asbestos, which has been proven to be hazardous. To this end, the asbestos collecting device which collects asbestos is introduced from overseas or domestic. After the capture, the filter was collected and analyzed.

However, there are some cases where it takes a day to finish depending on the time and scope required for measuring the asbestos by collecting the asbestos. However, there is a problem in that it is necessary to perform continuous measurement for a certain period of time for a week or more in demolition or demolition work.

As a result, the asbestos collection requires the worker to continuously visit the site to perform the work such as setting up, exchanging and recovering the filter, and recharging the equipment. Therefore, it takes a considerable amount of manpower and time, which is inconvenient and unreasonable. , There is a problem that the measurement reliability of the collected asbestos is deteriorated.

In the conventional asbestos sampling method, the worker moves with the asbestos sampler to sample the air on the filter paper of the asbestos filter, and after handling, it is handled carefully so as not to be contaminated by the second, and then the analyzing analyst preprocesses the filter paper Transparent and microscopically analyzed, which takes complex and time-consuming analysis time.

The pretreatment process is as follows: (1) Clean the slide glass and cover glass thoroughly, add 40-60 mL of acetone in an acetone vaporizer, heat the mixture to 60-70 ° C, and heat the acetone vaporizer slowly to boil the acetone. (2) Place 25% of the filter paper on a slide glass so that the dusty side is upwardly cut so as not to be torn with the surgical knife, and the filter paper cut on the cleaned slide glass is placed with the dust facing upward. The filter paper is transparent when the steam is sprayed for about 2 ~ 5 seconds in front of about 1 ~ 2cm from the place where the acetone vapor is generated.

Next, (3) 3 to 3.5 microliters of triacetin is dropped using a micropipette, the cover glass is placed obliquely on the filter paper so as not to cause bubbles, and the edge of the cover glass is sealed with a lacquer or a manicure.

The analyst analyzes the sample that has undergone the preprocessing process by various microscopic analysis methods such as optical microscopy, phase contrast microscopy, and scanning electron microscopy.

The existing asbestos sampling method requires a large number of manpower to be sampled by visiting the work site from time to time, and it takes a long time in the preprocessing process and it is difficult to confirm the analysis result immediately.

In order to solve such problems, it is an object of the present invention to provide a real-time scattered asbestos measuring device based on light scattering and image pattern recognition, which calculates asbestos count and concentration in real time on the spot and transmits the same in a wireless manner to the outside.

In order to achieve the above object, the present invention provides a real-time scattered asbestos measuring apparatus based on light scattering and image pattern recognition,

A static eliminator for neutralizing and removing static electricity of particles in the air introduced from the injection port;

A chamber which is connected to an output end of the electrostatic eliminator and has a predetermined space therein and through which air having passed through the electrostatic eliminator passes; And

The image data acquired from the camera module, which is installed on one side of the chamber, is correlated with the database part storing the characteristic information of the asbestos, and judges the asbestos fiber by referring to the image data and the characteristic information of the asbestos of the database part And an image pattern recognition device having a control unit for counting asbestos fibers and transmitting them to the outside through a transmission unit.

According to the above-mentioned constitution, the present invention has an effect of installing asbestos counting device on the field and observing and monitoring the concentration of asbestos in real time, thereby preventing damages caused by harmful asbestos.

The present invention provides an asbestos counting device installed in the field to receive asbestos coefficient and concentration wirelessly, thereby dramatically reducing complex and time-consuming analysis time such as microscopic analysis and preventing secondary contamination.

The present invention has the effect of promptly confirming the analysis result as compared with the conventional asbestos measurement method, and reducing the workforce drastically in real time by unattended operation.

The present invention is effective in managing asbestos hazardous factors that are more efficient than conventional asbestos analysis methods, confirming the results from time to time, and enabling accurate asbestos analysis work.

1 is a block diagram of a real-time scattered asbestos-measuring apparatus based on light scattering and image pattern recognition according to an embodiment of the present invention.
2 is a block diagram briefly showing a configuration of an image pattern recognition apparatus according to an embodiment of the present invention.
3 is a flowchart illustrating an asbestos coefficient algorithm according to an embodiment of the present invention.
4 to 6 are flowcharts illustrating a process of counting asbestos according to the flow of air using a real-time scattered asbestos-measuring apparatus based on light scattering and image pattern recognition according to an embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art can easily carry out the present invention. The present invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. In order to clearly illustrate the present invention, parts not related to the description are omitted, and similar parts are denoted by like reference characters throughout the specification.

Throughout the specification, when an element is referred to as "comprising ", it means that it can include other elements as well, without excluding other elements unless specifically stated otherwise.

FIG. 1 is a block diagram of a real-time scattered asbestos-measuring apparatus based on light scattering and image pattern recognition according to an embodiment of the present invention. FIG. 2 is a block diagram schematically showing the configuration of an image pattern recognition apparatus according to an embodiment of the present invention. And FIG. 3 is a flowchart illustrating an asbestos coefficient algorithm according to an embodiment of the present invention.

A real-time asbestos asbestos measuring apparatus 10 based on light scattering and image pattern recognition according to an embodiment of the present invention includes an inlet 100 for liquids and gases, a filter 100 for blocking leaves, etc. installed at an output end of the inlet 100, An inlet valve 112 provided at an output end of the filter 110, an air heater 200 installed at an output end of the inlet valve 112, a cooling and condensing device 210 installed at an output end of the air heater 200, A chamber 240 provided at an output end of the electrostatic eliminator 220; a light scattering type asbestos counting device 400 installed at an output end of the chamber 240; The asbestos filter 510 installed at the output end of the filter valve 500, the flow rate sensor 530 installed at the rear end of the asbestos filter 510, the flow rate sensor 500 installed at the output end of the light scattering type asbestos counting device 400, A pump 540 installed at the output end of the pump 530, an outlet (outlet) provided at the output end of the pump 540 550). A first bypass valve 230 connected to an input end of the air heater 200 and an output end of the cooling and condensing device 210; , And a second bypass valve (520) connected to an input end of the filter valve (500) and an output end of the asbestos filter (510).

The air heater 200 is a device for heating air, and includes a heater housing through which the air introduced through the filter is transferred, and a heating member installed in the heater housing. The conventional air heater 200 will be described in detail with reference to the components The air passing through the filter is heated to a certain temperature.

The air heater 200 directly heats the air at a temperature of 300 ° C or higher in the heater housing to burn pollen, dust, etc. in addition to the asbestos in the air introduced from the injection port 100 to evaporate.

The air heater 200 can raise the temperature to remove the humidity of the fibers, thereby preventing recognition errors and completely burning dust, cellulosic fibers, etc. at a temperature of 550 ° C or higher to selectively leave asbestos.

The cooling and condensing device 210 is a device for cooling and condensing the internal piping or other coupled devices when the air introduced from the injection port 100 is heated to a maximum temperature of 600 ° C., This is a device that reduces the recognition error in asbestos counting by providing a means for condensing the moisture.

To this end, the cooling and condensing apparatus 210 is provided with a cooling unit for mutually exchanging heat while air passing through the air heater 200 is transferred, a water jacket provided around the cooling unit for circulating the cooling water therein, And a condensation water collecting part for injecting condensation water into the radiator to increase the cooling efficiency. The technology for cooling the air through heat exchange is not well known in the art and will not be described in detail.

The electrostatic eliminator 220 includes a circuit constituent part for boosting a voltage and applying a high voltage, and an electrostatic precipitator 220 for forming ions in the vicinity of the ends by high pressure applied from the circuit constituent part, Or asbestos and other dusts are neutralized by the static electricity charged on the surfaces attached to each other due to the static electricity to remove the static electricity. Here, the electrostatic eliminator 220 is a conventional electrostatic eliminator 220, and detailed description of the components is omitted.

The chamber 240 connected to the rear end of the electrostatic eliminator 220 is provided with an image pattern recognition device 300 on one side of the side and a light scattering type asbestos counting device 400 on the downstream side to automatically count asbestos.

The image pattern recognition apparatus 300 includes a microscope lens and a high-speed camera 310, an illumination unit 320, a pattern image detection unit 330, a database unit 340, a control unit 350, and a transmission unit 360.

The image pattern recognition apparatus 300 irradiates light inside the chamber 240 and acquires image data using the microscope lens and the high-speed camera 310. [

The microscope lens and the high-speed camera 310 have a magnification of 4 (magnification 1.20 mm x 0.90 mm), 6 magnification (0.80 mm x 0.60 mm), 8 magnification (0.60 mm x 0.45 mm), 9 magnification mm × length 0.40 mm) and 12 times magnification (0.40 mm × 0.30 mm width).

1, the control unit 350 includes an inlet 100, an inlet valve 112, an air heater 200, a cooling and condensing unit 210, an electrostatic eliminator 220, a light scattering type asbestos counting unit The first bypass valve 230, the second bypass valve 520, the flow rate sensor 530, and the discharge port 550, as shown in FIG.

The pattern image detecting unit 330 recognizes the image by referring to the feature information of the asbestos image data by linking the image data obtained from the microscope lens and the high speed camera 310 with the database unit 340 storing the feature information of the asbestos. Here, the image recognition technology is a well-known algorithm for determining whether an input image exists in reference data existing in a specific DB.

Here, the characteristic information of the asbestos indicates color information, a length of 5 mu m or more, and a length-to-diameter ratio of 3: 1 or more.

The pattern image detecting unit 330 extracts input feature points (feature vectors) from the image data, and matches the extracted input feature points with the feature points of the feature information of the asbestos stored in the database unit 340 through a predetermined matching method, It is judged whether or not it is asbestos fiber.

The pattern image detecting unit 330 may extract feature points from a predetermined image and may extract a feature point according to the type of the image recognition algorithm. The pattern image detecting unit 330 may be a variety of methods such as Scale Invariant Feature Transform (SIFT) and Speed Up Robust Feature An image recognition algorithm can be applied.

When the image data is recognized as containing the feature information of the asbestos, the pattern image detecting unit 330 may extract the asbestos from the asbestos, and if it is recognized that the particles are present in the air and the particles have a length of 5 mu m or more and a length- In the case of asbestos fibers are judged.

The pattern image detecting unit 330 generates fiber result information by analyzing the image data by referring to the image data and the feature information of the asbestos, and transmits the generated fiber result information to the controller 350. Here, the fiber result information includes the length of the fiber, the ratio of the length to the diameter, whether the fiber is in the form of a bundle, and whether the end of the fiber is distinct.

The control unit 350 determines that the fibers are of the bundle type when the fiber information is received from the pattern image detector 330. The controller 350 counts the asbestos fibers when the ends of the fibers are distinct, If the ends of each fiber are not clearly visible, count them as one.

The end of the fiber is clearly visible in the form of a bundle that appears to cross the two fibers but not appear in the same bundle.

However, if it is judged that the two fibers from the dust are different fibers, the controller 350 judges asbestos fibers only when the length of each fiber is 5 μm or more and the ratio of the length to the diameter is 3: 1 or more .

A light scattering type asbestos counting device 400 is a known device made for the measurement of fiber length in air, which attracts air containing particles passing through a chamber 240, charges both ends of the asbestos in the air, Electrode and the positive electrode.

In the light scattering type asbestos counting apparatus 400, when a plurality of - electrodes and + electrode apparatuses having different polarities are provided, the polarity of each electrode is sequentially interchanged (+ to - and + to +) when passing through the electrode apparatus. And the asbestos charged is rotated as the motor rotates.

The light scattering type asbestos counting device 400 receives the laser scattering light when the laser beam strikes the particle by the size or thickness of the particles or the asbestos when the laser beam is irradiated on the rotating asbestos particle, It is grasped in the vertical ratio.

The light scattering type asbestos counting device 400 is a device for counting asbestos particles in which asbestos particles are rotated and laser beams are rotated so that the asbestos particles in the air are charged by the negative electrode and the positive electrode, The larger the particle length, the greater the amplitude of light intensity. The larger the thickness, the larger the amount of light.

The light scattering type asbestos counting apparatus 400 uses the point where the energy and the amplitude of the scattered light are small because the particle is close to the spherical shape (circular shape) when the laser light is irradiated at a ratio of the particle (ratio of the length to the diameter) Judge whether or not it is asbestos.

The light scattering type asbestos counting apparatus 400 can be used for counting as many fibers as the asbestos counting algorithm used in the pattern image detecting unit 330 described above (FIG. 3), a fiber length of 5 μm or more and a length- : Asbestos fibers are counted only if they are 1 or more, counted as asbestos fibers when the ends of the fibers are distinct, and counted as 1 if the ends of each fiber are not clearly visible (S200, S202, S204, S206, S208, S210, S212).

The light scattering type asbestos counting device 400 is configured to limit the kind of fibers to asbestos in a conventional fiber counting device.

The light scattering type asbestos counting apparatus 400 counts asbestos and transmits the counted result to the image pattern recognizing apparatus 300.

The air passing through the light scattering type asbestos counting apparatus 400 passes through the filter valve 500 and is collected in the asbestos filter 510.

The asbestos filter 510 collects asbestos by collecting the collected asbestos and counts the number of asbestos by the conventional method to finally determine the number of asbestos counted by the image pattern recognition apparatus 300 and the light scattering type asbestos counting apparatus 400 .

That is, the asbestos coefficient collected by the asbestos filter 510 can be provided as an auxiliary sample in the verification of the recognition error and the abnormal operation of the image pattern recognition apparatus 300 and the light scattering type asbestos counting apparatus 400.

The process of counting and processing asbestos according to the flow of air will be described in detail with reference to FIGS. 4 to 6, in the real-time scattered asbestos measuring apparatus 10 based on light scattering and image pattern recognition according to an embodiment of the present invention.

The control unit 350 closes the inlet valve 112 and opens the second bypass valve 520 and opens the N2 gas valve 114 (S100, S102, S104).

The control unit 350 closes the N2 gas valve 114 and opens the inlet port valve 112 and opens the inlet valve 112. In this case, 2 bypass valve 520 to stop the pump 540, and transmits the control signal to the respective constituent devices (S110, S112, S114, and S116).

The control unit 350 controls the air heater 200 to operate up to a predetermined temperature range and generates a control signal for stopping the air heater 200 when the temperature of the air heater 200 reaches a predetermined temperature To the air heater 200 (S118, S120, S122).

The control unit 350 generates a control signal to open the filter valve 500 and operate the cooling and condensing apparatus 210, the static eliminator 220, the illumination unit 320 and the pump 540, (S124, S126, S128, S130, S132), the light scattering type asbestos counting apparatus 400 and the image pattern recognizing apparatus 300 are operated to operate two kinds of asbestos counting apparatuses (S134).

The light scattering type asbestos counting device 400 applies electricity to the fibers and aligns them in parallel with the polarity and the electric field and counts asbestos among the aligned fibers and the image pattern recognition device 300 passes through the chamber 240 using image recognition technology Count asbestos in air containing one particle.

The controller 350 determines whether asbestos has been counted in the light scattering type asbestos counting apparatus 400 and the image pattern recognizing apparatus 300. When the asbestos counting is performed in the light scattering type asbestos counting apparatus 400 and the image pattern recognizing apparatus 300, The asbestos coefficient of the apparatus and the concentration value thereof are calculated and transmitted to the outside through the transmitter 360 in a wireless manner (S136, S138, S140, S142, S144).

The control unit 350 controls the air heater 200 to operate up to a predetermined temperature range. When the temperature of the air heater 200 reaches a predetermined temperature, the control unit 350 receives the flow rate value from the flow rate sensor 530, It is determined whether the flow rate value is maintained (S146, S148, S150).

The flow rate sensor 530 is a sensor for measuring the flow rate of air, and measures the flow rate value to ensure reliability of data measurement.

The control unit 350 determines whether the flow rate value received from the flow rate sensor 530 has reached a predetermined flow rate value or has reached a preset operation time and reaches a predetermined flow rate value or operation time (S152, S154) The power of the condensing apparatus 210, the static eliminator 220, the illumination unit 320, the pump 540, the light scattering type asbestos counting apparatus 400 and the image pattern recognizing apparatus 300 are turned off (S154) If the predetermined flow rate value or operation time has not been reached, the flow advances to step S124 to execute the next step.

The control unit 350 controls to close the filter valve 500, open the second bypass valve 520, close the inlet valve 112 and open the N2 gas valve 114 (S156, S158, S160, and S162) .

The control unit 350 closes the N2 gas valve 114 and stops the pump 540 and closes the inlet valve 112 when the predetermined time has elapsed after the pump 540 has been operated for a predetermined maximum time (S164, S166, S168, S170, and S172).

The embodiments of the present invention described above are not implemented only by the apparatus and / or method, but may be implemented through a program for realizing functions corresponding to the configuration of the embodiment of the present invention, a recording medium on which the program is recorded And such an embodiment can be easily implemented by those skilled in the art from the description of the embodiments described above.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, It belongs to the scope of right.

10: Real time scattered asbestos measuring device
100: inlet
110: filter
112: inlet valve
114: N2 gas valve
116: N2 gas storage tank
200: Air heater
210: cooling and condensing device
220: static eliminator
230: first bypass valve
240: chamber
300: image pattern recognition device
310: Microscope lens and high speed camera
320:
330: pattern image detecting unit
340:
350:
360: Transmitter
400: Light scattering type asbestos counting device
500: Filter valve
510: Asbestos filter
520: second bypass valve
530: Flow sensor
540: Pump
550: Outlet

Claims (8)

A static eliminator for neutralizing and removing static electricity of particles in the air introduced from the injection port;
A chamber connected to the output terminal of the electrostatic eliminator and having a predetermined space therein to allow air passing through the electrostatic eliminator to pass therethrough; And
Image data obtained from a camera module installed at one side of the chamber and interrogating particles of the air passing through the chamber is interlocked with a database unit storing characteristic information of asbestos to refer to the image data and characteristic information of the asbestos of the database unit A pattern image detecting unit for judging asbestos fibers, and an image pattern recognizing device having a control unit for counting the asbestos fibers and transmitting them to the outside through a transmitter
Based asbestos-based asbestos measuring device based on light scattering and image pattern recognition. The method according to claim 1,
A light source which is provided at an output end of the chamber and which passes the laser through a path in which the ends of the fibers in the air are charged with the negative electrode and the positive electrode and the polarity of the charged fibers is crossed and the fibers are counted in parallel with the polarity and the electric field Asbestos counting device
And a light scattering and image pattern recognition based real-time scattered asbestos measuring device. 3. The method of claim 2,
The image pattern recognition device or the light scattering type asbestos counting device is a real-time scattered asbestos measuring device based on light scattering and image pattern recognition that counts asbestos fibers when the fiber length is 5 μm or more and the length to diameter ratio is 3: . 3. The method according to claim 1 or 2,
An air heater installed at an output end of the injection port for heating the air introduced from the injection port to a predetermined temperature by burning the material other than the asbestos,
A cooling and condensing device installed at an output end of the air heater for cooling the air heated by the air heater to a predetermined temperature and connecting the static eliminator to an output end,
And a light scattering and image pattern recognition based real-time scattered asbestos measuring device. The method according to claim 1,
Wherein the pattern image detecting unit transmits the image data and the fiber result information compared with the asbestos sample image to the control unit, and when the end of the fiber is distinct based on the fiber result information, the controller counts each asbestos fiber, Real time scattered asbestos measuring device based on light scattering and image pattern recognition, counted as one when the end of the fiber is not clearly visible. 3. The method of claim 2,
The asbestos filter installed at the output end of the filter valve, the asbestos filter installed at the output end of the filter valve for collecting the asbestos, the flow sensor installed at the rear end of the asbestos filter for measuring the flow rate, A pump installed at an output end, an outlet provided at an output end of the pump,
And a light scattering and image pattern recognition based real-time scattered asbestos measuring device. 3. The method of claim 2,
The asbestos counting apparatus and the image pattern recognizing apparatus, the asbestos counting apparatus and the image pattern recognizing apparatus, the asbestos counting apparatus, and the image pattern recognizing apparatus, A real - time ash - based asbestos measuring system based on light scattering and image pattern recognition which is transmitted to the outside via radio. delete

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