KR102267665B1 - In-Duct Type Collecting Device of Fine Metal Particulate Matter - Google Patents

Abstract

The present invention relates in detail to a dust collector for collecting fine metallic dust in an underground tunnel with an induct-type metallic fine dust collecting apparatus using Faraday's principle, and maintains a comfortable underground environment by collecting fine dust such as heavy metal and treating it separately It can protect the health of subway passengers and workers, and it collects dust continuously during subway operation hours, eliminating the need for separate nighttime work, saving related budgets, and recycling the collected heavy metal dust into individual metals through a separate reprocessing process. can do

Description

In-Duct Type Collecting Device of Fine Metal Particulate Matter

The present invention relates to an induct-type metallic fine dust collecting device for collecting metallic fine dust in a subway underground tunnel, and more particularly, collecting metallic fine dust in an underground tunnel with an induct-type metallic fine dust collecting device using the Faraday principle. It relates to a dust collector for

The conventional dust collector has a problem in that its configuration is complicated, and thus it may cost a lot for commercialization and maintenance. In addition, the existing technology for handling charged dust and dust has problems such as requiring a separate and continuous external power. As described above, existing devices are neglected due to the complexity of their configuration, so it is necessary to facilitate practical application and to dramatically reduce operation and maintenance costs.

The fundamental problem is metallic scattering dust in the underground section of the subway, and the key is how to effectively collect the heavy metal mass composed of non-metallic fine dust aggregating around this metallic core. In the present invention, in order to strengthen the dust collection performance in the duct, Faraday's electromagnetic induction coil is installed in the lower correlative part of the duct, and a permanent magnet is placed in the collecting part at the bottom to prevent re-scattering and increase the dust collection efficiency, thereby solving the problems of the prior art. Solved.

Considering that fine dust scatters in the air rather than accumulating on the floor during train operation hours and metal dust caused by rail abrasion, dust collection during train operation hours using the present invention can be a fundamental measure to improve underground air quality.

Korean Patent Laid-Open Publication No. 10-2010-0073939 Korean Patent Laid-Open Publication No. 10-2001-0068435 Japanese Laid-Open Patent Publication No. 2005-021835 Japanese Laid-Open Patent Publication No. 02-307548

The present invention is a rectangular body having an inlet, an outlet, and a dust storage tank to collect heavy metal lumps that are combined with heavy metal dust and general dust worn due to mutual friction between tracks, electric wheels, and electric wires while the electric vehicle is running in a subway tunnel. and a duct dust collector composed of a plurality of coil parts, by placing a permanent magnet at the bottom of the dust storage tank at the bottom to prevent re-scattering of fine dust and further improve dust collection efficiency An object of the present invention is to provide a subway duct-type dust collector to reduce the budget by preventing malfunction of advanced electrical and electronic equipment and substation systems due to dust.

According to a feature of the present invention for achieving the above object, the present invention is an air flow facility in the subway that is opened at one end of the platform connected to the tunnel in the direction of entry of the subway, and air flows through one side of the tunnel by the pressure difference in the tunnel. an inlet opening 100; a duct 200 that communicates with the opening and is installed in the platform; a dust storage tank 300 installed and attached to communicate with one side of the duct and configured to store metallic fine dust in the air; one or more first coil parts 400 that share the central part of the installed dust storage tank and are installed in a duct; and an air purifying unit 700 for discharging the air from which the metallic fine dust has been removed to the platform.

In addition, a second coil portion 500 formed inside the first coil portion and sharing a central axis with the discharge pipe; may be further included.

In addition, the first coil part and/or the second coil part is negatively (-) or positively (+) charged to collect metallic fine dust in the body part, which lowers the charged metallic fine dust, and sequentially collects it in the dust storage tank connected to the lower part. can be

In addition, it is attached to the lower portion of the dust storage unit, a permanent magnet unit 600 for preventing the fine dust collected in the dust storage unit from scattering again; may further include. In addition, the metallic fine dust contained in the air is lowered by the magnetic field formed by the first coil unit and is primarily collected in the dust storage unit, and the air from which the metallic fine dust is removed moves along the duct and the It is supplied to the platform, and the second coil unit may increase the strength of the magnetic field to further lower the metallic fine dust, which is small in dust, moving along the flow of air.

In addition, the air from which the metallic fine dust is removed by the first and second coils in the body may be discharged to the outside through the cylindrical discharge pipe. In addition, an insulating insulator 410 for preventing the wiring of the first coil part and/or the second coil part from being electrically energized; may be further provided.

In addition, the air purifier may be discharged to the platform through a mesh network after passing through a filter for secondarily purifying the air from which the metallic fine dust has been removed.

The present invention removes dust flowing into the platform from the inside of the tunnel by the running wind of the subway vehicle and purifies the air of the platform, so that the platform is naturally purged without additional power or power, and maintenance is easy and have the effect of being cheaper.

In addition, since the dust is continuously collected during the train operation time, a separate night operation is not required, thereby reducing the related budget, and the collected heavy metal dust is easily recycled into individual metals through a separate reprocessing process.

Also, unlike other dust collectors, filters and external power are not required, so the maintenance cost is low and operation is simple.

In addition, by applying a coil in the duct, it is possible to effectively remove PM1.0 fine dust by collecting heavy metal fine dust that is not collected by magnetic force by the coil and is scattered through the outlet.

1 is a SEM picture of each size of fine dust on the platform of the subway Yeouinaru Station.
2 is an elemental analysis table for each size of fine dust on the subway Yeouinaru Station platform.
3 is an induct-type metallic fine dust collecting device according to an embodiment of the present invention;
4 is an induct-type metallic fine dust collecting device configured in a platform according to an embodiment of the present invention;
5 is a conceptual diagram illustrating a configuration of a first coil part and a second coil part according to an embodiment of the present invention;

The terms or words used in the present specification and claims should not be construed as being limited to their ordinary or dictionary meanings, and the inventor may properly define the concept of the term in order to best describe his invention. It should be interpreted as meaning and concept consistent with the technical idea of the present invention based on the principle that there is. Therefore, since the embodiments described in this specification are only the most preferred embodiment of the present invention and do not represent all the technical spirit of the present invention, there are various equivalents and modifications that can be substituted for them at the time of the present application. It should be understood that

1 is an SEM picture of each size of fine dust on a platform at Yeouinaru subway station.

Comparing the SEM photos of PM 1.0, PM 2.5 and PM 10, the needle structure can be confirmed as the dust size decreases.

2 is an elemental analysis table for each size of fine dust on the subway Yeouinaru Station platform.

PM10 and PM2.5 are composed of a large amount of Fe-oxide and trace amounts of Al-oxide and Cu-oxide generated due to friction of the rail, and PM1.0 is composed of Si-oxide introduced from the atmosphere.

The wastewater after wet dust collection is judged to mainly contain a lot of Fe or Si ions.

3 is a view showing an induct-type metallic fine dust collecting device according to an embodiment of the present invention.

Referring to FIG. 1 , the present invention may be configured with two or more collecting devices.

The dust collecting device may be installed and attached to communicate with one surface of the duct, and a dust storage tank for storing the metallic fine dust in the air may be formed. The part in which the dust storage tank is installed is formed to be connected by forming an opening in the upper or lower part of the duct, and one or more first coil parts that share the central part of the installed dust storage tank and are installed in the duct may be formed.

The first coil part may be formed in a cross-sectional area of the duct and in a direction directly above the opening. The first coil part formed of one or more coils is energized by a power source to form a magnetic field, and as the air containing the metallic fine dust passes through the first coil part, the metallic fine dust is guided toward the dust storage tank formed directly below by the magnetic field. can be

The metallic fine dust may be charged with (-) or (+), and a plurality of coil units are formed to form a magnetic field to induce (-) or (+) charged metallic fine dust in the direction of the dust storage tank. have.

In addition, the duct may be provided with an inlet through which air containing metallic fine dust is introduced and an outlet pipe through which air containing fine dust is removed, and may be included in each of the rectangular bodies.

The present invention uses the first coil part and the second coil part to efficiently separate and extract metallic fine dust such as iron, nickel, cobalt, and tungsten scattered in subway tunnels and platforms. The first coil part is made of a conductive material such as a coil, and forms a magnetic field inside the rectangular duct so that the charged dust can be efficiently collected.

The dust collected and adhered to the wall can be removed by periodically performing a procedure to remove it through energization and disconnection, or by reversing the electrodes of the first coil part and the second coil part to annihilate the magnetic field.

In addition, it may be formed in the connecting portion connecting the lower correlative body and the dust storage unit.

The cause of most fine dust is friction, and static electricity is generated when objects are rubbed. Therefore, most of the generated dust has an electric charge, and the electric charge, which is the order that determines the type of electric charge during friction, is (+) fur - ivory - crystal - glass - pongee - wood - rubber - sulfur - ebonite (-). do.

The present invention can efficiently remove fine dust charged negatively (-) or positively (+) in this way at once. On the other hand, from the analysis result that the dust in the underground tunnel of the subway is a 'heavy metal lump', which is a combination of heavy metal dust and general dust from tracks, trains, and electric lines, it can be seen that it is possible to effectively collect dust lumps using electromagnetic force.

Additionally, the rectangular duct may be formed to seal the duct except for a region in which the gas discharge pipe and the insulating insulator protrude to the outside.

The gas discharge pipe has a long cylindrical shape with an empty interior, is located near the center of the lid, one end protrudes a predetermined height above the lid, and the other end is located at a predetermined depth of the cylindrical portion.

An insulating insulator may also be formed in a portion in which the first coil part and the second coil part contact the duct part.

In addition, the Lorentz force may occur in the duct according to an embodiment of the present invention.

4 is an induct-type metallic fine dust collecting device configured in a platform according to an embodiment of the present invention.

Through the configuration of the present invention, the air containing the metallic fine dust introduced into the duct can maximize the dust collection efficiency through the primary first coil part dust collection and the secondary second coil part dust collection.

A spiral (-)-type coil configured at a predetermined position may be wound as air moves along the rectangular body through the air inlet of the duct, and a vertical magnetic field is formed in the center of the body.

Since the negatively charged dust receives a Lorentz force in a direction perpendicular to the direction of air as shown in FIG. 4, it is prevented from escaping along the dust storage tank located at the center of the opening of the duct.

Although the present invention has been described in detail with reference to several examples, the examples are presented for the purpose of understanding the present invention, and the scope of the present invention is not limited to the above examples. Those skilled in the art will understand that various modifications are possible without departing from the scope of the technical spirit of the present invention, and the scope of the present invention should be construed by the appended claims.

100: opening
200: duct
300: dust storage tank
400: first coil part
410: insulator
500: second coil part
600: permanent magnet unit
700: air purification unit

Claims (8)

An opening 100 through which air is introduced by a pressure difference in the tunnel through one side of the tunnel while being opened in the entry direction of the subway at one end of the platform connected to the tunnel among the air flow facilities in the subway;
a duct 200 that communicates with the opening and is installed in the platform;
a dust storage tank 300 installed and attached to communicate with one side of the duct and for storing the metallic fine dust in the air;
one or more first coil parts 400 that share the central part of the installed dust storage tank and are installed in a duct; and
and an air purification unit 700 for discharging the air from which the metallic fine dust is removed to the platform;
It further includes; a second coil part 500 formed inside the first coil part and sharing a central axis with the discharge pipe;
The first coil part and the second coil part are negatively (-) or positively (+) charged to lower the charged metallic fine dust, and are sequentially collected in the dust storage tank connected to the lower part,
The metallic fine dust contained in the air is descended by the magnetic field formed by the first coil unit and is primarily collected in the dust storage tank,
The air from which the metallic fine dust has been removed is supplied to the platform by moving along the duct,
The inducted metallic fine dust collecting device, characterized in that the first coil unit increases the strength of the magnetic field to further lower the metallic fine dust with small dust moving along the flow of air.
delete delete According to claim 1,
The induct-type metallic fine dust collecting device further comprising a; a permanent magnet attached to the lower part of the dust storage tank to prevent the fine dust collected in the dust storage tank from scattering again.
delete According to claim 1,
The air from which the metallic fine dust has been removed by the first coil part and the second coil part is discharged to the outside through a cylindrical discharge pipe.
According to claim 1,
An inductor-type metallic fine dust collecting device further comprising an insulating insulator (410) for preventing the wiring of the first coil part and the second coil part from being electrically energized.
According to claim 1,
The air purifier passes through a filter that secondaryly purifies the air from which the metallic fine dust has been removed, and then is discharged to the platform through a mesh network.

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