KR101923446B1 - Dust collecting system - Google Patents

Abstract

The present invention relates to a fine dust collecting system, in which water or dry ice is sprayed and charged in a high concentration of fine dust such as a subway and a tunnel, and coagulates and precipitates together with fine dust in the air by electrical coupling, The dust collecting system comprising:
The present invention relates to a dust collection system installed in a subway or a tunnel, comprising: a storage part for storing water or dry ice; a first injection device for spraying polarized droplets of water or dry ice supplied from the storage part; A second injecting device for injecting water or a cathode-made droplet of dry ice supplied from the storage part, and a power supply for supplying power to the first and second injecting devices.

Description

[0001] Dust collecting system [0002]

The present invention relates to a fine dust collecting system, in which water or dry ice is sprayed and charged in a high concentration of fine dust such as a subway and a tunnel, and coagulates and precipitates together with fine dust in the air by electrical coupling, The dust collecting system comprising:

Fine dust is generated from combustion process of fossil fuel, dust such as road and railroad, and has a particle size of 0.1 to 10 μm while floating in the air.

In recent years, there has been a growing interest in health hazards, such that particulate matter below 0.1 μm is classified as ultra fine dust and managed separately.

Fine dust causes an inflammatory reaction in the bronchial bronchus, causing or exacerbating asthma, chronic bronchitis, airway obstruction, etc., and may also cause a respiratory infection by obstructing the inactivation or elimination of bacteria in the lung tissue.

In addition, fine dust is an important risk factor for cardiovascular diseases such as myocardial infarction, stroke, heart rate abnormality, sudden death.

The risk of such fine dust is closely related to the composition of fine dust, and when the fossil fuel is generated by the combustion of fossil fuel, which is an important source of fine dust, the structure in which the carbon component is surrounded by organic hydrocarbons, nitrates, metals, and sulfates These ingredients play an important role in the toxicity of fine dust.

As described above, the emission source of fine dust is likely to be combustion of fossil fuels and scattering from roads and railways. In the case of a specific emission source such as an industrial facility or a vehicle, it is possible to remove fine dust only by a dust collecting facility. There is no effective countermeasures against fugitive dust from railroad tracks.

In addition, even in the case of a mobile emission source such as a vehicle, the fine dust is first removed by the fine dust reduction device attached to the vehicle at the time of discharge, and then the discharge is performed. However, , It is difficult to achieve proper ventilation. It is more than 100 μg / m3. This high concentration of fine dust is a big problem in commuting time from 7:00 to 9:00 and 18:00 to 20:00, which are used by tens of thousands of people.

Various devices and techniques have been developed to remove such fine dust, such as filter media, electrostatic precipitators, and cyclones. However, there are various problems to be applied to subways and tunnels.

Korean Patent No. 10-1638065, for example, removes fine dust in the air by using a HEPA filter. However, in this case, a pressure loss of at least 25 mmAq is generated and the amount of air that can be treated per hour is low, It is difficult to remove fine dust in a short period of time when the train passes.

Korean Patent Laid-Open Nos. 10-2016-0054137 and 10-2010-0107344 disclose techniques for removing fine dust using an electrostatic precipitator or a cyclone. However, in the electrostatic precipitator and the cyclone, Based dust collecting facility is relatively fast, but has a problem of low treatment efficiency for fine dusts of 2.5 μm or less.

Korean Patent No. 10-1638065 Korean Patent Publication No. 10-2016-0054137 Korean Patent Publication No. 10-2010-0107344

Disclosure of Invention Technical Problem [8] Accordingly, the present invention has been made keeping in mind the above problems occurring in the prior art, and it is an object of the present invention to provide a method and apparatus for spraying and charging water or dry ice in an environment in which fine dust such as a tunnel, And a fine dust collecting system for removing fine dust by coagulating and sedimenting the fine dust collecting system.

Another object of the present invention is to provide an air jet nozzle for jetting water, which has an impingement plate on which fine pores are formed, and an ultrasonic vibrator provided on the impingement plate to vibrate the impinging plate, And it is an object of the present invention to provide a fine dust collecting system capable of improving the fine dust removing efficiency by spraying a fine and large amount of droplets.

SUMMARY OF THE INVENTION [0006] A dust collecting system installed in a subway or a tunnel, comprising: a storage part storing water or dry ice; a first injecting device for injecting polarized droplets of water or dry ice supplied from the storage part; A second injector for injecting negative electrode droplets of water or dry ice to be supplied, and a power supply for supplying power to the first and second injectors.

The first injection device includes a first air injection nozzle for injecting compressed air, a first injection nozzle provided inside the first air injection nozzle for spraying water or dry ice of the storage part, A first earth electrode provided on an outer circumferential surface of an end portion of the air injection nozzle and a first discharge electrode protruding forward from an end of the first air injection nozzle to generate a bipolar discharge.

The second injection device includes a second air injection nozzle for injecting compressed air, a second injection nozzle provided inside the second air injection nozzle for spraying water or dry ice of the storage part, A second earth electrode disposed on an outer circumferential surface of an end portion of the air injection nozzle and a second discharge electrode protruding forward from an end of the second air injection nozzle to generate a cathode discharge.

The first injection device includes a third air injection nozzle having an air inlet at one side thereof for spraying air, a third injection nozzle provided inside the third air injection nozzle for spraying water in the storage part, A third earth electrode disposed on an outer circumferential surface of the end portion of the third air injection nozzle and a third discharge electrode protruding forward from an end of the third air injection nozzle to generate a bipolar discharge.

The second injection device includes a fourth air injection nozzle having an air inlet at one side thereof for spraying air, a fourth injection nozzle provided inside the fourth air injection nozzle for spraying water in the storage part, A fourth earth electrode disposed on an outer circumferential surface of the end portion of the fourth air injection nozzle and a fourth discharge electrode protruding forward from an end of the fourth air injection nozzle to generate a cathode discharge.

The third and fourth injection nozzles are formed such that their diameters decrease toward the end portions.

In addition, the first to fourth air injection nozzles may include an impingement plate having micropores formed at the ends thereof.

The impact plate is provided with an ultrasonic vibrator.

The apparatus may further include an electric dust collection unit for removing fine dust aggregated by the first and second injectors.

The electrostatic dust collecting unit may include an electrostatic precipitator having a positive polarity or a negative polarity, a dust storage unit for storing dust collected through the electrostatic dust collector, and a dust discharge unit for discharging the dust stored in the dust storage unit to the outside .

According to the present invention having the above-described configuration, water or dry ice is sprayed and charged in an environment in which fine dust such as a tunnel and a tunnel exists, and coagulates and precipitates together with fine dust in the air by electrical coupling to remove fine dust .

According to another aspect of the present invention, there is provided an air jet nozzle for jetting water, comprising an impingement plate having micropores formed at an end thereof, and an ultrasonic transducer provided on the impingement plate to vibrate the impingement plate, so that water passes through the micropores of the impingement plate, So that the droplet is jetted to improve the fine dust removing efficiency.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a view showing a fine dust collecting system according to the present invention. FIG.
2 is a view showing an embodiment of a first injecting device of a fine dust collecting system according to the present invention.
3 is a view showing an embodiment of a second injecting device of a fine dust collecting system according to the present invention.
4 is a view showing another embodiment of the first injecting apparatus of the fine dust collecting system according to the present invention.
5 is a view showing another embodiment of the second injecting device of the fine dust collecting system according to the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. The same reference numerals are used for the same constituent elements in the drawings and redundant explanations for the same constituent elements are omitted. It is to be understood that the present invention may be embodied in many different forms and should not be construed as limited to the embodiments set forth herein.

FIG. 1 is a view showing a fine dust collecting system according to the present invention, FIG. 2 is a view showing an embodiment of a first injecting apparatus of a fine dust collecting system according to the present invention, FIG. 4 is a view showing another embodiment of the first injecting device of the fine dust collecting system according to the present invention, and FIG. 5 is a sectional view of the first embodiment of the fine dust collecting system according to the present invention FIG. 2 is a view showing another embodiment of the second injector of the fine dust collecting system according to FIG.

The present invention relates to a fine dust collecting system for spraying and charging water or dry ice in an environment in which fine dust such as a tunnel and a subway exists and coalescing and precipitating with fine dust in the air by electrical coupling to remove fine dust 1, comprises a storage part 100 in which water or dry ice is largely stored, a first storage part 100 for discharging a polarized droplet of water or dry ice supplied from the storage part 100, A second injector 300 for injecting negative electrode droplets of water or dry ice supplied from the storage unit 100 and a second injector 300 for supplying power to the first and second injectors 200 and 300, And a power supply unit 400 for supplying power.

In more detail, the storage unit 100 stores water or dry ice therein, and is connected to the first and second injectors 200 and 300 through piping (not shown) 200,300). ≪ / RTI >

Here, if dry ice is stored in the storage unit 100, the dry ice is stored in a fine particle state.

The power supply unit 400 supplies power to the first and second injectors 200 and 300 so that discharging is performed at the discharge electrodes 240, 280, 340 and 380 of the first and second injectors 200 and 300, And the second injectors 200 and 300, or may be supplied with power from a power cable installed on the railway.

2, the first injector 200 injects a polarized droplet of water or dry ice supplied from the storage unit 100, and is configured to inject a compressed air into the first air injection nozzle A first injection nozzle 220 provided inside the first air injection nozzle 210 for spraying water or dry ice supplied from the storage unit 100, A first ground electrode 230 provided on the outer circumferential surface of the end portion of the first air injection nozzle 210 and a first discharge electrode 240 protruding forward from the first air injection nozzle 210 to generate a bipolar discharge.

At this time, a pump 212 is provided at one side of the first air injection nozzle 210 to supply compressed air to mix water or dry ice and compressed air injected from the first injection nozzle 220, So that it can be jetted at high speed by compressed air.

A power supply cable (not shown) connected to the power supply unit 400 is connected to the first ground electrode 230 and the first discharge electrode 240 to supply power to the first ground electrode 230. In the first discharge electrode 240, .

Therefore, water or dry ice liquid droplets mixed in the air injected from the first air injection nozzle 210 and the first injection nozzle 220 are polarized by the cathode discharge generated in the first discharge electrode 240, And the minute dust floating in the air flocculates in the polarized water or the dry ice liquid droplet, so that the size of the fine dust becomes large and sinks to the ground due to gravity.

As shown in FIG. 3, the second injector 300 injects water or a cathode-made liquid droplet of dry ice supplied from the storage unit 100, and the second injector 300 injects compressed air, A second spray nozzle 320 disposed inside the second air spray nozzle 310 to spray water or dry ice supplied from the storage unit 100, A second earth electrode 330 provided on an outer circumferential surface of an end portion of the nozzle 310 and a second discharge electrode 340 protruding forward from an end of the second air injection nozzle 310 to generate a cathode discharge.

At this time, a pump 312 is provided at one side of the second air injection nozzle 310 to supply compressed air to mix water or dry ice and compressed air injected from the second injection nozzle 320, So that it can be jetted at high speed by compressed air.

A power supply cable (not shown) connected to the power supply unit 400 is connected to the second ground electrode 330 and the second discharge electrode 340 to supply power to the second ground electrode 330 and the second discharge electrode 340, .

Therefore, the water or the dry ice liquid mixed in the air injected from the second air injection nozzle 310 and the second injection nozzle 320 is converted into a negative electrode by the negative discharge generated in the second discharge electrode 340, And the fine dust floating in the air is agglomerated in the negative electrode water or the dry ice liquid droplet, so that the size of the fine dust becomes large and sinks to the ground due to gravity.

Here, the water or the dry ice droplets polarized or cathodically polarized by the first jetting device 200 and the second jetting device 300 coalesce with the fine dust, and the droplets polarized by the polarity of the droplets coalesced with the fine dust And the negative electrode droplets are combined with each other, so that the size of the fine dust becomes larger, so that the sedimentation due to gravity becomes more smooth, and the fine dust in the air can be quickly removed.

According to another embodiment of the fine dust reduction system 50 according to the present invention, water is stored in the storage unit 100, and as shown in FIG. 4, the first injection device 200 ' A third air injection nozzle 250 having an air inlet 252 formed at one side thereof for spraying the polarized droplets of water supplied from the first air injection nozzle 100 and a third air injection nozzle 250 provided inside the third air injection nozzle 250, A third air nozzle 270 disposed on an outer circumferential surface of an end of the third air spray nozzle 250 and a third air nozzle 270 disposed on an outer circumferential surface of the third air spray nozzle 250, And a third discharge electrode 280 protruding forward from an end of the first discharge electrode 250 to generate a bipolar discharge.

At this time, a pump (not shown) is provided at one side of the third injection nozzle 260 to supply water at a high pressure to mix with the air introduced through the air inlet 252 of the third air injection nozzle 250 So that it can be sprayed at a high speed by water pressure.

A power supply cable (not shown) connected to the power supply unit 400 is connected to the third ground electrode 270 and the third discharge electrode 280 to supply power to the third ground electrode 270 and the third discharge electrode 280, .

Accordingly, the water droplets mixed in the air injected from the third air injection nozzle 250 and the third injection nozzle 260 are polarized by the positive polarity discharge generated in the third discharge electrode 280 and injected into the air, In the polarized water droplet, the fine dust floating in the air agglomerates, and the size of the fine dust becomes large, and it sinks to the ground due to gravity.

As shown in FIG. 5, the second injector 300 'injects the negative electrode droplets of the water supplied from the storage part 100, and the fourth injector 300' A fourth injection nozzle 360 disposed inside the fourth air injection nozzle 350 for spraying water supplied from the storage unit 100 and a fourth air injection nozzle 350 And a fourth discharge electrode 380 protruding forward from the end of the fourth air injection nozzle 350 to generate a bipolar discharge. The fourth ground electrode 370 is disposed on the outer circumferential surface of the fourth air injection nozzle 350.

At this time, a pump (not shown) is provided at one side of the fourth injection nozzle 360 to supply water at a high pressure to mix with the air introduced through the air inlet 352 of the fourth air injection nozzle 350 So that it can be sprayed at a high speed by water pressure.

A power supply cable (not shown) connected to the power supply unit 400 is connected to the fourth grounding electrode 370 and the fourth discharge electrode 380 to supply power to the fourth grounding electrode 370. In the fourth discharge electrode 380, .

Therefore, the water droplets mixed in the air injected from the fourth air injection nozzle 350 and the fourth injection nozzle 360 are made negative by the cathode discharge generated in the fourth discharge electrode 380, and are injected into the air , The minute dust floating in the air is agglomerated in the cathode water droplet, and the size of the fine dust becomes large, and it sinks to the ground due to gravity.

Here, the droplets polarized or polarized by the first jetting device 200 'and the second jetting device 300' coalesce with the fine dust particles and become polarized by the polarity of the droplets coagulated with the fine dust particles, The negative electrode droplets are combined with each other to increase the size of the fine dust particles, so that the sedimentation due to gravity can be smoothly performed, and the fine dust particles in the air can be removed quickly.

The third and fourth injection nozzles 260 and 360 are formed to have a smaller diameter toward the end portion so that water supplied at a high pressure from the storage portion 100 can be sprayed at a high speed to more effectively remove fine dust .

Meanwhile, when water is stored and supplied to the storage unit 100, impingement plates 290 and 290 formed with micropores (not shown) at the ends of the first to fourth air injection nozzles 210, 250, 310 and 350 are sprayed Water is sprayed in the form of fine particles to improve the fine dust removing efficiency.

That is, as the water is sprayed through the micropores of the impingement plates 290 and 390 provided in the first to fourth air injection nozzles 210, 250, 310 and 350, the water droplet particles are formed smaller than the micropores, And the number of the water droplets is increased, so that it becomes possible to coagulate with a larger amount of fine dust, so that the fine dust removing efficiency is further increased.

An ultrasonic vibrator (not shown) is provided on the impingement plates 290 and 390 so that the impingement plates 290 and 390 are vibrated by the ultrasonic vibrator and water droplets passing through the micropores of the impingement plates 290 and 290 are finely formed And the effect as described above can be further increased.

Meanwhile, the fine dust collecting system 50 according to the present invention may further include an electric dust collecting unit 500 for removing fine dust aggregated by the first and second injectors 200, 200 ', 300, and 300'.

The battery dust collecting unit 500 includes an electrostatic precipitator 510 having a positive electrode or a negative electrode and a dust storage unit 500 disposed below the electrostatic dust collector 510 to store dust collected through the electrostatic dust collector 510. [ And a dust discharge unit 530 for discharging the dust stored in the dust storage unit 230 to the outside.

Here, since the electrostatic precipitator 510 is a commonly used technique, a detailed description thereof will be omitted.

However, the polarized or cathodized water or dry ice liquid droplets injected by the first and second injectors 200, 200 ', 300, 300' are collected by the electrostatic precipitator 510 having a polarity by aggregating with the fine dust, When the collected fine dust becomes heavy, the dust is dropped and stored in the dust storage part 520, and is discharged to the outside through the dust discharge part 530.

At this time, the dust discharging part 530 moves the dust to a certain space by using a suction fan or the like, thereby facilitating the maintenance of the electric dust collecting part 500.

Therefore, according to the fine dust collecting system 50 of the present invention, water or dry ice is sprayed and charged in an environment in which fine dust such as a tunnel and a tunnel exist in a high concentration, so that cohesion And an impingement plate (290,390) having micropores formed at the ends of the air injection nozzles (210,250,310,350) for spraying the water as well as an ultrasonic vibrator on the impingement plates (290,390) (290, 390) to vibrate so that water passes through the micropores of the impingement plates (290, 390) and a more minute amount of droplets is injected, thereby improving the fine dust removing efficiency.

While the present invention has been described in connection with what is presently considered to be preferred embodiments thereof, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims.

The present invention relates to a fine dust collecting system, in which water or dry ice is sprayed and charged in a high concentration of fine dust such as a subway and a tunnel, and coagulates and precipitates together with fine dust in the air by electrical coupling, The dust collecting system comprising:

50: Fine dust collection system
100: storage unit 200, 200 ': first injection device
210: first air injection nozzle 212: pump
220: first injection nozzle 230: first earth electrode
240: first discharge electrode 250: third air injection nozzle
252: Air inlet 260: Third injection nozzle
270: third ground electrode 280: third discharge electrode
290: Collision plate 300, 300 ': Second injection device
310: second air injection nozzle 312: pump
320: second injection nozzle 330: second earth electrode
340: second discharge electrode 350: fourth air injection nozzle
352: Air inlet 360: Fourth injection nozzle
370: fourth earth electrode 380: fourth discharge electrode
390: Collision plate 400: Power supply unit
500: electric dust collector 510: electrostatic precipitator
520: dust storage part 530: dust discharge part

Claims (10)

In a dust collection system installed in a subway or a tunnel,
A first injector for injecting a polarized droplet of water supplied from the reservoir; a second injector for injecting a cathode droplet of water supplied from the reservoir; And an electric dust collection unit for removing fine dust aggregated by the first and second injection devices,
The third injection device includes a third air injection nozzle having an air inlet on one side thereof and a third air injection nozzle provided on the inner side of the third air injection nozzle and having a smaller diameter toward the end thereof, A third earth electrode provided on an outer circumferential surface of an end portion of the third air spray nozzle; and a third discharge electrode protruding forward from an end of the third air spray nozzle to generate a bipolar discharge,
The fourth jetting device may include a fourth jetting nozzle having an air inlet at one side thereof and a fourth jetting nozzle provided at an inner side of the fourth air jetting nozzle and having a smaller diameter toward the end thereof, A fourth earth electrode provided on the outer circumferential surface of the end portion of the fourth air injection nozzle and a fourth discharge electrode protruding forward from an end of the fourth air injection nozzle to generate a cathode discharge,
Wherein an impingement plate provided with micropores at end portions of the third and fourth air injection nozzles and equipped with an ultrasonic vibrator is provided,
The dust collecting unit may include an electrostatic precipitator having a positive polarity or a negative polarity, a dust storage unit for storing the dust collected through the electrostatic dust collector, a dust discharge unit for discharging the dust stored in the dust storage unit to the outside, Wherein the fine dust collecting system comprises:
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