KR102071990B1 - Apparatus for airborne particle collection - Google Patents

Abstract

The present invention relates to an apparatus for collecting particles in air, the apparatus for collecting particles in air according to the present invention comprises: a housing; and a rotating part rotatably supported in an insulated state in the housing; and the rotating part disposed in the housing. Cylindrical filter unit to rotate with; and, the inlet unit for supplying air to the internal space of the filter unit; and the discharge unit for discharging the air passing through the filter unit to the outside of the housing; and, applying the rotational driving force to the rotating unit A rotary drive unit; and a charge unit disposed at the inlet unit to charge air supplied to the inlet unit, and to which a DC high voltage is applied; And a ground part which is grounded so that the charged particles in the charged part may be collected by an attractive force and is disposed on an inner wall surface of the housing.

Description

Particle collection unit in air {APPARATUS FOR AIRBORNE PARTICLE COLLECTION}

The present invention relates to a particle collecting device in the air, and more particularly, it is possible to separate solid and liquid particles using the cyclone principle, and to separate ultrafine particles having a relatively small mass using the electrostatic precipitating principle. The present invention relates to an airborne particle collection device that can greatly improve efficiency.

Conventional rotary cyclone dust collector using a rotating disk, as shown in Figure 1, the inlet 11 is formed in the lower center and the exhaust port 12 is formed on one side of the upper side, and the interior of the housing 10 A shaft 21 rotatably disposed at the lower end connected to the inlet 11, a plurality of disks 22 spaced apart along the axial direction on an outer circumferential surface of the shaft, and a rotational force is applied to the shaft 21. It is configured to include a motor (30).

The rotary cyclone dust collector is more complicated in structure than the non-rotating cyclone dust collector, but is installed in a place where high dust collection performance is required because of superior separation performance of fine particles.

According to the conventional rotary cyclone dust collector, the air supplied to the inlet 11 moves outwardly through the space between the disks 22 and moves along the inner wall surface of the housing 10 to discharge the outlet 12. Through the discharged to the outside of the housing (10). In this process, the particles contained in the air are separated from the air by the cyclone effect, collected on the inner wall surface of the housing 10, and dust collection is performed. However, as shown in FIG. 2, particles of 1 micrometer (μm) or more contained in air are separated by the cyclone principle, but ultrafine particles of 1 micrometer (μm) or less are difficult to effectively separate.

Accordingly, in order to improve the dust collection efficiency of the cyclone dust collector, as shown in FIG. 3, a part of the air discharged through the exhaust port 12 is recovered to the inlet port 11 to the cyclone dust collector 1. The recycling method is adopted. According to this recirculation structure, it is expected that the ultrafine particles of 1 micrometer (μm) or less are agglomerated with each other and separated from the air by the cyclone principle. There is a problem that is discharged, there is a problem that the amount of electricity consumed for dust collection.

Patent Document 1. Utility Model Registration 20-0299650 (2003.01.03)

Accordingly, an object of the present invention is to solve such a conventional problem, and to separate solid and liquid particles of high mass using a cyclone principle, and to separate ultrafine particles of small mass using an electrostatic precipitating principle. Therefore, the present invention provides an air particle collecting device that can greatly improve dust collection efficiency.

In addition, since the particles collected on the inner wall surface of the housing to be discharged to the outside of the housing through the drain hole, to provide a particle collecting device in the air capable of continuous dust collection without using a separate filter.

The object is, according to the present invention, a housing; and a rotating part rotatably supported in an insulated state in the housing; and a cylindrical filter part disposed in the housing and rotating together with the rotating part; and the filter part An inlet for supplying air to the inner space; an outlet for discharging the air passing through the filter unit to the outside of the housing; and a rotating driver for applying rotation driving force to the rotating unit; and charging the air supplied to the inlet. A charging unit disposed at the inlet to be applied with a DC high voltage; And a grounding part which is grounded to collect dust charged by the attractive force by the attraction force and is disposed on an inner wall surface of the housing.

Here, the charged portion is composed of a discharge electrode and a ground electrode which are spaced apart from each other, it is preferable that the particles in the air passing between the discharge electrode and the ground electrode is charged by the corona discharge generated between the discharge electrode and the ground electrode.

In addition, a high voltage generator for applying a high voltage to the filter unit; preferably includes.

In addition, it is preferable that the filter unit includes a porous filter provided in plural and arranged in a radial direction.

In addition, it is preferable that the porous filter disposed at the outermost side of the porous filter is made of a conductive material and a high voltage is applied by the high voltage generating unit.

In addition, it is preferable that the plurality of porous filters are provided with different densities, and are arranged in such a manner that the density gradually increases as the radial direction moves from the center of the filter part.

The apparatus may further include a power supply connecting part stably supplying a high voltage provided from the high voltage generating part to the filter part rotating in the housing.

The power supply connection unit may include a connection terminal electrically connected to the high voltage generation unit and contacting the porous filter made of a conductive material, and an elastic member elastically supporting the connection terminal toward the filter unit.

In addition, it is preferable that the filter part is provided with a ring-shaped track terminal that is electrically connected to the porous filter made of the conductive material and disposed on an outer surface of the filter part so that the connection terminal can be contacted.

The power supply connection unit may further include an air injection unit for injecting high pressure air from the rear end of the connection terminal toward the filter unit.

In addition, the lower one side of the housing is preferably provided with a drain hole for discharging the particles collected on the inner wall surface of the housing.

In addition, the discharge portion is formed on the upper end of one side of the inner wall surface of the housing, it is preferable that the depression is formed on the lower end of the discharge portion.

In addition, the depression is preferably formed with a connection passage for inducing the particles collected in the depression to the drain hole.

According to the present invention, it is possible to separate solid and liquid particles of high mass by using the cyclone principle, and to separate ultrafine particles of small mass by using the electrostatic precipitating principle, so that the particles in the air can greatly improve the dust collection efficiency. A collection device is provided.

In addition, since the particles collected on the inner wall surface of the housing is discharged to the outside of the housing through the drain hole, there is provided an air particle collecting device capable of continuous dust collection without using a separate filter.

1 is a cross-sectional view of a conventional cyclone dust collector,
2 is a graph showing the dust collection efficiency of the conventional cyclone dust collector;
3 is a block diagram for improving the dust collection efficiency of the conventional cyclone dust collector,
Figure 4 is a cross-sectional view of the air particle collecting device according to a first embodiment of the present invention
5 is an enlarged view of a charging unit according to the present invention;
6 is an enlarged view of a power connection unit according to the present invention.

Prior to the description, in the various embodiments, components having the same configuration will be representatively described in the first embodiment using the same reference numerals, and in other embodiments, different configurations from the first embodiment will be described. do.

Hereinafter, an air particle collecting apparatus according to a first embodiment of the present invention will be described in detail with reference to the accompanying drawings.

4 is a cross-sectional view of a particle collecting device in the air according to the first embodiment of the present invention, Figure 5 is an enlarged view of the charging unit according to the present invention, Figure 6 is an enlarged view of the power connection unit according to the present invention.

As shown in the drawings, the present invention collects air particles in the housing 110, the rotating unit 120, the filter unit 130, the rotary drive unit 140, the charging unit 170, the grounding unit, high voltage generator ( 150 and a power connection unit 160 are configured.

The housing 110 includes a cylindrical inner space, an inlet 111 for introducing air into the inner space is provided at the center of the lower end of the housing 110, the housing (110) on the upper side of the housing 110; 110 is provided with a discharge unit 112 for discharging the air to the outside, the lower side of the housing 110 is collected on the inner wall surface of the housing 110 in contact with the inner space to discharge the particles flowing along the inner wall surface A drain hole 113 is provided.

A depression 114 is formed at the lower end of the discharge part 112 of the inner wall surface of the housing 110 in a circumferential shape along the inner wall surface of the housing 110, and the depression at the lower end of the depression 114. A connection passage 116 is formed to guide the particles collected in the portion 114 to the drain hole 113. Specifically, the depression 114 may be formed in a ring shape along the inner wall surface of the housing 110, a plurality of through holes 115 are formed at the bottom of the depression 114, a plurality of through holes ( 115 is connected to the drain hole 113 by a connecting passage 116.

The rotating part 120 is an upper rotating disk 121 rotatably supported on an upper inner wall surface of the housing 110 and a lower inner wall surface of the housing 110 at a position facing the upper rotating disk 121. It includes a lower rotating disk 122 rotatably supported, wherein the upper rotating disk 121 and the lower rotating disk 122 is made of an insulating material.

In addition, the lower rotating disk 122 is formed with a through hole 122a connecting the inlet 111 and the internal space of the filter unit 130, and the upper rotating disk 121 and the lower rotating disk 122 A guide (not shown) may be provided to guide the coupling position of the filter unit 130, and at least one of the upper rotating disk 121 and the lower rotating disk 122 may be replaced with the filter unit 130. It is preferable to be detachably assembled to the housing 110 for.

The filter unit 130 is formed in a cylindrical shape, the upper and lower ends are coupled to the upper rotating disk 121 and the lower rotating disk 122 so as to rotate together with the rotating unit 120, the inside of the filter unit 130 The space is connected to the inlet 111 through a through hole 122a.

The filter unit 130 includes a plurality of cylindrical porous filters 131a, 131b, and 131c configured to have different diameters so that they can be overlapped in a radial direction. Preferably, the plurality of porous filters 131a, 131b, and 131c are provided with different densities, and are disposed in such a manner that the density gradually increases as the radial direction moves from the center of the filter unit 130. As such, when the density of the porous filters 131a, 131b, and 131c is configured differently, the porous filters 131a, 131b and 131c disposed inside the rotation center and the porous filters 131a, 131b and 131c disposed outside of The exchange periods can be relatively matched, and the concentration of particles in the air can be prevented from being collected only in one of the porous filters 131a, 131b, and 131c.

The charging unit 170 includes a discharge electrode 171 and a ground electrode 172 and is installed at the inlet 111 side of the housing 110. The discharge electrode 171 is disposed in the inlet 111 and a direct current high voltage is applied. The ground electrode 172 is disposed and grounded so as to surround the discharge electrode 171 so that corona discharge is generated between the discharge electrode 171 and the discharge electrode 171. Therefore, particles in the air passing between the discharge electrode 171 and the ground electrode 172 at the inlet 111 side of the housing 110 are charged by the ions generated between the discharge electrode 171 and the ground electrode 172.

The dust collector is disposed downstream of the charged portion 170 on the air flow path in the housing 110 and is grounded so that the charged particles in the charged portion 170 can be collected by the attraction force. In the present embodiment, for example, the dust collector is integrally formed with the housing 110. To this end, the housing 110 may be made of a conductor and grounded, but a cylindrical conductor configured as a non-conductor and separated from the housing 110 may be formed on the inner wall surface of the housing 110 as necessary. It may also be possible to configure the dust collector by grounding after placement.

Meanwhile, dust collecting performance may be further improved by applying a direct current high voltage having the same polarity as the discharge electrode 171 of the charging unit 170 to the filter unit 130. Specifically, the porous filter 131c disposed at the outermost side of the porous filters 131a, 131b, and 131c is made of a conductive material such as metal, and a high voltage is applied by the high voltage generator 150. It is preferable that the outer surface of 131c has a shape in which sharp protrusions are irregularly protruded to induce corona discharge between the housing 110 and the housing 110. Meanwhile, except for the porous filter 131c disposed at the outermost side, the remaining porous filters 131a and 131b may be made of an insulating material such as ceramic or resin. In addition, the filter unit 130 is a ring-shaped track terminal concentric with the rotation center of the filter unit 130 so that the power connection unit 160 is in electrical contact with the porous filter 131c made of the conductive material. 132 may include.

The high voltage generation unit 150 applies a direct current high voltage to the porous filter 131c disposed at the outermost side of the filter unit 130 to generate ions from the porous filter 131c, and the housing 110 is porous. Since the potential difference with the filter 131c is grounded, particles in the air passing through the porous filter 131c may be charged and collected on the inner wall surface of the housing 110.

The power connection unit 160 is for stably supplying the high voltage provided from the high voltage generator 150 to the filter unit 130 that rotates in the housing 110, and is electrically connected to the high voltage generator 150. A connection terminal 161 connected to the porous filter 131c made of the conductive material, an elastic member 162 elastically supporting the connection terminal 161 toward the filter unit 130, and the The high pressure air supply part 163 which injects high pressure air from the rear end of the connection terminal 161 toward the filter part 130, and the high end air of the high pressure air provided from the high pressure air supply part 163 It is configured to include a guide 164 to discharge toward. Here, the high pressure air supply unit 163 is for preventing the conductive water film from being formed on the outer surface of the connection terminal 161 by oil or moisture contained in the air, and the supply pressure of the high pressure air is the housing 110. It would be desirable to set the pressure relatively higher than the internal air pressure. In addition, the guide 164 is preferably made of an insulating material to maintain an electrically insulated state with the connection terminal 161.

On the other hand, the inlet 111 of the housing 110 may be connected to the exhaust fumes 112 of the internal combustion engine, hereinafter solids such as dust contained in the soot using an air particle collection device according to the present embodiment The process of separating particles and liquid particles such as oil mist, as well as ultrafine particles smaller than 1 micrometer (μm) from soot will be described as an example.

The operation of the first embodiment of the above-described airborne particle collecting apparatus will now be described.

As shown in FIGS. 4 and 5, the charging unit 170 is disposed at the inlet 111 side of the housing 110, and the discharge electrode 171 is disposed at the center of the inlet 111. The ground electrode 172 is applied and grounded in a state in which the discharge electrode 171 is arranged in a ring shape. Accordingly, monopolar ions are generated between the discharge electrode 171 and the ground electrode 172 by the corona discharge, and the particles in the soot supplied to the inlet 111 of the housing 110 are charged by the monopolar ions.

The upper rotating disk 121 and the lower rotating disk 122 constituting the rotating part 120 are rotatably supported in an insulated state from the housing 110 in a state in which the upper rotating disk 121 and the lower rotating disk 122 are spaced up and down inside the housing 110. The upper rotating disk 121 is rotated by receiving a rotational force from the rotation driving unit 140.

In addition, the plurality of porous filters 131a, 131b, and 131c constituting the filter unit 130 are fixed between the upper rotating disk 121 and the lower rotating disk 122 to rotate together with the rotating unit 120. .

Therefore, the air supplied to the inlet 111 of the housing 110 is introduced into the internal space of the filter unit 130 through the through hole 122a of the lower rotating disk 122, and the plurality of porous filters 131a. While passing through 131b and 131c, particles in the air are sequentially filtered according to their size.

In addition, since the centrifugal force is applied to the air passing through the filter unit 130 by the rotation of the filter unit 130, the solid and liquid particles of 1 micrometer (μm) or more contained in the air are subjected to the cyclone phenomenon in the housing 110. The solid particles and the liquid particles collected on the inner wall surface of the housing 110 flows down along the inner wall surface of the housing 110 in a mixed state, and is provided at one side of the bottom of the housing 110. It is discharged to the outside of the housing 110 through the drain hole.

In particular, since the particles in the soot moving toward the inner wall surface of the housing 110 by the centrifugal force in the rotating unit 120 is charged by the ions provided from the charging unit 170, the housing 110 constituting the dust collecting unit Will stick to the inner wall of the

In addition, since the high voltage of the same polarity as that of the charged part 170 is applied to the rotating part 120, an electrostatic force acts between the rotating part 120 and the housing 110. Therefore, solid and liquid particles of 1 micrometer (μm) or more contained in the air, as well as fine particles of less than 1 micrometer (μm), are charged by the monopolar ions generated in the porous filter 131c of the conductive material, and the electrostatic force Because it can be collected on the inner wall surface of the housing 110, it can be effectively separated to fine particles of less than 1 micrometer (μm). (See Figure 6)

As described above, the fine particles collected on the inner wall surface of the housing 110 are mixed with the solid and liquid particles flowing along the inner wall surface of the housing 110 and discharged to the outside through the drain hole 113. It is possible to prevent the fine particles from being mixed in the air flow rising toward the discharge portion 112 in the inner space of the.

On the other hand, the fumes discharged from the rotating part 120 forms an air flow that rises toward the upper side of the housing 110 while rotating along the inner wall surface of the housing 110, and the raised air flow is collected on the inner wall surface of the housing 110. The particles can be moved upward.

At this time, the particles rising along the inner wall surface of the housing 110 by the rising air is caught by the ring-shaped depression 114 formed at the lower end of the discharge portion 112 of the housing 110 to move toward the discharge portion 112 side. Since it is limited, the particles collected on the inner wall surface of the housing 110 can be prevented from being discharged through the discharge portion (112).

In addition, particles that are restricted by the depression 114 and move to the discharge part 112 side are discharged through the through-hole 115 formed in the bottom of the depression 114, the through-hole 115 and the drain hole 113 It is guided to the drain hole 113 side via the connecting passage 116 to connect is discharged to the outside of the housing (110).

As described above, according to the particle collecting device in the air according to the present embodiment, since the particles in the smoke supplied to the filter unit 130 is charged while passing through the charge unit 170 disposed on the inlet 111, the filter The fine particles passing through the unit 130 are collected on the inner wall surface of the housing 110 constituting the dust collecting unit by the potential difference. At this time, since the filter unit 130 rotates together with the rotating unit 120, the particles passing through the filter unit 130 not only move toward the inner wall surface of the housing 110 by the cyclone principle, but also the outermost porous filter. Since the electrostatic force is applied to the dust collecting part while the direct current high voltage having the same polarity as the charged part 170 is applied to 131c, the capturing performance of the fine particles may be further maximized.

In particular, the filter unit 130 may be applied to a cyclone dust collection method using centrifugal force, so that particles having a large size may be filtered by the filter unit 130. Therefore, in the cyclone dust collecting method, it is possible to solve the problem that the particles in the air are dispersed while colliding with the inner wall surface of the housing 110 by the centrifugal force to increase the fine particles. In addition, since the relatively small mass particles can be collected in the dust collecting unit by using the electrostatic precipitating principle, the dust collecting efficiency can be greatly improved.

In addition, since the particles collected on the inner wall surface of the housing 110 is discharged to the outside of the housing 110 through the drain hole 113, continuous dust collection is possible. Therefore, even when the flow rate of air supplied to the inlet 111 of the housing 110 is severe, such as an internal combustion engine, the dust collection performance can be effectively maintained even when the flow rate is fast.

Meanwhile, as illustrated in FIG. 6, the power connection unit 160 contacts the filter unit 130 that rotates in the housing 110 while the rear end thereof is supported on the inner wall surface of the housing 110 so that the porosity of the conductive material is increased. A high voltage is applied to the filter 131c.

Specifically, the connection terminal 161 constituting the power connection unit 160 contacts the ring-shaped track terminal 132 formed on the outer circumferential surface of the filter unit 130, and the ring-shaped track terminal 132 by the elastic member 162. Since it is elastically supported toward, it is possible to stably apply a high voltage to the rotating porous filter 131c of the conductive material. At this time, the high pressure air is injected into the rear end of the connection terminal 161 by the high pressure air supply unit 163, and the high pressure air is guided toward the front end of the connection terminal 161 by the guide 164.

Therefore, the high pressure air is sprayed along the outer surface of the connection terminal 161 to prevent the oil or water contained in the air from being applied to the surface of the connection terminal 161, thereby forming a conductive water film on the surface of the connection terminal 161. As formed, the housing 110 and the porous filter 131c of the conductive material may be prevented from being electrically connected.

The scope of the present invention is not limited to the above-described embodiments but may be implemented in various forms of embodiments within the scope of the appended claims. Without departing from the gist of the invention claimed in the claims, it is intended that any person skilled in the art to which the present invention pertains falls within the scope of the claims described herein to various extents which can be modified.

110: housing, 111: inlet, 112: discharge,
113: drain hole, 114: depression, 115: through hole,
116: connecting passage, 120: rotating part, 121: upper rotating disk,
122: lower rotating disk, 122a: through hole, 130: filter portion,
131a, 131b, 131c: porous filter, 132: track terminal,
140: rotation driving unit, 150: high voltage generating unit, 160: power supply connection unit,
161: connection terminal, 162: elastic member, 163: high pressure air supply,
164: the guide, 170: the charged portion, 171: the discharge electrode,
172: grounding pole

Claims (13)

housing;
A rotating part rotatably supported in an insulated state in the housing;
A cylindrical filter part disposed in the housing and rotating together with the rotating part;
An inlet for supplying air to the inner space of the filter part;
A discharge part for discharging the air passing through the filter part to the outside of the housing;
A rotation driving unit applying a rotation driving force to the rotation unit;
A charging unit disposed at the inlet unit to charge air supplied to the inlet unit and to which a DC high voltage is applied;
A grounding part which is grounded to allow the charged particles in the charged part to be collected by an attractive force and is disposed on an inner wall surface of the housing;
A high voltage generator for applying a high voltage to the filter unit; And
And a power connection unit for stably supplying a high voltage provided from the high voltage generation unit to the filter unit rotating in the housing.
The power supply connection unit includes a connection terminal electrically connected to the high voltage generation unit and contacting the filter unit, and a high pressure air supply unit for injecting high pressure air from the rear end of the connection terminal toward the filter unit. Heavy particle collection device. The method of claim 1,
The charged part is composed of a discharge electrode and a ground electrode which are spaced apart from each other, and the particles in the air passing through the discharge electrode and the ground electrode charged by the corona discharge generated between the discharge electrode and the ground electrode is charged. delete The method of claim 1,
The particle collecting device in the air, characterized in that it comprises a plurality of porous filters provided radially overlapping disposed. The method of claim 4, wherein
The porous filter disposed in the outermost of the porous filter is made of a conductive material, characterized in that the high voltage is applied by the high voltage generating unit airborne particle collection device. The method of claim 4, wherein
The plurality of porous filters are provided with different densities and are arranged in such a manner that the density is gradually increased as the radial direction moves from the center of the filter part. delete The method of claim 5,
The power supply connection unit, the air particle collecting device, characterized in that it comprises an elastic member for elastically supporting the connection terminal toward the filter unit. The method of claim 8,
The filter unit, the air particle collecting device, characterized in that the electrically connected to the porous filter made of the conductive material and is provided with a ring-shaped track terminal disposed on the outer surface of the filter unit so that the connection terminal is in contact. delete The method according to any one of claims 1, 2, 4 to 6, 8 and 9,
Particle collecting device in the air, characterized in that the lower one side of the housing is provided with a drain hole for discharging the particles collected on the inner wall surface of the housing. The method of claim 11,
The discharge part is formed in the upper end of one side of the inner wall surface of the housing, the air particle collecting device, characterized in that the depression is formed in the lower end. The method of claim 12,
The recessed portion is formed in the air, characterized in that the connecting passage for inducing the particles collected in the recess to the drain hole.

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