KR102089342B1 - Precipitation Device having Dielectrophoresis Particle Separating Module - Google Patents

Abstract

The present invention relates to a precipitator. More specifically, the present invention relates to a precipitator equipped with a dielectrophoresis particle separating module. According to an embodiment of the present invention, disclosed is the precipitator equipped with the dielectrophoresis particle separating module which comprises: a particle separating module provided on an air flow path flowing in one direction, equipped with at least one electrode sheet on which an electrode is disposed, so that particles in the air flowing near the surface of the electrode sheet are collected by dielectric force generated by the power applied to the electrode sheet; and a housing on which the particle separating module is mounted and comprises a housing provided with a connection terminal for applying a voltage to the electrode sheet.

Description

Precipitation Device having Dielectrophoresis Particle Separating Module

The present invention relates to a dust collecting device, and more particularly, to a dust collecting device equipped with a particle separation module of a dielectric spectroscopy method.

Recently, it has been recognized as a serious social problem as fine dust has been identified as a major cause of hopi, cardiovascular and skin diseases.

Accordingly, at home or industrial sites, various types of dust collecting devices are used to collect and filter particulate matter contained in the air.

In general, a method widely used in homes is a method of using a filtration filter such as a HEPA filter. Due to the characteristics of the filtration filter, the better the collection efficiency, the faster the HEPA filter is blocked, resulting in severe decompression, resulting in a large pressure loss due to the filter. The power consumption increases. In addition, the replacement cycle of the filter becomes faster, which leads to the hassle of maintenance and increases the maintenance cost.

In addition, a dust collector using an ion generating device without a filter is also used. This type of dust collecting device constitutes an electrode with an ionizing part and a dust collecting part, and attaches particles such as fine dust to the dust collecting parts of two metal parallel plates by performing a single-pole charge. Although it has excellent ability as a dust collecting device, it discharges harmful gases such as ozone during discharge. There is a risk of being generated. Recently, unlike a conventional filtration type filter or a dust collecting device to which an ion generating device is applied, a dielectric immersion type dust collecting device is being studied. The air applied to the air purifier and the electrostatic precipitator is equipped with a force applied to the dielectric, that is, a dust collecting electrode having the form of collecting on the surface of the electrode plate, which implements a microelectrode pattern that collects oil, vapor, moisture, and fine dust by adopting a dielectric migration method By applying it, it is possible to reduce the pressure loss of the filter method while providing a new type of dust collector without corona discharge, which generates nitrogen oxides harmful to the human body.

On the other hand, as a result of recent research, there is a result that a lot of fine dust is generated during cooking in the kitchen of a home or restaurant as well as an industrial site. The fine dust generated in these places is discharged to the outside through a smoke exhaust device such as a hood, and there is a problem in that the fine dust is discharged without being filtered and pollutes the atmosphere.

In addition, the fine dust generated during cooking contains an oil component, and thus clogs the pores of the filter, making it difficult to apply a general filtration filter.

The present invention is to solve the above problems, and it is an object to provide a dust collecting device equipped with a particle separation module of a dielectric spectroscopy method capable of removing fine dust with higher efficiency.

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

In order to solve the above problems, according to an embodiment of the present invention, it is provided on the air flow path that flows in one direction, at least one electrode sheet is disposed on the electrode is provided, the vicinity of the surface of the electrode sheet A particle separation module and the particle separation module in which particles in the flowing air are collected by the dielectric motive force generated by the power applied to the electrode sheet are mounted, and a connection terminal for applying a voltage to the electrode sheet is provided. Disclosed is a dust collecting device equipped with a particle separation module of a dielectrophoretic method comprising a housing.

The particle separation module may include a core forming a central axis, concentric with the core, and spaced apart from the core in an outer diameter direction, and may include a plurality of electrode sheets electrically connected to each other.

Alternatively, the particle separation module may include a core forming a central axis, and an electrode sheet wound in a spiral shape a plurality of times to move away from the core.

The electrode sheet may be arranged such that the first electrode and the second electrode to which different voltages are applied alternate.

The first electrode may face the second electrode of the opposite electrode sheet, and the second electrode may be disposed to face the first electrode of the opposite electrode sheet.

On the upstream side of the particle separation module, a mesh type pre-filter may be further provided.

A plurality of particle separation modules may be provided in series along the air flow direction in the housing.

Among the plurality of particle separation modules disposed in the housing, a voltage applied from the particle separation module disposed on the downstream side may be greater than a voltage applied to the particle separation module disposed on the upstream side.

The particle separation module is provided in series in the air flow direction in the housing, and among the plurality of particle separation modules disposed in the housing, the gap between the electrode sheets of the particle separation module disposed downstream is disposed on the upstream side. It may be narrower than the gap between the electrode sheets of the particle separation module.

The particle separation module is provided in series with a plurality of particles in the air flow direction in the housing, and the first electrode disposed on the electrode sheet of the particle separation module disposed downstream of the plurality of particle separation modules disposed in the housing. The gap between the two electrodes may be narrower than the gap between the first electrode and the second electrode disposed on the electrode sheet of the particle separation module disposed on the upstream side.

A heater for heating the particle separation module may be further provided to remove foreign substances adsorbed on the particle separation module.

The particle separation module may further include an electrostatic capacity measurement sensor for measuring the electrostatic capacity.

As the capacitance measured by the capacitance measurement sensor increases,

The magnitude of the voltage applied to the particle separation module may be continuously or stepwise increased.

A heater for heating the particle separation module to remove foreign substances adsorbed on the particle separation module is further provided, and when the capacitance measured by the capacitance measurement sensor exceeds a preset value, the heater is controlled to operate. You can.

It may further include a blowing fan for forcibly flowing air in the housing.

As the capacitance measured by the capacitance measurement sensor increases, the amount of air flow by the blower fan can be increased.

According to the present invention, since a separate filter is not used, the life span is semi-permanent, thereby reducing the initial installation cost and maintenance cost, and separating the particles in a dielectric filtration method in which no harmful substances are generated in the conventional ion generation method. A dust collector equipped with a module is provided.

The effects of the present invention are not limited to the effects mentioned above, and other effects not mentioned will become apparent to those skilled in the art from the description of the claims.

The detailed description of the preferred embodiments of the present application described below, as well as the summary described above, will be better understood when read in connection with the accompanying drawings. For the purpose of illustrating the invention, preferred embodiments are shown in the drawings. However, it should be understood that the present application is not limited to the precise arrangements and instrumentalities shown.
1 is a perspective view showing a form in which a dust collecting device equipped with a particle separation module of a dielectric immersion method according to an embodiment of the present invention is coupled to an exhaust duct;
Figure 2 is a perspective view showing the inside by cutting a portion of the housing of the dust collecting device is equipped with a particle separation module of the dielectrophoresis method of Figure 1;
Figure 3 is a cross-sectional view showing a dust collecting device equipped with a particle separation module of the dielectric spectroscopy method of this embodiment;
Figure 4 is a perspective view showing the particle separation module of the dust collecting device is provided with a particle separation module of the dielectrophoresis method of Figure 3;
5 is a perspective view showing a state in which the outer frame of the particle separation module of Figure 4 is removed;
Fig. 6 is a sectional view of Fig. 5;
7 is a view showing an electrode sheet of the particle separation module of Figure 4;
FIG. 8 is a view showing a state in which a plurality of electrode sheets of FIG. 7 are spaced apart at regular intervals;
9 is a view showing a form in which the heating wire is provided on the electrode sheet of FIG. 8;
10 is a view showing a form in which a hot wire layer is provided between the electrode sheets of the particle separation module of FIG. 4;
11 is a view showing another embodiment of the particle separation module of FIG. 2; And,
12 is a cross-sectional view showing a form in which a foreign matter recovery unit is provided in an exhaust duct in which a dust collecting device equipped with a particle separation module of a dielectric distillation method is combined.

Hereinafter, preferred embodiments of the present invention, in which the object of the present invention can be specifically realized, will be described with reference to the accompanying drawings. In describing the present embodiment, the same name and the same code are used for the same configuration, and additional description will be omitted.

A dust collecting device (hereinafter, referred to as a 'dust collecting device' for convenience of description) equipped with a particle separation module of a dielectric distillation method according to the present embodiment, as shown in FIGS. 1 to 3, the housing 110 ), The particle separation module 120 and the blowing fan 130 may be included.

The housing 110 may be coupled to the end of the exhaust duct 10 such as communication, or may be installed in the exhaust duct 10. The housing 110 may form a space in which the particle separation module 120 is mounted.

The housing 110 is formed in a form in which one side and the other side are opened so that the air flowing through the exhaust duct 10 flows inside, and the particle separation module is configured to apply power to the mounted particle separation module 120. 120) may be provided with a terminal 112 that is electrically connected.

The particle separation module 120 is located on the air passage flowing in one direction inside the housing 110, the electrode sheet 124 on which the electrode is disposed is wound a plurality of times around the central axis, and the space between the wound is separated. It can be formed as possible.

In addition, the electrode sheet 124 is electrically connected to a terminal of the housing 110 to receive power, and dielectric motive force may be generated through the supplied power.

Therefore, as the air flows between the spaced apart portions of the electrode sheet 124, particles contained in the air may be collected on the surface of the electrode sheet 124 by the dielectric motive force applied by the electrode sheet 124. .

The blowing fan 130 is installed on the downstream side of the air flow direction of the housing 110 and the rear side of the particle separation module 120 to force air flowing in the housing 110 and the particle separation module 120. It's a building block.

The particle separation module may include an outer frame 122, a core 126, and an electrode sheet 124, as shown in FIGS. 4 to 6.

The outer frame 122 forms the outer shape of the particle separation module 120, and forms a space in which the core 126 and the electrode sheet 124 are located. The outer frame 122 as described above may be opened in a direction in which air flows in and out, and may be closed in the other direction.

On the other hand, the core 126 is a component forming a central axis, and the electrode sheet 124 is concentric with the core 126, and is spaced apart from the core 126 in a diameter outward direction so that a plurality of layers are at a constant distance from each other. Spaced apart and arranged in a circle, each electrode sheet 124 may be supplied with the same voltage or may be supplied with different voltages.

At this time, the electrode sheet 124 may be a flexible material that is free of warpage. Of course, the electrode sheet 124 is not necessarily limited to this, and may be formed of a material that is not flexible.

Meanwhile, as illustrated in FIG. 7, a first electrode 128 and a second electrode 129 may be formed on the electrode sheet 124.

The first electrode 128 and the second electrode 129 may be formed on one surface of the electrode sheet 124 or may be formed on both surfaces of the electrode sheet 124. Of course, the back surfaces of the two electrode sheets 124 on which the first electrode 128 and the second electrode 129 are formed may be overlapped and attached to each other to form one electrode sheet.

As for the first electrode 128 and the second electrode 129, a plurality of sets may be arranged side by side as two of them are alternately spaced apart at regular intervals in the electrode sheet 124.

Different voltages may be applied to the first electrode 128 and the second electrode 129. For example, DC or AC power may be applied to the first electrode 128 and the second electrode 129. When a DC voltage is applied, the first electrode 128 forms a ground electrode. In addition, a preset DC voltage may be applied to the second electrode 129.

At this time, as shown in Figure 8, the first electrode 128 and the second electrode 129 formed on each electrode sheet 124 of a plurality of layers formed around the core 126, the facing layer The first electrode 128 and the second electrode 129 formed on the electrode sheet may be formed to face different electrodes.

That is, the first electrode 128 faces the second electrode 129 of the opposite electrode sheet 124, and the second electrode 129 is the first electrode 128 of the opposite electrode sheet 124. It can be arranged to face the.

Accordingly, the dielectric sheet is generated by the power applied to the electrode sheet 124 on which the first electrode 128 and the second electrode 129 are disposed, and particles contained in air are generated by the dielectric sheet. It can be moved to the (124) side and captured on the surface.

Also, unlike the above, as shown in FIG. 10, the electrode sheet 224 of the particle separation module 220 is wound in a spiral shape a plurality of times so that one electrode sheet 224 moves away from the core 226. It may be formed.

On the other hand, as shown in Figure 3, the upstream side of the particle separation module 120, the front side of the housing 110 may be provided with a mesh-shaped pre-filter 140 for filtering large particles. The pre-filter 140 may be detachably formed to facilitate cleaning, and may be formed of a metal or synthetic resin material.

Of course, in addition to the pre-filter 140, a medium filter or an activated carbon filter for deodorization may be provided. Changes and additions to these known types of filters can be carried out freely.

Meanwhile, the magnitude of the dielectric force generated according to the distance D1 between the first electrode 128 and the second electrode 129 may be different. In addition, the size of the dielectric force generated according to the gap D2 between each electrode sheet 124 and the electrode sheet facing each other may vary.

That is, even when the same power is applied, the smaller the distance D1 between the first electrode 128 and the second electrode 129 or the facing electrode sheet 124 (D2), the greater the amount of dielectric force generated. May increase, and thus the collection efficiency of particles may be increased.

In addition, even if the interval D1 between the first electrode 128 and the second electrode 129 or the interval D2 between the electrode sheets 124 is the same, the size of the power applied to the electrode sheet 124 is the same. As it grows, the magnitude of the dielectric force may also increase.

As illustrated in FIG. 3, a plurality of particle separation modules 120 may be provided in series along the flow direction of air in the housing 110. In addition, each particle separation module 120 may be controlled to receive different power.

For the efficient collection of particles, the voltage applied from the particle separation module 120 disposed on the downstream side of the plurality of particle separation modules 120 disposed on the housing 110 is disposed on the upstream side ( 120).

That is, the dielectric force generated by the particle separation module 120 disposed on the downstream side may be greater than the dielectric force generated by the particle separation module 120 disposed on the upstream side.

Therefore, particles are first collected by the particle separation module 120 disposed on the upstream side, and dust particles are again collected by the more powerful dielectric force from the particle separation module 120 disposed on the downstream side, thereby increasing the collection efficiency. Can be.

Alternatively, among the plurality of particle separation modules 120 disposed in the housing 110, the gap D2 between the electrode sheets 124 of the particle separation module 120 disposed on the downstream side is separated from the particles disposed on the upstream side. It may be narrower than the distance D2 between the electrode sheets 124 of the module 120.

Alternatively, among the plurality of particle separation modules disposed in the housing 110, the first electrode 128 and the second electrode 129 disposed on the electrode sheet 124 of the particle separation module 120 disposed downstream. The interval D1 may be narrower than the interval D1 between the first electrode 128 and the second electrode 129 disposed on the electrode sheet of the particle separation module 120 disposed on the upstream side.

Therefore, the dielectric force generated in the particle separation module 120 disposed on the downstream side may be greater than the dielectric force generated in the particle separation module 120 disposed on the upstream side.

Therefore, particles are first collected by the particle separation module 120 disposed on the upstream side, and dust particles are again collected by the more powerful dielectric force from the particle separation module 120 disposed on the downstream side, thereby increasing the collection efficiency. Can be.

Meanwhile, a heater 160 for heating the particle separation module 120 may be further provided to remove foreign substances collected on the electrode sheet 124 of the particle separation module 120.

When particles, such as dust or oil, are accumulated on the surface of the electrode sheet 124, the collection performance decreases, and thus it is necessary to remove the dust.

As illustrated in FIGS. 9 and 11, the heater 160 may be formed of a heating wire disposed in the middle of the electrode sheet or a heating wire embedded in the electrode sheet 124 and embedded.

That is, as illustrated in FIG. 9, when two electrode sheets 124 are attached to each other to form one electrode sheet 124, a hot wire may be embedded therebetween. Alternatively, as illustrated in FIG. 11, a heater layer 160 in which a hot wire is embedded may be disposed between the electrode sheets 124.

Alternatively, although not shown in the drawings, it may be provided to increase the temperature of the particle separation module 120 by supplying hot air of high temperature to the particle separation module 120.

In the case where the dust collected in the particle separation module 120 is burned by the heater 160 or when the dust contains an oil component, the oil component emulsified by heating flows along with the dust to be removed by gravity. You can.

On the other hand, as shown in Figure 3, may further include a capacitive measurement sensor 150 for measuring the electrostatic capacity of the particle separation module 120.

As the foreign matter such as fine dust accumulates on the electrode sheet 124 of the particle separation module 120, the electrostatic capacity increases. A capacitance measurement sensor 150 is provided to measure the capacitance applied to the electrode sheet 124. By doing so, it is possible to estimate the amount of foreign matter such as particles collected on the electrode sheet 124 by measuring the capacitance applied to the electrode sheet 124.

In addition, a control unit 170 for controlling a power unit (not shown) for applying power to the capacitive measurement sensor 150, the blower fan 130, the heater 160, and each particle separation module 120 may be provided. You can.

The control unit 170 may control the magnitude of the voltage applied to the particle separation module 120 to increase continuously or stepwise as the capacitance measured by the capacitance measurement sensor 150 increases.

That is, an increase in the capacitance measured by the capacitance measurement sensor 150 may mean that there are many particles, such as dust, in the air flowing in the housing 110, so the voltage applied to the particle separation module 120 By controlling the size of the particles to be continuously or stepwise increased, the dielectrophoretic force can be increased to increase the particle trapping power.

Alternatively, the control unit 170 may increase the amount of air filtering by the blowing fan 130 as the capacitance measured by the capacitance measurement sensor 150 increases.

Meanwhile, when the capacitance measured by the capacitance measurement sensor 150 exceeds a predetermined value, the controller 170 may operate the heater 160.

That is, since the capacitance measured by the capacitance measurement sensor 150 increases, it means that there are many particles such as dust collected on the electrode sheet 124, the heater 160 is operated to remove foreign substances. have.

Meanwhile, a foreign material recovery unit may be further provided.

The foreign substance recovery unit is a component that receives foreign substances falling from the particle separation module 120 when the heater 160 is operated.

At this time, in order to maximize the effect of gravity, the housing 110 may be upright. In addition, an exhaust duct 10 is coupled to the housing 110, and a portion of the exhaust duct coupled to the housing 110 may extend in a vertical direction.

A trap 18 bent in a horizontal or U shape is formed at a lower end of the portion where the exhaust duct 10 extends in the vertical direction, and a foreign material drain 182 may be installed at the lower end of the trap 18. have.

In addition, a container 184 capable of receiving a foreign material may be detachably installed in the foreign material drain 182.

Therefore, the foreign matter flowing out of the particle separation module 120 by the operation of the heater 160 flows down the exhaust duct 10 by gravity and discharges the foreign matter drain 182 installed on the lower side of the trap 18. Discharged through, the discharged foreign matter is accommodated in the container 184, and when the container 184 is filled with a certain amount or more, the container 184 can be removed and cleaned.

As described above, the preferred embodiments according to the present invention have been examined, and the fact that the present invention can be embodied in other specific forms without departing from the spirit or scope of the embodiments described above has ordinary skill in the art. It is obvious to them. Therefore, the above-described embodiments are to be regarded as illustrative rather than restrictive, and accordingly, the present invention is not limited to the above description and may be changed within the scope of the appended claims and their equivalents.

100: dust collector equipped with a dielectric separation type particle separation module
110: housing 120: particle separation module
122: outer frame 124: electrode sheet
126: core 128: first electrode
129: second electrode 130: blowing fan
140: pre-filter 150: capacitance measurement sensor
170: control unit
D1: spacing between the first electrode and the second electrode
D2: gap between electrode sheets 182: foreign material drain
184: Courage

Claims (17)

It is provided on an air passage that flows in one direction, and at least one electrode sheet on which electrodes are disposed is provided, and particles in the air flowing around the surface of the electrode sheet are generated by power applied to the electrode sheet. A particle separation module that is collected by the dielectrophoretic force; And
The particle separation module is mounted, the housing provided with a connection terminal for applying power to the electrode sheet; includes,
The electrode sheet is wound a plurality of times around the central axis, and is formed to be spaced apart between windings. As the air flows between the electrode sheets, the electrode sheet is driven by a dielectric force generated by power applied to the electrode sheet. It is configured to collect particles in the flowing air,
In addition, the particle separation module,
A core forming a central axis; And
Containing the core and the concentric, spaced apart from the core in the outer direction, a plurality of electrode sheets electrically connected to each other; includes,
On the other hand, the particle separation module is provided with a plurality of in series in the air flow direction in the housing, the first electrode disposed on the electrode sheet of the particle separation module disposed downstream of the plurality of particle separation modules disposed in the housing The gap between the second electrode and the second electrode is formed narrower than the gap between the first electrode and the second electrode disposed on the electrode sheet of the particle separation module disposed on the upstream side, or among the plurality of particle separation modules disposed on the housing, on the downstream side. The particle separation module is disposed so that the gap between the electrode sheets of the particle separation module is arranged narrower than the gap between the electrode sheets of the particle separation module disposed on the upstream side, and the dielectric force generated by the particle separation module disposed on the downstream side is disposed on the upstream side. It is composed larger than the dielectric motive force generated by the separation module,
In addition, further comprising a capacitance measurement sensor for measuring the capacitance of the particle separation module, as the capacitance measured by the capacitance measurement sensor increases, the magnitude of the voltage applied to the particle separation module continuously or stepwise. Controlled to increase,
On the other hand, a heater for heating the particle separation module is further provided to remove foreign substances adsorbed on the particle separation module,
When the capacitance measured by the capacitance measurement sensor exceeds a predetermined value, the dust collecting device equipped with a particle separation module of a dielectric spectroscopy method that is controlled to operate the heater. delete delete delete delete delete delete delete delete delete delete delete delete delete delete According to claim 1,
A dust collecting device equipped with a particle separation module of a dielectrophoretic method further comprising a blowing fan for forcibly flowing air in the housing. The method of claim 16,
A dust collecting device equipped with a particle separation module of a dielectrophoretic method that increases the amount of air flow by the blower fan as the pressure value measured by the pressure loss measurement sensor increases.

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