KR102120716B1 - Ionized fine Dust Remover - Google Patents

Abstract

The present invention relates to an apparatus for removing ionized fine dust to provide high fine dust capturing efficiency. According to the present invention, the apparatus for removing ionized fine dust comprises: a case having a reception space formed therein; a support plate unit having an opening hole formed at a center thereof; an air blower unit suctioning air from the upper part of the support plate unit to discharge the air to the lower part of the support plate unit and the lower part of the case; a stand unit including a cylindrical unit assembly unit; a cylindrical dust collection unit; and a cylindrical unit having at least one anionization module disposed on an upper end thereof to electrically charge molecules included in the air with anions.

Description

Ionized fine dust remover

The present invention relates to an ionized fine dust remover that removes after ionizing the fine dust.

It is reported that 47% of the fine dust measured on the Korean Peninsula comes from China and 41% comes from domestic industry and vehicle fumes. The ultra-fine dust from China is less than 2.5 micrometers in diameter, and is only one-third the thickness of the hair. These ultra-fine dusts not only contain heavy metals, which are carcinogens, and various harmful substances, but they cannot be seen with the naked eye and have no smell.

Moreover, ultrafine dust causes various respiratory diseases and penetrates into the deepest part of the respiratory system such as lungs and enters blood vessels to increase the viscosity of blood, causing cardiovascular diseases such as stroke and various cancers.

There is a growing interest in the incidence of various diseases and cancer caused by indoor air quality and fine dust, and interest in the risk of fine dust in the air is increasing. Among these harmful gas components, gas components (formaldehyde, volatile organic compounds, etc.) that are harmful to health are mixed with contaminants, and dust and bacteria enter the respiratory tract, including dust and bacteria. Most bacteria and heavy metals mixed in the air are often attached to fine dust or flow on their own.

Currently, there is increasing awareness of the need to purify air by removing dust from the air. Accordingly, the development of a fine dust eliminator is rapidly progressing as an urgent measure for national disasters for national health and medical welfare.

Along with the development of the fine dust eliminator, many devices for removing fine dust using an electrostatic precipitating principle have been developed. As an example, a device for removing fine dust by a parallel plate electric field and a water film type dust collecting device using water and electricity have been developed since the fine dust is collected in a water film type dust collecting pole and then collected in a water tank by spraying water.

However, a device that removes fine dust with a parallel plate uses high voltage to present an electrical stability problem and a fire hazard, and a water film type dust collector has a risk in that water and electricity are used together. In addition, the filtering method that passes through various types of filters receives air resistance, so a strong ventilation fan is required. When a lot of fine dust and general dust are deposited, it is resisted by the passage of the passage, increasing noise generation and reducing foreign matter removal per unit time. Have

Republic of Korea Registered Patent No. 10-1925848 (Dec. 07, 2018)

Accordingly, the technical problem to be achieved by the present invention is to use it safely without using water together with electricity without using high voltage, and have the efficiency of removing fine dust and sterilizing harmful microorganisms (such as various bacteria and highly infectious viruses). It is to provide an improved ionized fine dust remover.

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

The ionized fine dust remover of the present invention for achieving the above technical problem, after ionizing the inflowing fine dust, adheres to the filter of the dust collecting part. It is not the way that the introduced air passes through the filter, but the air flow path and the stacked filter module are installed in parallel to each other so that the ionized fine dust is attached to the stacked filter module by the electric field segment in the cylindrical mesh network without disturbing the flow path. This can smoothly reduce the time required to remove harmful substances per unit time.

The ionized fine dust remover includes a case in which an accommodation space is formed;

It is installed inside the case, the support plate portion is formed with an opening hole in the center;

A blower unit which is installed on a lower surface of the base plate portion and sucks air from an upper portion of the base plate portion and discharges it to the lower portion of the case;

It includes a plurality of support modules, one end of the plurality of support modules is spaced apart from the upper surface of the support plate part, the other end is inclined in an upward direction from one end to be connected to one central assembly, the lower end from the upper surface of the support module A mounting portion including a cylindrical assembly part connected to a cylindrical portion on the outside, including a plurality of positive electrode installation holes connected to the positive electrode line and a plurality of negative electrode installation holes connected to the positive electrode line;

The negative electrode installation hole spaced apart from the first dust collecting module installed in the positive electrode installation hole to collect anionized foreign substances, including a cylindrical first mesh network composed of line segments for induction of a strong line segment electric field with the laminated filter module attached Cylindrical dust collecting unit including a second mesh network installed in (consisting of 7 mesh networks and 3 stacked filter modules);

It is formed in a hollow shape, is fixed to the top of the base plate portion, accommodates the cylindrical dust collecting portion therein, and emits electrons into the air inside the cylinder at the top to negatively ionize an ionization module (Electron Ionizer: EI) installed at least one cylinder Includes wealth.

The mounting portion may be provided with an annular first UV lamp installed on the connecting member to irradiate ultraviolet rays toward the cylindrical dust collecting portion and sterilize harmful bacteria adhered to the cylindrical dust collecting portion.

It is installed between the positive electrode installation hole and the negative electrode installation hole of the mounting portion, further comprising a plurality of second UV lamps (LED Type) for irradiating ultraviolet light toward the cylindrical dust collecting part and sterilizing harmful bacteria adhered to the cylindrical dust collecting part can do.

The other end of the plurality of support modules is inclined upward from one end to be connected to one by the central assembly unit, and a point connected to one may be located above the center point of the opening hole.

To accommodate the first dust collecting module at the top (a structure in which three stacked filter modules are attached to three cylindrical segment mesh networks), fix the first dust collecting module in the positive electrode installation hole and fix the positive electrode connected to the positive electrode wire at the bottom The second mesh network (consisting only of four cylindrical line segment mesh networks) is accommodated in the conductor wire and the upper portion to fix the second mesh network in the negative electrode installation hole, and a negative electrode fixing lead wire protruding to the negative electrode installation hole is further added. It can contain.

A plurality of first dust collecting modules and a plurality of second mesh networks may be alternately installed in the mounting portion.

The first dust collecting module (including three first mesh networks and a stacked filter module, which are direct current positive electrodes) is grounded and maintained as a “Zero bolt”, and the second mesh network (four mesh networks, DC negative electrodes) is in contact with the human body. The first dust collecting module connected to the ground (zero volt) is applied as a “Zero volt” to the human body even if it comes into contact with the human body, so that current cannot flow into the human body.

The positive and negative voltages are alternately applied to the first mesh network and the second mesh network of the first dust collecting module by alternately applying positive and negative voltages by alternating DC voltage pulse alternative electric-field (PAEF) methods, thereby causing the negative ionized fine dust to the left and right. The speed is reduced by the movement, increasing the probability of trapping in the layered filter module, and detaching the fine dust attached to each mesh network to be collected again in the layered filter module to connect the power unit that can clean each mesh network by electric field method itself. Can be.

The ionized fine dust remover according to the present invention can more effectively collect fine dust through a dust collecting part forming a radial line segment electric field in a 360° direction. And by irradiating ultraviolet rays in the direction of 360°, it is possible to sterilize/remove microorganisms and viruses adhered to the laminated filter module. In particular, the ionized fine dust eliminator is formed in a concentric shape of the dust collecting section to maximize the electric field area, and the electric field direction is distributed in the entire spatial direction to strongly form the electric field in the 360° direction. Dust can be collected by concentrating only one direction of the laminated filter module. In addition, the ionized fine dust eliminator of the present invention is equipped with a dust collecting part (first and second mesh networks) and a filter parallel to the flow path direction to minimize flow path resistance and allow a large amount of wind to flow in.

In addition, since the present invention applies a solution that does not evaporate at room temperature to the filter, one fine dust removal filter can be used for a long time, and such a filter can be easily replaced. In addition, the present invention is to ground the positive electrode (Ground) and using the negative electrode as a negative voltage to ensure electrical stability to the user to prevent safety accidents due to electricity.

1 is a perspective view of an ionized fine dust remover for an embodiment of the present invention.
FIG. 2 is an exploded perspective view of the ionized fine dust remover of FIG. 1.
FIG. 3 is a view showing a state in which a first ultraviolet lamp for sterilization is installed on a connection member at a lower portion of the mounting portion of FIG. 2.
4 is a view showing a second ultraviolet lamp for sterilization installed on the upper surface of the mounting portion of FIG.
5 is a view showing a state in which the base plate is installed under the mounting portion of FIG.
6 is a view showing a cylindrical dust collecting part and an entire dust collecting part (three stacked filter modules and three first mesh networks) and a mesh network (four second mesh networks) into which a circular stacked filter module is inserted.
FIG. 7 is a view showing a state in which the cylindrical dust collecting part of FIG. 6 is installed in the mounting portion.
FIG. 8 is a view showing a state in which each cylindrical dust collecting part is inserted into the positive electrode installation hole and the negative electrode installation hole of the mounting part of FIG. 7 and mounted by a fixing module (conductor for fixing the positive electrode and negative electrode) of the cylindrical dust collecting part.
FIG. 9 is a view showing a state in which an electrode line (positive electrode line and negative electrode line) is connected to the lower portion of the mounting portion after the cylindrical dust collecting portion is installed in the mounting portion of FIG. 7.
FIG. 10(a) is a view showing a state in which a base plate for attaching a system to a case is installed and fixed at a lower portion of the mounting portion of FIG. 9, and FIG. 10(b) is connected to a cylindrical assembly portion of the mounting portion to a top of the supporting portion. It is a view showing a state in which a cylindrical portion made of plastic is installed to block the inflow of external wind and protect the cylindrical dust collecting portion.
FIG. 11 is a view showing a state in which a blower unit for introducing contaminated air is installed in the support plate of FIG. 10.
FIG. 12(a) is a view showing a case portion of the entire system, FIG. 12(b) is a view showing a state in which the entire device of FIG. 11 is installed inside the case portion, and FIG. 12(c) is a top cover of the entire case It is a drawing with a plate and 3 cicadas attached and the display displayed.
13 shows the air flow direction during operation of the ionized fine dust remover according to an embodiment of the present invention of FIG. 1, intakes air to the upper side of the case, and the air blowing direction from the top to the bottom, and clean air to the bottom side of the case It is a view showing the discharged state.
14 is a view schematically showing a state of smooth flow path discharge according to the operation of the blower unit installed at the bottom of the cylindrical dust collecting part of the ionized fine dust remover of FIG. 1.
FIG. 15(a) is a view showing the direction and distribution of a strong cylindrical line segment focused electric field formed when electrodes are applied to three first mesh networks and four second mesh networks, each of which includes a multilayer filter module, in a cylindrical dust collecting part, and FIG. 15 (b) is a diagram schematically showing a distribution that moves in the opposite direction to the direction of the electric field in which the anionized foreign substances are concentrated only in the direction of the stacked filter module by the strong cylindrical line electric field.
Figure 16 (a) is a view showing when a normal direct current is applied to the cylindrical dust collecting anionized fine dust in the direction of the stacked filter module as shown in Figure 15 (b) due to the strong cylindrical line focusing electric field of Figure 15 (a) It is a view schematically showing a state in which only the induction is collected, and FIG. 16(b) is a view showing when alternating DC voltage PAEF (Pulse Alternative Electric-Field) is applied to the cylindrical dust collector.

Advantages and features of the present invention and methods for achieving them will be clarified with reference to embodiments described below in detail together with the accompanying drawings. However, the present invention is not limited to the embodiments disclosed below, but may be implemented in various different forms.

However, the present embodiments are provided only to complete the disclosure of the present invention and to fully inform the person of ordinary skill in the art to which the present invention pertains, the scope of the present invention, and the present invention is defined only by the claims. It can be.

Hereinafter, an ionized fine dust remover according to an embodiment of the present invention will be described in general with reference to FIG. 1.

1 is a perspective view of an ionized fine dust remover for an embodiment of the present invention.

The ionized fine dust remover 1 according to an embodiment of the present invention is primarily a dust with a primary air dust filter attached to the upper side of the case when external air is introduced into the interior through the blower unit 30. (General dust larger than fine dust) is removed, and secondly, the second air dust filter completely filters the general dust, so it can collect fine dust, thus protecting the laminated filter module and extending the service life. If dust accumulates on the stacked filter module, it is possible to prevent a fire due to sparks. The anionization module 610 emits electrons into the air in the cylindrical portion 60 to anionize the introduced fine dust. Then, a string chaos electric field is formed in the direction of 360° through the cylindrical dust collecting part 50 to collect and collect the anionized fine dusts with the multilayer filter module 500. In addition, it is possible to sterilize harmful microorganisms and viruses by irradiating ultraviolet rays toward the inside of the cylindrical dust collecting part 50 collected in the multi-layer filter module 500. Here, the fine dust may be dust including ultrafine dust.

The ionized fine dust remover 1 anionizes air in the direction of 360°, focuses and collects the anionized fine dust into a strong cylindrical line segment electric filter module 500, and collects it more effectively than a conventional fine dust remover. It can exert power and sterilization power. In addition, in the ionized fine dust remover 1, the cylindrical dust collecting part 50 is installed in a direction in which the lamination filter module 500 and the flow path direction are parallel, minimizing the flow path resistance so that the wind can be discharged smoothly. In addition, a special mixed solution of a glycerin component harmless to the human body that does not evaporate at room temperature is applied to the laminated filter module 500, so that the laminated filter module 500 can be used for a long time by maintaining adhesive strength for a long time.

The ionized fine dust remover (1) is a case 10, the support plate portion 20 installed inside the case, the blower portion 30 installed on the lower surface of the support plate portion 20, the support plate portion 20 The mounting part 40 installed on the upper surface, the cylindrical dust collecting part 50 installed on the upper side of the mounting part 40, and the cylindrical dust collecting part 50 inside the cylindrical part 60 are accommodated, and the supporting plate part 20 It is included as a component to be fixed to the upper side.

In addition, the ionized fine dust remover (1) fixes the cylindrical dust collecting part (50) to the first ultraviolet lamp (710), the second ultraviolet lamp (720) and the mounting part (40) irradiating ultraviolet rays to the cylindrical dust collecting part (50). The positive electrode fixing lead wire 4011 and the negative electrode fixing lead wire 4021 may further include a power supply unit 70 for applying power to the components. Here, the power supply unit 70 may include AC PCB, SMPS, and cylindrical mesh DC-PCB.

In addition, the upper cover plate 101 covering the top of the case 10, cicada ring 102 for fixing the top cover plate 101 to the case 10, the primary air dust filter installed on the upper side of the case ( 103), a filter 109 for preventing foreign matter from being installed on the lower side of the case, a carrying handle 104 installed on the outer side of the case, and a lower separation plate installed at the bottom of the case to create an installation space for the power unit 70 (105) and the lower cover plate 106 covering the lower end of the case and the rubber feet 107 installed at the lower end of the lower cover plate 106, and the like.

Hereinafter, components of the ionized fine dust eliminator and a connection relationship between the components will be described with reference to FIGS. 2 to 16.

However, in order to make the description of the present invention clear and concise, in the components constituting the present invention, descriptions of well-known accessories such as accessories and devices operated by well-known facts are omitted and main features of the present invention are omitted. Only the components that can be exerted and the operation of the components will be described in detail.

FIG. 2 is an exploded perspective view of the ionized fine dust remover of FIG. 1, and FIG. 3 is a view showing a state in which a first UV lamp for sterilization is installed on a connection member at a lower portion of the mount of FIG. 2. And Figure 4 is a view showing a second ultraviolet lamp for sterilization installed on the upper surface of the mounting portion of FIG.

And Figure 5 is a view showing a state in which the base plate is installed in the lower portion of Figure 2, Figure 6 is a cylindrical dust collecting part and the entire dust collecting part (three stacked filter modules and three first mesh network) with a circular stacked filter module inserted This is a view showing a mesh network (four second mesh networks). And FIG. 7 is a view showing a state in which the cylindrical dust collecting part of FIG. 6 is installed in the mounting portion. And FIG. 8 is a view showing a state in which each cylindrical dust collecting part is inserted into the positive electrode installation hole and the negative electrode installation hole of the mounting part of FIG. 7 and mounted by a fixed module (conductor for fixing positive and negative electrodes) of the cylindrical dust collecting part. 7 is a view showing a state in which an electrode line (positive electrode line and negative electrode line) is connected to the lower portion of the mounting portion after the cylindrical dust collecting portion is installed in the mounting portion of FIG. 7. And Figure 10 (a) is a view showing a state in which the base plate to attach the system to the case at the bottom of the mounting portion of Figure 9 is installed and fixed, Figure 10 (b) is connected to the cylindrical assembly of the mounting portion of the top of the base A view showing a state in which a cylindrical portion made of a plastic material that blocks an external wind inflow and protects a cylindrical dust collecting portion is installed, and FIG. 11 is a view showing a state in which a blower portion for introducing contaminated air is installed in the base plate of FIG. 10. And Figure 12 (a) is a diagram showing the entire system case, Figure 12 (b) is a diagram showing a state in which the entire device of Figure 11 is installed inside the case, Figure 12 (c) is the top of the entire case The cover plate and three cicadas are attached, and the display is displayed.

In addition, FIG. 13 shows the air flow direction during operation of the ionized fine dust remover according to an embodiment of the present invention of FIG. 1, intakes air to the upper side of the case, and the air blowing direction from the top to the bottom, and cleans the bottom side of the case. It is a view showing a state in which the air is discharged, and FIG. 14 is a view schematically showing a state of smooth flow passage discharge according to the operation of the blower part installed at the bottom of the cylindrical dust collecting part among the ionized fine dust remover of FIG. 1. And Fig. 15 (a) is a diagram showing the direction and distribution of a strong cylindrical line segment focused electric field formed when electrodes are applied to three first mesh networks and four second mesh networks each including a laminated filter module in a cylindrical dust collecting part, FIG. 15(b) is a view schematically showing a distribution that moves in the opposite direction to the direction of the electric field in which the anionized substances are focused only in the direction of the layered filter module by the strong cylindrical line electric field. And Fig. 16 (a) is a view showing when a normal direct current is applied to the cylindrical dust collecting part, the anionized fine dust is concentrated in the direction of the stacked filter module as shown in Fig. 15 (b) due to the strong cylindrical electric field concentration in Fig. 15 (a). It is a view schematically showing a state in which only is collected by induction, and FIG. 16(b) is a view showing when an alternating DC voltage PAEF (Pulse Alternative Electric-Field) is applied to a cylindrical dust collector.

The case 10 accommodates a plurality of components constituting the present invention in which the accommodation space 100 is formed. For example, the base plate portion 20, the mounting portion 40, the cylindrical dust collecting portion 50 including the laminated filter module 500, the cylindrical portion 60 including the anionization module 610, the first ultraviolet ray for sterilizing harmful microorganisms The lamp 710, the blower unit 30, and the like can be accommodated. In this case 10, the upper portion may be covered by the upper cover plate 101 and the lower portion may be covered by the lower cover plate 106. Here, six rubber feet 107 may be installed on the lower cover plate 106 so that the case 10 can be more stably erected on the bottom surface. In addition, the air intake port 108 on the top of the outer surface of the case 10 and the air outlet port 110 on the bottom of the outer surface may be arranged in a constant shape. Here, a primary air dust filter 103 is attached to the top of the case 10 so as to overlap with the air intake port 108 on the inner surface of the case 10, and a filter 109 for preventing foreign matter from entering is attached to the air outlet port 110 at the bottom. have. The case 10 may be formed in various shapes such as hexagonal, octagonal and cylindrical shapes. And the outer surface air inlet, outlet 108, 110 may also be formed in a variety of shapes, such as circular, triangular, square and pentagonal.

The support plate 20 is formed in a shape corresponding to the shape of the case 10, as shown in Figure 5, is installed inside the case, the mounting portion 40, the cylindrical dust collecting portion 50, the cylindrical portion on the upper side (60) so that it can be installed. And so that the blower unit 30 can be installed on the lower side. In addition, the support plate portion 20 is the opening hole 200 is formed in the center when the blower unit 30 installed on the lower side is operated, so that the wind can flow in the direction of the blower unit 30 from the top of the case portion .

As shown in FIG. 11, the blower unit 30 is installed on the lower surface of the support plate unit 20 through the blower connector 340 and the air discharge guide 350 or the like. The plastic circular frame of the air discharge guide 350 serves as a flow path guide for discharging the wind from the blower unit 30 from top to bottom and prevents air backflow. The blower unit 30 includes a plurality of cylindrical rotating shaft modules 310 and a plurality of blade modules 320 which are regularly spaced apart from the rotating shaft modules 310. The blower unit 30 is operated through a power applied from the outside, and the air discharge guide 350 helps the wind to flow out from the upper portion to the lower portion.

The mounting portion 40 may be formed by connecting a plurality of support modules. In one example, the first support module 410, the second support module 420 and the third support module 430 are spaced apart at a predetermined interval, one end is located below, the other end is facing upward, and one by the central assembly 460 It may be formed in a connected structure. At this time, the point where the plurality of support modules are connected to one is located above the center point of the opening hole 200 in the base plate portion 20 and may be located where it overlaps the center point of the opening hole.

The mounting portion 40 may be fixed to the upper surface of the base plate portion 20 through the assembly connector 450. In addition, a plurality of positive electrode installation holes 401 and negative electrode installation holes 402 are formed on the upper surface of the mounting portion 40 to a plurality of first dust collecting modules 510 and a plurality of second mesh networks 520. The cylindrical dust collecting part 50 may be stably fixedly installed.

In addition, the positive electrode fixing wire connected to the positive electrode line 411 and accommodating the first dust collecting module 510 in the positive electrode installation hole 401 so that the cylindrical dust collecting part 50 can be more stably installed in the mounting part 40. A conductive wire 4021 for fixing the negative electrode that accommodates the second mesh network 520 and is connected to the negative electrode line 422 may be installed in the 4011 and the negative electrode installation hole 402. At this time, the first dust collecting module 510 is installed on the top of the positive electrode fixing wire 4011, and the second mesh network 520 is installed on the top of the negative electrode fixing wire 4021. In addition, a positive electrode line 411 may be connected to a lower end of the positive electrode fixing wire 4011 and a negative electrode line 422 may be connected to and installed at the lower end of the negative electrode fixing wire 4021.

The power supply unit 70 changes the positive and negative voltages by alternating DC voltage PAEF (Pulse Alternative Electric-Field) method to the positive electrode line 411 and the negative electrode line 422 as shown in FIG. 16(b) (10~ 30 times/sec).

Through this, the first three mesh networks 504 themselves, to which the multi-layer filter module 500 is attached, and the circular line segment without the multi-layer filter module 500, the second mesh network 520 itself, which are partially attached to the four anionized The electric field is formed in a direction opposite to that of the fine dust, and can be collected and collected again in the stacked filter module 500 by focusing and moving in the direction of the stacked filter module 500. Therefore, each mesh network can be cleaned by electric field method. In addition, since the alternating electric field direction is changed, ionized fine dust has a high probability of being attached to the multi-layer filter module 500 due to a decrease in speed due to horizontal motion.

The cylindrical dust collecting part 50 is composed of three first dust collecting modules 510 and four second mesh networks 520. And it is formed in a hollow shape is accommodated inside the cylindrical portion 60 is fixed to the top of the base plate module. At least one anionization module 610 that emits electrons into the air and negatively ionizes them at the top of the cylindrical portion 60 is installed to negatively ionize fine dust (foreign matter) flowing into the cylindrical dust collector 50.

The cylindrical dust collecting part 50 may collect anionized fine dust through three first dust collecting modules 510. Here, three first dust collecting modules 510 are coated with a mixed solution of glycerin that absorbs moisture in the air and maintains viscosity and prevents mold growth without evaporation at room temperature, resulting in a maximum filter thickness of 0.1 mm (501), the third filter layer, is attached between them, generates a static electricity, the laminated filter module 500 including a second static electricity film 502 having a maximum thickness of 0.2mm may be composed of three layers .

When the positive electrode is applied to the three first dust collecting modules 510, the cylindrical dust collecting unit 50 pulls the anionized fine dust by the attraction of the electric field, and the three stacked filter modules 500 of the first dust collecting module 510 Fine dust can be attached to. On the other hand, when the negative electrode is applied to the second mesh network 520, the cylindrical dust collecting unit 50 separates the anionized fine dust from the second mesh network 520 by the repulsive force of the electric field, thereby easily stacking the filter module ( 500) Focusing is induced in three directions to be adsorbed and removed. The cylindrical dust collecting part 50 forms an electric field as shown in the direction shown in Fig. 15 (a), and thus the anionized fine dust has three stacked filter modules 500 as shown in the direction shown in Fig. 15(b). Focusing can be induced in the direction in which it is located. The cross section of this is shown as Fig. 16(a), and some may be attached to each mesh network itself.

As described above, three first dust collecting modules 510 and four second mesh networks 520 are alternately installed in the positive electrode installation holes 401 and negative electrode installation holes 402 of the mounting portion, and a total of seven are installed. As an example, as shown, the first dust collecting module 510 includes a multi-layer filter module 500 and a first mesh network 504, and the second mesh network 520 is composed only of a cylindrical line segment mesh network. The first second mesh network 520 is installed at the other end of the mounting portion, and the first first dust collecting module 510 is spaced apart from the outside, and spaced apart from the first dust collecting module 501. The second second mesh network 520 may be installed. In addition, the second first dust collecting module 510 is installed by being spaced outward from the second second mesh network 520, and the second second dust collecting module 510 is spaced outwardly. The mesh network 520 may be installed. And a third first dust collecting module 510 is installed by being spaced apart from the third second mesh network 520, and a fourth second being spaced apart from the third first dust collecting module 510. The mesh network 520 may be installed. Here, the first first dust collecting module 510 has a diameter of 60mm, the second first dust collecting module 510 has a diameter of 120mm, and the third first dust collecting module 510 has a diameter of 180mm. It can be formed into a shape having. And the first second mesh network 520 has a diameter of 30mm, the second second mesh network 520 has a diameter of 90mm, and the third second mesh network 520 has a diameter of 150mm, The fourth second mesh network 520 may be formed in a shape having a diameter of 210 mm. The height of the first dust collecting module 510 is 200 mm, and the height of the second mesh network 520 is 190 mm.

The cylindrical dust collecting part 50 may be composed of a plurality of first dust collecting modules 510 and a plurality of second mesh networks 520 as described above.

Three of the first mesh networks 504 of the first dust collecting module 510 are grounded to indicate “Zero Voltage”, that is, zero voltage, and four of the second mesh networks 520 are charged with negative voltage. It is safe even if an electric shock occurs during operation while preventing an electric accident due to contact with the human body, and has electrical safety internally and externally while maintaining the chaos electric field effect.

The first UV lamp 710 or the second UV lamp (which continuously irradiates harmful microorganisms independent of the harmful microorganisms in the fine dust attached to the three stacked filter modules 500 of the cylindrical dust collecting part 50 by a strong line segment electric field ( LED) 720.

Hereinafter, the first ultraviolet lamp 710 and the second ultraviolet lamp (LED) 720 installed in the mounting unit 40 will be described with reference to FIGS. 3 and 4.

FIG. 3 is a view showing an annular first UV lamp 710 installed at the bottom of the mounting portion 40 of FIG. 2, and FIG. 4 is a positive electrode installation hole 401 and a negative electrode installation hole of the mounting portion 40 of FIG. 2 A diagram showing a second ultraviolet lamp (LED) 720 in which a plurality of 402 are installed.

The first ultraviolet lamp 710 is formed in a ring shape, and emits ultraviolet rays up and down. The first UV lamp 710 may be connected to a connecting member 440 formed in a ring shape at the bottom of the mounting portion 40. The first UV lamp 710 configured as described above is installed under the cylindrical dust collecting part 50 to irradiate ultraviolet light toward the cylindrical dust collecting part 50 and sterilize bacteria and viruses attached to the laminated filter module 500.

The second ultraviolet lamp 720 may be formed between a positive electrode installation hole 401 and a negative electrode installation hole 402 of the mounting portion 40 as shown in a small rectangular shape. For example, the second UV lamp 720 may be installed between nine between the positive electrode installation hole 401 and the negative electrode installation hole 402 of the mounting portion 40. The second UV lamp 720 installed as described above may irradiate ultraviolet light toward the cylindrical dust collecting part 50 and sterilize bacteria and viruses adhered to the laminated filter module 500.

Hereinafter, the operation of the ionized fine dust remover 1 according to an embodiment of the present invention will be described in detail with reference to FIGS. 13 and 14.

13 is an operation diagram of the ionized fine dust remover 1 according to an embodiment of the present invention of FIG. 1, and FIG. 14 is a blower installed in the mounting portion 40 among the ionized fine dust remover 1 of FIG. 1 It is a view schematically showing a state according to the operation of the unit 30.

When the blower unit 30 is driven, the ionized fine dust remover 1 flows outside air into the inside. The cylindrical dust collecting part 50 is formed of a cone type with an upper surface rising upward, and a cone type rising above a lower surface. The top cone type expands the air intake area and also increases the line segment electric field area. Therefore, the air inflow amount and the electric field area are increased to improve the efficiency of removing fine dust. The lower cone type is a dead zone having no air flow rate formed in the center of the rotary shaft module 310 of the blower unit 30, forming a buffer zone due to the shape of a dead zone (air) It has the effect of uniformly discharging the distribution rate as a whole. The blower unit 30 rotates the air B located at the bottom of the buffer zone by using a plurality of wing modules 320, and naturally rotates to the air at the top of the buffer zone, thereby removing all air located in the cone-shaped space. Discharge to the outside. In addition, the air located in the cone-shaped space can reduce the discharge resistance and generate a large amount of noise, without discharging the entire amount of air (B) to the outside. In addition, the upper surface of the mounting portion 40 has a streamlined shape, thereby allowing the air passage to flow more fluidly, thereby maximizing the above effect. In addition, it is possible to smoothly intake air to the outside of the case 10.

At this time, the intake air (A) is primarily filtered through the primary air dust filter 103 attached to overlap with the air intake 108, secondary air installed on the top of the cylindrical portion 60 Secondary filtering of general dust through the dust filter 602 filters foreign matter introduced with the air. In addition, the fine dust of the first and second filtered air is anionized by the anionization module 610 and collected in three stacked filter modules 500 in the cylindrical dust collecting part 50, and the air is thirdarily introduced with foreign matter at the bottom. It is finally filtered with a filter 109 for prevention. The filtered air is discharged to the bottom of the case. In addition, microorganisms and viruses collected in the cylindrical dust collecting part 50 are sterilized through a first ultraviolet lamp 710 or a second ultraviolet lamp (LED) 720.

In other words, the ionized fine dust remover 1 maintains an interior clean state, discharges clean air to the outside, and adjusts the space in which the ionized fine dust remover 1 is installed to a comfortable environment.

Although the embodiments of the present invention have been described with reference to the accompanying drawings, a person skilled in the art to which the present invention pertains may be implemented in other specific forms without changing the technical concept or essential features of the present invention. You will understand. Therefore, it should be understood that the embodiments described above are illustrative in all respects and not restrictive.

1: Ionized fine dust remover
10: case 100: accommodation space
101: upper cover plate 102: cicadas
103: primary air dust filter 104: handle
105: lower separation plate 106: lower cover plate
107: rubber feet 108: air intake
109: filter for preventing foreign matter from entering 110: air outlet
1011: Display
20: base plate 200: opening hole
30: blower unit 310: rotating shaft module
320: wing module 340: blower connector
350: air exhaust guide
40: mounting portion 401: positive electrode installation hole
402: negative electrode installation hole 410: first support module
411: positive electrode wire 420: second support module
422: negative electrode wire 430: third support module
440: connecting member 450: assembly connector
451: cylindrical assembly 460: central assembly
4011: Lead wire for fixing the positive electrode 4021: Lead wire for fixing the negative electrode
50: Cylindrical dust collector 500: Multi-layer filter module
501: first filter layer 502: second electrostatic film
503: third filter layer 504: first mesh network
510: first dust collecting module 520: second mesh network
60: cylindrical portion 610: anionization module (EI)
620: secondary air dust filter
70: power supply unit 710: first UV lamp
720: second ultraviolet lamp (LED)

Claims (11)

In the ionized fine dust remover (1) to adhere to the dust collecting part after ionizing the incoming fine dust,
A case 10 in which the accommodation space 100 is formed;
It is installed inside the case 10, the support plate portion 20 is formed with an opening hole 200 in the center;
A blower unit 30 installed on a lower surface of the support plate portion 20 to suck air from an upper portion of the support plate portion 20 and discharge it to a lower portion of the support plate portion 20 and a lower portion of the case 10;
It includes a plurality of support modules, one end of the plurality of support modules is installed spaced apart on the upper surface of the support plate portion 20, the other end is inclined in an upward direction from one end to be connected to the central assembly unit 460, the A plurality of positive electrode installation holes 401 connected to the positive electrode line and a plurality of negative electrode installation holes 402 connected to the positive electrode line, which are perforated from the upper surface to the lower surface of the support module, and connected to the cylindrical portion 60 on the outside. A mounting part 40 including a cylindrical part assembly part 451;
A stacked filter module 500 including a first filter layer 501, a third filter layer 503 and a second electrostatic film 502 generating static electricity therebetween, and the stacked filter module 500 attached to one surface The second mesh is installed in the negative electrode installation hole 402 spaced apart from the first dust collecting module 510 installed in the positive electrode installation hole 401, including a first mesh network 504, to collect anionized foreign substances. A cylindrical dust collecting part 50 including a mesh net 520; And
It is formed in a hollow shape is fixed to the top of the base plate portion, accommodates the cylindrical dust collector 50 therein and anionization module 610 for negative ionization of molecules in the air at the top of at least one cylindrical portion 60 is installed Containing, ionized fine dust remover. According to claim 1,
The mounting portion 40 is provided with an annular first UV lamp 710 on the connecting member 440 to irradiate ultraviolet rays toward the cylindrical dust collecting part 50 and detect bacteria and viruses adhered to the cylindrical dust collecting part 50. Sterilized, ionized fine dust remover. According to claim 1,
Bacteria attached between the positive electrode installation hole 401 and the negative electrode installation hole 402 of the mounting portion 40, irradiating ultraviolet light toward the cylindrical dust collecting part 50 and adhering to the cylindrical dust collecting part 50, and An ionized fine dust remover comprising a plurality of second ultraviolet lamps 720 for sterilizing the virus. According to claim 1,
The mounting portion 40, the other end of the plurality of support modules are inclined upward from one end connected to one by a central assembly unit, the point connected to one is located above the center point of the opening hole, the ionized fine dust remover. According to claim 1,
The first dust collecting module 510 is accommodated at the top, and the first dust collecting module 510 is fixed to the positive electrode installation hole 401, and the positive electrode fixing conductor 4011 connected to the positive electrode wire 411 is connected to the lower electrode. The wire for fixing the negative electrode, which accommodates the second mesh network 520 at the upper end and fixes the second mesh network 520 at the negative electrode installation hole 402 and protrudes to the negative electrode installation hole 402 at the bottom. ), further comprising an ionized fine dust remover. According to claim 1,
All laminated filter modules and mesh networks are configured in parallel with each other in the direction of air flow, which increases the flow rate without resisting air flow, thereby improving the removal rate of ionized fine dust and harmful microorganisms per unit time and reducing noise. , Ionized fine dust remover. According to claim 1,
The plurality of first dust collecting modules 510 and the plurality of second mesh networks 520 are alternately installed on the mounting portion 40 to be configured in a cone type both up and down, and the upper cone expands the air intake area, and the lower end The cone has a structure capable of removing the flow dead zone formed in the rotating shaft module 310 of the blower unit 30 and inhaling air with a constant distribution by forming a buffer zone, ionized fine dust. Eliminator. According to claim 1,
The first mesh network 504 of the first dust collecting module 510 is grounded, and the second mesh network 520 is charged with a negative voltage and is unable to contact the human body at the same time. Ionized fine dust remover that is applied as a zero bolt to the human body even when it comes into contact with the dust collecting module 510. delete delete According to claim 1,
A method of forming a focused electric field in a 360° omnidirectional direction formed inside the cylindrical dust collecting part 50 and inducing and collecting ionized fine dust into three or more stacked filter modules 500 of the first dust collecting module 510 Having, ionized fine dust remover.

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