KR20200077995A - Deordorizing filter dry coating apparetus based atmospheric dry aerosol process - Google Patents

Abstract

The present invention relates to an apparatus for coating a porous filter media, such as a ceramic honeycomb filter, with a metal oxide nanoparticles based on an atmospheric dry aerosol process. According to the present invention, metal oxide nanoparticles are attached to a filter media based on an atmospheric dry aerosol process that combines a method of generating metal oxide nanoparticles using a nanoparticle generator and a particle collection mechanism of an electrostatic precipitating method. In particular, a new type eco-friendly atmospheric dry aerosol coating apparatus that can perform the entire coating process through a continuous automation process is implemented by combining a nanoparticle generator for generating metal oxide nanoparticles, an electrostatic precipitating coating module for coating the metal oxide nanoparticles, a three-axis robot for inputting and discharging the filter media, and a duct structure providing a movement path for the metal oxide nanoparticles. Thus, the deodorizing filter dry coating apparatus based on atmospheric dry aerosol can solve various problems of the wet adhesion method, improve the coating efficiency, produce products with low energy consumption and low cost, improve productivity, and secure the product quality.

Description

Deodorizing filter dry coating device based on atmospheric pressure dry aerosol {DEORDORIZING FILTER DRY COATING APPARETUS BASED ATMOSPHERIC DRY AEROSOL PROCESS}

The present invention relates to an atmospheric pressure dry aerosol-based deodorizing filter dry coating device, and more particularly, to an apparatus for dry coating metal oxide nanoparticles on a porous filter media such as a ceramic honeycomb filter based on an atmospheric pressure dry aerosol process. will be.

In general, as environmental pollution increases due to industrial development at home or industrial sites, the harmfulness of the human body due to air pollution is increasing day by day, and air pollution, which occupies most of the environmental pollution, is not only the outdoor air, but also indoors where people work for a long time. Polluting the air more seriously.

For example, indoor air is more polluted than outdoor air due to the continuous circulation of polluted air in a limited space, and contaminants are released due to the emergence of new construction materials, and indoor air pollution is caused by the use of various household products. It is increasing.

In general, air cleaners are installed and used in indoor spaces such as homes, offices, hospitals, factories, etc. to purify indoor air and provide a comfortable environment. These air cleaners collect fine dust or bacteria or remove dust and dirt. In addition, various types of filters are equipped to perform odor, harmful gas, and deodorization functions.

For example, dust and contaminants are removed by passing air containing contaminants through a plasma pre-filter, a hepa pre-filter, and a photocatalyst filter.

Recently, as well as removing contaminants, it is a trend that requires a deodorizing filter that can protect bacteria by removing germs and odors such as mold and maintain excellent antibacterial power for a long time.

As an example, the activated carbon filter coated with the photocatalyst proposed in Korean Patent Publication No. 10-2003-0010848 has a disadvantage in that the deodorizing effect is lowered by being partially embedded in the fiber layer by using a deodorant or a photocatalyst in a predetermined binder mixture. .

As another example, the filter using the silver compound and zeolite as a catalyst in Korean Patent Publication No. 10-2003-0039811, after immersing the filter in the silver compound, and then immersing the zeolite again through a high-temperature drying step, the silver is covered with an antibacterial effect. It is difficult to expect, there is a possibility of clogging pores, and there are disadvantages of increasing drying costs as well as environmental problems due to wastewater treatment due to complicated wet methods.

As another example, in the case of a non-woven air filter including an anion generating material proposed in Korean Patent Publication No. 10-2003-0015646 and its manufacturing method, the mineral material that generates anion is a newly discovered granite that is made into powder. After applying to the yarn during the non-woven fabric manufacturing process, the non-woven fabric is manufactured through a process of high temperature/compression/drying. This method is also insufficient in terms of performance, such as the risk of powder spillage and the loss of ventilation function early after saturation of hazardous substances. And the manufacturing process is not only complicated, but also has a disadvantage of high manufacturing cost.

Deodorizing filters are usually manufactured by coating a porous filter media such as ceramic foam with metal oxide particles, which are deodorizing particles, by a complex process including wet impregnation and dry firing.

However, the wastewater generated in the wet impregnation process has a disadvantage of causing an environmental burden, and the filter media capable of performing the dry firing process is limited to a material that can withstand high heat, as well as a disadvantage that requires a lot of energy and time. have.

In addition, in the case of a process for manufacturing a deodorizing filter by a wet impregnation process or a dry calcination process, there is a disadvantage in that the manufacturing cost increases as the process is performed in a non-continuous process and through several process steps.

Korean Patent Registration No. 10-0395676 Korean Patent Registration No. 10-1691145

Accordingly, the present invention was devised in view of this point, and based on the atmospheric pressure dry aerosol process incorporating a method for generating metal oxide nanoparticles using a spark discharge module and a particle collection mechanism of an electrostatic precipitation method, the metal oxide nanoparticles While attaching the particles to the filter media, in particular, the spark discharge module for generating metal oxide nanoparticles, the electrostatic immersion coating module for coating metal oxide nanoparticles, the 3-axis robot for the input and discharge of filter media, the metal oxide nanoparticles By implementing a new type of eco-friendly atmospheric pressure dry aerosol coating device that can perform the entire coating process in a continuous automated process by linking duct structures, etc. that provide a progression path, various problems according to the wet impregnation method can be solved. In addition, it is possible to improve the coating efficiency, produce products with low energy consumption and low cost, as well as improve productivity, and to provide a dry coating device based on atmospheric pressure dry aerosol deodorization filter that can secure product quality. have.

In order to achieve the above object, the atmospheric pressure dry aerosol-based deodorizing filter dry coating device provided by the present invention has the following features.

The atmospheric pressure dry aerosol-based deodorizing filter dry coating apparatus is a duct structure having a closed structure that constitutes a passage for metal oxide nanoparticles, and a nanoparticle generator that is installed in the duct structure to generate metal oxide nanoparticles, for example A spark discharge module that generates metal oxide particles through spark discharge by applying power to a pair of electrodes, and a first blower device installed at the upper inlet of the vertical duct portion of the duct structure and supplying fluid to the interior of the spark discharge module Wow, installed in the horizontal duct part of the duct structure, an openable door device for input and discharge of filter media is installed, and an electrostatic precipitating method to attach the metal oxide nanoparticles supplied from the spark discharge module side to the filter media in an electrostatic precipitation method. A coating module and a filter media input/discharge device, which is installed on one side of the electrostatic immersion coating module and injects a filter media for coating or discharges a filter media after coating, for example, comprises a structure including a 3-axis robot .

As a preferred embodiment, the atmospheric pressure dry aerosol-based deodorizing filter coating device is installed in the front end portion of the electrostatic dust-coating type coating module in the horizontal duct portion of the duct structure, and a particle charging module for charging metal oxide nanoparticles moving along the horizontal duct portion It may further include.

As a preferred embodiment, the atmospheric pressure dry aerosol-based deodorizing filter dry coating apparatus is installed on a horizontal duct portion close to the electrostatic dust-collecting coating module and is a multi-stage input magazine for drying the filter media after coating and atmosphere of the filter media before coating. And a discharge magazine.

As a preferred embodiment, the atmospheric pressure dry aerosol-based deodorizing filter dry coating device may further include a second blowing device installed at the front end of the horizontal duct portion of the duct structure and blowing metal oxide nanoparticles to the electrostatic dust coating module side. have.

As a preferred embodiment, the atmospheric pressure dry aerosol-based deodorizing filter dry coating apparatus is installed at the boundary between the vertical duct portion and the horizontal duct portion of the duct structure, and the metal oxide nanoparticles supplied in the vertical direction from the spark discharge module are horizontally disposed. It may further include a particle guiding tube that is converted to lead to the inner central region of the horizontal duct portion.

As a preferred embodiment, the atmospheric pressure dry aerosol-based deodorizing filter dry coating device may further include an exhaust duct part connected to a rear end of the horizontal duct part of the duct structure, and trap the residual metal oxide nanoparticles inside the exhaust duct part. A particle recovery module in which at least one collection filter is built-in may be installed.

In particular, the horizontal duct portion of the duct structure is composed of a combination of two rows of first horizontal duct portions and second horizontal duct portions that branch from the vertical duct portion, and in the electrostatic dust collecting coating module in the first horizontal duct portion, the vertical posture is In addition to performing the primary coating on the filter media, the electrostatic dust collecting coating module in the second horizontal duct part is characterized in that the secondary coating on the filter media in a horizontal attitude is performed.

As a preferred embodiment, the atmospheric pressure dry aerosol-based deodorizing filter dry coating device is installed between one side of the exhaust duct portion of the duct structure and one side of the spark discharge module while circulating a portion of the exhaust discharged through the exhaust duct portion to the spark discharge module side The circulation duct may be further included.

In addition, the door device of the electrostatic coating type module includes a door that opens and closes the filter media entrance, a door frame that is arranged side by side on the front of the module and is movable up and down by both LM devices, and is supported on the front of the door frame and loaded. A plurality of door cylinders connected to the door side through, a bar structure installed on the door frame side to support the rear end of the door cylinder, and a plurality of supports formed in a slideable structure on the door frame side extending from the door side It may be made of a structure including a guide bar.

The atmospheric pressure dry aerosol-based deodorizing filter dry coating device provided by the present invention has the following effects.

First, by adopting a coating device based on an atmospheric pressure dry aerosol process including a method of generating metal oxide nanoparticles using a spark discharge module, existing problems such as environmental pollution problems due to wastewater generation or high energy consumption are adopted. There is an effect that can solve various problems according to the wet deposition method.

Second, by adopting a new coating device that combines the method of generating metal oxide nanoparticles using the spark discharge module and the particle collection mechanism of the electrostatic precipitation method, it is possible to improve the coating efficiency and minimize energy consumption while at the same time being inexpensive. It has the effect of being able to produce the product economically at a cost, and improving the productivity and securing the quality of the product.

Third, a spark discharge module for generating metal oxide nanoparticles, an electrostatic dust-coating coating module for coating metal oxide nanoparticles, a 3-axis robot for input and discharge of filter media, and a duct structure that provides a path for metal oxide nanoparticles. By adopting a new coating device capable of performing the entire coating process in a continuous automated process by combining them in combination, it is possible to improve the efficiency of the coating process, improve productivity, and increase the coating quality.

Fourth, by adopting the particle collection mechanism of the electrostatic precipitator during the coating process based on the atmospheric pressure dry aerosol process, the nanoparticles are attached to the filter with a coulomb force, so particles with a particle size from tens of nanometers to hundreds of micrometers are added to the filter. It can be coated and can secure up to 99.9% of the filter coating efficiency sprayed at a low current regardless of the type of filter media, and because it uses very little current, it has low energy consumption and can produce products at a low cost. have.

Fifth, a filter using a 3-axis robot and a structure in which a spark discharge module for generating metal oxide nanoparticles, a rectifying perforated plate module for particle charging, a metal oxide nanoparticle coating device, etc. are arranged in a continuous duct structure. By adopting the input and discharge system of the filter media, it is possible to increase the utilization efficiency of the metal oxide nanoparticles and at the same time protect the worker's safety from various risks related to human inhalation of the nanoparticles.

1 is a front view showing an atmospheric pressure dry aerosol-based deodorizing filter dry coating apparatus according to an embodiment of the present invention
Figure 2 is a plan view showing an atmospheric pressure dry aerosol-based deodorizing filter dry coating apparatus according to an embodiment of the present invention
3 and 4 is a perspective view showing an electrostatic dust-coated coating module in a dry coating device based on atmospheric pressure dry aerosol according to an embodiment of the present invention
5 and 6 is a side view showing the operating state of the electrostatic precipitating coating module in the atmospheric pressure dry aerosol-based deodorizing filter dry coating apparatus according to an embodiment of the present invention
Figure 7 is a cross-sectional view showing the process of coating the metal oxide nanoparticles on the filter medium in the atmospheric pressure dry aerosol-based deodorizing filter dry coating apparatus according to an embodiment of the present invention

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

1 is a front view showing an atmospheric pressure dry aerosol-based deodorizing filter dry coating device according to an embodiment of the present invention, and FIG. 2 is a plan view illustrating an atmospheric pressure dry aerosol-based deodorizing filter dry coating device according to an embodiment of the present invention to be.

1 and 2, the atmospheric pressure dry aerosol-based deodorizing filter dry coating device includes a duct structure 12 having a closed structure as a means for creating a passage for metal oxide nanoparticles.

The duct structure 12 may be composed of only a vertical duct portion, or only a horizontal duct portion, or a combination of a vertical duct portion and a horizontal duct portion. In the present invention, the vertical duct portion 10 and the horizontal duct portion 11 may be used. It shows an example that is configured, the vertical duct portion 10 and the horizontal duct portion 11 can be in communication with each other.

Here, in the case of the horizontal duct portion 11, the front end section connected to the lower end of the vertical duct section 10 and the rear end section connected to the front end section by a vertical posture "∩" shaped duct can be configured.

In the vertical duct portion 10 of the duct structure 12, a nano particle generator 13, etc., which will be described later, can be installed, and the particle charging module, which will be described later, in the internal rear end section of the horizontal duct portion 10 ( 18), the electrostatic immersion coating module 16 and the like can be installed.

Accordingly, the metal oxide nanoparticles can be coated on the filter media by moving along the vertical duct portion 10 and the horizontal duct portion 11 of the duct structure 12, and in the end, the metal oxide nanoparticles are blocked from the outside. The coating of the particles can be made.

Here, the exhaust duct part 23 is connected to the rear end section of the horizontal duct part 11 of the duct structure 12.

The exhaust duct part 23 is a duct that discharges the fluid flow in the duct structure 12 to the outside.

At least one collection filter 24, for example, an ultra-low-penetration air filter and a high-efficiency particulate air filter, are built in and out of the exhaust duct part 23. The particle recovery module 25 is installed.

Accordingly, the residual metal oxide nanoparticles in the fluid flowing along the exhaust duct part 23 can be collected by the ulpa filter and the hepa filter of the particle recovery module 25 before being discharged to the outside, and eventually the metal oxide It becomes possible to solve the problem of air pollution caused by the emission of nanoparticles.

Here, the particle recovery module 25 is in the form of a duct of the same standard as the exhaust duct part 23, and can be installed by a duct connection structure using flange fastening in a predetermined section of the exhaust duct part 23.

In particular, the horizontal duct portion 11 of the duct structure 12 is made of a combination of two rows of parallel first horizontal duct portions 11a and second horizontal duct portions 11b branching from the vertical duct portion 10. do.

That is, the rear end section of the horizontal duct part 11 is branched from the vertical posture "∩" shaped duct connected to the front end section of the horizontal duct part 11 connected to the vertical duct part 10 side, and is divided into two rows. The first horizontal duct portion 11a and the second horizontal duct portion 11b are installed.

Here, each rear end portion of the first horizontal duct portion 11a and the second horizontal duct portion 11b can be joined to the “∩” shaped duct side of the horizontal position of the exhaust duct portion 23.

The first horizontal duct part 11a and the second horizontal duct part 11b are respectively provided with a particle charging module 18 and an electrostatic coating type module 16a, 16b, in which case the first horizontal duct part 11a The filter media mounted on the electrostatic precipitating coating module 16a can be coated in a vertically standing posture, and the filter media mounted on the electrostatic precipitating coating module 16b of the second horizontal duct part 11b is horizontal. It can be coated in a lying position.

Accordingly, in the electrostatic immersion coating module 16a in the first horizontal duct portion 11a, the primary coating treatment for the filter media in the vertical posture can be performed, and the second horizontal duct portion 11b continues. In the electrostatic precipitating coating module 16b, a secondary coating treatment for the filter media in a horizontal attitude can be achieved.

In this way, the coating of the filter media is performed twice by sequentially using the electrostatic coating module 16a in the first horizontal duct portion 11a and the electrostatic coating module 16b in the second horizontal duct portion 11b. By performing and coating the corners without blind spots while changing the posture of the filter media, it is possible to maximize the filter coating efficiency with simple process and equipment, and with low energy consumption and low cost.

In addition, the duct structure 12 includes a circulating duct part 26 that circulates exhaust gas discharged through the exhaust duct part 23 and can recycle metal oxide nanoparticles in the exhaust.

The front end of the exhaust duct part 23 is connected to a "⊃" shaped duct that takes a horizontal attitude, and one side of the "⊃" shaped duct installed in this way is connected to the rear end of the horizontal duct part 11 and the other One end of the circulation duct 26 is connected, and the other end of the circulation duct 26 is connected to the interior of the nanoparticle generator 13.

That is, the circulation duct part 26 is installed connected between the exhaust duct part 23 side and the nanoparticle generating device 13 side, whereby a part of the exhaust gas discharged through the exhaust duct part 23 is nanoparticles It can be circulated to the generator (13).

Of course, dampers capable of adjusting the displacement are respectively installed at the inlet side and the outlet side of the “⊃” shaped duct.

In addition, the atmospheric pressure dry aerosol-based deodorizing filter dry coating device includes a nanoparticle generator 13 as a means for generating metal oxide particles through spark discharge by applying power to a pair of electrodes.

Here, the nanoparticle generator 13 is a device for generating metal oxide nanoparticles by heating to a high temperature, a device for generating metal oxide nanoparticles using plasma, a device for generating metal oxide nanoparticles using vacuum, etc. The present invention provides an embodiment in which a device for generating metal oxide nanoparticles using spark discharge, that is, a spark discharge module 13 is applied.

The nanoparticle generator 13 is installed in the interior of the duct structure 12, for example, the vertical duct 10 or the horizontal duct 11, the nanoparticle generator 13 is installed in this way It has a structure in communication with the vertical duct portion 10.

Here, the nanoparticle generating device 13 may apply the nanoparticle generating unit disclosed in Korean Patent Registration No. 10-1691145.

For example, the nanoparticle generating unit is a configuration for generating metal nanoparticles attached to a ceramic honeycomb carrier through high voltage discharge, wherein the first metal electrode and the second metal electrode are disposed opposite to each other, and the discharge unit It is composed of a controller that controls voltage supply and discharge.

The first and second metal electrodes disposed in the discharge unit may be selected from among copper (Cu), manganese (Mn), gold (Au), and potassium (K), and may be employed as metals of the same type, or two. If the above-mentioned different metal oxide nanoparticles need to be generated and attached to the filter media, the first and second metal electrodes disposed in the discharge unit may be used as different types of metals.

Alternatively, the first metal electrode is adopted as one metal, and the second metal electrode (ground side) is composed of a plurality of electrodes that are adopted as different types of metals to generate two or more different metal oxide nanoparticles. I can do it.

At this time, a high voltage supply unit that provides a high voltage for discharge is connected to the discharge portion of the nanoparticle generating unit, and preferably, the high voltage supply unit includes a protection circuit to prevent exceeding a set voltage when a high voltage is applied.

Therefore, when controlling the application of the high voltage supplied from the high voltage supply unit to the discharge unit in the controller of the nanoparticle generating unit, spark discharge occurs in the discharge unit and the first and second metal electrodes facing each other are rusted. While the metal oxide nanoparticles are generated, the metal oxide nanoparticles generated in this way are sent to the electrostatic coating module 16 and coated on the surface of the metal filter medium.

Then, the duct structure 12 to which the nanoparticle generator 13 belongs, for example, the vertical duct part 10 as well as the periphery of the front end section of the horizontal duct part 11 are surrounded by a negative pressure chamber 34. In this case, the negative pressure chamber 34 serves to prevent the metal oxide nanoparticles from leaking out.

In addition, the atmospheric pressure dry aerosol-based deodorizing filter dry coating device is installed at the upper inlet of the vertical duct portion 10 of the duct structure 12 as a means for supplying fluid to the interior of the nanoparticle generator 13 It includes a blower (14).

The first blowing device 14 includes a first blowing fan 35 and a first blowing duct 37 in which a HEPA filter 36 is built, and through the first blowing duct 37 It is connected to the side of the nanoparticle generator 13 to supply clean air to the interior of the nanoparticle generator 13.

Accordingly, the clean air made in the first blower 14 is blown into the discharge part (not shown) of the nanoparticle generator 13 through the first blower duct 37, and the flow of clean air blown out like this By the pressure, the metal oxide nanoparticles can be sent to the lower end of the vertical duct portion 11 together with clean air.

In addition, the atmospheric pressure dry aerosol-based deodorizing filter dry coating device is installed in the front end section of the horizontal duct portion 11 of the duct structure 12 as a means of blowing metal oxide nanoparticles toward the electrostatic coating module 16 side. It includes a second blowing device (21).

The second blowing device 21 includes a second blowing fan 38 and a second blowing duct 39 in which a HEPA filter 36 is built, and through the second blowing duct 39 It is connected to the front end section of the horizontal duct part 11 and serves to blow and send metal oxide nanoparticles to the side of the electrostatic precipitating coating module 16 installed in the horizontal duct part 11.

Accordingly, the clean air made in the second blower 21 is blown through the second blower duct 39 to the front end section of the horizontal duct 11, and the metal oxide is produced by the flow pressure of the blown clean air The nanoparticles can be sent to the horizontal duct section 11 through the “∩” shaped duct along with the clean air.

In addition, the atmospheric pressure dry aerosol-based deodorizing filter dry coating device includes a particle induction pipe 22 as a means for supplying the total amount of metal oxide nanoparticles descending to the side of the horizontal duct 11 to the electrostatic collection coating module 16 side as much as possible. do.

The particle guiding tube 22 is in the form of a "J" shaped pipe, the upper inlet facing the upper side of the vertical duct 10 and the lower outlet in the second blower in the front end section of the horizontal duct 11 ( 21) is installed in a structure that connects the vertical duct portion 10 side and the front end section side of the horizontal duct portion 11 in a state where the side is facing.

For example, the lower end portion of the vertical duct portion 10 is installed in a structure supported on the duct support 40, the upper end portion of the particle guide tube 22 vertically penetrates the bottom plate of the vertical duct portion 10 At the same time, it is located inside, and at the same time, the lower end penetrates the upper section of the front end section of the horizontal duct section 11 and is located in the central region therein (located on the axis of the front end section of the horizontal duct section).

Here, the particle guiding tube 22 can be supported in a structure that is fastened to the bottom plate of the vertical duct portion 10 and the top plate of the horizontal duct portion 11.

Accordingly, it is supplied vertically from the nanoparticle generator 13 by the particle guide tube 22 installed at the boundary between the vertical duct portion 10 and the horizontal duct portion 11 of the duct structure 12. As the metal oxide nanoparticles are converted to the horizontal direction, they are guided to the central region inside the shear section of the horizontal duct part 11, and the metal oxide nanoparticles thus induced are horizontal duct parts by the blowing force of the second blower 21 side. It is sent to the "∩" shaped duct in (11).

That is, the metal oxide nanoparticles descending along the vertical duct part 10 enter the inside of the induction tube through the inlet of the particle induction tube 22, and the metal oxide nanoparticles thus entered are of the particle induction tube 22. After exiting through the outlet, it is sprinkled in the central region inside the front end section of the horizontal duct part 11, and can be continuously sent to the "∩" shaped duct part side of the horizontal duct part 11.

As described above, the metal oxide nanoparticles produced by the nanoparticle generator 13 are guided by the particle guide tube 22 and directly discharged to the inner central region of the horizontal duct 11 to directly collect electricity by blowing force. Since it is sent to the coating module 16 side, the entire amount of metal oxide nanoparticles that have entered the inside of the horizontal duct part 11 can be directly sent to the electrostatically coated coating module 16 side, and ultimately, the utilization rate of the metal oxide nanoparticles is maximized. I can do it.

If, without the particle guide tube 22, the vertical duct portion 10 and the horizontal duct portion 11, the structure that directly communicates with the structure, the metal oxide nanoparticles descending from the vertical duct portion 10 side is horizontal While the amount of metal oxide nanoparticles sent to the electrostatic coating module 16 side is reduced while being accumulated or attached to the bottom side (bottom side) of the front end section of the duct portion 11, the particle guide tube 22 is adopted to form a metal. By allowing the oxide nanoparticles to be intensively ejected in the central region of the front end section of the horizontal duct portion 11, the entire amount of metal oxide nanoparticles is sent directly to the electrostatic coating module 16 side.

In addition, the atmospheric pressure dry aerosol-based deodorizing filter dry coating device includes a particle charging module 18 as a means to further increase the efficiency of coating metal oxide nanoparticles on a filter media.

The particle charge module 18 is made of a discharge needle charge type or a wire load charge type, and takes the vertical posture perpendicular to the flow direction of the metal oxide nanoparticles, and the inside of the duct structure 12, For example, while being disposed inside the horizontal duct portion 11, the duct portion is installed in a structure that is fastened by bolts.

Particle charge module 18 in the present invention may be applied to the discharge needle charge type, the particle charge module 18 of the discharge needle charge type at this time has the flange at both ends and the same as the horizontal duct portion (11) The particle charging module body 18a is made of a particle charging module body 18a in the form of a standard duct, and a plurality of discharge needles 18b arranged vertically across the inner region of the particle charging module body 18a. ) Can be installed by a duct connection structure using flange fastening in a state inserted between some sections of the horizontal duct portion 11 using the flange.

The particle charging module 18 provides a charge to the metal oxide nanoparticles so that the coating material is well applied to the filter medium to be coated with a synergistic effect.

For example, the particle charging module 18 is able to charge the metal oxide nanoparticles generated in the nanoparticle generator 13 to be monopolar or bipolar.

In other words, the metal oxide nanoparticles introduced into the inner region of the particle charging module 18 are a pair of discharge needle chargers that serve as electrodes to which one of the "+" or "-" poles is applied, or It flows between the wire rod charges, and the metal oxide nanoparticles are charged while flowing along the charge flow path in the particle charge module 18.

In addition, the atmospheric pressure dry aerosol-based deodorizing filter coating device includes an electrostatic coating module 16 as a means for coating charged metal oxide nanoparticles on the filter media with electrostatic force by an electric field, and this electrostatic coating module 16 ) Will be described in detail later.

In addition, the atmospheric pressure dry aerosol-based deodorizing filter dry coating device is installed on one side of the electrostatic coating module 16, for example, it is installed directly in front of the door 28 provided in the electrostatic coating module 16. It includes a filter media input / discharge device 17 as a means for injecting the filter media for or to discharge the filter media after coating.

As a preferred embodiment, various devices may be applied as the filter media input/discharge device 17, or a method in which an operator directly inputs and discharges filter media can be applied. In the present invention, a 3-axis robot is applied. Provides

The three-axis robot, that is, the filter media input/output device 17 includes an X-axis driving unit 17a operating in a left-right direction (duct length direction), a Y-axis driving unit 17b operating in a vertical direction, and a front-rear direction (duct width). Direction) and a Z-axis driving unit 17c, and a known grip device 17d is installed on the slide side of the Z-axis driving unit 17c.

Accordingly, the filter media input/discharge device 17 uses the grip device 17d operating in the X-axis, Y-axis and Z-axis directions to each of the driving units 17a to 17c to electrostatically collect the filter media. In addition to the role of injecting into the interior of the (16) or taking out the outside of the electrostatic coating type module (16), it can also serve to take out or put the filter media into the input magazine 19 or the exhaust magazine 20 to be described later. It becomes possible.

Thus, by handing the filter media using the filter media input/discharge device 17, it is possible to prevent an operator from being exposed to the metal oxide nanoparticles harmful to the human body. It will be able to block the risks of various safety accidents.

3 and 4 is a perspective view showing an electrostatic dust-coating coating module in a dry coating device based on a pressure-sensitive dry aerosol according to an embodiment of the present invention.

As shown in FIGS. 3 and 4, the electrostatic dust collecting coating module 16 is installed in the horizontal duct portion 11 of the duct structure 12, and a plurality of filter media slits for mounting the filter media therein ( 41a) and includes the electrostatic dust-coated coating module body 16-1 in the form of a duct of the same standard as the horizontal duct part 11.

At this time, the electrostatic immersion coating module body 16-1 can be installed by a duct connection structure using a flange fastening in a predetermined section of the horizontal duct portion 11.

In addition, a filter media door 27 that can be opened and closed by a door device 15, which will be described later, is formed on the front surface of the electrostatic coating module main body 16-1, and the filter media is filtered through the filter media door 27 at this time. The electrostatic immersion coating module can be mounted inside the body 16-1 or taken out from the inside.

Here, when the electrostatic coating module 16 is an electrostatic coating module 16a installed in the first horizontal duct part 11a, the filter formed inside the electrostatic coating module module 16-1 at this time The filter media slit (41a) is made of a pair formed at a position facing each other on the ceiling and the bottom surface of the electrostatic coating module main body (16-1), and this pair of filter media slit (41a) is a coating module Since it is made of several pairs arranged at regular intervals along the left and right width directions of the body 16-1, the filter media is erected vertically, that is, the filter media erected vertically while taking a posture blocking the duct passage. On the other hand, when the electrostatic coating module 16 is an electrostatic coating module 16b installed in the second horizontal duct portion 11b, the electrostatic coating module body 16-1 at this time The filter media slit (41a) formed in the interior of the pair is formed of a pair formed at a position facing each other on the front and rear wall surfaces of the electrostatic filtration coating module body (16-1), and this pair of filter media slit (41a) ) Is made of several pairs arranged at regular intervals along the vertical direction of the coating module body 16-1, so that the filter media is laid horizontally, that is, the filter media is in the direction of flow of nanoparticles in the duct passage. It can be mounted while lying horizontally while taking a parallel posture.

In addition, the electrostatic coating type module 16 includes a door device 15 that can be opened and closed for input and discharge of filter media, and the door device 15 will be described later.

The electrostatic precipitating coating module 16 serves to attach (coat) the metal oxide nanoparticles supplied from the nanoparticle generator 13 side to the filter media in an electrostatic precipitating method.

For example, the electrostatic coating module 16 generates an electric field on the path of the metal oxide nanoparticles with the filter media interposed therebetween, so that the charged metal oxide nanoparticles pass through the particle charging module 18 to the filter media. It serves to coat in a dust-collecting manner.

At this time, the electrostatic immersion coating module 16 includes a pair of electrode bodies (not shown) connected to a current portion (42 in FIG. 6) for applying electric current to generate an electric field. It is provided so as to face each other, and an electric field is applied to the filter media.

For reference, as the polarity of the metal oxide nanoparticles charged by the particle charging module 18 is alternated at regular intervals, it is preferable to apply an alternating current to the electrostatic dust-collecting coating module 16.

Accordingly, the metal oxide nanoparticles charged in the filter media positioned between the alternating electric fields generated by the electrostatic immersion coating module 16, for example, as the unipolarly charged metal oxide nanoparticles pass through the electrostatic force by the electric field Metal oxide nanoparticles are coated on the filter media.

Since the metal oxide nanoparticle coating of the electrostatic precipitating method by the electrostatic force can obtain a coating rate of 99.99% for the filter media, it is possible to secure a high coating efficiency regardless of the type of filter media.

As a preferred embodiment,

In addition, the atmospheric pressure dry aerosol-based deodorizing filter coating device includes a multi-stage structure for the input magazine 19 and the discharge magazine 20 as a means for supplying the filter media and drying the filter media.

The input magazine 19 and the discharge magazine 20 are installed in a structure that can be mounted on the horizontal duct portion 11 of the duct structure 12 in the form of a square box with an open front surface, and this input magazine (19) and the inside of the discharge magazine 20, filter media slits (41b), which can be equipped with multiple filter media, are formed respectively.

Here, as an example of the filter media slit (41b) formed in the input magazine 19 and the discharge magazine 20, it is made of a pair formed in a position facing each other on the top and bottom surfaces of the magazine and In addition, the pair of filter media slit (41b) is made of a plurality of pairs arranged at regular intervals along the left and right width direction of the magazine, so that multiple filter media can be mounted side by side in a vertically standing state.

As another example of the filter media slit 41b, the pair of filter media slits 41b are formed at a predetermined interval along the vertical direction of the magazine in addition to being made of a pair formed at positions facing each other on the left and right wall surfaces of the magazine. Since it is composed of several pairs arranged, it is possible to mount multiple filter media side by side in a horizontally laid state.

Therefore, the filter media before coating installed in the input magazine 19 can be picked up by the filter media input/discharge device 17 and can be input into the electrostatic coating module 16, and the coating process is completed. The filter media in the dust-collecting coating module 16 is picked up by the filter media input/discharge device 17 so that it can be subjected to a normal temperature drying process while being mounted in the discharge magazine 20.

Here, instead of moving the filter media that has been coated in the electrostatic immersion coating module 16 to a separate subsequent drying place, the exhaust magazine 20 adjacent to the electrostatic precipitating coating module 16 with the filter media input/discharge device 17 ) To ensure the coating quality of the filter media, such as to prevent the coating condition of the filter media from being damaged or contaminated by putting it directly in and drying it.

In particular, the electrostatic coating module 16 includes a door device 15 as a means that can effectively block the area where the filter media is being coated.

The door device 15 includes a door 28 for opening and closing the filter media entrance 27, and the door 28 is made of a transparent glass material having a frame in the center, and in the closed state, the inner edge is circumferential. It is possible to completely close the filter media inlet 27 by using a seal member (not shown) attached to the.

In addition, a door frame 30 is provided to support the door 28, and the door frame 30 is disposed side by side on the front surface of the electrostatic precipitating coating module 16, that is, on the front surface of the door 28. It is installed to be movable up and down by both LM devices 29 on the inlet frame 43 installed along the outer periphery of the filter media inlet 27.

That is, the door frame 30 is installed across the slider of the LM device 29 installed on both sides, and can be moved up and down according to the operation of the LM device 29.

In addition, a plurality of door cylinders 31, for example, two door cylinders 31, left and right, are installed on the front surface of the door frame 30, and the load of the door cylinder 31 installed in this way is a door frame 30 ) After passing through is installed connected to the front of the door (28).

In addition, the bar structure 32 for opening and closing is composed of a square bar horizontally arranged parallel to the front of the door frame 30 and three round bars fixed to the door frame 30 while being coupled to the rear of the square bar. , It serves to support the rear side of the door cylinder 31.

Accordingly, when the door cylinder 31 is operated, the filter media inlet 27 can be opened and closed while the door 28 is also operated back and forth by a front-rear operation of the rod.

Here, a plurality of guide bars 33 serving to guide the opening and closing operation of the door 28, for example, four guide bars 33 are provided, wherein the guide bar 33 is a door 28 While being formed extending from the front surface of the door frame 30, it is supported in a slidable structure on the bush side.

Accordingly, the door 28 can be opened and closed stably while being guided by four guide bars 33 arranged at each corner portion of the rectangle.

5 and 6 is a side view showing the operating state of the electrostatic precipitating coating module in the atmospheric pressure dry aerosol-based deodorizing filter dry coating apparatus according to an embodiment of the present invention.

As shown in FIGS. 5 and 6, here, a state in which a filter medium is input or a filter medium is discharged in a door open state is shown.

That is, when the door 28 is slightly moved forward when the door cylinder 31 is operated forward, the filter media inlet 27 of the electrostatic precipitating coating module 16 is slightly opened, and the LM device 29 continues When the door 28 is completely moved downward by the lowering operation, the filter media inlet 27 of the electrostatic coating module 16 is completely opened.

In this state, the filter media 100 contained in the input magazine 19 is moved one by one by repeated operation of the filter media input/discharge device 17, or is thrown inside the electrostatic dust-coating type coating module 16, Alternatively, the filter media 100, which has been coated inside the electrostatic precipitating coating module 16, is transferred one by one and mounted in the discharging magazine 20.

As shown in Fig. 5, here, the door is closed.

That is, in a state in which the filter media 100 contained in the input magazine 19 is moved one by one by repetitive operation of the filter media input/discharge device 17, and is completely injected into the electrostatic dust-coated coating module 16, When the door 28 is completely moved upward by the rising operation of the LM device 29, the door 28 at this time is located just in front of the filter media inlet 27 of the electrostatic coating module 16, When the door 28 is moved slightly to the rear when the door cylinder 31 is continuously operated, the filter media inlet 27 of the electrostatic coating module 16 is closed in a completely closed state by the door 28 Lose.

7 is a cross-sectional view showing a process in which metal oxide nanoparticles are coated on a filter media in an atmospheric pressure dry aerosol-based deodorizing filter dry coating apparatus according to an embodiment of the present invention.

As shown in FIG. 7, a discharge unit (not shown) including a pair of electrodes (not shown) after air supplied from the first blower 14 flows into the nanoparticle generator 13. When passing through, spark discharge occurs and metal oxide nanoparticles are generated.

At this time, the discharge portion including the pair of electrodes is made of a metal oxide containing a deodorizing catalyst material, for example, copper or manganese, thereby generating nanoparticles including copper oxide or manganese oxide.

The metal oxide nanoparticles generated in this way are moved along the vertical duct part 10 and the horizontal duct part 11, and then introduced into the particle charging module 18, where they are charged as unipolar or bipolar.

As an example, the "-" pole and the "+" pole are alternately generated by the particle charging module 18 alternately to charge the metal oxide nanoparticles, or in another example, the particle charging module 18 is "- By simultaneously applying the "pole" and the "+" pole, the metal oxide nanoparticles are positively charged.

Subsequently, while passing through the particle charging module 18, the charged metal oxide nanoparticles are coated on the filter media 100 by electrostatic force by a direct current or alternating electric field by passing through the electrostatic immersion coating module 16.

That is, the metal oxide nanoparticles generated by the spark discharge are charged to the maximum while passing through the anode ionizer, and when the charged metal oxide nanoparticles reach the filter media 100, for example, a ceramic honeycomb filter along the duct, the filter is applied to the filter. It is attached to the filter and coated by receiving electric power from the installed AC electrode magnetic field.

Subsequently, the air (including some metal oxide nanoparticles) that has passed through the electrostatic precipitating coating module 16 is filtered by the particle recovery module 25 and then discharged to the exhaust duct 23 or the circulation duct 26 To be cycled.

Here, it is important to find a metal having a high removal efficiency for the target gas when manufacturing a filter using a technique of manufacturing a metal oxide nanoparticle by a spark discharge method and coating the filter.

In this regard, in the case of a metal oxide coated with a deodorant for a refrigerator, one or more metals may be used to use copper or manganese, and in the case of copper or manganese, it is effective in deodorizing methylmercaptan and trimethylamine. It works.

In addition, Pinacol Coupling Reaction and Transition Metal Catalyst methods can be performed on metal oxides that are effective against VOCs and aldehyde gas. Iron, nickel, cobalt, magnesium, titanium, vanadium, zinc, molybdenum, etc. have.

As described above, in the present invention, a new method of coating metal oxide nanoparticles on a filter media based on an atmospheric pressure dry aerosol process incorporating a method of generating metal oxide nanoparticles using a nanoparticle generator and an electrostatic dust collecting mechanism. By providing an eco-friendly atmospheric pressure dry aerosol coating device, it is possible to improve the coating efficiency compared to the conventional wet impregnation method and to improve the productivity and secure the quality of the product, such as being able to produce the product with low energy consumption and low cost.

10: vertical duct part
11: horizontal duct part
11a: 1st horizontal duct part
11b: 2nd horizontal duct part
12: Duct structure
13: nanoparticle generator
14: first blower
15: door device
16,16a,16b: Electrostatic dust coating module
17: filter media input / discharge device
18: particle charging module
19: input magazine
20: discharge magazine
21: second blower
22: particle induction tube
23: exhaust duct
24: collection filter
25: particle recovery module
26: circulation duct
27: filter media entrance
28: door
29: LM device
30: door frame
31: door cylinder
32: bar structure
33: guide bar
34: negative pressure chamber
35: first blow fan
36: Hepa Filter
37: 1st ventilation duct
38: second blow fan
39: second song duct
40: duct support
41a, 41b: filter media slit
42: current section
43: slot frame

Claims (10)

A duct structure 12 having a closed structure that forms a passage for metal oxide nanoparticles;
A nanoparticle generator 13 installed in the duct structure 12 to generate metal oxide nanoparticles;
A first blowing device 14 installed at the inlet of the duct structure 12 and supplying fluid to the interior of the nanoparticle generator 13;
The metal oxide nanoparticles supplied from the nanoparticle generating device 13 side are installed in the filter media in the duct structure 12 and installed with a door device 15 that can be opened and closed for input and discharge of filter media. An electrostatic precipitating coating module 16 to be attached;
A filter media input/discharge device 17 installed on one side of the electrostatic coating module 16 to inject filter media for coating or discharge filter media after coating;
Atmospheric pressure dry aerosol-based deodorizing filter dry coating device characterized in that it comprises a.
The method according to claim 1,
It characterized in that it further comprises a particle charging module (18) that is installed on the front end of the electrostatic precipitating coating module (16) in the duct structure (12) to charge the metal oxide nanoparticles moving along the duct structure (12). Deodorizing filter dry coating device based on atmospheric pressure dry aerosol.
The method according to claim 1,
It is installed on the horizontal duct portion 11 close to the electrostatic coating module 16 and the multi-stage inlet magazine 19 and the outlet magazine 20 for drying the filter media after coating and atmosphere of the filter media before coating 20 Atmospheric pressure dry aerosol-based deodorizing filter dry coating device further comprising a.
The method according to claim 1,
It is installed on the front end of the horizontal duct 11 of the duct structure 12, characterized in that it further comprises a second blowing device 21 for blowing metal oxide nanoparticles to the electrostatic coating module 16 side Deodorizing filter dry coating device based on atmospheric pressure dry aerosol.
The method according to claim 1,
While being installed at the boundary between the vertical duct portion 10 and the horizontal duct portion 11 of the duct structure 12, the metal oxide nanoparticles supplied in the vertical direction from the nanoparticle generating device 13 are converted to horizontal and horizontal. Atmospheric pressure dry aerosol-based deodorizing filter dry coating device further comprising a particle guiding tube (22) leading to the inner central region of the duct (11).
The method according to claim 1,
Further comprising an exhaust duct portion 23 is installed connected to the rear end of the horizontal duct portion 11 of the duct structure 12, the inside of the exhaust duct portion 23 at least 1 to collect the residual metal oxide nanoparticles Atmospheric pressure dry aerosol-based deodorizing filter dry coating device, characterized in that a particle recovery module (25) having more than one collection filter (24) is installed.
The method according to claim 1,
The horizontal duct portion 11 of the duct structure 12 is composed of a combination of two rows of parallel first horizontal duct portions 11a and second horizontal duct portions 11b branched from the vertical duct portion 10, and In the electrostatic dust collecting coating module 16a in the first horizontal duct part 11a, the primary coating of the filter media in the vertical posture is performed, and the electrostatic dust collecting coating module 16b in the second horizontal duct part 11b ) Is the atmospheric pressure dry aerosol-based deodorizing filter dry coating device characterized in that a secondary coating is applied to the filter media in a horizontal position.
The method according to claim 6,
The nanoparticle generating device 13 is part of the exhaust discharged through the exhaust duct part 23 while being connected between one side of the exhaust duct part 23 of the duct structure 12 and one side of the nanoparticle generating device 13. ) Drying device for atmospheric deodorizing filter based on atmospheric pressure aerosol, further comprising a circulation duct portion 26 circulating to the side.
The method according to claim 1,
The door device 15 of the electrostatic coating module 16 is a door 28 that opens and closes the filter media entrance 27 and a door that is movable up and down by both LM devices 29 while being arranged side by side on the front of the module. A frame 30, a plurality of door cylinders 31 supported on the front surface of the door frame 30 and connected to the door side through a rod, and the door cylinder 31 while being installed on the door frame 30 side The atmospheric pressure dry aerosol-based deodorizing filter dry coating device comprising a bar structure (32) supporting the rear end.
The method according to claim 9,
A dry coating device based on atmospheric pressure dry aerosol, characterized in that it further comprises a plurality of guide bars (33) supported in a slidable structure on the door frame (30) while extending from the door (28).

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