KR100641105B1 - Integrated negative ion generator and fabrication and method producing it? integrated negative and positive ion generator and fabrication, method producing it and method using it - Google Patents

Abstract

The present invention relates to an integrated negative ion generating device and a manufacturing method thereof, and an integrated negative negative ion generating device, a manufacturing method and a method of using the same, comprising: a container having at least one surface opened; A high voltage generator installed inside the container; An anion generating unit on a plane installed inside the container and electrically connected to the high voltage generating unit; In addition, it is simpler in structure and easy to attach to various electronic devices, and it is possible to sterilize by supporting precious metal nanoparticles as well as increasing the generation efficiency of negative ions and increasing the air purification function by using a flat felt type activated carbon fiber. A container having at least one surface open while providing an integrated negative ion generating device and a method for producing the same, the effect of increasing the effect; A positive electrode high voltage generator and a negative electrode high voltage generator installed in the container to be spaced apart from each other; A planar cation generating unit and a planar negative ion generating unit installed spaced apart from each other in the container and electrically connected to the positive electrode high voltage generating unit and the negative electrode high voltage generating unit, respectively; Including, by integrally generating an anion or cation as needed or generating an anion and a cation at the same time, the integrated yinyang ion generating device that can perform a sterilization function and air purification at the same time, a method of manufacturing the same and a method of using the same To provide.

 Ion generator, activated carbon fiber, anion, cation

Description

INTEGRATED NEGATIVE ION GENERATOR AND FABRICATION AND METHOD PRODUCING IT; INTEGRATED NEGATIVE AND POSITIVE ION GENERATOR AND FABRICATION, METHOD PRODUCING IT AND METHOD USING IT}

1 is a schematic diagram showing the principle of the generation of negative ions by the electron emission method.

Figure 2a and 2b is a perspective view showing a wire-type discharge tip structure of the negative ion generating device according to the prior art.

Figure 3 is a perspective view showing the configuration of a negative ion generating device according to the prior art.

4A to 4E are perspective views illustrating an integrated negative ion generating device according to an embodiment of the present invention.

4A illustrates a container including a high voltage generator.

Figure 4b shows a planar felt type negative ion generating unit.

Figure 4c shows a support plate coated with a conductive layer on one surface.

4d illustrates a container cover.

Figure 4e illustrates an integrated negative ion generating device of the assembled form.

Figure 5 is an enlarged photo of the microstructure of the activated carbon fiber of the negative ion generating unit provided in the integrated negative ion generating device of Figures 4a to 4e.

6A to 6E are perspective views illustrating a method of manufacturing the anion generator of FIGS. 4A to 4E.

Figure 6a shows an insulation step after installing the high voltage generating portion in the container.

6B shows the container after mounting the high voltage generator.

Figure 6c shows the step of mounting the support plate.

Figure 6d shows the step of mounting the negative ion generating unit.

6E illustrates a container cover mounting step.

7 is a flowchart illustrating a method of manufacturing the integrated negative ion generating device of FIGS. 6A to 6E.

Figure 8 is an exploded perspective view showing the configuration and manufacturing method of a unitary negative yin ion generating apparatus according to another embodiment of the present invention.

FIG. 9 is a flowchart illustrating a manufacturing process of the integrated negative ion generator of FIG. 8; FIG.

110, 210: Container 120: high voltage generating unit

220a: positive electrode high voltage generator 220b: negative electrode high voltage generator

130: anion generator 230a: cation generator

230b: negative ion generating unit 140, 240: support plate

141, 241a, 241b: conductive layer 150, 250: container cover

151, 251: Slit

The present invention relates to an integrated negative ion generating device and a method of manufacturing the same, to an integrated negative ion generating device, a method of manufacturing the same and a method of using the same, more specifically, a high voltage generating unit and an anion generating unit formed integrally an anion generating device and The manufacturing method, the positive electrode high voltage generator, the positive ion generator, the negative electrode high voltage generator, and the negative ion generator are formed integrally, and a manufacturing method and a method of using the same.

As environmental pollution becomes serious, the number of people who have various respiratory diseases or allergic reactions due to the polluted air is increasing. Accordingly, the effort to pleasantly clean the polluted air by generating negative ions as a means of improving air quality. There are various attempts to sterilize bacteria or microorganisms by generating cations.

Negative ions and cations refer to a state in which molecules such as oxygen and nitrogen in the air have negative and positive charges, among which anions are very beneficial to the human body and are effective for removing dust and odors. There are reports that it is effective to sterilize bacteria and microorganisms. Accordingly, in recent years, as well as air cleaners, most household appliances such as hair dryers and water purifiers have been added to generate anions or cations.

In general, ion generators include corona discharge, electron emission, lena-de effect, and α-ray method. Among them, the lena-de effect and α-ray method have very high equipment. Since it is expensive and its use is mainly used for industrial purposes, it is not generally applied to home appliances.

In addition, since the corona discharge method is designed to face the positive electrode and the negative electrode forming the negative electrode, there are many disadvantages than the electron emission method in terms of space design, and the use thereof is gradually decreasing.

Hereinafter, an ion generating apparatus according to the prior art will be described with reference to the accompanying drawings.

Figure 1 is a schematic diagram showing the principle of generating negative ions by the electron radiation method, Figures 2a and 2b is a perspective view showing a wire-type discharge tip structure of the negative ion generating device according to the prior art, Figure 3 is a negative ion generation according to the prior art It is a perspective view which shows the structure of an apparatus.

As shown in FIG. 1, the electron emission method refers to a method in which a tip portion applies a pulsed cathode high voltage to a sharp tip to emit electrons directly into the air. It combines with air molecules to generate negative ions.

In order to apply high voltage to the air, a material having a sharp tip is used as the discharge tip, because the smaller the tip radius is, the higher the voltage is applied to the tip end even when the same voltage is applied. The same principle applies to the electron emission method as well. Conventionally, a tip made of artificially pointed wire or a wire type is used, but a tip manufactured by physically processing has a limitation in reducing the tip radius. As a result, the amount of ions that can be generated per area is small, the volume is large, and the power consumption is also large.

As a solution to this, a product using a discharge tip of the type as shown in Figures 2a and 2b has emerged.

As shown in FIG. 2A, the ion generating device in which the discharge tip 10 is formed by using one wire may have a smaller tip radius than when the needle is discharged by physically processing metal. It is used to process like a needle, through which to further reduce the radius of the tip. This reduces power consumption for electron emission and increases electron emission efficiency. However, even with such a wire, there is a limit to reducing the actual tip radius.

FIG. 2b is a carbon fiber bundle having a nano-sized tip radius to have a finer tip radius than that of FIG. 2a. The discharge tip 10 is formed by using carbon fiber, which is relatively mass-produced and inexpensive. In this case, the tip radius can be reduced to about 6 μm.

As described above, when using an anion discharge tip of a new material that can reduce the tip radius to increase the electron emission efficiency, the efficiency will be higher than the conventional method of sharply cutting a metal plate, but placed in a large area in a small area There is a problem in that the cost for manufacturing the ion generating device is high because the configuration for making it difficult.

Such ion generators are widely used as air purifiers due to the social trend of well-being, and additional functions for filtering fine dust while generating large amounts of negative ions beneficial to the human body are being applied. To this end, products have been developed that arrange filters for filtering basic fine dust while inhaling air into the ion generating unit that generates ions.

However, since the filter for purifying air becomes an additional component separate from the negative ion generating device, it is necessary to periodically clean the negative ion generating device and the added filter for continuous management, which causes inconvenience in management.

On the other hand, as shown in Figure 3, the current commercially available negative ion generating device has a structure in which the high voltage generator 30 and the negative ion generating tip 20 are separated. Such a structure has a problem in that a portion for attaching the high voltage generator 30 and a portion for attaching the negative ion generating tip may be separately provided when the negative ion generating device is attached to the electronic device.

The present invention has been made to solve the problems described above, and an object thereof is to provide a new type of integrated negative ion generating device which is simpler in structure and easy to attach to various electronic devices.

In addition, the present invention is provided with an anion generator and a cation generator at the same time, to provide an integrated negative negative ion simultaneous generator that can selectively generate an anion or a cation as needed or generate an anion and a cation simultaneously. do.

In order to achieve the above object, the present invention provides a container having at least one surface opened; A high voltage generator installed inside the container; An anion generating unit on a plane installed inside the container and electrically connected to the high voltage generating unit; It provides an integrated negative ion generating device comprising a.

This is to have a simpler structure by having a high voltage generator and an anion generator integrally in one container.

Here, the negative ion generating unit is composed of a felt made of activated carbon fibers, which is to maximize the negative ion generating efficiency by allowing the cross-section of the numerous activated carbon fibers to serve as a discharge tip.

In addition, the present invention comprises the steps of installing a high voltage generating unit in at least one surface of the container opening; Filling the container with a molding liquid to insulate the high voltage generator; Installing a support plate coated with a conductive layer on the container; Providing an anion generator on a surface made of activated carbon fibers on an upper surface of the conductive layer of the support plate; It provides a method of manufacturing an integrated negative ion generating device that is performed sequentially.

On the other hand, the present invention is a container with at least one surface opened; A positive electrode high voltage generator and a negative electrode high voltage generator installed in the container to be spaced apart from each other; A planar cation generating unit and a planar negative ion generating unit installed spaced apart from each other in the container and electrically connected to the positive electrode high voltage generating unit and the negative electrode high voltage generating unit, respectively; It provides a unitary negative yin ion simultaneous generator configured to include.

This is to provide a cation generator and an anion generator at the same time to selectively generate a cation or anion, or to generate a cation and an anion at the same time if necessary.

In addition, the present invention comprises the steps of installing the positive electrode high voltage generating unit and the negative electrode high voltage generating unit spaced apart from each other at least on one side of the container opening; Filling the container with a molding liquid to insulate the positive electrode high voltage generator and the negative electrode high voltage generator; Installing a support plate coated with two conductive layers on the container; Providing a planar anion generator and a planar cation generator on the two conductive layers of the support plate, respectively; Provided is a method for manufacturing an integrated negative yin ion simultaneous generator that is performed sequentially.

In addition, the present invention provides a method of using an integrated negative negative ion generating device, comprising: applying power only to a negative electrode high voltage generating unit so that negative ions are emitted only from the negative ion generating unit; Applying power only to the positive electrode high voltage generator to release the positive ions only from the positive ion generator; Applying power to the negative electrode high voltage generator and the positive electrode high voltage generator so that the negative and positive ions are simultaneously released from the negative ion generator and the positive ion generator; It provides a method of using an integrated yin yang ion generator comprising a.

This means that the user generates only negative ions to purify the air for a pleasant environment, only positive ions to kill bacteria or microorganisms in the air, and simultaneously generates negative ions and positive ions if necessary. To do this.

Hereinafter, an integrated negative ion generating device according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

However, in the following description of the present invention, a description of a known function or configuration will be omitted to clarify the gist of the present invention.

4A to 4E are perspective views illustrating an integrated negative ion generating device according to an embodiment of the present invention, and FIG. 4A illustrates a container including a high voltage generating part, and FIG. 4B illustrates a flat felt negative ion generating part. 4c shows a support plate coated with a conductive layer on one surface, FIG. 4d shows a container cover, FIG. 4e shows an integrated negative ion generating device in an assembled form, and FIG. 5 shows FIG. 4a. 4E are enlarged photographs of the fine structure of the activated carbon fibers of the negative ion generator provided in the integrated negative ion generator of FIG.

As shown in Figure 4a to 4e, the integrated negative ion generating device 100 according to an embodiment of the present invention, the container 110 having an upper opening, and a high voltage generating unit installed inside the container 110 The support plate 120 is provided between the negative ion generator 130 and the high voltage generator 120 and the negative ion generator 130 installed inside the container 110 to support the negative ion generator 130. 140 and a container cover 150 covering the opening of the container 110.

In this case, the high voltage generator 120 and the negative ion generator 130 are electrically insulated from each other inside the container 110.

In this case, the high voltage generator 120 may be disposed inside the container 110 and an insulating layer may be formed by covering the surface of the high voltage generator 120 with an insulating material. Alternatively, a method of installing a separate insulation member between the high voltage generator 120 and the negative ion generator 130 may be possible.

The support plate 140 serves to secure the inside of the container 110, while maintaining the shape of the negative ion generating unit 130 on the surface, the container 110 is slightly spaced apart from the high voltage generating unit 120 It is preferable to be installed inside.

In addition, the support plate 140 is preferably made of an insulating material, in the embodiment of the present invention used a PCB (PCB) substrate. In this case, the support plate 140 may be fixed to the container 110 by a separate fastening means so that the support plate 140 may be mounted inside the container 110, and may be mounted in various other known methods.

In addition, a conductive layer 141 coated with a conductive material is formed on the upper surface of the support plate 140. In this embodiment, copper is used, and aluminum, silver, gold, and other conductive metals may be used.

The support plate 140 is provided between the high voltage generator 120 and the negative ion generator 130, and the conductive layer 141 and the high voltage generator 120 and the negative ion generator 130 of the support plate 140 are electrically connected. It is configured to be connected.

Since the negative ion generator 130 is in surface contact with the upper surface of the conductive layer 141 of the support plate 140, the negative ion generator 130 is stably supported by the support plate 140 inside the container 110. The high voltage may be applied from the high voltage generator 120 through the conductive layer 141.

In this case, even if the conductive layer 141 is not formed on the upper surface of the support plate 140, the support plate 140 is configured to only serve to mechanically support the negative ion generator 130, and the high voltage generator 120 and the negative ion The same effect may be obtained by directly connecting the generator 130.

The negative ion generating unit 130 is preferably in the form of a felt formed by the activated carbon fibers fused (縮 絨). As shown in FIG. 5, the activated carbon fibers produced in the felt form are intricately intertwined with finely sized carbon fibers, and are manufactured to have a predetermined surface by cutting on the surface, so that the cut surfaces have numerous carbon fibers. The longitudinal section of the yarn is generated. The longitudinal cross section of the carbon fiber yarn serves as a discharge tip.

Felt using activated carbon fibers of several micrometers in diameter has a specific surface area of 1000 m 2 / g or more, and thus, itself has an air cleaning function due to adsorption of harmful substances.

In one embodiment of the present invention, the activated carbon fiber felt having a longitudinal section of a myriad of carbon fiber yarns as described above is used as the anion generator 130. That is, by allowing all of the very fine and numerous carbon fiber longitudinal cross sections to be used as the anion discharge tip, it is possible to stably generate a large amount of anions from the front surface of the activated carbon fiber felt.

Since the activated carbon fiber felt made of such activated carbon fibers is fused and woven into a fiber shape, the size and shape of the activated carbon fiber felt can be easily defined, and there is an advantage of freely carrying precious metal particles. In one embodiment of the present invention, evenly distributed noble metal nanoparticles on the activated carbon fiber felt to add anion and the ability to remove microorganisms such as bacteria and bacteria in the air. Precious metal nanoparticles include gold, silver, platinum, copper, aluminum, chromium, tungsten, molybdenum and the like.

The container cover 150 is coupled to the top opening of the container 110 to cover the opening of the container 110. In this case, the container cover 150 is preferably in the form of a plate is formed with a plurality of slits 151 to serve as a passage through which anions can be released, the size or shape of the slit 151 is shown in Figure 4d As can be changed appropriately.

The container cover 150 serves to fix the negative ion generating unit 130 from the top and at the same time serves as a passage for releasing negative ions generated from the negative ion generating unit 130 through the slit 151 to the outside.

4E illustrates anion generator 100 of a completed form in which each of the above-listed components is integrally assembled, and the container cover 150 is fixed to the container 110 by fastening means such as bolts and rivets. It may be mounted by other known other methods.

Referring to the principle of operation of the integrated negative ion generating device 100 according to an embodiment of the present invention configured as described above are as follows.

When power is applied to the high voltage generator 120 installed inside the container 110, the high voltage power applied from the high voltage generator 120 flows to the negative ion generator 130 on the plane through the conductive layer 141. .

In this case, since there are numerous longitudinal cross-sections of the activated carbon fibers in the anion generator 130, the longitudinal cross-sections of the activated carbon fibers serve as discharge tips due to the high voltage applied to each activated carbon fiber. Is released.

Such negative ions are released to the outside through the slit 151 of the container cover 150, so that the surrounding air can be comfortably purified.

On the other hand, when describing the manufacturing method of the integrated negative ion generating device 100 according to an embodiment of the present invention.

6A through 6E are perspective views illustrating a method of manufacturing the negative ion generator of FIGS. 4A through 4E, and FIG. 6A illustrates an insulation step after the high voltage generator 120 is installed in the container 110. 6b illustrates the container 110 after the high voltage generator 120 is mounted, FIG. 6c illustrates the mounting of the support plate 140, and FIG. 6d illustrates the mounting of the negative ion generator 130. 6E illustrates a step of mounting the container cover 150, and FIG. 7 is a flowchart illustrating a method of manufacturing the integrated negative ion generating device 100 of FIGS. 6A to 6E.

As shown in FIGS. 6A to 7, first, the high voltage generator 120 is installed by mounting circuit components for generating a high voltage in the container 110 (S1), and the insulating liquid molding liquid 160 is connected to the high voltage. It is injected into the generation unit 120 and cured (S2).

When the insulating liquid molding liquid 160 is cured, the high voltage generator 120 is maintained in an insulating state. Alternatively, a separate insulation member may be installed on the high voltage generator 120 to insulate the anion generator 130.

Next, the support plate 140 is installed inside the container 110 (S3). As illustrated in FIG. 6C, a conductive layer 141 is coated on the upper surface of the support plate 140, and a groove 140a through which an electrical connection medium (for example, an electric conductor) passes through the edge is formed. .

Next, the surface-shaped felt negative ion generating unit 130 is mounted on the support plate 140 (S4). As shown in FIG. 6D, since the negative ion generating unit 130 is electrically connected to the conductive layer 141, a high voltage generated from the high voltage generating unit 120 may be applied, and the high voltage may generate negative ions. A plurality of carbon fibers constituting the unit 130 emits electrons to generate negative ions.

Finally, after placing the container cover 150 on the negative ion generating unit 130, it is fixed by a fastening means such as a bolt 170 to complete the negative ion generating device 100.

On the other hand, the configuration and operation principle of the integrated negative yin ion simultaneous generator 200 according to another embodiment of the present invention will be described.

However, the description of the parts overlapping with the configuration and operation principle of the integrated negative ion generating device 100 according to an embodiment of the present invention as described above will be omitted.

FIG. 8 is an exploded perspective view illustrating a configuration and a manufacturing method of the integrated negative positive ion generating device 200 according to another embodiment of the present invention, and FIG. 9 is a manufacturing process of the integrated negative negative ion generating device 200 shown in FIG. 8. Is a flow chart illustrating.

As shown in FIG. 8, the integrated negative ion generating apparatus 200 according to another embodiment of the present invention includes a container 210 having an upper surface opened and an anode provided to be spaced apart from each other in the container 210. The high voltage generator 220a and the negative electrode high voltage generator 220b, the cation generator 230a and the anion generator 230b which are installed to be spaced apart from each other inside the container 210, and the positive electrode high voltage generator 220a. And a support plate 240 provided between the cathode high voltage generator 220b, the cation generator 230a, and the anion generator 230b to support the cation generator 230a and the anion generator 230b, and a container ( It consists of a container cover 250 covering the opening of 210.

Here, in order to insulate the positive electrode high voltage generator 220a and the negative electrode high voltage generator 220b, the cation generator 230a, and the anion generator 230b, a cation generator 230a and anion are generated in the container 210. It is preferable to form an insulating film by covering the surfaces of the positive electrode high voltage generator 220a and the negative electrode high voltage generator 220b with the insulating material 260 before installing the unit 230b. In this case, it is also possible to provide another insulation member.

The support plate 240 is provided with two conductive layers 241a and 241b coated with a conductive material, thereby electrically connecting the positive electrode high voltage generator 220a and the cation generator 230a to each other, and the negative electrode high voltage generator ( 220b) and the negative ion generator 230b are electrically connected to each other. In this case, the conductive layers 241a and 242b are made of copper, aluminum, gold, silver, and other conductive metals.

The cation generator 230a and the anion generator 230b are configured in the form of a flat felt, and the felt is formed by the fusion of activated carbon fibers. This is to facilitate the release of the cation or anion by utilizing the longitudinal cross-section of a myriad of activated carbon fibers as a discharge tip as described above. In addition, the active carbon fiber can increase the sterilization function of bacteria and bacteria in the air by evenly supporting the precious metal nanoparticles such as gold, silver, copper, platinum, aluminum, chromium, tungsten, molybdenum.

The container cover 250 is configured such that a plurality of slits 251 are formed to cover the openings of the container 210 so that positive or negative ions are released to the outside through the plurality of slits 251.

Referring to the principle of operation of the integrated negative negative ion generating apparatus 200 according to another embodiment of the present invention configured as described above are as follows.

When the user wants to purify the indoor air comfortably by using the integrated negative and negative ion generating device 200, when the power is applied only to the negative electrode high voltage generator 220b, the negative electrode high voltage generator ( A negative electrode high voltage is applied to the negative ion generating unit 230b electrically connected to 220b), and negative ions are released to the longitudinal cross-sections of the numerous activated carbon fibers of the negative ion generating unit 230b. This anion is released to the outside through the plurality of slits 251 of the container cover 250.

When the user wants to sterilize dust, bacteria, and microorganisms contained in the indoor air by using the integrated negative ion generator 200, the conductive layer 241a is applied when only the anode high voltage generator 220a is supplied with power. The positive electrode high voltage is applied to the positive ion voltage generator 230a which is electrically connected to the positive electrode high voltage generator 220a to release the cations to the end surfaces of the numerous activated carbon fibers of the positive ion generator 230a. This cation is released to the outside through the plurality of slits 251 of the container cover 250.

In addition, when the user simultaneously applies a voltage to the positive electrode high voltage generator 220a and the negative electrode high voltage generator 220b of the integrated negative positive ion generator 200, the positive electrode high voltage is applied to the positive ion generator 230a and negative ions are generated. Since the negative electrode high voltage is applied to the unit 230b, positive and negative ions are simultaneously released through the plurality of slits 251 of the container cover 250, so that the sterilization function and the air purification function may be simultaneously performed.

On the other hand, when describing the manufacturing method of the integrated negative negative ion generating apparatus 200 according to another embodiment of the present invention.

First, by mounting circuit components for generating the positive and negative high voltages inside the container 210, the positive and high voltage generating parts 220a and the negative and high voltage generating parts 220b are installed (S1), and the insulating liquid molding liquid 260 is prepared. The anode high voltage generator 220a and the cathode high voltage generator 220b are immersed to be locked (S2).

When the insulating liquid molding liquid 260 is cured, the positive electrode high voltage generator 220a and the negative electrode high voltage generator 220b are maintained in an insulating state. Alternatively, a separate insulating member may be installed on the positive electrode high voltage generator 220a and the negative electrode high voltage generator 220b to insulate the cation generator 230a and the anion generator 230b.

Next, the support plate 240 is installed inside the container 210 (S3). As shown in FIG. 8, two conductive layers 241a and 241b are coated on the upper surface of the support plate 240, and grooves 240a through which an electrical connection medium (for example, an electric conductor) can pass near the edges thereof. ) Is formed.

Subsequently, the surface-shaped felt cation generator 230a and the anion generator 230b are mounted on the support plate 240 (S4). Since the cation generator 230a and the anion generator 230b are electrically connected to the conductive layers 241a and 241b, the high voltage generated from the positive electrode high voltage generator 220a and the negative electrode high voltage generator 220b This high voltage allows the positive or negative ions to be released through the longitudinal cross-sections of the plurality of carbon fibers constituting the cation generator 230a and the anion generator 230b.

Finally, after the container cover 250 is positioned on the cation generator 230a and the anion generator 230b, the container cover 250 is fixed by fastening means such as a bolt 270 to complete the integrated negative ion generating device 200. (S5).

Although the exemplary embodiments of the present invention have been described above by way of example, the scope of the present invention is not limited only to the specific embodiments as described above, and may be appropriately changed within the scope described in the claims.

As described above, the present invention has a simpler structure and is easy to attach to various electronic devices, and improves the generation efficiency of negative ions and increases the air purification function by using a flat felt-type activated carbon fiber, and also improves precious metal nanoparticles. Provided are an integrated negative ion generating device that increases sterilization effect by supporting and a method of manufacturing the same.

In addition, the present invention is equipped with an anion generator and a cation generator at the same time, by selectively generating anion or cation as needed, or by generating an anion and a cation at the same time, an integral type that can perform sterilization function and air purification function at the same time Provided are a yin-yang ion generating device, a manufacturing method thereof, and a method of using the same.

Claims (17)

delete A container having at least one surface opened; A high voltage generator installed inside the container; It is installed inside the container and includes an anion generator on the surface electrically connected to the high voltage generating portion, The negative ion generating unit is an integrated negative ion generating device, characterized in that the felt made of activated carbon fibers. The method of claim 2, The activated carbon fiber is an integrated negative ion generating device, characterized in that coated with precious metal nanoparticles. The method of claim 3, wherein The precious metal nanoparticle is an integrated negative ion generator, characterized in that any one of gold, silver, platinum, copper, aluminum, chromium, tungsten, molybdenum. The method according to any one of claims 2 to 4, The negative ion generator is electrically connected to a support plate coated with a conductive layer on one surface thereof, The high voltage generator is an integrated negative ion generating device, characterized in that electrically connected with the support plate. The method of claim 5, A plurality of slits are formed and the integrated negative ion generating device further comprises a container cover for covering the opening of the container. Installing a high voltage generator in at least one container with an open surface; Filling the container with a molding liquid to insulate the high voltage generator; Installing a support plate coated with a conductive layer on the container; Installing anion generator on the top surface of the conductive layer of the support plate formed of activated carbon fibers; A method of manufacturing an integrated negative ion generator, characterized in that it is carried out sequentially. The method of claim 7, wherein And installing a container cover in the opening of the container. A container having at least one surface opened; A positive electrode high voltage generator and a negative electrode high voltage generator installed in the container to be spaced apart from each other; A planar cation generating unit and a planar negative ion generating unit installed in the container and spaced apart from each other and electrically connected to the cathode high voltage generating unit and the cathode high voltage generating unit, respectively; Integrated negative yin ion simultaneous generator, characterized in that comprising a. The method of claim 9, The negative ion generating unit and the positive ion generating unit integrated negative ion generating device, characterized in that the felt made of activated carbon fibers. The method of claim 10, The activated carbon fiber is a unitary negative ion co-generation device characterized in that the coating of precious metal nanoparticles. The method of claim 11, The precious metal nanoparticles are integrated negative ion generators, characterized in that any one of gold, silver, platinum, copper, aluminum, chromium, tungsten, molybdenum. The method of claim 12, A plurality of slit is formed and the integrated negative ion generator, characterized in that it further comprises a container cover for covering the opening of the container. The method of claim 13, The anion generator and the cation generator are electrically connected to the support plate coated with a conductive layer on one surface thereof, And the anode high voltage generator and the cathode high voltage generator are electrically connected to the support plate, respectively. Installing the positive electrode high voltage generator and the negative electrode high voltage generator at least one side of the container to be spaced apart from each other; Filling the container with a molding liquid to insulate the positive electrode high voltage generator and the negative electrode high voltage generator; Installing a support plate coated with two conductive layers on the container; Providing a negative ion generating part and a positive ion generating part each consisting of activated carbon fibers on top surfaces of the conductive layers of the two support plates; A method for manufacturing an integrated negative yin ion generator, characterized in that it is carried out sequentially. The method of claim 15, The method of claim 1, further comprising the step of installing a container cover to the container. In the method of using the integrated negative ion generating device according to any one of claims 9 to 14, Applying power only to the negative electrode high voltage generator to release negative ions only from the negative ion generator; Applying power only to the positive electrode high voltage generator to release cations only from the cation generator; Applying power to the negative electrode high voltage generator and the positive electrode high voltage generator so that negative ions and positive ions are simultaneously released from the negative ion generator and the positive ion generator; Method of using an integrated yin yang ion generating device comprising a.

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