KR100976839B1 - Apparatus for generating nano colloid using stick-type pouring liquid cartridge and cartridge for use therein - Google Patents

Abstract

The present invention relates to an apparatus for producing nanocolloids by inducing plasma generation in liquid.

According to the present invention, a device for generating a nano-colloid in a liquid plasma method, generates a constant high-voltage electrical energy and supplies the generated electrical energy to the internal electrode provided in the holder portion on which the stick cartridge is mounted under the control of the control means. Main body; A stick-shaped body portion having a space for accommodating liquid therein, an electrode coupled to one side of the body portion in the form of a lid and mounted to a holder of the main body and connected to the internal electrode and one side of the electrode A cartridge comprising a cartridge lid having a metal wire attached thereto; And a safe guard formed of an elastic material surrounding the outer circumferential surface of the cartridge and supporting the contact surface of the cartridge with the holder when the cartridge is mounted to the holder of the main body. The nano colloid generating apparatus used is disclosed.

Colloid, Cartridge, Metal Wire, Submerged Plasma, Safeguard

Description

Apparatus for generating nano colloid using stick-type pouring liquid cartridge and cartridge for use therein}

The present invention relates to an apparatus for producing a colloid, and more particularly, to an apparatus for manufacturing a nano colloid by inducing plasma generation in a liquid.

In recent years, a plasma method in a liquid has been widely used among methods of preparing a colloid in order to use precious metal processing. This conventional submerged plasma method applies a high density of charged energy to the metal wire inserted into the liquid solvent, induces the plasma in the liquid generated by resistance heating in a short time of 1 ~ 50 ㎲ (micro second) to generate nano colloids It is a technique to manufacture. In the conventional nanocolloid manufacturing apparatus using this method, a metal wire is used by a user by hand or by a gripper to transfer a metal wire to each of the high voltage electrode portions to which high density energy is applied. This is because the force of the high voltage electrode holding the metal wire is not constant according to the diameter of the metal wire, and thus the resistance heating property is changed as the contact resistance is changed, so that the nanocolloid concentration reproducibility generated is remarkably inferior, even the contact property is poor. There is a problem that a high density current is leaked into the liquid and nano colloids are not produced.

In addition, there is a cassette type method in which a metal wire is coated on a film which is perforated in another way. In this case, when the metal wire fixed to the film is supplied to the high voltage electrode, the contact resistance with the metal wire which is in contact with the electrode is large, and only a part of the high density current is applied, and the film is loose due to the pressure generated during the manufacturing of the nano colloid. When it is lost or loosened, there is almost no contact with the high voltage electrode, and a high density of current leaks into the liquid solvent, such that nanocolloids are not manufactured.

Therefore, these days, a nano colloid generation method using a consumable cartridge in which metal wires are bonded by improving them has been used. In this case, the nanocolloid reproducibility can be secured by improving the phenomenon that the contact between the electrode and the metal wire, which is a problem of the conventional method, is not maintained the same. However, since the cartridge and the liquid are separately configured, the cartridge component for attaching and detaching the cartridge, the shanghai region for moving the cartridge up and down, and the liquid container detector for detecting whether the liquid is filled in a predetermined amount or more are inserted into the liquid container. It is a cause of frequent failures. In addition, there is a limit to completely eliminate the plasma noise in the liquid even if the container cover that seals the upper portion of the liquid container, and when the position of the liquid container is shifted to one side, sharp noise that is not erased occurs, which is unpleasant and stressful to the user. This results in a serious problem that continues to provide.

Recently, nano colloid manufacturing apparatus using an integrated cartridge in which an electrode including a liquid and a metal wire are both present inside the cartridge has been developed and used.

However, the method using the electrode-integrated cartridge as described above has been found to have problems such as deterioration in properties after the nano-colloid generation, increase in unit cost, and productivity in the method of bonding the electrode and the metal wire. In other words, if the existing bonding method is used, deformation is likely to occur at high temperatures, and only one side of the electrode and the metal wire are bonded, so that leakage to the unbonded surface is severe when instantaneous high density current is applied. have.

In addition, the instantaneous high-voltage energy is applied during the manufacturing of the nano-colloid, a sudden pressure change occurs inside the cartridge, in which case the cartridge plug portion in which the electrode is located may be separated or the cartridge itself may be broken. Furthermore, a phenomenon in which the cartridge mounted in the manufacturing apparatus applying high voltage is caused to bounce out of the holder of the manufacturing apparatus due to the sudden pressure change.

Therefore, the present invention was devised to solve the above problems, and improved workability and nano colloid in the method of attaching the electrode and the metal wire and the structure of the electrode at the time of attachment in the cartridge of the cartridge-integrated nano colloid generating apparatus. The purpose is to improve the properties after creation.

In addition, by improving the structure of the cartridge and the electrode cap provided in the cartridge to prevent breakage and leakage of liquid during the manufacturing of nano colloids, and to improve the structure for mounting the manufacturing device and the cartridge to prevent the cartridge from flipping. It has a different purpose.

Other objects and advantages of the invention will be described below and will be appreciated by the embodiments of the invention. Further, objects and advantages of the present invention can be realized by the means and the combination shown in the appended claims.

Nano colloid generating device using a stick-shaped liquid injection type cartridge according to the present invention for achieving the above object, as a device for generating nano colloids in a liquid plasma method, generates a constant high-voltage electrical energy and A main body for supplying the generated electric energy to the internal electrode provided in the holder to be mounted under the control of the control means; A stick-shaped body portion having a space for accommodating liquid therein, an electrode coupled to one side of the body portion in the form of a lid and mounted to a holder of the main body and connected to the internal electrode and one side of the electrode A cartridge comprising a cartridge lid having a metal wire attached thereto; And a safe guard formed of an elastic material surrounding the outer circumferential surface of the cartridge and supporting the contact surface of the cartridge and the holder when the cartridge is mounted to the holder of the main body.

According to another aspect of the present invention, the integrated cartridge device for generating nano-colloids by receiving the high voltage energy is mounted to the nano-colloid generating device according to the liquid plasma method, a space for accommodating the liquid is formed therein one side An open stick shaped body portion; An outer cap coupled to an open side of the body portion in a lid form and mounted to the nano colloid generating device in a state of being coupled to the body portion; An insert cap coupled to the outcap and having a pair of electrodes connected to an internal electrode to which high voltage energy provided in the nanocolloid generating device is applied; A metal wire attached and connected to the pair of electrodes provided in the insert cap through a pressing method, wherein the nano-colloid particles are generated when high voltage energy is applied; And an aluminum cap covering and compressing and sealing the entire outcap and the insert cap while the outcap and the insert cap are fastened to each other. A stick-shaped liquid injectable cartridge device for a nano colloid generating device is provided. .

According to the present invention, when the electrode and the metal wire is attached to the inside of the cartridge of the nano-colloid generating apparatus using a crimping method and the shape of the electrode is formed so that the attachment surface with the metal wire to the maximum, the metal wire and the nano-colloid manufacturing The large attachment surface of the electrode provides the effect of maintaining good productivity and reliability.

Furthermore, when the cartridge is connected to the main body, it is provided with a safety guard that supports the cartridge and the main body to prevent the cartridge from being bounced, and the insert cap having the out cap and the electrode coupled to the cartridge is sealed with an aluminum cap to seal and leak the liquid. Provides the effect of preventing separation phenomenon.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. Prior to this, terms or words used in the present specification and claims should not be construed as being limited to the common or dictionary meanings, and the inventors should properly explain the concept of terms in order to best explain their own invention. Based on the principle that can be defined, it should be interpreted as meaning and concept corresponding to the technical idea of the present invention. Therefore, the embodiments described in the specification and the drawings shown in the drawings are only the most preferred embodiment of the present invention and do not represent all of the technical idea of the present invention, various modifications that can be replaced at the time of the present application It should be understood that there may be equivalents and variations.

1 is a perspective view showing the appearance of the nano-colloid generating device using a stick-shaped liquid injection cartridge according to an embodiment of the present invention, Figure 2 is a partial cross-sectional view showing the configuration of part A of Figure 1, 4 is a cross-sectional view showing the configuration of a stick-shaped liquid injection cartridge device used in the nano-colloid generating device according to an embodiment of the present invention, Figure 4 is a stick shape used in the nano-colloid generating device according to an embodiment of the present invention The separated sectional drawing which shows the structure of the liquid injection type cartridge apparatus of this invention.

Referring to Figures 1 to 4 will be described the configuration of the nano-colloid generating device using a stick-shaped liquid injection cartridge according to an embodiment of the present invention.

As shown in Figure 1, the nano-colloid generating apparatus 1 according to the present invention is equipped with a stick-shaped liquid injection cartridge (cartridge) 100, the cartridge 100 is attached to a metal wire attached to the electrode, A main body 200 for supplying high voltage electric energy to the mounted cartridge 100, and a safe for supporting the cartridge 100 and the main body 200 when the cartridge 100 and the main body 200 are mounted. Guard 300 and the like.

First, in the configuration of the main body 200 for supplying electrical energy charged at a high voltage to the cartridge 100, a space is formed to allow the cartridge 100 to be mounted and detached, and the high voltage electricity to the cartridge 100 is provided. A cartridge holder 210 provided with an internal electrode to supply energy, a cartridge keeper 220 capable of temporarily storing the cartridges 100, and charging and discharging electric energy. It consists of a circuit for sensing the metal wire attached to the cartridge electrode and consists of a system controller 230 for controlling the operation of programs and devices.

The cartridge holder 210 has a space in which the cartridge can be inserted. The cartridge holder 210 is provided with an internal electrode capable of supplying electrical energy by connecting to an electrode provided in the cartridge 100. The internal electrode has a structure that is connected to the electrode provided in the cartridge 100 when the cartridge 100 is inserted and mounted. Therefore, the internal electrodes are formed in a form corresponding to the electrodes provided in the cartridge 100. As the electrodes of the cartridge 100 are configured in pairs, the internal electrodes are also configured in pairs. In addition, the internal electrode is made of beryllium copper and tungsten alloy, silver-based alloy material of the contact material, through which it is possible to reduce the wear and corrosion of the electrode due to repeated mounting, desorption.

The cartridge storage unit 220 is formed in a shape of a storage box in which a space is formed to temporarily store a cartridge to be used for generating nano colloids and a used cartridge. As shown in the figure, a plurality of cartridges are inserted and stored in the cartridge storage unit 220. In addition, the cartridge may be inserted and stored upside down is made of a straight side opposite the electrode.

The system control unit 230 is supplied with power from the outside to charge a high voltage of electrical energy, and includes a control circuit that can supply it to the mounted cartridge 100 instantaneously. In addition, the system control unit 230 is provided with a sensor for detecting whether the cartridge is mounted. The sensor serves to detect whether the cartridge 100 is normally mounted in the cartridge holder 210 to connect the electrodes of the cartridge and the internal electrodes of the main body. In addition, the sensor may detect a connection state of the metal wire attached to the electrode of the cartridge 100 to detect whether the cartridge is already used or a cartridge before use. Through this, the system control unit 230 can control to operate only in the normal cartridge mounting state, it is possible to prevent a safety accident due to malfunction.

Further, the electrical circuit of the system control unit 230 includes a reverse voltage protection circuit to prevent failure or malfunction due to instability from reverse voltage and surge. In addition, the system control unit 230 includes a constant voltage holding circuit to receive a variety of external power to output a constant constant voltage. That is, it is possible to form a constant current and voltage irrespective of the external power supply by country and region forming various external power supply environments.

In addition, the main body 200 charges a voltage of 600 V to 5000 V through a circuit of the system controller 230 and provides it to the mounted cartridge. In addition, the electrical circuit of the system control unit 230 has a charging capacity of 1 kV to 500 kV. This makes it possible to charge enough voltage.

The safe guard 300 supports the main body 200 and the cartridge 100 when the cartridge 100 is mounted on the main body 200 and when the colloid generation operation is performed after the mounting. It serves to fix the cartridge and the body to prevent. The safe guard 300 is made of a material such as ABS having a flexible characteristic. Referring to FIG. 2, the cartridge 100 is mounted on the cartridge holder 210 of the main body 200, and the safe guard 300 is positioned between the cartridge 100 and the cartridge holder 210. To support and fix the two. Therefore, the safe guard 300 surrounding the outer circumferential surface of the cartridge 100 prevents vibration, shaking, and the like, thereby allowing the electrodes to be stably connected. In addition, the cartridge 100 mounted on the cartridge holder 210 may be held by the safe guard 300 to prevent the cartridge from being bounced.

Next, the stick-shaped liquid injection cartridge device 100 used in the nano-colloid generating device according to an embodiment of the present invention will be described in detail with reference to FIGS.

3 to 4, the cartridge device 100 according to the present invention is a cartridge lid portion 120, the aluminum cap 180 consisting of a body portion 110, an out cap 130 and an insert cap 140 ), The safe guard 300 and the like.

The body portion 110 is formed of a plastic material having a flexibility to form a space for accommodating liquid therein and one side is open. The body portion 110 is injected with a liquid to produce a nano colloid. In addition, the body portion 100 is made of a plastic material having flexibility, so as not to break even in a strong pressure when producing nano colloids.

The cartridge lid portion 120 is formed of an out cap 130 coupled to the open surface of the body portion 110 in the form of a lid, and an insert cap 140 having an electrode 150 and a metal wire 160. The outer cap 130 is one side is coupled to the body portion 110 and the other side is the insert cap 140 is inserted and coupled. The outcap 130 has a coupling fastening structure to couple to the open surface of the body portion 110. Although the fitting coupling structure is illustrated in the drawings, various coupling coupling structures such as a screw coupling structure may be adopted.

The insert cap 140 is formed of an electrode 150 that is connected to an internal electrode of the main body to receive electric energy, a metal wire 160 attached to the electrode 150, a waterproof member 190, and the like. The insert cap 140 is located at the lower end of the out cap 130, and is sealed by the aluminum cap 180 to be described later. The waterproof member 190 is to prevent leakage of the liquid when it is coupled to the out cap 130, for example O-ring (O-ring) may be used. In addition, the waterproof member 190 may be made of a silicon material for an effective waterproof function.

The electrodes 150 are formed in a pair and are designed to have a symmetrical structure with each other. The electrode 150 is composed of an insert-extruded outlet type. In addition, the electrode 150 is formed through the top and bottom surfaces of the insert cap 140, the electrode located at the lower end is connected to the internal electrode when mounted on the cartridge holder 210 of the main body 200 Structure. The electrode located at the upper end of the insert cap 140 is attached to the metal wire 160, when the electrical energy is supplied to supply instantaneous strong electrical energy to the metal wire. Through this, the metal wire is changed into a nano colloidal state in the liquid by a plasma phenomenon in the liquid.

The electrode 150 and the metal wire 160 are attached by a compression method. As the pressing method, for example, a press pressing method or an air chuck pressing method may be used. In addition, the electrode 150 is made of various shapes to position the metal wire 160 and to maintain the bonding surface of the metal wire 160 and the electrode 150 as wide as possible by pressing. 5 to 9 illustrate various structures of electrodes to which metal wires are attached in a nano colloid generating device using a stick-shaped liquid injection cartridge according to an embodiment of the present invention.

First, referring to FIG. 5, a pair of electrodes 151 formed on the top surface of the insert cap 140 has a groove formed on a surface thereof. The metal wire 160 is positioned in the groove of the date, and the metal wire located in the groove is buried in the electrode 151 through a crimping process. Through this, the electrode 151 and the metal wire 160 may have a wide bonding surface in which all of the outer circumferential surface of the metal wire 160 are bonded to the electrode.

Next, referring to FIG. 6, a structure in which a plurality of straight grooves are present on the surface of the electrode 152 is illustrated. Through this, the metal wire 160 may be easily positioned in the groove of the surface of the electrode 152. That is, in the case of one groove, since the electrodes exist in pairs, it is not easy to position the metal wires in two straight lines at the same time, but by forming a plurality of grooves at various angles, the metal wires can be easily positioned on the two electrodes. Will be. 6 illustrates an example of a structure in which the grooves on the surface form a '*' shape by arranging three straight grooves on the surface of the electrode 152 at an angle to cross each other. Although the above figure shows an example of a '*' shape in which three grooves are formed at different angles in each electrode, the cross shape is formed in a different angle so that two straight grooves cross each other on the electrode surface. Various groove shapes can be formed, such as a shape or a shape in which four straight grooves are formed on the electrode surface at different angles so as to cross each other.

Referring to FIGS. 7 and 8, the electrode 153 formed on the top surface of the insert cap 140 may have a groove having a shape surrounding the side rather than the surface thereof. The metal wire 160 is positioned in the form of winding along the groove formed in the side (see FIG. 7) or in the form of a straight line (see FIG. 8), and the metal wire and the electrode through the pressing process in the vertical direction. Are attached and bonded to each other.

As another example, referring to FIG. 9, an example in which a through hole of a metal wire thickness is formed on a side surface of the electrode 154 is illustrated. The metal wire 160 is inserted and positioned through the through hole formed in the side of the electrode, and the metal wire and the electrode are bonded and attached through a vertical pressing process. In this case, the same through hole should be formed in two electrodes in a straight line, and thus, during manufacturing, an electrode is first formed in the insert cap 140 and then a process of forming a through hole penetrating two electrodes at the same time is used.

Next, the metal wire 160 is selected as a material for producing a nano colloid, and a material suitable for the nano colloid is selected and prepared in the form of a metal wire, and then attached to the electrode. The metal wire 160 has a diameter of 0.3 mm or less. In addition, the length of the metal wire 160 is formed in the range of 5mm ~ 50mm. This is a factor that affects the concentration of the generated nano colloids and the pressure during the production of nano colloids, such that concentration, pressure, colloidation, etc. can be smoothly performed within the above numerical range. In addition, the metal wire 160 may be a conductive pure metal wire, alloy wire, coated metal wire and the like.

The aluminum cap 180 is formed of a thin thin film that surrounds the outer surface of the cartridge cap 120 to which the out cap 130 and the insert cap 140 are coupled. The aluminum cap 180 covers the outer surface of the outer cap 130 and the insert cap 140 in a coupled state, and then seals the outer cap 130 through a pressing process. The cartridge cap 120 is tightly coupled and sealed through the aluminum cap 180 so that internal liquid leaks or the insert cap 140 is separated from the outcap 130 despite the strong pressure generated when the nano-colloid is generated. It is possible to prevent the phenomenon. The aluminum cap 180 may be made of various materials capable of sealingly coupling the insert cap 140 and the outcap 130 through a pressing process as well as aluminum.

Hereinafter, an operation of generating nano colloids using a nano colloid generating device using a stick-shaped liquid injection cartridge according to an embodiment of the present invention will be described.

10 is a view showing a state in which the safe guard is inserted into the cartridge in the nano-colloid generating device using a stick-shaped liquid injection type cartridge according to an embodiment of the present invention.

An operation of the nano colloid generating device according to the present invention will be described with reference to FIGS. 1 and 10.

First, a liquid to generate a nano colloid is injected into the body of the cartridge 100. At this time, the liquid is injected through the open surface of the body portion, and the cartridge lid portion is coupled to the open surface of the body portion to create a sealed cartridge state.

A metal wire is attached to the electrode of the lid of the cartridge.

Next, as shown in FIG. 1, the cartridge 100 is inserted into the cartridge holder 210 of the main body 200 and the safety guard 300 is covered with the cartridge, and then fixed to the inner circumferential surface of the holder 210. do.

Alternatively, as shown in FIG. 10, the safe guard 300 is covered with the cartridge prepared above. At this time, since the cartridge lid portion may protrude further on the outer circumferential surface than the body portion 100, the cover 100 is covered from the top surface of the body portion 100, and then the cartridge 100 covered with the safe guard 300 is covered with the main body ( It is inserted into the cartridge holder portion 210 of the 200.

At this time, the inner electrode of the holder 210 and the electrode of the cartridge are connected with the insertion mounting, and the inner circumferential surface of the holder 210 and the outer circumferential surface of the cartridge are fixed to each other by the safe guard 300. As a result, the phenomenon that the cartridge is easily shaken or the cartridge bounces off the holder 210 can be prevented.

Next, the power is supplied through the system controller 230 and the electric energy is charged. When the high voltage electrical energy is charged, the mounted cartridges supply instantaneous energy. At this time, high voltage electrical energy is supplied to the electrode of the cartridge through the inner electrode of the holder, and instantaneously transfers the electrical energy supplied to the metal wire attached to the electrode in the cartridge. Then, the metal wire is generated in the liquid and liquid plasma in the cartridge to nano-colloid. Through the above operation, the nanocolloid can be easily generated in the liquid in the cartridge.

Although the present invention has been described above by means of limited embodiments and drawings, the present invention is not limited thereto and will be described below by the person skilled in the art to which the present invention pertains. Of course, various modifications and variations are possible within the scope of the claims.

The following drawings, which are attached to this specification, illustrate exemplary embodiments of the present invention, and together with the detailed description of the present invention serve to further understand the technical spirit of the present invention, the present invention includes matters described in such drawings. It should not be construed as limited to.

1 is a perspective view showing the appearance of a nano-colloid generating device using a stick-shaped liquid injection cartridge according to an embodiment of the present invention.

FIG. 2 is a partial cross-sectional view showing a configuration of part A of FIG. 1.

3 is a cross-sectional view showing the configuration of a stick-shaped liquid injection cartridge device used in the nano-colloid generating device according to an embodiment of the present invention.

Figure 4 is an exploded cross-sectional view showing the configuration of a stick-shaped liquid injection cartridge device used in the nano-colloid generating device according to an embodiment of the present invention.

5 to 9 are views illustrating various structures of electrodes to which metal wires are attached in a nano colloid generating device using a stick-shaped liquid injection cartridge according to an embodiment of the present invention.

10 is a view showing a state in which the safe guard is inserted into the cartridge in the nano-colloid generating device using a stick-shaped liquid injection cartridge according to an embodiment of the present invention.

<Description of Major Reference Marks in Drawings>

100: cartridge 200: body

300: Safe Guard

Claims (20)

An apparatus for producing nano colloids by a plasma method in liquid, A main body generating constant high voltage electric energy and supplying the generated electric energy to an internal electrode provided in a holder part in which a stick-type cartridge is mounted under the control of a control means; A stick-shaped body portion having a space for accommodating liquid therein, an electrode coupled to one side of the body portion in the form of a lid and mounted to a holder of the main body and connected to the internal electrode and one side of the electrode A cartridge comprising a cartridge lid having a metal wire attached thereto; And Using a stick-shaped liquid injection type cartridge comprising a; a material formed of an elastic material surrounding the outer circumferential surface of the cartridge, the safe guard for supporting the contact surface of the cartridge and the holder when the cartridge is mounted to the holder of the main body; Nano Colloid Generation Device. The method of claim 1, Electrode of the cartridge is made of a pair, the metal wire is nano-colloid generating device using a stick-shaped liquid injection type cartridge, characterized in that attached to the electrode by a crimping method. The method according to claim 1 or 2, The electrode of the cartridge cap portion is formed with a groove on the surface so that the metal wire is located, the metal wire is nano-colloid generating device using a stick-shaped liquid injection type cartridge, characterized in that after being attached to the groove is pressed . The method of claim 3, wherein The shape of the groove formed on the surface of the electrode is a nano-colloid generating device using a stick-shaped liquid injection cartridge, characterized in that any one of a straight, cross-shaped, '*' shape. The method according to claim 1 or 2, The electrode of the cartridge lid portion is formed with a groove surrounding the side so that the metal wire is placed in a straight line or wound form on the side, the metal wire is placed in a straight line or wound along the groove and then compressed Nano-colloid generating device using a stick-shaped liquid injection cartridge, characterized in that attached. The method according to claim 1 or 2, The electrode of the cartridge lid portion is formed with a hole through which the metal wire is formed, the metal wire is nano-colloid generating device using a stick-shaped liquid injection cartridge, characterized in that the pressure is placed after being placed through the hole. The method of claim 2, The pressing method is a nano-colloid generating device using a stick-shaped liquid injection type cartridge, characterized in that the press injection or air chuck injection method. The method of claim 1, The cartridge cap is made of an out cap coupled to the body portion and the insert cap provided with the electrode, covering the entire cap portion with an aluminum cap in the state in which the out cap and the insert cap are fastened and sealed by pressing Nano-colloid generating device using a stick-shaped liquid injection cartridge characterized in that. The method of claim 8, Part of the cartridge cap portion of the out cap and the insert cap is fastened to the nano-colloid generating device using a stick-shaped liquid injection cartridge, characterized in that it further comprises a waterproof member made of silicon. The method of claim 1, The body of the cartridge is a nano-colloid generating device using a stick-shaped liquid injection type cartridge, characterized in that made of a flexible plastic material. The method of claim 1, Metal colloid generating device using a stick-shaped liquid injection cartridge, characterized in that the metal wire attached to the electrode of the cartridge is less than 0.3mm in diameter. The method of claim 1, The metal wire attached to the electrode of the cartridge is nano-colloid generating device using a stick-shaped liquid injection cartridge, characterized in that the length of 5mm ~ 50mm range. The method of claim 1, The metal wire attached to the electrode of the cartridge is a nano colloid generating device using a stick-shaped liquid injection cartridge, characterized in that any one of a conductive pure metal wire, alloy wire, coated metal wire. The method of claim 1, In the control means of the main body, And a sensor for detecting whether the cartridge is mounted, and controlling not to operate when the cartridge is not mounted. The method of claim 1, The main body, Nano-colloid generating device using a stick-shaped liquid injection type cartridge, characterized in that to provide a 600V ~ 5000V voltage to the mounted cartridge through the internal electrode. The method of claim 1, The main body, A nano colloid generating device using a stick-shaped liquid injectable cartridge, which has a filling capacity of 1 microfarad to 500 microfarads. The method of claim 1, The inner electrode of the main body is a nano-colloid generating device using a stick-shaped liquid injection cartridge, characterized in that the contact material made of copper beryllium, tungsten alloy and silver-based alloy material. The method of claim 1, The main body nano-colloid generating device using a stick-shaped liquid injection cartridge, characterized in that the main body includes a reverse voltage protection circuit. The method of claim 1, In the main body, Nano-colloid generating device using a stick-shaped liquid injection type cartridge, characterized in that it includes a constant voltage holding circuit for outputting a constant constant voltage by receiving various external power. An integrated cartridge device which is mounted on the nano-colloid generating device according to the plasma method in the liquid and receives the high voltage energy to generate the nano-colloid, A stick-shaped body portion having a space for accommodating liquid therein and having one side open; An outer cap coupled to an open side of the body portion in a lid form and mounted to the nano colloid generating device in a state of being coupled to the body portion; An insert cap coupled to the outcap and having a pair of electrodes connected to an internal electrode to which high voltage energy provided in the nanocolloid generating device is applied; A metal wire attached and connected to the pair of electrodes provided in the insert cap through a pressing method, wherein the nano-colloid particles are generated when high voltage energy is applied; And Stick-shaped liquid injection type cartridge device used in the nano-colloid generating device comprising a; aluminum cap which is sealed by pressing the cap and the entire outer cap and the insert cap in the state in which the out cap and the insert cap is fastened.

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