KR102447273B1 - Sterilization water production device using plasma - Google Patents

Abstract

The present invention provides a sterilizing water production apparatus configured to supply a large amount of high-quality sterilizing water by configuring the plasma to react uniformly and efficiently with a large amount of water. The present invention is a plasma for generating active species by plasma reaction in water by spraying plasma to the water surface by having a water surface forming part in which a water surface is formed by temporarily storing or flowing water therein, and a plasma nozzle facing the water surface. It includes a generator and a driver for moving the surface forming part or the plasma generating part so that the plasma nozzle relatively moves with respect to the water surface.

Description

Sterilization water production device using plasma {STERILIZATION WATER PRODUCING DEVICE USING PLASMA}

The present invention relates to an apparatus for producing sterilizing water using plasma, which is capable of producing a large amount of sterilizing water containing active species such as ozone and OH radicals in water by spraying plasma directly on the water surface and reacting with water. it's about

In recent years, as interest in hygiene issues has increased, use water free from contamination of bacteria and viruses at home or industrial sites, or to sterilize viruses from various devices or parts of the body that people come into contact with, such as hands. The demand for sterilization water, such as the use of water, is increasing.

1 is a device for generating such sterilized water, and is disclosed in Korean Patent Registration No. 10-1069982.

Referring to FIG. 1 , a conventional sterilizing water generator installs two or more discharge cells 1 in water, generates plasma discharge between the discharge cells 1 installed in water, and converts water into sterilizing water. It is configured to sterilize various types of bacteria present in

In order to obtain sterilization water, the discharge current sensing unit 2 and the discharge current sensing unit 2 and It is configured to constantly control the current supplied to the discharge cell 1 by the power control unit 3 .

On the other hand, Figure 2 relates to a conventional flow-through type sterilizing water production apparatus, which is described in Utility Model Registration No. 20-0464612.

Referring to FIG. 2 , the supply of running water and the discharge of sterilizing water can be made by the pressure of running water flowing in connection with a water supply facility, and a running water space 6a surrounded by a case 6 is provided, and the running water space 6a is provided. ) is sterilized by plasma.

That is, water is supplied to the running water space 6a inside the case 6 through the first water pipe 5a, and sterilization is performed by the low-temperature plasma while passing through the low-temperature plasma generating unit 7, and the low-temperature plasma By discharging the sterilized water through the second water pipe 5b, it is possible to continuously sterilize the flowing water.

Looking at the above-mentioned conventional sterilizing water production apparatus, discharge or plasma is generated in water to react plasma with water, but discharge or plasma generation in water is not easy, and in particular, plasma is unstable in flowing water. Because it is easy to become, there is a problem that the reaction of water and plasma cannot be made uniformly and effectively.

Accordingly, there is a problem in that the conventional devices described above are not suitable for sufficiently supplying a large amount of high-quality sterilizing water by uniformly and effectively reacting a large amount of water with the plasma.

The present invention has been devised in view of the above, and an object of the present invention is to provide a sterilizing water production apparatus configured to supply a large amount of high-quality sterilizing water by configuring plasma to react uniformly and efficiently with a large amount of water. .

Accordingly, the apparatus for producing sterilized water according to the present invention includes a water surface forming part in which a water surface is formed by temporarily storing or flowing water therein, and a plasma nozzle facing the water surface, and by spraying plasma to the water surface, plasma in water It characterized in that it comprises a plasma generating unit for generating active species by reaction, and a driver for moving the surface forming unit or the plasma generating unit so that the plasma nozzle moves relative to the water surface.

In addition, in the sterilizing water production apparatus according to the present invention, the water surface forming part is fixed in an up-and-down state and is installed on a cylindrical wall having an inner space, and is installed on the upper end of the cylindrical wall and water flows along the inner surface of the cylindrical wall. and an upper head for falling down, and wherein the plasma generating unit rotates by the driver in a state erected in the inner space along the outer circumferential surface so that a plurality of the plasma nozzles face the water falling from the inner surface of the cylindrical wall. Another feature is that it comprises a nozzle installation structure installed, and a power source for generating plasma from the plasma nozzle toward the water by connecting both electrodes to the plasma nozzle and water falling from the inner surface of the cylindrical wall, respectively.

In addition, in the sterilizing water production apparatus according to the present invention, the water surface forming part has an inner space in an up and down state and rotates by the actuator so that the water in the inner space receives a centrifugal force and flows along the inner surface of the cylindrical wall. The plasma generating unit includes a nozzle installation structure that is fixedly installed in an upright state in the inner space and installed along an outer circumferential surface such that a plurality of the plasma nozzles face water on the inner surface of the cylindrical wall, the plasma nozzle and the cylindrical wall It is another feature to include a power source for generating plasma from the plasma nozzle toward the water by connecting both electrodes to the water on the inner surface of the .

In addition, the apparatus for producing sterilized water according to the present invention includes a container-shaped rotating body having a storage space for temporarily storing water as the water surface forming unit rotates by the actuator, and the plasma generating unit comprises: It is installed on the upper side of the rotating body and includes a fixed structure installed on the lower surface of the plurality of plasma nozzles to face the water in the storage space, and both electrodes are connected to the plasma nozzle and the water in the storage space, respectively, in the plasma nozzle. It is another feature to include a power source to generate a plasma toward the water in the storage space.

In addition, in the sterilizing water production apparatus according to the present invention, the plasma nozzle includes a nozzle hole formed at an end portion for spraying plasma from the inside to the outside, a dielectric formed around the inner periphery of the nozzle hole, and the dielectric inside the dielectric. and a discharge electrode positioned in contact with and installed on the periphery of the nozzle hole, wherein a step by the dielectric is present on a path where the discharge electrode and the nozzle hole are connected, so that plasma is generated from the discharge electrode and sprayed together with the air Another feature is that when ejected through the nozzle hole, plasma is generated to flow along the stepped surface of the dielectric.

The apparatus for producing sterilizing water using plasma of the present invention can generate plasma in the air and water and plasma react at the water surface, so that stable generation of plasma is possible and effective treatment by plasma is also performed at the water surface, so that high-quality sterilizing water can be generated. manufacturing is possible.

In addition, since the surface of the water to be treated and the plasma can react in contact with each other in a wide area, it is possible to manufacture and supply a large amount of sterilizing water.

1 is a configuration explanatory diagram illustrating the configuration of a conventional sterilizing water generator;
2 is a configuration explanatory diagram illustrating the configuration of a conventional flow-through sterilization water production apparatus;
3 is a configuration explanatory diagram showing the configuration of an apparatus for producing sterilized water according to an embodiment of the present invention;
4 is a configuration explanatory diagram showing an enlarged cross-sectional configuration of the upper portion of the sterilizing water production apparatus according to the embodiment of the present invention;
5 is an explanatory view illustrating the configuration and operation of a plasma nozzle in the sterilizing water production apparatus according to an embodiment of the present invention;
6 (a) and (b) are explanatory views explaining the internal configuration and operation of the plasma nozzle in the sterilizing water production apparatus according to the embodiment of the present invention;
7 is an explanatory view for explaining the configuration and operation of the plasma nozzle in which there is no step difference due to the dielectric on the path where the discharge electrode and the nozzle hole are connected.
8 is an explanatory view illustrating an action of spraying plasma to the water surface while the nozzle installation structure rotates in the sterilizing water production apparatus according to an embodiment of the present invention;
9 is a configuration explanatory diagram showing the configuration of an apparatus for producing sterilized water according to another embodiment of the present invention;
10 is a configuration explanatory diagram showing the configuration of an apparatus for producing sterilized water according to another embodiment of the present invention;

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

Referring to FIG. 3 , the apparatus for producing sterilized water according to an embodiment of the present invention includes a water surface forming part 10 in which a water surface S is formed by temporarily storing or flowing water 40 therein, and the water surface S A plasma generating unit 20 for generating active species by plasma reaction in water by spraying plasma to the water surface (S) by having a plasma nozzle 21 facing the water surface (S), and a plasma nozzle ( 21) includes a driver 30 for moving the plasma generating unit 20 to move relatively.

The water surface forming unit 10 is a part that forms a water surface S by supplying water 40 that is a treatment target of the plasma P, and the water 40 is temporarily stored or flows inside the water surface S. to form

The water surface forming part 10 shown in FIGS. 3 and 4 forms a water surface S by flowing water 40 up and down from the inside, and the cylindrical wall 13 is fixed in an up and down state and has an inner space. ) and an upper head 11 installed on the upper end of the cylindrical wall 13 and dropping water 40 along the inner surface of the cylindrical wall 13 to flow down.

The cylindrical wall 13 is a portion on which the water 40 falls on the inner surface, and is formed of a conductor such as a metal, and the electrode 27 of the power source is connected to the cylindrical wall 13 .

This is a structure in which the cylindrical wall 13 and the water 40 in contact with the inner surface are electrically connected to each other so that the water 40 serves as a counter electrode.

The upper head 11 is a portion coupled to the upper end of the cylindrical wall 13 erected up and down, and the water 40 supplied by the water supply pipe 14 is temporarily stored while the water 40 is transferred to the cylindrical wall 13. discharged into the inner side of

That is, the water discharge hole 12 is formed on the inner surface of the cylindrical wall 13 so that the water 40 inside the upper head 11 rides on the inner surface of the cylindrical wall 13 and falls.

A plurality of water discharge holes 12 of the upper head 11 are installed at regular intervals along the circumference of the cylindrical wall 13, so that water 40 rides and flows from the entire surface of the inner surface of the cylindrical wall 13. let it be

An air outlet 17 is formed in the upper head 11 to connect the inner space of the cylindrical wall 13 and the inner space of the upper head 11 so that air can be discharged into the inner space of the upper head 11, , the air in the inner space of the upper head 11 is discharged to the outside through the air exhaust pipe 16 of the upper head 11 .

The air outlet 17 is installed to discharge the air ejected from the plasma nozzle 21 to be described later to the outside, and is fixed to the bottom surface inside the upper head 11 so as to communicate with the inside of the cylindrical wall 13 . By becoming a cylindrical column shape in which the upper end is located at a position higher than the water surface S inside the upper head 11 in the state, air can move upwards of the water surface S in the inner space of the cylindrical wall 13 .

An activated carbon filter, etc. is installed in the air discharge pipe 16 through which air is discharged to the outside, so that harmful gases such as ozone gas by plasma P can be removed.

On the other hand, the plasma generating unit 20 is provided with a plasma nozzle 21 facing the water surface (S) to inject plasma (P) to the water surface (S) to generate active species such as ozone and OH radicals by plasma reaction in water. part of doing it.

3 and 4, the plasma generating unit 20 is rotated by the driver 30 in a state of being erected in the inner space of the cylindrical wall 13, and a plurality of plasma nozzles 21 are formed on the cylindrical wall ( 13) a nozzle installation structure 23 installed along the outer circumferential surface to face the water 40 falling from the inner surface, and positive electrodes to the plasma nozzle 21 and water 40 falling from the inner surface of the cylindrical wall 13 26 and 27 are connected to each other and include a power source (not shown) for generating plasma P from the plasma nozzle 21 toward the water 40 .

The nozzle installation structure 23 is preferably a cylindrical body, and the plasma nozzles 21 are distributed at regular intervals along the outer peripheral surface thereof.

The nozzle installation structure 23 has an upper end supported by a bearing so as to be rotatable by an upper head 11 , and a lower end is also supported by a bearing on the lower end support 19 .

Accordingly, when the nozzle installation structure 23 is rotated by the upper actuator 30, the plasma nozzle 21 moves relative to the water surface S of the falling water 40 and faces the water surface S. (P) injection is made.

The lower pedestal 19 serves to support the nozzle installation structure 23 so as to be rotatable, and collects water 40 that falls on the cylindrical wall 13 , that is, sterilizing water, and sterilizes it through the connection pipe 15 . It is moved to a facility where the water is used or stored.

The actuator 30 includes a motor and is coupled to the rotation shaft 33 of the nozzle installation structure 23 and the shaft coupling part 32 on the upper side of the upper head 11 to generate the rotation of the nozzle installation structure 23 . .

The power is connected to the plasma nozzle 21 and the both electrodes 26 and 27 to the water 40 falling from the inner surface of the cylindrical wall 13, respectively, so that the plasma (P) from the plasma nozzle 21 toward the water 40 ), one electrode 26 is connected to the shaft coupling part 32 so as to be connected to the inside of the plasma nozzle 21, and the other electrode 27 is attached to the outer surface of the cylindrical wall 13. make electrical contact.

In addition, the plasma generator 20 includes an air supply device 24 for supplying air to the inside of the plasma nozzle 21 .

In the air supply device 24 , an air supply pipe 24a is installed on the bottom support 19 so that air is introduced into the nozzle installation structure 23 , and air is sprayed through each plasma nozzle 21 .

The air injected through the plasma nozzle 21 pushes and discharges the plasma, and the injected air may be discharged to the outside through the above-described air outlet 17 .

On the other hand, the plasma nozzle 21 is installed so that a plurality of the nozzle installation structure 23 is distributed to spray the plasma (P) toward the water surface (S).

Referring to FIGS. 5 and 6 , the plasma nozzle 21 includes a nozzle hole 21a that is formed at an end and sprays plasma from the inside to the outside, and a dielectric 21c formed around the inner periphery of the nozzle hole 21a. ) and a discharge electrode 21d which is located inside the dielectric 21c and is in contact with the dielectric 21c and is installed around the nozzle hole 21a.

Specifically, the dielectric 21c is formed in an annular shape and arranged around the nozzle hole 21a in the inside of the plasma nozzle 21, and the annular discharge electrode 21d is positioned further inside to be laminated with the dielectric 21c. . Here, the inner side means the side farther from the nozzle hole 21a toward the inner side of the plasma nozzle 21 , and the discharge electrode 21d is connected to the power source by the connection terminal 26a.

At this time, based on the nozzle hole 21a, the discharge electrode 21d is installed to be disposed at a position more radially outward than the dielectric 21c, or a discharge electrode having an annular shape than the center hole of the annular dielectric 21c ( The central hole of 21d) is formed to be larger and stacked.

This structure is such that the discharge electrode 21d does not directly face on the shortest distance connected to the water 40, which is the opposite electrode, and the dielectric 21c on the path where the discharge electrode 21d and the nozzle hole 21a are connected. When the plasma (P) is generated from the discharge electrode (21d) and ejected into the nozzle hole (21a) together with the injected air, the plasma (P) flows along the stepped surface of the dielectric (21c). make it happen

6 (a) is a structure in which the body 21b of the plasma nozzle 21 forming the nozzle hole 21a is formed of a dielectric 21c, so that a separate dielectric 21c is not installed, and in FIG. b) shows a structure in which the body 21b of the plasma nozzle 21 is made of metal and a separate dielectric 21c is installed therein.

Referring to (a) and (b) of Figure 6, both of the discharge electrode 21d and the opposite electrode, water 40, are connected by the shortest distance, the step of the dielectric 21c exists on the discharge electrode 21d. The generated plasma P is configured to be sprayed into the nozzle hole 21a together with the air sprayed in the form of flowing along the step of the dielectric 21c.

Such a type of discharge has the advantage of lowering the discharge starting voltage and inducing arc discharge, thereby reducing electrode consumption.

In addition, since multiple discharges toward the water 40 can be induced from the annular discharge electrode 21d through the nozzle hole 21a, the area in which the plasma P is generated around the nozzle hole 21a is wide.

7 shows a structure in which there is no step difference due to the dielectric 21c on the path where the discharge electrode 21d and the nozzle hole 21a are connected. Since the discharge can occur without interruption of the dielectric 21c toward 40, the single discharge P1, which is a single discharge in the form of a spark discharge, easily occurs.

In the configuration shown in FIG. 7 , due to the single discharge P1 in the form of a spark discharge, the region in which the plasma P is generated is localized, the discharge initiation voltage is high, and there is a problem in that the electrode is severely consumed.

Hereinafter, a process for producing sterilized water by the sterilizing water producing apparatus according to the above-described configuration will be described below.

When water 40 is supplied to the inside of the upper head 11 through the water supply pipe 14 of the upper head 11, the water 40 rides on the inner surface of the cylindrical wall 13 through the water discharge hole 12. Water 40 flows down.

At the same time, the actuator 30 rotates the nozzle installation structure 23 , and supplies air to the plasma nozzle 21 by the air supply device 24 , and power is supplied to generate plasma P .

Accordingly, as the nozzle installation structure 23 rotates, the plasma P is generated toward the water surface S through the plasma nozzle 21 .

As shown in FIG. 5, the plasma P generated through the plasma nozzle 21 is sprayed toward the water surface S, and the water 40 and air together plasma react at the water surface S to generate active species such as ozone and OH radicals. created and penetrated into the water.

Accordingly, since the water 40 contains active species such as ozone and OH radicals, it not only sterilizes itself but also has sterilization power, so it can be used as sterilizing water.

Referring to FIG. 8 , since the plasma nozzle 21 continues to move relatively with respect to the water surface S while the nozzle installation structure 23 rotates, the plasma P generated in the plasma nozzle 21 is at the water surface. It moves while being drawn along (S), and in the process of moving, a wide area of the water surface (S) is plasma-reacted to generate a wide range of active species such as ozone and OH radicals in the water.

Since the plasma nozzle 21 continuously moves relative to the water surface S and continuously generates a plasma reaction with respect to a wide water surface S, it is suitable for the production and continuous supply of a large amount of sterilizing water.

In addition, in this embodiment, the plasma (P) is not generated in water, but in the air, so that water and air are plasma-reacted together at the water surface (S) to penetrate the active species in water, so that the plasma (P) in water Compared to the generation method, plasma P can be generated stably, and high-quality sterilizing water can be produced due to a uniform and effective plasma reaction.

Even if there is no supply of air, discharge from the plasma nozzle 21 toward water can be made and sterilization water can be produced at the water surface, but the reaction efficiency is relatively low.

The following describes an apparatus for producing sterilized water according to another embodiment of the present invention.

9 shows a configuration in which the actuator 30 rotates the water surface forming unit 10 so that the plasma nozzle 21 moves relatively with respect to the water surface S. Referring to FIG.

Referring to FIG. 9 , in this embodiment as well as in the above-described embodiment, the water surface forming unit 10 has a cylindrical wall 13 through which water 40 flows along the inner surface in an up and down state, and a plasma generating unit Reference numeral 20 includes a nozzle installation structure 23 and a power source.

The nozzle installation structure 23 is fixedly installed in a state of being erected in the inner space of the cylindrical wall 13, and a plurality of plasma nozzles 21 are installed along the outer circumferential surface so as to face the water 40 of the inner surface of the cylindrical wall 13, , the power source is connected to generate plasma P from the plasma nozzle 21 toward the water 40 by connecting both electrodes to the water 40 on the inner surface of the plasma nozzle 21 and the cylindrical wall 13, respectively. .

However, in this embodiment, since the cylindrical wall 13 is rotated in a state in which the nozzle installation structure 23 is fixed, the actuator 30 installed on the lower side rotates the rotation shaft of the cylindrical wall 13 and the nozzle installation structure ( 23) is fixed.

The upper head 11 coupled to the upper end of the nozzle installation structure 23 is separated from the cylindrical wall 13 at a predetermined interval so that the cylindrical wall 13 can be rotated, but the water discharge hole 12 of the upper head 11 is ) falling through the water 40 is arranged to run down the inner surface of the cylindrical wall (13).

Water 40 flowing down on the inner surface of the cylindrical wall 13 is in close contact with the inner surface by centrifugal force, but the rotational speed is not high, so the flow state of falling to the lower side is maintained without departing to the outside.

At the lower end of the cylindrical wall 13, a lower support 19 coupled to rotate together with the cylindrical wall 13 is installed, and a discharge pipe 18 is installed in the lower support 19, and discharged from the discharge pipe 18 A collection tank 60 for collecting sterilizing water is installed. The upper wall of the collection tank 60 is installed to surround the rotating discharge pipe 18 from the outside, so that the sterilizing water of the discharge pipe 18 may collide with the top wall and be collected.

Meanwhile, FIG. 10 shows an apparatus for producing sterilized water according to another embodiment of the present invention.

Referring to FIG. 10 , the water surface forming unit 110 includes a container-shaped rotating body 112 having a storage space for temporarily storing the water 40 as rotated by the driver 130 , and plasma The generator 120 includes a fixed structure 124 installed on the upper side of the rotating body 112 and installed on the lower surface of the plurality of plasma nozzles 121 to face the water 40 of the storage space.

In addition, the power supply is such that both electrodes 126 and 127 are respectively connected to the plasma nozzle 21 and the water 40 in the storage space to generate plasma P from the plasma nozzle 121 toward the water 40 in the storage space. is composed

Even in this structure, the plasma nozzle 121 is moved relative to the water surface S by the rotation of the rotating body 112, and the width of the water surface S is caused by the plasma P sprayed from the plasma nozzle 121. Plasma reaction can be made in a wide area.

Although the preferred embodiment of the present invention has been described above, the above embodiment is only one embodiment within the scope of the technical spirit of the present invention, and for those skilled in the art, within the technical spirit of the present invention Of course, other modified implementations are possible.

10; sleep formation unit 11; top head
12; water outlet 13; cylindrical wall
14; water supply line 15; connector
16; air exhaust pipe 17; air outlet
18; discharge tube 20; Plasma generator
21; plasma nozzle 21a; nozzle ball
21b; body 21c; dielectric
21d; discharge electrode 23; Nozzle installation structure
24; air supply 24a; air supply pipe
26,27; electrode 30; actuator
32; shaft coupling part 33; rotation shaft
40; water 60; collector
110; sleep forming unit 112; rotating body
120; Plasma generator 121; plasma nozzle
124; fixed structures 126,127; electrode
130; actuator

Claims (5)

A water surface forming part in which water is temporarily stored or flows inside to form a water surface;
A plasma generating unit for generating active species by plasma reaction in water by spraying plasma to the water surface by having a plasma nozzle facing the water surface;
a driver for moving the water surface forming unit or the plasma generating unit to relatively move the plasma nozzle with respect to the water surface;
and a power source for generating plasma from the plasma nozzle toward the water by connecting both electrodes to the water of the plasma nozzle and the water surface forming part, respectively,
The plasma generating unit includes an air supply device for supplying air to the inside of the plasma nozzle,
The plasma nozzle is
A nozzle hole formed at the end to spray plasma from the inside to the outside,
a dielectric formed around the inner periphery of the nozzle hole;
A discharge electrode positioned in contact with the dielectric from the inside of the dielectric and installed around the nozzle hole,
In order for the discharge electrode and water to not directly face each other on the shortest distance where the discharge electrode is connected to water, the step difference by the dielectric is blocked on the path where the discharge electrode and the nozzle hole are connected, so that plasma is generated at the discharge electrode When the air is ejected from the nozzle hole together with the sprayed air, plasma is generated in the form of flowing along the stepped surface of the dielectric. According to claim 1,
The water surface forming unit includes a cylindrical wall that is fixed in an up-and-down state and has an internal space, and an upper head installed on the upper end of the cylindrical wall and dropping water along the inner surface of the cylindrical wall,
The plasma generating unit comprises a nozzle installation structure installed along an outer circumferential surface such that a plurality of the plasma nozzles are installed along an outer circumferential surface to face water falling from the inner surface of the cylindrical wall as rotated by the driver in a state of being erected in the inner space. sterilization water production device According to claim 1,
The water surface forming unit has an inner space in a vertical standing state and by rotating by the actuator, the water in the inner space is provided with a cylindrical wall that flows along the inner surface while receiving centrifugal force,
The plasma generating unit is fixedly installed in a state of being erected in the inner space, and a plurality of the plasma nozzles are installed along the outer circumferential surface so as to face the water on the inner surface of the cylindrical wall. According to claim 1,
The water surface forming unit includes a container-shaped rotating body having a storage space for temporarily storing water as rotated by the actuator,
The plasma generating unit is installed on the upper side of the rotating body and a plurality of the plasma nozzles are installed on the lower surface to face the water in the storage space sterilizing water production apparatus, characterized in that it comprises a fixed structure delete

Images