KR101632640B1 - Apparatus for discharged ozone recycling - Google Patents

Abstract

The present invention provides an apparatus for recycling discharged ozone, comprising: a water supply unit; a water storage unit for receiving water from the water supply unit and storing the water; a water transfer pipe for transferring the water stored in the water storage unit; a first and a second ozone supply unit connected to the water transfer pipe, and guiding ozone to be dissolved in the water flowing in the water transfer pipe; an ozone generation unit for generating ozone and supplying the ozone to the first and the second ozone supply unit; a first and a second discharged ozone supply unit connected to the water transfer pipe, and guiding the ozone to be dissolved in the water flowing in the water transfer pipe; and a sterilized water storage unit for storing the water in which the ozone is dissolved, wherein the first and the second ozone supply unit are spaced apart from each other at a first space angle; the first and the second discharged ozone supply unit are spaced apart from each other at a second space angle; and a first angle space middle line, which is a spaced middle line of the spaced first space angle of the first and the second ozone supply unit, and a second angle space middle line, which is a spaced middle line of the spaced second space angle of the first and the second discharged ozone supply unit, are spaced apart from each other. The purpose of the present invention is to provide sterilized water by using discharged ozone generated in a water sterilizer using ozone.

Description

[0001] APPARATUS FOR DISCHARGED OZONE RECYCLING [0002]

The present invention relates to an ozone recycling apparatus.

Food poisoning accidents due to food poisoning accidents caused by unsanitary treatment of food, contamination by microorganisms present in the hands of processing companies and handlers using ground water and deep seawater may occur. In addition, there is an urgent need for an efficient cleaning method in the treatment of food materials requiring sterilization. Generally, tap water is treated with sterilization and removal of foreign substances in several steps in a water purification plant, but the rate of secondary contamination is high through other treatment such as chlorine, and the time of transfer from each water purification plant to each home, This may cause problems with the propagation of bacteria due to secondary pollution.

On the other hand, ozone has long been used safely in many fields, including large water purification plants in Europe and USA.

Unlike chlorine, such ozone is not produced harmful residues (secondary contaminants) when used as an oxidizing agent, and has a strong sterilizing power to remove bacteria and viral bacteria and has strong bleaching power. There is a growing interest in ozone water in order to overcome pollution problems in living water and obtain more beneficial substances. However, there is not enough technology available to easily obtain sterilized ozone water in living facilities.

Korean Patent Laid-Open Publication No. 2015-0028155 (Mar. 13, 2013)

Embodiments of the present invention aim to provide sterilized water by using ozone generated in a sterilizing machine using ozone.

In addition, embodiments of the present invention aim to provide smooth mixing of water and ozone by supplying ozone in different directions in the course of manufacturing sterilized water by recycling ozone.

Embodiments of the present invention also aim to provide sufficient mixing of ozone in the water through the ozone supply part and the ozone supply part.

In addition, embodiments of the present invention aim to provide the dissolved concentration of sterilized water through the dissolved concentration control display window as time information.

It is another object of the present invention to provide a detachable ozone supply unit and a ozone supply unit.

According to an embodiment of the present invention, a water supply unit; A water storage unit for receiving water from the water supply unit and storing the water; A water conveyance pipe for conveying the water stored in the water storage section; A first ozone supply unit and a second ozone supply unit connected to the water supply pipe and guiding the ozone to dissolve ozone in the water flowing in the water supply pipe; An ozone generator for supplying ozone to the first ozone supply unit and the second ozone supply unit and generating ozone; A first ozone supply unit and a second ozone supply unit connected to the water supply pipe and guiding the ozone to dissolve ozone in the water flowing inside the water supply pipe; A sterilizing water reservoir for storing ozone-dissolved water; The first ozone supply part and the second ozone supply part are angularly spaced by a first separation angle, and the first ozone supply part and the second ozone supply part are angularly spaced by a second separation angle, and the distance between the first ozone supply part and the second ozone supply part A first angular spacing intermediate line that is a spaced median line of the first separation angle and a second intermediate spacing line that is a spaced median line of spaced second spacing angles of the first and second ozonizer feeds, The ozone recycling apparatus is provided.

Embodiments of the present invention can provide sterilized water using ozone generated from sterilization water using ozone.

Embodiments of the present invention can provide smooth mixing of water and ozone by supplying ozone in different directions in the course of manufacturing sterilized water by recycling ozone.

In addition, the ozonizer recycling apparatus according to the present invention can provide sufficient mixing of ozone to the water through the ozonizer and the ozonizer.

In addition, the ozonizer recycling apparatus according to the present invention can provide the dissolved concentration of sterilized water through the dissolved concentration control display window as time information.

The apparatus for recycling ozone according to the present invention can provide an ozone supply unit and a ozone supply unit which are detachable.

1 is a schematic view for explaining an ozone recycling apparatus according to an embodiment of the present invention;
2 is a cross-sectional view for explaining a joining structure of a supply part of the ozonizer recycling apparatus according to an embodiment of the present invention;
3 is a cross-sectional view for explaining installation intervals between respective supply units of the ozone recycling apparatus according to an embodiment of the present invention
4 is a cross-sectional view for explaining the installation angle between each supply part of the ozone recycling apparatus according to the embodiment of the present invention
5A and 5B are cross-sectional views illustrating a screw type detachment structure of a transfer part and a water supply pipe of the ozonizer recycling apparatus according to an embodiment of the present invention
6A and 6B are cross-sectional views for explaining a flange type desorption structure of a transfer part and a water supply pipe of the ozonizer recycling apparatus according to an embodiment of the present invention
7 is a perspective view for explaining the arrangement of the supply portion of the ozone recycling apparatus according to the embodiment of the present invention.
8 is a view for explaining supply angle separation of the ozone recycling apparatus according to an embodiment of the present invention;

Hereinafter, specific embodiments of the present invention will be described with reference to the drawings. However, this is merely an example and the present invention is not limited thereto.

In the following description, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear. The following terms are defined in consideration of the functions of the present invention, and may be changed according to the intention or custom of the user, the operator, and the like. Therefore, the definition should be based on the contents throughout this specification.

The technical idea of the present invention is determined by the claims, and the following embodiments are merely a means for effectively explaining the technical idea of the present invention to a person having ordinary skill in the art to which the present invention belongs.

The connection pipe 110, the water pipe 300, the reflux pipe 210, the ozone transfer pipe 420, the supply unit 500, the transfer unit 700, and the supply hole 701 are circular However, the present invention is not limited thereto, and it is of course possible to modify various embodiments so long as it is a shape capable of forming a flow of fluid.

1, one ozone supply unit 510 is coupled to the first transfer unit 710, but a plurality of ozone supply units 510a and 510b may be coupled to the first transfer unit 710. 2 to 6, two ozone supplying units 510a and 510b are coupled to the first transferring unit 710. As shown in FIG. However, the present invention is not limited thereto, and one ozone supply unit (not shown) or three or more ozone supply units (not shown) may be coupled to the first transfer unit 710.

Similarly, in FIG. 1, one ozone supply unit 520 is coupled to the second transfer unit 720, and two ozone supply units 520a and 520b are shown in FIG. 7 and FIG. 8, respectively. However, the present invention is not limited to this, and it goes without saying that three or more ozone supply units may be combined.

The structure in which the first transfer portion 710 and the ozone supply portions 510a and 510b are coupled to each other will be mainly described and the structure in which the ozone supply portion 520 is coupled to the second transfer portion 720 will be described in detail .

1 is a schematic view for explaining an ozone recycling apparatus according to an embodiment of the present invention.

The apparatus for recycling ozone according to one embodiment includes a water supply unit 100, a water storage unit 200, a water supply pipe 300, a sterilizing water supply liner 400, a supply unit 500, an ozone generator 600, and a transfer unit 700 ).

The water supply unit 100 may be, for example, a faucet or a water tank when the water is water. The water supply unit 100 is connected by the connection pipe 110 to supply water to the water storage unit 200, The water passing through the water storage unit 110 may be connected to the water storage unit 200. At this time, the connection pipe 110 may be provided with a valve 111 on the connection pipe 110, and the opening and closing of the connection pipe 110 may be controlled by operating the valve 111 of the user.

The water supplied to the water storage unit 200 through the connection pipe 110 can be transferred through the water supply pipe 300. The water conveyed through the water conveying pipe 300 can pass through the conveying unit 700. Here, the transfer unit 700 includes a first transfer unit 710 and a second transfer unit 720, and the water can pass through the first transfer unit 710 first.

The first transfer part 710 is connected to the supply part 500. The first transfer part 710 may include a supply part 500 and a supply part 500 which may include an ozone supply part 510 and a ozone supply part 520 and is connected to the first transfer part 710, Is referred to as an ozone supply unit 510 and a supply unit 500 connected to the second transfer unit 720 is referred to as a ozone supply unit 520. [

Since the transfer unit 700 and the supply unit 500 are connected to each other in correspondence with each other as in this structure, the numbers may be the same. Although two feeders 710 and 720 and two feeders 510 and 520 are illustrated in this embodiment, the number of feeders may be modified to various embodiments.

The first transfer part 710 is connected to one side of the ozone supply part 510 and the other side of the ozone supply part 510 can be connected to the ozone supply pipe 610. The ozone supply part 510 has a suction port 511 . The ozone supply pipe 610 connects the ozone generator 600 and the ozone supply unit 510 and guides the ozone generated by the ozone generator 600 to the ozone supply unit 510 through the ozone supply pipe 610 .

Here, the ozone generator 600 is an apparatus for generating ozone through electric discharge. The ozone generator 600 includes a discharge tube (glass, ceramic) sandwiched between electrodes, and applies a high voltage to the discharge tube to collide a large number of electrical energies between + and - When air or oxygen is passed through it, oxygen (O2) is divided into two O by collision with electrical energy, and a method of combining ozone (2) with some unseparated oxygen can be used .

The ozone 2 generated in the ozone generator 600 can be transferred to the ozone supply unit 510 along the ozone supply pipe 610. Since the ozone supply unit 510 is connected to the first transfer unit 710, the ozone 2 transferred to the ozone supply unit 510 is transferred to the first transfer unit 710. The process of transferring the ozone from the ozone supply unit 510 to the first transfer unit 710 is performed by the venturi effect. The process of moving the ozone 2 by the venturi effect will be described later with reference to FIG.

When the ozone 2 generated in the ozone generator 600 is moved to the ozone supply part 510 and flows into the water transportation pipe 300 to be dissolved in the water 1, . Here, the catalyst may be one or more of chlorine, chlorine dioxide, potassium manganate, hydrogen peroxide, and a pH modifying catalyst.

The water (1) in which the ozone (2) is dissolved together with the catalyst can be transferred to the second transfer part (720) through the water supply pipe (300). The water 1 transferred to the second transfer part 720 can be supplied with the ozone 2 from the ozone supply part 520 connected to the second transfer part 720.

Since the ozone supply unit 520 is connected to the second transfer unit 720, the ozone 2 transferred to the ozone supply unit 520 is transferred to the second transfer unit 720. The process of transferring the ozone 2 from the ozone supply unit 520 to the second transfer unit 720 is performed by the venturi effect. The process of moving the ozone 2 by the venturi effect will be described later with reference to FIG.

When the ozone 2 is moved to the ozone supply unit 520 and flows into the water supply pipe 300 to be dissolved in the water 1, the ozone supply unit 520 is connected to the ozone supply unit 510 and the water supply pipe 300 Of the first and second axes. For example, as shown in FIGS. 7 and 8, the ozone supply portions 520a and 520b may be angularly spaced from the ozone supply portions 510a and 510b. This structure, which is located at different angles, causes unevenness in the direction of supply of the ozone 2 introduced by the venturi effect, so that vortex or turbulence occurs in the water 1 inside the water conveyance pipe 300, It is possible to induce smooth mixing of the water (2) and the water (1).

Then, the water 1 mixed with the ozone 2 flows into the sterilizing water reservoir 400 through the separate swirling agitator 340. The sterilizing water table 400 includes a discharge tube 460 through which the sterilizing water 1a is discharged to provide sterilized water 1a to the user, a reflux tube 210 through which the sterilizing water 1a is refluxed, The ozone can be connected to the delivery pipe 420. The discharge pipe 460 includes a discharge pipe valve 461 and a user can control the opening and closing of the discharge pipe 460 by operating the discharge pipe valve 461. [

The sterilizing water table 400 may also include a concentration indicating window 410 that allows the user to transmit the ozone dissolution concentration of the sterilizing water 1a inside the sterilizing water table 400 to the visual information. The user can check the concentration display window 410 and return the sterilized water 1a in the sterilization water reservoir 400 to the water storage unit 200 so that the ozone dissolution process can be repeated if the ozone concentration is low.

The reflux sterilization water 1a may be transferred to the water storage 200 through the reflux tube 210 connecting the sterilization water reservoir 400 and the water reservoir 200. The sterilized water 1a flowing into the water storage part 200 may be mixed with the water 1 and moved in the direction of the sterilization water storage part 400 according to the guidance of the water supply pipe 300. The transfer of the sterilizing water 1a may be possible by the user checking the concentration display window 410 and controlling the opening and closing of the reflux pipe 210 by operating the reflux pipe valve 211 located in the reflux pipe 210.

On the other hand, when the sterilized water 1a in the sterilized water reservoir 400 is sufficiently dissolved in the ozone 2 and the residual ozone 2 is present in the air inside the sterilization water reservoir 400, the remaining ozone 2 The remaining ozone 2 can be transferred through the ozone transfer pipe 420 to the ozone supply unit 520.

However, when the ozone recycling apparatus is in operation, the remaining ozone 2 can be transferred to the ozone supply unit 520 through the ozone conduction pipe 420. If the ozone recycling apparatus is not in operation, (Not shown) so that the ozone state can be decomposed and discharged to the outside. Here, the flow of the residual ozone 2 during operation or unfiltering of the ozone recycling apparatus can be determined by a three-way valve (not shown) located in the ozone transfer pipe 420.

During the operation of the ozone recycling apparatus, the remaining ozone (2) can be passed through the gas-liquid separator (440) located in the ozone transfer pipe (420). Therefore, when the ozone recycling apparatus is in operation, the three-way valve (not shown) and the gas-liquid separator 440 are sequentially disposed in a path where the remaining ozone 2 is moved in the direction of the ozone supply unit 520 through the ozone transfer pipe 420 Lt; / RTI >

The remaining ozone 2 guided by the ozone transfer pipe 420 is transferred to the ozone supply unit 520 and flows into the second transfer unit 720 by the water 1 flowing in the water supply pipe 300, 2) and the water (1) can be performed. The secondary water-dissolved water (1) can be introduced into the sterilization water reservoir (400) after smooth mixing by the vortex stirring part (340). Here, the vortex agitator 340 generates a vortex in the water 1 previously mixed with the ozone 2, so that the mixing can be smoothly performed.

In the flow of the water 1, the process of dissolving the ozone 2 and the water 1 is omitted in the above description. The process of dissolving the ozone 2 and the water 1 will be described later with reference to Fig.

2 is a view for explaining a coupling structure of a supply part 500 of the ozonizer recycling apparatus according to an embodiment of the present invention.

The first transfer part 710 may be provided with supply holes 701 and 705 at portions connected to the ozone supply parts 510a and 510b. The ozone 2 in the ozone supply portions 510a and 510b may be introduced through the supply holes 701 and 705 and may be mixed and dissolved in the water 1 in the water conveyance pipe 300.

Here, the ozone supply units 510a and 510b may be selected and used as long as they can supply ozone according to the movement of the water 1 in the form of a venturi tube or an orifice. Hereinafter, the case where the ozone supply units 510a and 510b are provided in the form of a venturi pipe will be mainly described.

The speed of the water 1 inside the water transport pipe 300 forms a pressure difference between the inside of the ozone supply parts 510a and 510b and the inside of the water transportation pipe 300 so that the ozone 2 inside the ozone supply parts 510a and 510b Can be joined to the flow of the water (1).

The first transfer part 710 may be formed with a throttling part 750 having a reduced diameter and a predetermined length extending to a relatively small diameter and supply holes 701 and 705 are formed in the throttling part 750 . The small diameter here can determine the speed at which the water 1 flows in the throttling portion 750 and the speed of the water 1 can cause a pressure difference inside the first transfer portion 710 and inside the ozone supply portions 510a and 510b This can be a factor.

Here, as described above, the ozone supply unit 520 may be coupled to or formed in the second transfer unit 720 in the same manner. 1, the ozone 2 transferred from the sterilizing water reservoir 400 through the ozone transfer pipe 420 can be transferred to the ozone supply unit 520, and the transferred ozone 2 may be combined and mixed with the flow of the water 1 in the ozone supply part 520. [ On the other hand, the ozone supply unit 510 and the ozone supply unit 520 may have different ozone supply capacities. Thereby, each of the supply units 510 and 520 can guide different amounts of ozone 2 in accordance with the desired dissolving capacity of the ozone 2. The amount of ozone 2 differs depending on the concentration of ozone 2 in the water conveyance pipe 300 because the concentration of ozone 2 in the water 1 may vary depending on the position in the water conveyance pipe 300, May be possible.

3 is a view for explaining the arrangement of the supply unit 500 of the ozonizer recycling apparatus according to an embodiment of the present invention. When two or more ozone supply parts 510a and 510b are arranged in series on the first transfer part 710, they are spaced apart from each other while forming a predetermined installation space b between the ozone supply parts 510 . Such an installation spacing b may be formed with an installation spacing b of at least 10 mm.

If the distance between the ozone supply portions 510a and 510b is less than 10 mm, the generation of vortex or turbulence due to the supply of ozone is increased and the flow of the flow rate may not be smooth. The ozone supply portions 510a and 510b ) May be spaced by at least 10 mm. Further, the distance between the ozone supply units 510a and 510b may be selected by a person skilled in the art within a range of 10 mm or more considering the diameter of the water transportation pipe 300 and the amount of water supplied, have. For example, the distance between the ozone supply portions 510a and 510b may be 30 mm or less.

When the ozone supply unit 510 and the ozone supply unit 520 are coupled to the first transfer unit 710 and the second transfer unit 720, The space between the ozone supply unit 510 and the ozone supply unit 520 may be maintained at 15 cm or more to avoid a decrease in pressure due to the turbulence or vortex due to the delay of the flow rate of the water 1. The spacing between the ozone supply unit 510 and the ozone supply unit 520 may be selected by a person skilled in the art in consideration of the occupied area of the equipment, and may be, for example, 40 cm or less.

The efficient mixing and dissolution process of the ozone 2 and the water 1 is described by keeping the predetermined installation interval b with reference to FIG. Hereinafter, referring to FIG. 4, an efficient mixing and dissolution process between the ozone 2 and the water 1 will be described through a structure other than the installation space b.

4 is a cross-sectional view for explaining an installation angle (a in FIG. 4, 2θ in FIG. 8) between the ozone supply units 510a and 510b of the ozonizer recycling apparatus according to an embodiment of the present invention. In the following description, "angular spacing" is used to express that angles are combined with each other. Specifically, "angular spacing" means a case where two or more ozone supply portions 510a and 510b are angularly shifted from each other (refer to FIGS. 7 and 8).

The ozone supply parts 510a and 510b may be arranged in series in the longitudinal direction in the first transfer part 710. [ The ozone supply portions 510a and 510b may be angularly spaced about the axis of the first transfer portion 710 and the angle of separation may be a predetermined installation angle (a, 2?). For example, the predetermined installation angle (a, 2?) May be 30 to 180 degrees. The installation angles a and 2θ are set such that the ozone 2 moved from the ozone supply portions 510a and 510b to the transfer portion 710 is mixed with the water 1 flowing in the water conveyance pipe 300, Structure.

When the installation angle (a, 2?) Is 30 degrees or more as described above, the ozone supply parts 510a and 510b may be angularly spaced, Or the occurrence of turbulence. However, when the installation distance b of the ozone supply parts 510a and 510b is less than 10 mm, the generation of vortex or turbulence due to the supply of the ozone 2 is increased and flow of the flow rate may not be smooth. 510a, 510b may be spaced apart by 10 mm or more. On the other hand, the installation angle (a, 2 [theta]) may be at most 180 degrees, which is the case where the ozone supply parts 510a and 510b face each other.

The ozone supply unit 510 and the ozone supply unit 520 may be separated from each other owing to the pressure difference due to the speed of the water 1 flowing into the water conveyance pipe 300. [ The ozone 2 can be mixed by the venturi effect that joins the flow of the water 1. That is, the pressure of the water 1 is lowered by the velocity of the water 1 (Bernoulli effect) when the water 1 passes through the first transfer part 710, A pressure difference is generated between the water (1). Therefore, the ozone 2 can move to the region of the water 1 having a relatively low pressure in the region on the ozone 2 side where the pressure is relatively increased.

Thus, the ozone 2 inside the ozone supply units 510a and 510b can join with the water 1 flowing in the first transfer unit 710. [ On the other hand, irregular flow occurs due to discontinuous collision between the ozone 2 and the water 1, change of the wire, and the like in the merging process. Such irregular flow may cause turbulence or turbulence in the water 1, which may increase the mixing efficiency of the water 1 and the ozone 2. [

Likewise, the ozone 2 inside the ozone supply part 520 can be mixed with the water 1 inside the second transfer part 720 as well. The ozone supply unit 510a and the ozone supply unit 520 are spaced from each other by an installation angle a and 2θ so that the ozone 2 flows into the first transfer unit 710 from the ozone supply units 510a and 510b. And the point of the turbulent flow generated by the ozone 2 flowing into the second conveyance part 720 from the ozone supply part 520 to the inside of the water conveyance pipe 300 based on the axis of the water conveyance pipe 300 The turbulence or eddy current can be generated at a plurality of points of the flow path section of the transfer section 700 by forming two or more turbulent flow generation points. Thereby, the mixing efficiency of the ozone 2 and the water 1 in the transfer part 700 can be improved. 8) between the ozone supply parts 510 and 520a and the ozone supply parts 520a and 520b is equal to an average installation line of the ozone supply part 520 and the ozone supply parts 510a and 510b 7 and 8 CC and DC). The term " average installation line " (CC, DC) means that, for example, when the ozone supply portions 510a and 510b or the ozone supply portion 520 include two venturi pipes angularly spaced from each other, It can mean intermediate installation lines (installation angle line, CC and DC).

7, the first ozone supply part 510a and the second ozone supply part 510b are disposed in series on the water supply pipe 300 and the first ozone supply part 520a and the second ozone supply part 510b are disposed in series, The center line C1 of the first ozone supply part 510a and the center line C2 of the second ozone supply part 510b are angularly spaced from each other by the first separation angle 2? The center line D1 of the ozone supplying portion 520a and the center line D2 of the second ozone supplying portion 520b may be angularly spaced by the second separation angle 2 ?. At this time, the trunk CC of the first angle spacing, which is the middle line between the center lines C1 and C2 of the first ozone supply unit 510a and the second ozone supply unit 510b, which are spaced apart from each other by the first separation angle 2? The trunk line DC among the second angular separations is a middle line between the center lines D1 and D2 of the first and second ozone supplying units 520a and 520b spaced apart from each other by the second spacing 2? Can be set.

In this case, the trunk line DC between the trunk line CC and the second angle separator can be spaced at an angle? From the first angle separation, thereby enhancing the unevenness between the ozone supply unit 510 and the ozone supply unit 520 Irregular flow of the ozone 2 and the water 1 in the water conveyance pipe 300 is improved due to discontinuous collision of the ozone 2 and water flow. Such irregular flow may cause turbulence or turbulence in the water 1, which may increase the mixing efficiency of the water 1 and the ozone 2. [

The first ozone supply part 510a and the second ozone supply part 510b may be arranged so that the first ozone supply part 510a, the second ozone supply part 510b, the first ozone supply part 510b, Two or more angles of the center lines C1, C2, D1, and D2 of the supply unit 520a and the second ozone supply unit 520b may be spaced apart from each other. In this case, it is needless to say that the effect of mixing enhancement due to the occurrence of vortex or turbulence, such as when the trunk line DC is distant from the trunk line CC in the first angle separation and the second angle separation, can be generated. The first ozone supply unit 510a, the second ozone supply unit 510b, the first ozone supply unit 510b, and the first ozone supply unit 510b may be arranged such that the trunk line DC is not separated from the trunk line CC C2, D1, and D2 of the first ozone supplying unit 520a and the second ozone supplying unit 520b may be spaced apart from each other.

5A and 5B are cross-sectional views illustrating a screw type detachment structure of a transfer part and a water supply pipe of a ozonizer recycling apparatus according to an embodiment of the present invention.

At least one transfer unit 700 included in the water conveying pipe 300 may be installed and configured to be detachable. For example, the transfer unit 700 may have a structure for removing the transfer unit screws 704 at both ends in the longitudinal direction. At this time, a conveyance pipe thread 304 that can be assembled in a screw manner with the conveyance part screw 704 of the conveyance part 700 may be formed at the end of the water conveyance pipe 300.

Here, the thread and the groove formed in the feed tube screw 304 and the feed tube screw 704 can be variously applied if they are formed to correspond to each other. In addition, the present invention can be applied variously if threads are formed on the inner side or the outer side of the ends of the transfer unit 700 and the water supply pipe 300, and they are formed to correspond to each other.

A sealing member (not shown) may be included in the threaded assembly to maintain watertightness with respect to the internal fluid when assembling the water supply pipe 300 and the transfer unit 700. Further, it is needless to say that the entire transferring part 700 can be modularized into one and combined with the water conveying pipe 300.

6A and 6B are cross-sectional views illustrating a flange-type desorption structure of a transfer part and a water supply pipe of the ozone recycling apparatus according to an embodiment of the present invention.

The transfer part 700 included in the water supply pipe 300 may be installed at least one or more than one (for example, the first transfer part 710 and the second transfer part 720) and may be configured to be detachable. For example, the transfer unit 700 may be formed with a transfer flange 702 at both ends in the longitudinal direction. At this time, a conveyance pipe flange 302 can be formed at the end of the water conveyance pipe 300 so as to be assembled with the conveyance part flange 702 of the conveyance part 700 in a flanged manner.

Here, holes may be formed in each of the flange surfaces of the conveyance pipe flange 302 and the conveyance flange 702 to be fixed by at least one screw and nut. The holes on the side of the conveying pipe flange 302 and the holes on the side of the conveying flange 702 are formed so as to correspond to each other when the flanges are brought into contact with each other. A seal member (not shown) may be disposed between the conveyance portion flange 702 and the conveyance pipe flange 302 to maintain the watertightness with respect to the fluid inside the water conveyance pipe 300.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, but, on the contrary, . Therefore, the scope of the present invention should not be limited to the above-described embodiments, but should be determined by equivalents to the appended claims, as well as the appended claims.

1: water
1a: sterilized water
2: ozone
a: Installation angle
b: Install interval
100: Water supply part
110: connector
111: Connection valve
200: Water storage unit
210: reflux tube
300: water pipe
302: Feed pipe flange
304: Feed tube screw
340: Vortex stirring part
400: sterilized water bowl
410: Concentration display window
420: ozone transfer pipe
440: gas-liquid separator
460:
500:
510, 510a: Ozone supply part
511: inlet
520: Ozone supply part
600: ozone generator
610: Ozone supply pipe
611: Ozone supply line valve
700: transfer part
701: Supply ball
702: Feed pipe flange
704: Feeder screw
710: First transfer section
720:
750:
?,?,?: spacing angle
C1, C2, D1, D2: Center line
CC, DC: Separating trunk line

Claims (1)

A water supply unit;
A water storage unit receiving the water from the water supply unit and storing the water;
A water conveyance pipe for conveying the water stored in the water storage portion;
The ozone is guided to dissolve the ozone in the water flowing inside the water pipe and is positioned at a distance of 10 mm or more and 30 mm or less from each other to prevent a pressure drop due to a change in the flow rate of the water An ozone supply unit including a first ozone supply unit and a second ozone supply unit;
An ozone generator for supplying the ozone to the first ozone supply unit and the second ozone supply unit and generating the ozone;
A sterilizing water reservoir for storing the water in which the ozone is dissolved;
A first ozone supply unit and a second ozone supply unit extending from the sterilization water reservoir and connected to the water supply pipe and guiding ozone not dissolved in the water stored in the sterilization water reservoir to the water supply pipe again A ship ozone supply unit;
Wherein the first ozone supply part and the second ozone supply part are angularly spaced by a first separation angle and the first ozone supply part and the second ozone supply part are angularly spaced by a second separation angle,
A first angle separating intermediate line which is a spaced intermediate line between the first ozone supplying section and the second ozone supplying section and which is spaced apart from the first separating angle by a distance between the first ozone supplying section and the second ozone supplying section, The trunks of the second angular spacings, which are the spaced median lines of the spacing angles, are angularly spaced from each other,
Wherein the ozone supply part and the ozone supply part are positioned while maintaining a distance of 15 cm or more.

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