WO2016171409A1

WO2016171409A1 - Ionized water generating device

Info

Publication number: WO2016171409A1
Application number: PCT/KR2016/003337
Authority: WO
Inventors: 안종석
Original assignee: 주식회사 젬마그린
Priority date: 2015-04-20
Filing date: 2016-03-31
Publication date: 2016-10-27
Also published as: KR101576863B1; CN106660838B; CN106660838A

Abstract

The present invention relates to an ionized water generating device, and the purpose of the present invention is to develop an ionized water generating device, which causes water to flow between permanent magnets, thereby ionizing the same, and which has a high ionization efficiency while guaranteeing easy fabrication and assembly. Particularly, the present invention relates to an ionized water generating device configured such that, when water flows in through one side thereof, the same vertically penetrates between permanent magnets, which are contained therein, and which have different polarities, and is ionized with no discharge phenomenon occurring, the ionized water generating device comprising: a lower connection portion, which has a thread formed on the inner peripheral surface thereof, and which has a first O-ring insertion groove formed thereon; an upper connection portion, which has a thread formed thereon, and which has a second O-ring insertion groove formed thereon; a housing having one or more horizontal reinforcement ribs; a metal tube for pressurizing a first O-ring; and an upper finish cap having a third O-ring insertion groove formed thereon, into which a third ring is inserted, wherein the lower portion of the housing is integrally connected to the upper portion of the lower connection portion such that a channel extends through the power portion.

Description

Ion Water Generator

The present invention relates to an ionized water generating device, which will be described in more detail in the ionized water generating device developed to increase the ionization efficiency while easy to manufacture and assemble an ionized water generating device for ionizing water through the permanent magnets. It is about.

Although Korea is one of the nations with insufficient water, the water used for eating and washing is relatively abundant, but the water that can be directly consumed due to environmental pollution is decreasing. In most cases, tap water is consumed directly or by boiling.

Recently, as the incidence of various atopic diseases increases, tap water is not just boiled or simply drunk, but various natural ingredients or medicinal herbs are added to boil or go through a water purifier or buy bottled water.

In particular, tap water is likely to penetrate various bacteria or impurities through aging water pipes or dirty water tanks, and it is necessary to be careful not only when drinking but also when washing the body.

When the water is small in size and forms a magnetic field at right angles to the direction of water flow as it passes between the permanent magnets, the surface tension of the water is increased, and the molecular structure of the water is ion-activated. Increasingly, there is an increasing use of simply mounted ionized water generators for generating ionized water.

However, most of them are formed by forming a space that can be built in the shower, and it is necessary to develop an ionized water generator that can be easily mounted on a hose or faucet and is easy to manufacture and assemble.

The present invention has been developed to solve the above problems, the object of the present invention is to develop an ionized water generating device that can be easily installed in a variety of places, easy to manufacture and easy to assemble.

In addition, the present invention is to develop an ionized water generator that can stably and efficiently make a larger amount of water into ionized water.

In order to achieve the above object, the present invention provides an ionized water generating device that ionizes water and prevents discharge from occurring while vertically penetrating between permanent magnets facing different polarities when water is introduced to one side. ;

The ionizer generating device has a lower connection portion formed with a screw thread formed on an inner circumferential surface of the bottom surface thereof, the lower outer diameter of which is bent upwards, and a first O-ring insertion groove formed therein, the first O-ring being inserted therein;

A second o-ring insertion groove into which a top surface is opened and an upper outer diameter is narrowly reduced, and is recessed along an outer circumferential surface and a second o-ring insert groove is inserted into the upper circumferential surface thereof;

A pair of main bulkheads having a plate shape vertically penetrating between the pair of disks spaced up and down and passing through the center of the disk, and having a flow path vertically penetrating in the shape of a long long hole; Two pairs of reinforcing ribs spaced apart from each other, two magnet inserting holes formed by left and right reinforcing ribs and an inner main partition wall into which permanent magnets are inserted, and grooves formed by the reinforcing ribs and the main partition wall except for the magnet inserting holes. A housing having one or more horizontal reinforcing ribs connected to each other;

A metal tube formed of a cylindrical metal to surround the housing and pressurize a first O-ring at a lower end thereof;

The center consists of an upper closing cap through which an upper end of the upper connection part is formed, and a third O-ring inserting groove into which a third O-ring for pressing the upper end of the metal tube is inserted inward after the bottom outer diameter surface is bent downward;

The lower portion of the housing is integrally connected with the upper portion of the lower connection portion, characterized in that the passage extends downward.

In addition, the housing is integrally connected with the lower portion of the upper connection portion so that the flow path is extended through the upper portion, the upper closing cap is integrally formed in a shape that is vertically bent downward after protruding in the normal direction from the lower outer diameter of the housing, A first coupling portion is further formed at the center of the bottom surface, the first coupling portion having a screw thread on the inner diameter surface thereof;

The second coupling part protrudes upward on the upper surface of the lower connection part to form a screw thread coupled to the first coupling part on the outer diameter surface, and the outer diameter is narrowly reduced on the lower end of the thread of the second coupling part, and then the fourth O-ring is extended. The fourth O-ring insertion groove is inserted, and a through hole vertically penetrating from the center of the upper surface and interlocked with the flow path.

In addition, the main partition wall of the housing is formed in parallel to form a second magnet insertion hole therebetween, the second magnet insertion hole is mounted on the second permanent magnet and both sides in the center to be in close contact with the inner diameter surface of the metal tube. A pair of interval maintaining blocks are mounted, and each of the flow paths is formed on each main partition wall of the second permanent magnet.

In addition, the housing is further formed with a separation partition connecting the center between the pair of the main partition wall, the second permanent magnet and the interval maintaining block is mounted on both sides separated by the separation partition, the flow path is a second Two main partitions on each side of the permanent magnet is characterized in that formed two.

As described above, the present invention can be easily manufactured and assembled by a mold, so that it can be connected to various places such as a hose or a connecting pipe, and can be mounted and applied to more places such as a sink and a shower, so that ionized water can be used.

In addition, there is an effect that can generate a large amount of ionized water more stably and efficiently by having a passage passing between two or more different polar magnetic fields.

1 is a perspective view according to an embodiment of the present invention

Figure 2 is an exploded perspective view according to an embodiment of the present invention

3 is a partial cutaway perspective view according to an embodiment of the present invention

4 is a cross-sectional plan view according to an embodiment of the present invention.

5 is an exploded perspective view according to a first enlarged embodiment of the present invention;

6 is a cross-sectional plan view according to a first enlarged embodiment of the present invention.

7 is a plan sectional view according to a second enlarged embodiment of the present invention.

8 is an exploded perspective view according to a third enlarged embodiment of the present invention;

9 is a side cross-sectional view according to a third enlarged embodiment of the present invention.

Accordingly, the configuration of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art can easily understand and reproduce.

1 is a perspective view according to an embodiment of the present invention, Figure 2 is an exploded perspective view according to an embodiment of the present invention, Figure 3 is a partial cutaway perspective view according to an embodiment of the present invention, Figure 4 is the present invention In the cross-sectional view according to an embodiment of the present invention, in the ionized water generating device to ionize the water and vertically penetrates between the permanent magnets facing the other polarity when water is introduced into one side to prevent the discharge phenomenon;

The ion water generator 1 has a bottom surface is open, the thread is formed on the inner circumferential surface, the outer diameter of the lower end is bent upwardly and then bent to the top of the first O-ring insertion groove 112 is inserted into the inside A lower connection part 11 formed therein;

An upper surface of which is opened, an upper outer diameter of which is narrowly reduced, and is recessed along the outer circumferential surface of the second O-ring inserting groove 122 into which the second O-ring 121 is inserted and an upper connection portion 12 having a thread formed on the upper outer circumferential surface thereof;

A main partition wall 132 having a plate shape vertically penetrated between a pair of disks spaced up and down and passing through the center of the disk and having a flow path 131 vertically penetrating in the shape of a long long hole, and the main partition wall 132 ) Are formed by two pairs of reinforcing ribs 133 extending from the center to both sides, respectively, and the left and right reinforcing ribs 133 and the inner main bulkhead 132 are inserted into two permanent magnets 134. A housing 13 having a magnet insertion hole 135 and at least one horizontal reinforcing rib 136 for horizontally connecting grooves formed by the reinforcement rib 133 excluding the magnet insertion hole 135 and the main partition 132. )and;

A metal tube (15) formed of a cylindrical metal to surround the housing (13) and having a lower end pressurized by the first O-ring (111);

A third O-ring inserting groove 162 through which the upper part of the upper connection part 12 penetrates, and a third O-ring 161 for pressing the upper end of the metal tube 15 is inserted therein after the bottom outer diameter surface is bent downward. The upper closure cap 16 is formed;

The lower portion of the housing 13 is integrally connected with the upper portion of the lower connection portion 11 has shown the ionized water generating device characterized in that the passage 131 extends downward.

The ionizer apparatus 1 of the present application forms a lower connection portion 11 and an upper connection portion 12 to be easily installed in various places such as connecting a hose of a shower head, a sink or a sink connection portion, and is continuously installed by a permanent magnet. Ionized water can be produced.

At this time, the lower connecting portion 11 formed integrally with the housing 130 is integrally molded by insert injection, so that the permanent magnet 134 can be simply inserted and the metal tube 15 and the upper closing cap 16 can be assembled. This is done very simply.

At this time, the flow path 131 formed on the main barrier wall 132 between the permanent magnets 134 on both sides is formed so that the width L1 of the flow path 131 is smaller than the width L2 of the permanent magnet 134, thereby stably ionizing the flow path 131. It is desirable to be able to be.

5 is an exploded perspective view according to a first enlarged embodiment of the present invention, Figure 6 is a plan sectional view according to a first enlarged embodiment of the present invention, the housing 13 is integrally with the lower portion of the upper connection portion 12 Is connected to the flow path 131 extends through the upper portion, the upper closing cap 16 is formed integrally in a shape that protrudes in the normal direction from the lower outer diameter of the housing 13 and then vertically bent downward, A first coupling part 137 is formed to be recessed to the top to form a thread on the inner diameter surface;

On the upper surface of the lower connection portion 11 protrudes to the upper surface of the second coupling portion 113 is formed with a screw thread coupled to the first coupling portion 137 on the outer diameter surface, the lower end of the screw thread of the second coupling portion 113 It is provided with a fourth O-ring inserting groove 115 into which the fourth O-ring 114 is inserted and the outer diameter thereof is shortened and expanded, and a through hole 116 vertically penetrating from the center of the upper surface to interlock with the flow path 131. An embodiment is shown as a feature.

According to the embodiment, the lower connection part 11 is manufactured separately from the housing 13, but the first connection part 137 and the second coupling part 113 have a structure in which the coupling is more tightly coupled. In the basic embodiment described above, there is a fear that flow may occur in the upper closing cap 16, but it is possible to reduce the risk of such a flow.

In particular, there is an effect that can block the possibility of water seeping into the permanent magnet 134 in a lot of contact with water.

7 is a cross-sectional plan view according to a second enlarged embodiment of the present invention, Figure 8 is an exploded perspective view according to a second enlarged embodiment of the present invention, the main partition wall 132 of the housing 13 is a pair in parallel And a second magnet insertion hole 138 formed therebetween, and the second magnet insertion hole 138 is attached to both sides of the second permanent magnet 139 at the center thereof to be in close contact with the inner diameter surface of the metal tube 15. A pair of interval maintaining blocks 140 are mounted, and the flow path 131 is provided with an embodiment characterized in that each one is formed in each of the main partitions 132 on both sides of the second permanent magnet 139.

One of the problems of the ionized water generating device is that the water is moved through the flow path 131 having the shape of a long long hole, so that the number of movements is limited and the degree of ionization decreases because it passes at a high pressure and a high speed inside. There is a disadvantage.

However, in the above embodiment, the two flow paths 131 are formed so that more quantities can be moved to more effectively generate ionized water.

FIG. 9 is a side cross-sectional view according to a third enlarged embodiment of the present invention. In the housing 13, a separation partition 141 connecting a center between the pair of main partitions 132 is further formed and separated. The second permanent magnet 139 and the interval maintaining block 140 are mounted on both sides separated by the partition wall 142, and the flow path 131 is respectively formed on both main partition walls 132 of the second permanent magnet 139. An embodiment is characterized by being formed two by one.

Although the above embodiment may be a way to allow a larger amount of water to pass through, the width of the flow path 131 may be narrowed to enable more efficient ionization.

[Description of the code]

1: ionized water generator

11: bottom connection

111: first O-ring 112: first O-ring insertion groove

113: second coupling portion 114: fourth O-ring

115: fourth O-ring insert groove 116: through hole

12: upper connection

121: second O-ring 122: second O-ring insertion groove

13: housing

131: Euro 132: main bulkhead

133: reinforcement rib 134: permanent magnet

135 magnet insertion hole 136 horizontal reinforcing rib

137: first coupling portion 138: second magnet insertion hole

139: the second permanent magnet 140: spacing block

141: separating bulkhead

15: metal tube

16: Upper Finish Cap

161: third O-ring 162: third O-ring insertion groove

Claims

In the ionized water generating device to ionize the water and prevent the discharge phenomenon while vertically penetrating between the permanent magnets facing the other polarity when the water is introduced to one side;

The ion water generator 1 has a bottom surface is open, the thread is formed on the inner circumferential surface, the outer diameter of the lower end is bent upwardly and then bent to the top of the first O-ring insertion groove 112 is inserted into the inside A lower connection part 11 formed therein;

An upper surface of which is opened, an upper outer diameter of which is narrowly reduced, and is recessed along the outer circumferential surface of the second O-ring inserting groove 122 into which the second O-ring 121 is inserted and an upper connection portion 12 having a thread formed on the upper outer circumferential surface thereof;

A main partition wall 132 having a plate shape vertically penetrated between a pair of disks spaced up and down and passing through the center of the disk and having a flow path 131 vertically penetrating in the shape of a long long hole, and the main partition wall 132 ) Are formed by two pairs of reinforcing ribs 133 extending from the center to both sides, respectively, and the left and right reinforcing ribs 133 and the inner main bulkhead 132 are inserted into two permanent magnets 134. A housing 13 having a magnet insertion hole 135 and at least one horizontal reinforcing rib 136 for horizontally connecting grooves formed by the reinforcement rib 133 excluding the magnet insertion hole 135 and the main partition 132. )and;

A metal tube (15) formed of a cylindrical metal to surround the housing (13) and having a lower end pressurized by the first O-ring (111);

A third O-ring inserting groove 162 through which the upper part of the upper connection part 12 penetrates, and a third O-ring 161 for pressing the upper end of the metal tube 15 is inserted therein after the bottom outer diameter surface is bent downward. The upper closure cap 16 is formed;

The lower portion of the housing (13) is integrally connected with the upper portion of the lower connecting portion (11) characterized in that the flow path (131) extends through the lower portion.
According to claim 1, wherein the housing 13 is integrally connected with the lower portion of the upper connecting portion 12, the passage 131 extends through the upper portion, the upper closing cap 16 is the lower outer diameter of the housing 13 Is formed integrally in a shape that is vertically bent downward after protruding in the normal direction, and further comprises a first coupling portion 137 recessed to the top in the center of the bottom to form a screw thread on the inner diameter surface;

On the upper surface of the lower connection portion 11 protrudes to the upper surface of the second coupling portion 113 is formed with a screw thread coupled to the first coupling portion 137 on the outer diameter surface, the lower end of the screw thread of the second coupling portion 113 It is provided with a fourth O-ring inserting groove 115 into which the fourth O-ring 114 is inserted and the outer diameter thereof is shortened and expanded, and a through hole 116 vertically penetrating from the center of the upper surface to interlock with the flow path 131. Ion water generator characterized in that.
The main partition 132 of the housing 13 is formed in a pair in parallel to form a second magnet insertion hole 138 therebetween, the second magnet insertion hole 138 In the center is mounted a second permanent magnet 139 and a pair of interval maintaining block 140 is mounted on both sides thereof to be in close contact with the inner diameter surface of the metal tube 15, the flow path 131 is a second permanent magnet Ion water generating apparatus, characterized in that each one formed on each side of the main partition 132 of the (139).
The method of claim 3, wherein the housing 13 is further formed with a partition partition 141 connecting the center between the pair of the main partition wall 132, respectively formed on both sides separated by the partition partition 142 2 permanent magnets (139) and the interval maintaining block 140 is mounted, the flow path 131 is an ionized water generating device, characterized in that each formed on each of the two main partitions (132) of the second permanent magnet (139).