KR20110133401A - Generation apparatus for complex ionic mineral activity water - Google Patents

Abstract

PURPOSE: An apparatus for generating complex ionic mineral active water is provided to decompose harmful materials in water using ceramic balls and to generate plenty of the complex ionic mineral active water based on flowing water. CONSTITUTION: An apparatus for generating complex ionic mineral active water includes an introducing part(10), a mineral dissolving bath(20), a voltage part(18), and a discharging part(32). Water is supplied through the introducing part from the outside. The water is supplied into the mineral dissolving bath through one end part, and the water is discharged through another end part of the mineral dissolving bath. Silver balls and metallic balls are arranged in the mineral dissolving bath. An electrode, to which a voltage is applied, is formed at one inner side of the mineral dissolving bath. The voltage part applies the voltage to the electrode. The discharging part discharge treated water to the outside. Ceramic balls are further arranged in the mineral dissolving bath.

Description

Composite ion mineral active water production equipment {GENERATION APPARATUS FOR COMPLEX IONIC MINERAL ACTIVITY WATER}

The present invention relates to a device for producing a composite ion mineral active water containing a silver component and various mineral components. In particular, the present invention is capable of generating a large amount of alkaline sterilizing water by applying a high voltage in a state where a silver ball and a mineral metal ball are placed in a flowing mineral melting tank. The present invention relates to a composite ion mineral active water production apparatus.

Recently, interest in health has increased due to the improvement of living standards and the appearance of various diseases, and the interest in water has been very high because it is essential to drink good water in order to protect such health.

Currently, most people drink commercially available water or water purified by water purifiers, and water purifiers used to purify such water are classified into hollow fiber membrane and reverse osmosis membrane water purifiers. Water purifiers are the most commonly used.

Reverse osmosis membrane type water purifier reversely uses the pressure (osmotic pressure) caused by the solvent migration from the lower concentration to the higher concentration when two liquids with different concentrations are blocked with a semi-permeable membrane. Essential salts that are beneficial to the human body as well as bacteria or the like are removed, and thus there is a problem that the water is acidified.

Accordingly, a method of confining a certain amount of water in an electrolytic cell and then ionizing and mixing the plate-shaped mineral metal with electricity has been proposed. However, this conventional method is limited in the capacity that can be treated because it traps a certain amount of water, in particular, there is a problem that is difficult to use in the place where water is continuously used.

The problem to be solved by the present invention is to provide a composite ion mineral active water production apparatus containing a silver component and various mineral components.

Still another object of the present invention is to provide a composite ion mineral active water production apparatus capable of generating a large amount of alkaline sterilizing water by applying a high voltage in a state in which a silver ball and a mineral metal ball are placed in a mineral melting tank flowing through a metal ball.

The composite ion mineral active water production apparatus of the present invention includes an inlet 10 for supplying water from the outside; Continuously supplied with water in one end and discharged to the other end, the silver ball 203, the metal ball 205 is located inside, the mineral fusion tank 20 is formed with an electrode 209 is supplied with a voltage on one side and ; A voltage unit 18 for applying a voltage to the electrode 209 of the mineral melting tank 20; It characterized in that it comprises a discharge portion 32 for discharging the treated water passing through the ion measuring unit 28 to the outside.

Preferably, the inside of the mineral melting tank is characterized in that the ceramic ball 207 is further included.

Preferably, between the inlet and the mineral fusion tank is characterized in that the magnetic force generating portion 12 for activating the water supplied from the outside by magnetic force.

Preferably, the front of the mineral fusion tank is characterized in that the pre-treatment filter unit 14 for filtering foreign matter contained in the water is formed.

Preferably, the mineral metal ball 205 is characterized in that any one of zinc ball, chromium ball, iron ball, selenium ball, copper ball, molybdenum ball, and mixed balls thereof.

Preferably, the mineral melting tank 20 is formed with a silver treatment tank 204 in which the silver ball 203 is placed and a mineral treatment tank 206 in which the mineral metal ball 205 is placed. An inlet through which water passed through 14 is introduced is formed, and a discharge port through which water passed through each treatment tank is discharged to the other side is formed.

Preferably, it is characterized in that it further comprises a post-treatment filter 24 for receiving the treated water passed through the mineral fusion tank 20 to remove bacteria, odors, impurities, etc. remaining in the treated water.

Preferably, the pressurizing portion for pressurizing the water flowing into the mineral melting tank is characterized in that it is further formed.

The composite ion mineral active water production apparatus of the present invention can easily produce a large amount of complex ion mineral active water containing a silver component and various mineral components while using flowing water without confining water.

In addition, the silver ball and the mineral metal ball is evenly distributed in the flowing water, there is an advantage that can easily activate the silver and mineral components in the ion state.

In addition, there is an advantage that can be used to sterilize the water contacted by the ceramic ball or to decompose harmful substances using the ceramic ball together.

1 is a block diagram of a composite ion mineral active water production apparatus according to the present invention.
2 is a cross-sectional view of the mineral melting tank according to the first embodiment of the present invention.
3 is a cross-sectional view of a mineral fusion tank according to a second embodiment of the present invention.
4 is a cross-sectional view of a mineral fusion tank according to a third embodiment of the present invention.
5 is a cross-sectional view of a mineral fusion tank according to a fourth embodiment of the present invention.

Hereinafter, an apparatus for producing a composite ion mineral active water according to the present invention will be described in detail with reference to the accompanying drawings.

As shown, the composite ion mineral active water production apparatus according to the first embodiment of the present invention, the inlet 10, the mineral melting tank 20, the voltage unit 18, the discharge unit 32.

The inlet 10 is connected to an external water supply pipe to supply water to the inside of the composite ion mineral active water production apparatus. At this time, the flow rate of the water supplied through the inlet 10 is preferably supplied at about 1 ~ 5m / sec.

The mineral melting tank 20 has a silver ball 203 and a metal ball 205 located therein, and an inlet 201 for continuously supplying water from the inlet 10 to the inside and a discharge port for discharging the treated water therein ( 202 is formed, and an electrode 209 to which a voltage is supplied is formed. At this time, the mineral melting tank 20 is preferably made of an insulator so that the internal voltage is not transmitted to the outside, the mineral melting tank is a motor, etc. in order to prevent the outlet is blocked by the balls inside the mineral melting tank 20. It is preferable to rotate by the rotating part 22 of. In addition, it is preferable that a plurality of through holes are formed in each ball. Each ball having a through hole formed therein can move in the treatment tank according to the flow rate of water, and can contact the water evenly.

The silver ball 203 located inside the mineral fusion tank 20 can remove various bacteria contained in the water while being ionized with silver ions supplied with voltage while being mixed with water flowing with strong sterilization power, and ionized by voltage. And mixed with water. In addition, the mineral metal ball may be used by selectively mixing a metal such as zinc, chromium, iron, selenium, copper, molybdenum, and the like ionized by a voltage and mixed in water. At this time, it is preferable that the inlet and outlet have a through hole smaller than the diameter of the balls in order to prevent the silver ball and the mineral metal ball from being discharged to the outside.

In addition, the mineral melting tank 20 is preferably arranged to further remove the various harmful substances contained in the water by contacting the water by placing a ceramic ball 207 excellent in sterilization power and decomposition ability of harmful substances.

The voltage unit 18 applies a voltage so that power is applied to the electrode 209 formed in the mineral fusion tank 20. At this time, the voltage supplied to the electrode 209 is preferably 100 to 10,000 V, 0.5 A or less. The voltage supplied to the mineral melting tank 20 is instantaneously supplied, and the time at which the voltage is supplied is controlled by a timer. When voltage is applied to the mineral electrolytic cell by the voltage unit 18, silver and metal minerals are ionized and mixed with water while current flows through the silver ball 203 and the mineral metal ball 205 along the water passing through the treatment tank.

The discharge part 32 supplies the treated water discharged through the discharge port of the mineral melting tank to be used from the outside.

On the other hand, the composite ion mineral active water production apparatus additionally the magnetic force generation unit 12, pre-treatment filter unit 14, pressurization unit 16, post-treatment filter unit 24, ion measurement unit 28, feedback unit 30 ).

The magnetic force generating unit 12 is positioned between the inlet and the mineral fusion tank is installed on the outside of the pipe through which the water introduced into the inlet 10 passes through to activate the water passing through the pipe by magnetic force. At this time, the magnet is a permanent magnet or an electromagnet is used. Such a magnet can activate water by dividing the cluster of water, that is, the molecular aggregate of water, by the action of a magnetic force and making it smaller.

The pretreatment filter unit 14 receives the water passing through the magnetic force generating unit 12 to remove impurities contained in the water. The pretreatment filter unit 14 preferably comprises a fibrous filter for removing solids contained in the water and a carbon filter for removing bad odors and the like contained in the water.

The pressurizing unit 16 is located in front of the mineral melting tank and pressurizes the water flowing into the mineral melting tank to be supplied at a constant pressure.

The post-treatment filter unit 24 receives the treated water passing through the mineral melting tank 20 to remove bacteria, odors, impurities, etc. remaining in the treated water. The post-treatment filter section 24 preferably uses a hollow fiber membrane filter.

In addition, the mixing unit 26 receives the treated water that has passed through the post-treatment filter unit 24 and mixes it evenly. That is, a screw line is formed in the mixing part 26 to mix the silver component and the mineral component in the treated water in an even distribution.

The ion measurement unit 28 receives the treated water in which the silver component and the mineral component are mixed in the mineral melting tank 20 and measures the silver component and the mineral component included in the treated water.

The feedback unit 30 supplies the treated water discharged from the ion measuring unit 28 back to the inlet unit 10 when the treated water caused by the silver component and the mineral component is detected by the ion measuring unit 28.

On the other hand, as shown in Figure 3, the mineral melting tank 20 according to the second embodiment of the present invention, is installed in the horizontal direction, the silver treatment tank 204 and the mineral ball 203 is placed therein It is preferable that the mineral treatment tank 206 on which the metal ball 205 is placed is formed separately.

In addition, as shown in Figure 4, the mineral melting tank 20 according to the second embodiment of the present invention is installed in the horizontal direction, the ceramic processing tank 208 and the silver ball 203 where the ceramic ball 207 is located. The silver treatment tank 204 in which is located) and the mineral treatment tank 206 in which the mineral metal ball 205 is located are sequentially formed. At this time, the water flowing into the mineral fusion tank 20 is formed to have a constant slope so that the water pressure toward the side of the treatment tank. A through hole 211 through which each ball does not pass is formed between the respective treatment tanks, and a through hole in the upper part of the upper part is formed larger than the through hole in the lower part so that water flowing into the treatment tank forms a vortex. In addition, at the bottom of each treatment tank into which water is introduced, a protrusion plate 212 extending upward to form a turbulent flow by hitting water introduced through the through-hole 211 is formed.

Water supplied through the pretreatment filter unit 14 of the mineral fusion tank 20 according to the second and third embodiments is introduced to the side surface of the ceramic treatment tank 208 to the protrusion plate 212. It collides to form turbulence inside the ceramic treatment tank 208, and the ceramic ball 207 contacts a lot of water while rotating the treatment tank along the turbulence. In addition, water passing through the ceramic treatment tank 208 flows into the silver treatment tank 204 along the through hole formed in the blocking plate. At this time, since a narrow through-hole is formed below the blocking plate, it flows into the silver treatment tank 204 with rapid hydraulic pressure. The water flowing into the silver treatment tank 204 is contacted with a lot of water while the silver ball 203 rotates along the water introduced from the inside of the silver treatment tank 204 due to the flow velocity difference between the water passing through the through holes in the lower part and the upper part. Done. At this time, when a voltage is applied into the silver treatment tank 204, silver is ionized and mixed with water. Then, water passing through the silver treatment tank 204 is introduced into the mineral treatment tank 206 along the through hole formed in the blocking plate. At this time, since the narrow through-hole is formed in the lower portion of the blocking plate flows into the ceramic treatment tank 208 at a rapid hydraulic pressure. Water flowing into the mineral treatment tank 206 is in contact with a lot of water as the mineral metal ball rotates inside the mineral treatment tank 206 along the water due to the flow rate difference of the water passing through the through hole in the lower part and the upper part. When voltage is applied to the treatment tank 206, various minerals are ionized and mixed with water.

As shown in Figure 5, the mineral melting tank 20 according to the fourth embodiment of the present invention is installed in the longitudinal direction, the ceramic treatment tank 208 and the silver treatment tank 204 and the mineral treatment tank 206 Are formed sequentially. Each treatment tank bottom is formed with a discharge hole 210 'protruding downward to give a high flow rate to the water passing through the treatment tank. Discharge hole 210 'is formed to a size that does not pass the balls of each treatment tank. In addition, the discharge port may prevent the balls from accumulating due to the pressure of the water flowing inwardly so that the discharge port 202 is protruded inward to prevent the through hole from being blocked by the ball.

Balls located in the respective treatment tanks are positioned above the treatment tank by the through-holes formed in the respective balls and come into contact with water by the flow rate and the self-rotation of the mineral melting tank. Therefore, when voltage is applied to the silver treatment tank 204 and the mineral treatment tank 206, the silver ball 203 and the mineral metal ball 205 are ionized and mixed with water.

<Examples>

As the mineral melting tank 20 of the composite ion mineral active water production apparatus, the ceramic treatment tank 208 in which the ceramic balls 207 are positioned in the horizontal direction and the silver treatment tank 204 in which the silver balls 203 are positioned, as shown in FIG. 2. And a mineral fusion tank 20 in which the mineral treatment tank 206 in which the mineral metal ball 205 is located is sequentially formed. The water was continuously supplied to the silver treatment tank 204 and the mineral treatment tank 206 at 550 V and 0.5 A while flowing water through the mineral melting tank 20 for 0.1 second. E. coli, Staphylococcus aureus, Salmonella, Shigella, Pseudomonas aeruginosa strains (CFU / mL) were added to 1 L of the treated water discharged from the mineral fusion tank 20, and the strains were measured at different time intervals for 10 minutes and 30 minutes. It is shown in Table 1.

Strain Prepared water (CFU / mL) 10 minutes later 30 minutes later Escherichia coli 1.5 ㅧ 10 ³ Not detected Not detected Staphylococcus aureus 1.3 ㅧ 10 ³ Not detected Not detected Salmonella 1.6 ㅧ 10 ³ Not detected Not detected Shigella 1.3 ㅧ 10 ³ Not detected Not detected Pseudomonas aeruginosa 1.2 ㅧ 10 ³ Not detected Not detected

As shown in Table 1, it can be seen that the treated water treated by the composite ion mineral active water production apparatus of the present invention contains a silver component and a mineral component and has high sterilizing power against various strains.

As described above, although the present invention has been described by way of limited embodiments and drawings, the present invention is not limited thereto, and the technical idea of the present invention and the following by those skilled in the art to which the present invention pertains. Of course, various modifications and variations are possible within the scope of equivalents of the claims to be described.

10: inlet portion 12: magnetic force generating portion
14 pretreatment filter unit 16 pressurization unit
18: voltage unit 20: mineral melting tank
22: rotating part 24: post-processing filter part
26 mixing portion 28 ion measuring unit
30: feedback unit 32: discharge unit
203: silver ball 204: silver treatment tank
205: mineral metal ball 206: mineral treatment tank
207: ceramic ball 208: ceramic treatment tank
211 through hole 209 electrode

Claims (11)

An inlet 10 for supplying water from the outside;
Continuously supplied with water in one end and discharged to the other end, the silver ball 203, the metal ball 205 is located inside, the mineral fusion tank 20 is formed with an electrode 209 is supplied with a voltage on one side and ;
A voltage unit 18 for applying a voltage to the electrode 209 of the mineral melting tank 20;
Complex ion mineral active water production apparatus, characterized in that it comprises a discharge portion (32) for discharging the treated water passed through the ion measurement unit 28 to the outside. The apparatus of claim 1, wherein a ceramic ball 207 is further included in the mineral fusion tank. The composite ion mineral active water production apparatus according to claim 1 or 2, wherein the ball has a plurality of through holes. The apparatus of claim 1, wherein a magnetic force generating unit 12 is formed between the inlet and the mineral fusion tank to magnetically activate water supplied from the outside. The apparatus of claim 1, wherein a pretreatment filter part 14 is formed at the front of the mineral fusion tank to filter foreign substances contained in the water. The apparatus of claim 5, wherein the pretreatment filter unit (14) comprises a fibrous filter for removing solids contained in water and a carbon filter for removing unpleasant odors contained in water. The apparatus of claim 1, wherein the mineral metal ball 205 is any one of zinc balls, chromium balls, iron balls, selenium balls, copper balls, molybdenum balls, and mixed balls thereof. The method of claim 1, wherein the mineral melting tank 20 is formed with a silver treatment tank 204 in which the silver ball 203 is placed and a mineral treatment tank 206 in which the mineral metal ball 205 is placed, and pretreatment to one side. An inlet through which water passing through the filter unit 14 is formed, and an outlet for discharging water passing through the respective treatment tanks to the other side is formed. The apparatus according to claim 8, wherein a ceramic treatment tank (208) in which the ceramic ball (207) is placed is formed inside the mineral melting tank. The method according to claim 1, characterized in that it further comprises a post-treatment filter unit 24 for receiving the treated water passed through the mineral fusion tank 20 to remove bacteria, odors, impurities, etc. remaining in the treated water. The apparatus of claim 1, further comprising a pressurizing unit configured to pressurize water introduced into the mineral melting tank.

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