KR101284366B1 - apparatus for producing alkalized water - Google Patents

Abstract

The apparatus for generating alkaline water according to the present invention includes a cylindrical water tank through which water is stored and water can be taken in and out through water inlets and outlets, and a coil wound outside the tank. A magnetic flux part for inducing denatured magnetic energy in the air, a power part for supplying electric energy necessary for generating the denatured magnetic energy, and mutually separated in the tank so as to contact the water. And two types of reactants included as individual individuals. One type of reactant is an alloy of a first metal (eg, zinc) having a higher ionization tendency than hydrogen (eg, zinc) and a second metal (eg, copper) having a lower ionization tendency than hydrogen (eg, a Cu ratio). : Zn = 8: 2) and other types of reactants are balls of a third metal (eg magnesium) component with a higher ionization tendency than the first metal.

Description

Alkaline water generator {apparatus for producing alkalized water}

The present invention relates to an apparatus for producing alkaline water having a high pH.

Alkaline water with a pH of 7 or more strengthens the structure of the water (hexagonal) to keep the body stable from external irritation or disturbance, and to return the acidified body fluid to alkalinity and removes free radicals that are harmful to the body. It is universally recognized. In particular, alkaline water above pH 9 is recognized for its effects on gastrointestinal abnormal fermentation, chronic diarrhea, indigestion, excessive stomach acid, constipation, and ionized water producing strong alkaline water is also treated as medical.

As a method of generating such alkaline water, a method of electrolyzing water and a method of using natural minerals are known.

The method using electrolysis allows accurate control of the pH, but has a disadvantage in that the structure is complicated and the waste of water is severe. Only about 40% of the water supplied can be drunk as alkaline water and the rest is discarded. This amount for electrolysis (+) of electrodes around susanhwayi warmth (OH ^-) to react with each other, creating a generator of oxygen (O) can not drink thus boosting melt the metal electrode is ionized, and negative (-) electrode surrounding This is because the electrode is inverted intermittently to remove calcium ions (Ca ⁺⁺ ) adhered to the water, and then the supplied water is used as washing water.

The method of using natural minerals is simple in structure and inexpensive because it only needs to contact natural minerals and water, but it is difficult to obtain strong alkaline water of desired pH through chemical reaction through natural contact with natural minerals. However, in order to obtain alkaline water having a slightly higher pH, the space occupied becomes larger, such as placing a large volume water tank or lengthening a water pipe to increase the contact area of natural minerals or to increase the contact time.

An object of the present invention is to provide an apparatus capable of supplying water to be supplied as strongly alkaline drinking water having a high pH without waste.

Another object of the present invention is to provide an apparatus capable of supplying strong alkaline drinking water while reducing the size of the occupied space by increasing the chemical reaction force of a substance for generating alkaline water.

Another object of the present invention is to provide a strong alkaline drinking water supply apparatus capable of removing a small amount of impurities generated for alkaline water generation.

The object of the present invention is not limited to the explicit purpose described above, and of course includes achieving the effect that can be derived from the specific and exemplary description of the present invention.

An alkaline water generating device according to an aspect of the present invention, the water is stored in the water tank through which the water can be obtained and withdrawn through the inlet and outlet, and the porcelain of the denaturation in the space in the tank 2 types of reactions included as magnetic flux parts for inducing energy, electric power parts for supplying electrical energy necessary for generating the denatured magnetic energy, and individuals separated from each other in the water tank in contact with the water It consists of a sieve. And one type of the reactant is a collection of alloying entities of a first metal having a higher ionization tendency than hydrogen and a second metal having a lower ionization tendency than hydrogen, and another type of the reactant has a higher ionization tendency than the first metal. It is a collection of high third metal entities.

In one embodiment according to the invention, the first metal is copper (Cu), the second metal is zinc (Zn), the third metal is magnesium (Mg), the first metal in the alloy is said It is contained in a higher weight ratio than the second metal, each of the reactants in ball or granular form, and the one type of reactant has a lower porosity than the other type of reactant. It is manufactured in small size.

In one embodiment according to the present invention, the power unit provides the electric energy by intermittently outputting a current.

In another embodiment according to the present invention, the power unit provides the electrical energy by outputting while inverting the polarity of the current.

In one embodiment according to the invention, the water tank is composed of a plurality of interconnected by a connecting pipe, each tank is provided with the magnetic flux, each magnetic flux is electrically connected in parallel to the power unit.

In one embodiment according to the present invention, the filter further comprises a filter for filtering substances deposited in the water discharged from the water tank installed in the outlet pipe connected to the outlet of the water tank.

In one embodiment according to the present invention, the water tank is configured in a cylindrical shape, and the magnetic flux part includes a solenoid configured as a coil helically wrapping the outside of the water tank.

At least one embodiment of the present invention described above and the present invention described in detail below can supply strong alkaline ionized water without waste of water by utilizing electrolysis, and thus the apparatus according to the present invention is economical. It can be installed in a small space.

1 conceptually illustrates a configuration of an alkaline water generating device according to an embodiment of the present invention,
2A is an example of an electrical energy waveform supplied to generate denatured magnetic energy, according to an embodiment of the invention,
2B is an example of an electrical energy waveform supplied to generate denatured magnetic energy according to another embodiment of the present invention,
3 illustrates that magnetic flux is induced in a water tank by electric energy supplied according to an embodiment of the present invention.
4 illustrates a configuration of the power supply unit of FIG. 1 according to an embodiment of the present invention.

An embodiment of an alkaline water generating device according to the present invention will be described in detail with reference to the accompanying drawings.

FIG. 1 conceptually shows a configuration of an alkaline water generating device according to an embodiment of the present invention. In general, two cylindrical water tanks 10a and 10b and spirally wound the water tanks 10a and 10b are spirally wound. And a solenoid 11a and 11b and a power supply 20 for electrically connecting the solenoids 11a and 11b to supply electrical energy, for example, a square wave current. The solenoids 11a and 11b are electrically connected in parallel to the power supply unit 20.

Each of the tanks 10a and 10b is partially filled with a reactant (hereinafter referred to as "media") of a metal material for causing a chemical reaction with the stored water. The media is composed of two kinds of objects each manufactured in the form of a ball so as to have a wide contact area. The first media is made of a metal having a very high ionization tendency, and the second media is an ionization tendency rather than the first media. It is made of an alloy of these two low metals. At this time, one of the two is composed of a metal having a higher ionization tendency than hydrogen and the other is composed of a metal having a lower ionization tendency than hydrogen. For example, the first medium is a magnesium (Mg) ball 31 of high purity, and the second medium is copper (Cu) having a lower ionization tendency than hydrogen and zinc having a higher ionization tendency than hydrogen ( Zn) is a copper alloy ball 32 with a ratio of approximately 8: 2. Media 31 and 32 in the drawings are shown to ignore the actual scale in order to specifically show the principle and concept of the present invention, preferably, the first media is a ball having a diameter of 1 ~ 5mm Form and the purity of magnesium is as high as possible (more than 99.95%) and the second media has a much lower porosity in the baths 10a, 10b than the first media (i.e. The contact area with water per unit volume is made in the form of fine particles or powder so that the contact area with water is wider than that of the first media, and filled in the respective tanks 10a and 10b. The numerical values and weight ratios presented herein are merely examples for carrying out the present invention, and are not necessarily limited to the numerical values and weight ratios presented for achieving the concept and principle of the present invention. Therefore, the invention which is carried out within the range which does not deviate from the concept and principle of this invention by the value different from the above-mentioned numerical value, a weight ratio, etc. shall be regarded as belonging to the scope of the present invention, unless excluded from a claim. The same applies to the specific numerical values, limitations, weight ratios, structures, and the like described in the following description and drawings.

Each of the tanks 10a and 10b are connected to each other through a connection pipe 14 through which water is used, and an inlet pipe 13 is provided in the water tank 10a in which the supplied water is primarily stored. Outflow pipe 15 is coupled to the water tank 10b, which is secondarily stored, and each of the water tanks 10a and 10b is coupled to the inflow pipe 13, the connection pipe 14, and the outflow pipe 15. A distribution hole is formed in the portion so that the water is freely distributed in the direction of water flow, and the portion except for the distribution hole and the discharge hole for discharging the gas vaporized for generating alkaline water is naturally sealed or packed so that water does not leak. For specific purposes, for example, for cleaning the water tank, the respective water tanks 10a and 10b may be provided with discharge ports for discharging water when necessary by removing the plug or the like.

Any part of the outlet pipe 15 is provided with a filter stage 16 to which a filter can be detachably attached, and a valve 17a that can block the flow of water after the filter stage 16. The spring 17 with) is coupled. When the valve 17a is opened using the on / off switch 17b of the water field 17, the water in the water tanks 10a and 10b is supplied to the inlet pipe 13 by the water pressure supplied to the inlet pipe 13. 14 is discharged from the outlet 17c of the spring 17 through the outflow pipe 15 and the filter stage 16.

At this time, the water drained from the outlet 17c is strongly alkaline ionized water (also may be weakly alkaline ionized water according to the method described below), as described above. Details how this is generated.

The water in each of the tanks 10a and 10b is present at equilibrium as water molecules, hydroxide ions and hydrogen ions according to the following reaction formula.

H ₂ 0 ↔ H ⁺ + OH ^- scheme (1)

The first media 31 of magnesium substance in each of the tanks 10a and 10b reacts with the hydrogen ions (H ⁺ ) in the water to produce hydrogen gas (H ₂ ) according to the following reaction formula. . This reaction occurs because magnesium provides electrons to hydrogen because the ionization tendency of magnesium is higher than that of hydrogen.

Mg + 2H ⁺ → Mg ⁺⁺ + H ₂ ↑ Scheme (2)

As hydrogen ions are vaporized with hydrogen gas, the concentration of hydrogen ions (H ⁺ ) in the water in the tanks (10a, 10b) is relatively lower than that of the hydroxide ion group (OH ⁻ ), and thus in the tanks (10a, 10b). The water becomes alkaline.

In the state where the above reaction equations (1) and (2) are naturally made, the power supply unit 20 applies the current of the square wave as illustrated in FIG. 2A to each of the solenoids 11a and 11b. In one embodiment according to the present invention, the voltage and current are 5 V and 6 A (3 A for each bath), respectively, with a duty ratio (= D / W) of 30% and frequency (1 / T) of 15 kHz. Use a square wave. The electrical energy supplied from the power supply unit 20 is converted into magnetic energy of denaturation in each of the solenoids 11a and 11b, and the magnetic energy is water in the tanks 10a and 10b. It acts to increase the alkalinity of. Thus, the rating of the square waves presented above can be varied in various ways to bring the alkalinity of the water to the desired pH value. For example, the duty ratio, the frequency can be increased or decreased, and the current and voltage can also be changed.

In another embodiment according to the present invention, as illustrated in FIG. 2B, a square wave whose polarity is inverted may be applied to the solenoids 11a and 11b.

When the square wave of FIG. 2A or 2B is applied to the solenoids 11a and 11b, the denatured magnetic flux 310 is induced in each of the tanks 10a and 10b as illustrated in FIG. In other words, the magnetic flux is induced intermittently or the direction is reversed up and down. The magnetic energy modified by the magnetic flux induced in this way excites the energy level of the electrons of the first media 31 of magnesium material while disturbing it. Accordingly, the outermost electron of magnesium can react with ions of opposite polarity more easily, so that the reaction according to reaction formula (2) becomes more active. This, in turn, increases the alkalinity in the water, much higher than that of magnesium's natural water contact, so that water of the desired alkalinity (pH 9-10) is produced in the digestion tank.

Meanwhile, magnesium (Mg ⁺⁺ ) of the first media 31 that loses electrons receives electrons from chlorine ions (Cl ⁻ ) dissolved in water and is reduced to magnesium. In addition, the zinc material in the second media 32, which is an alloy of copper and zinc, is also reduced to magnesium by accepting electrons emitted by ionization (Zn ⁺⁺ ). On the other hand, the magnetic energy 310 supplied intermittently or inverted from the solenoids 11a and 11b causes excitation while disturbing the energy level of the outermost electron with respect to the zinc metal of the second media 32. As a result, zinc is ionized at a relatively higher weight ratio than when it is naturally present in the water, ie, releases more electron ions into the water. And zinc (Zn ⁺⁺ ) in the alloy that loses electrons accepts the electrons emitted by copper ionization (Cu ^{N +} , N is determined by how much copper is used in the alloy). It may be reduced. Ionized copper receives electrons from chlorine ions (Cl ⁻ ) dissolved in water and reduces them to the original copper metal.

Magnesium in the first media 31 is supplemented with electrons supplied to hydrogen ions (H ⁺ ) while being ionized and reduced to metal as described above, so that the mass is preserved almost unchanged. Therefore, it can be used semi-permanently.

Preferably, the first media 31 is made of pure magnesium material, but it is almost impossible to manufacture the first media 31 with 100% purity. Therefore, the first media 31 inevitably contains about 0.05% of impurities even when manufactured in an optimal process. Such impurities may include heavy metals, and these heavy metal components may be dissolved in water and exist in an ionic state. The heavy metal ionized as described above captures electrons released into the water, for example, electrons emitted from zinc of the second media 32 and is precipitated as a metal material. The heavy metal material thus precipitated is the filter stage 16 installed in the outlet pipe 15 according to the flow of the valve 17a of the water field 17 when the water is discharged to the outlet 17c. Precipitates as a solid by a filter of.

As illustrated in FIG. 4, the power supply unit 20 for supplying electrical energy to each of the solenoids 11a and 11b includes a setting unit 410 that receives a setting such as a pH of water and a set condition according to a set condition. A waveform generator 430 for outputting an electric waveform, a power driver 440 for supplying a current having a specified intensity according to the output waveform, and a value or mode set by the setting unit 410 And a controller 420 for determining a suitable electrical energy condition (eg, driving waveform type, duty ratio, frequency, etc.) and designating the condition to the waveform generator 430.

The setting unit 410 may be a key that allows the user to set a pH value suitable for the purpose of drinking or using the drink, or a key for designating a drinking mode (for example, healthy water or therapeutic water). And a user presses a corresponding key to transmit a corresponding signal to the controller 420. The controller 420 determines or determines a pH value of water desired by the user from the transmitted signal, and sets an electrical variable, for example, a duty ratio and / or a frequency, required to generate water of the pH value. Determine the initial environmental variables (e.g. magnetic energy conversion of electrical energy, alkalinity of water according to magnetic energy to the dimensions of the bath). In one embodiment according to the present invention, an appropriate waveform (for example, a triangle wave envelope, a triangle wave, a sine wave, etc.) may be selected.

The waveform generator 430 generates an electric waveform that meets the conditions set by the controller 420, and the power driver 440 outputs a current rated according to the waveform, thereby providing the respective solenoids 11a and 11b. ) To supply electrical energy. As a result, the magnetic energy is supplied to the respective water tanks 10a and 10b intermittently or alternately so that the water becomes alkaline.

According to the above-described process, since the water in each of the tanks 10a and 10b can maintain the alkalinity as desired, the user can open the valve 17a at any time by opening the valve 17a of the spring 17. The individual withdrawn from 17c) can drink or use the weakly alkaline or strongly alkaline ionized water set for the intended use.

On the other hand, the present invention is not limited to the above-described typical preferred embodiments, but can be carried out in various ways without departing from the spirit and the subject matter of the present invention in various ways that can be carried out in the art Those of ordinary skill can easily understand. It is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, it is intended to cover various modifications within the scope of the appended claims.

10a, 10b: water tank 11a, 11b: solenoid
16: filter stage 17: spring
20: power supply 31, 32: metal reactant
410: setting unit 420: control unit
430: waveform generator 440: power driver

Claims (6)

In the apparatus for generating alkaline water,
A water tank in which water is stored and water can be obtained and discharged through inlets and outlets,
A magnetic flux part including a solenoid composed of a coil helically surrounding the outside of the water tank to induce denatured magnetic energy in the space within the water tank;
A power unit for supplying electrical energy necessary for generating the denatured magnetic energy;
And comprises two types of reactants that are included as separate entities within the tank to contact the water,
One type of the reactant is an alloy of copper (Cu) having a higher ionization tendency than hydrogen and a zinc (Zn) having a lower ionization tendency than hydrogen, and another type of the reactant is magnesium having a higher ionization tendency than the copper (Cu). (Mg),
In the alloy, the copper (Cu) and zinc (Zn) has a weight ratio of 8: 2,
Each of the reactants is in the form of a ball or granule, wherein the one type of reactant is manufactured to a smaller size so that the porosity is lower than that of the other types of reactants,
The water tank is composed of a plurality of interconnected by a connecting pipe, each tank is provided with the magnetic flux, each magnetic flux is electrically connected to each other in parallel to the power unit. delete The method of claim 1,
And said power unit provides said electrical energy by outputting current intermittently or with reversing polarity. delete The method of claim 1,
And a filter for filtering substances deposited in the water discharged from the water tank, installed in an outlet pipe connected to the water outlet of the water tank. delete

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