KR102244803B1 - Liquid Salts manufacturing system and Liquid Salts manufacturing method using the same - Google Patents

Abstract

Provided are a nano-energy water salt production system and a water salt production method using the same. According to the present invention, by dissolving sea salt, adjusting and reducing salinity, transferring minerals, removing heavy metals, and performing sterilization, liquefied water salt can be produced. Thus, convenience of storage and hygienic usage are possible according to airtight storage in a bottle or the like. In particular, when used for flour dough or pickled kimchi, the present invention enables simple and quick usage without a separate dissolution process. In addition, production is possible while minerals in salt are maintained. In particular, stability is secured at the time of ingestion according to the removal of heavy metals harmful to a human body. Also, potential energy is transferred to enable even and rapid absorption into a human body at the time of ingestion. A body potential balance for providing an optimal environment for microorganisms to live in a human body after ingestion is maintained. Accordingly, it is possible to enhance immunity.

Description

Nano energy water salt manufacturing system and water salt manufacturing method using the same {Liquid Salts manufacturing system and Liquid Salts manufacturing method using the same}

The present invention is for preparing liquid salt, and in more detail, it is possible to use hygienic, and in more detail, nano-energy water for promoting health when ingested by increasing the content of various ingredients that are beneficial to the human body while bringing convenience in use of salt. It relates to a salt manufacturing system and a water salt manufacturing method using the same.

Salt is a mineral obtained from the sea, salt lakes, and salt mines. In Korea, salt is mainly taken from the sea.

At this time, the salt obtained by evaporating seawater is called sea salt, and the salt obtained by removing impurities from the sea salt and boiling it is called re-decontamination.

Sea salt refers to salt produced by inflow of seawater into a reservoir and concentrating it using nature such as solar heat and wind.The method of manufacturing such sea salt is produced in the same way that it has been traditionally produced for hundreds of years.Therefore, there is a lot of controversy over the content of impurities. There is room

Nevertheless, re-decontamination is said to be better for health because various minerals disappear during the manufacturing process. However, since the quality of the sea salt varies depending on the water content (concentrated seawater) and the sanitary conditions of the salt field, re-decontamination may sometimes be better.

Nevertheless, since sea salt does not undergo a purification process, it does not contain only sodium chloride (NaCl), but also contains various minerals, amino acids, and enzymes, so it can be an alternative to solve the problem of purified salt.

However, the problem is the pollutants in the sea salt. As the sea is polluted, pollutants from various household wastes such as heavy metals and detergents flowing from rivers and factories are bound to be contained in the sea salt. In addition, Korea is pitifully carrying over 300,000 tons of livestock wastewater a year by boat to the sea, and the pollution of sea salt has reached a level that cannot be overlooked.

What is even more problematic is'Haeju'. In the process of making sea salt, there is a facility that traps seawater in a puddle to prevent rainwater from mixing when the weather is bad. Haeju is a valuable facility that is indispensable for making sea salt, but the problem is the roofing material. In the past, the roof was covered with things made of wood or straw, but it is a reality that most of them now wear slit.

Anyone who knows these slits may already know, but it contains a lot of asbestos. When it was new, only the asbestos powder that had been buried in it would fall, but later, as it gets old, it corrodes like iron, and a lot of asbestos comes out in between. As it is, it is mixed with the concentrated seawater contained in Haeju, and the vicious cycle continues to enter the sea salt.

On the other hand, Korean sea salt is superior to world-class luxury salts including French Guerrand salt in terms of the diversity and content of physiologically active substances such as minerals and amino acids. Nevertheless, these pollutants are playing a part in the fact that they do not stand out in the global luxury salt market. Considering this fact, in order to become a luxury sea salt, the development of technology to drastically reduce pollutants in sea salt must be preceded above all else.

Accordingly, in order to solve the above problems, various apparatuses and methods have been proposed for manufacturing re-decontamination containing minerals while minimizing contamination of sea salt.

However, since the above-described salt is similar to sea salt and forms solid crystals, it is difficult to handle such as storage, so there is a problem that it is contaminated in the handling process.In particular, it must be dissolved in water when pickling flour or kimchi. There was a very uncomfortable problem.

Korean Patent Registration No. 10-1636656. Korean Patent Registration No. 10-0232744.

The present invention was invented to solve the above problems, and it is possible to manufacture liquefied water salt through dissolution, salt control and reduction of sea salt, mineral transfer, removal of heavy metals, sterilization, etc., thereby sealing it in bottles, etc. Nano-energy water salt production system and water salt production method using the same to enable convenient and hygienic use according to storage, and to enable simple and quick use without a separate dissolution process, especially when used for dough or kimchi pickling It is an object of the present invention to provide.

In addition, it makes it possible to manufacture while maintaining the minerals contained in salt. In particular, it secures stability when ingested by removing heavy metals that are harmful to the human body, and enables even and rapid absorption in the body when ingested, and microorganisms inhabit the body after ingestion. It is an object of the present invention to provide a nano-energy water salt production system and a water salt production method using the same for increasing immunity according to maintaining the potential balance in the body, such as providing an optimal environment.

Specific means for achieving the above object include: a dissolving unit for obtaining water salt by dissolving the sea salt through receiving, heating, and stirring water and domestic sea salt;

A salinity control unit connected to the dissolving unit and a first transfer pipe having a pump to receive and cool the water salt in which the sea salt is heated and dissolved, and adjust the salinity while cooling;

A reduction unit that is connected to the salinity control unit and a second transfer pipe having a pump to receive water salt whose salinity is adjusted, and to alkalize the water salt by magnetizing the water salt;

A mineral transfer unit connected to the reduction unit and a third transfer pipe having a pump to receive alkalized water salt and transfer minerals to the water salt;

A first filtering unit connected to the mineral transfer unit and a fourth transfer pipe having a pump to receive water salt to which the mineral has been transferred, and to filter heavy metals contained in the water salt;

A maturation unit connected to the first filtering unit and a fifth transfer pipe having a pump to receive the first filtered water salt to be aged;

A second filtering unit connected to the aging unit through a sixth transfer pipe having a pump to receive the aging water salt and to filter the secondarily to remove residual heavy metals and foreign substances; And

It comprises a sterilization storage unit connected to the second filtering unit and a seventh transfer pipe having a pump to receive the filtered water salt and sterilize storage prior to shipment,

A dissolution step of obtaining water salt by dissolving the sea salt by using a nano-energy water salt production system, but stirring 50% by weight of domestic sea salt and 50% by weight of water in a solid form while maintaining a temperature of 70 to 80°C in a dissolution tank;

A salinity control step of accommodating and cooling the dissolved water salt to a salinity control tank and supplying cold water to reach a salinity of 20 to 30%;

A reduction step of storing and circulating the water salt whose salinity is adjusted in a reduced water storage tank to alkalinize it;

A mineral transfer step of transferring the minerals contained in the mineral to the water salt by passing the alkali and water salt through the mineral;

A first filtering step of adsorbing heavy metals contained in the water salt and removing odors by passing the water salt to which the minerals have been transferred through a carbon filter in a first filtering unit;

A aging step of aging the first filtered water salt;

A second filtering step of finally passing the aged water salt through a hollow fiber membrane filter in a second filtering unit to remove heavy metals and foreign substances contained in the water salt; And

This can be achieved by performing a sterilization storage step of storing and sterilizing the final filtered water salt in a storage tank.

As described above, the nano-energy water salt production system of the present invention and the water salt production method using the same include dissolution through stirring, control of salinity, removal of heavy metals, aging, and sterilization. This means that hygienic storage is easy according to simple storage in bottles, etc., and it is possible to obtain a very convenient effect by using an appropriate amount quickly and simply without a separate dissolution process.

In addition, since the minerals contained in salt are preserved and heavy metals harmful to the human body are effectively removed, safe intake is possible, and when ingested, even and rapid absorption in the body can be obtained, thereby improving health.

1 is an overall view of the nano-energy water salt production system of the present invention.
Figure 2 is a schematic view of the melting part of the nano-energy water salt production system of the present invention.
Figure 3 is a schematic view of the salinity control part of the nano-energy water salt production system of the present invention.
Figure 4 is a schematic view of the reduction part of the nano-energy water salt production system of the present invention.
Figure 5 is a schematic view of the reduction water system of the present invention nano-energy water salt production system.
Figure 6 is a partial view of the mineral transfer part of the nano-energy water salt production system of the present invention.
Figure 7 is a schematic view of the first filtering part of the nano-energy water salt production system of the present invention.
Figure 8 is a main part of the maturation part of the nano-energy water salt production system of the present invention.
9 is a main part of the second filtering unit of the nano-energy water salt production system of the present invention.
Figure 10 is a main part of the sterilization storage unit of the present invention nano-energy water salt production system.
11 is an overall process diagram showing a water salt production method using the nano-energy water salt production system of the present invention.

The terms or words used in the specification and claims should not be construed as being limited to their usual or dictionary meanings, and the inventor may appropriately define the concept of terms in order to describe his own invention in the best way. It should be interpreted as a meaning and concept consistent with the technical idea of the present invention based on the principle that there is.

Accordingly, the embodiments described in the present specification and the configurations shown in the drawings are only the most preferred embodiments of the present invention, and do not represent all the technical ideas of the present invention, so that they can be replaced at the time of application. It should be understood that there may be various equivalents and variations.

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

1 is an overall view of the nano-energy water salt production system of the present invention.

As shown in FIG. 1, the nano-energy water salt production system of the present invention includes a dissolution part, a salinity control part 200, a reduction part 300, a mineral transfer part 400, a first filtering part 500, and , A maturation part 600, a second filtering part 700, and a sterilization storage part 800.

First, the melting unit 100 is capable of obtaining a liquid water salt by heating and stirring with water while receiving the sea salt in constructing the nano-energy water salt production system of the present invention.

To this end, the dissolving unit 100 is configured with a dissolution tank 110 capable of receiving solid salt for dissolution, that is, sea salt and water, with reference to FIG. 2.

At this time, in the present invention, the dissolution tank 110 has a cylindrical shape with a hollow inside, and a sea salt inlet 111 through which the sea salt can be injected is formed on one side of the upper side thereof, and a separate water supply hose (in the drawing (Not shown) is connected to the water input valve 112 through which water can be injected through an opening/closing operation, so that a water tank or the like in which purified water is separately accommodated is configured to be connected.

And the dissolution tank 110 is configured to be connected to the salinity control unit 200 through the first transfer pipe (10).

In addition, the melting unit 100 is configured with a stirrer 120 for mixing the received sea salt and water, at this time, the stirrer 120 is not newly implemented, it is mounted on the melting tank 110, and a conventional motor 122 It is possible if a plurality of driven stirring blades 121 are formed, and the sea salt and water are stirred through the stirring blades 121.

In addition, the melting unit 100 is configured with a heater 130 that dissolves the sea salt by heating in the process of stirring the sea salt and water as described above, and at least one heater 130 is installed in the dissolution tank 110.

In addition, the melting unit 100 is configured with a temperature sensor 140 for measuring the temperature of the heated water in heating the sea salt and water through the heater 130 as described above, the temperature sensor 140 is a melting tank ( 110).

In addition, the melting unit 100 includes a temperature control unit 150 for maintaining a constant temperature of water heated through the temperature sensor 140 as described above.

At this time, the temperature control unit 150 is connected to the temperature sensor 140 and configured to set a heating reference temperature, and stops the operation of the heater 130 when the temperature measured by the temperature sensor 140 is higher than the reference value. , When it falls, it is operated to maintain a constant temperature continuously.

On the other hand, in the embodiment of the present invention, the reference temperature is preferably set to 70 ~ 80 ℃, this is to minimize the destruction of minerals contained in the sea salt.

That is, in the dissolution unit 100, the sea salt and water contained in the dissolution tank 110 are stirred and heated to dissolve the sea salt in water to obtain a liquid water salt.

The salinity control unit 200 is configured to control and cool the water salt dissolved in the melting unit 100 to a predetermined concentration in configuring the nano-energy water salt production system of the present invention. 1 is configured to be connected to the melting tank 110 of the melting unit 100 through the transfer pipe 10.

To this end, the salinity control unit 200 refers to FIG. 3, first, a salinity control tank 210 that is connected to the dissolution tank 110 and the first transfer pipe 10 to receive and store the dissolved water salt. It is composed.

At this time, in the present invention, a cold water supply valve 211 is configured to separately receive cold water such as purified water in the salinity control tank 210 so that the concentration of dissolved water salt can be adjusted and cooled by receiving cold water.

In addition, the salinity control tank 210 is connected to a second transfer pipe 20 connected to a reduction unit 300 to be described later, and is configured to discharge water salt whose salinity is adjusted to the reduction unit 300.

In addition, the salinity control unit 200 includes a salinity meter 220 capable of measuring the salinity controlled by supplying cold water as described above.

That is, the salinity control unit 200 stores the water salt dissolved in the salinity control tank 210, while supplying cold water to adjust cooling and salinity, and the adjusted salinity is measured through the salinity meter 220. As a result, it is possible to adjust a certain concentration.

The reduction unit 300 is configured to make the water salt whose salinity is adjusted as described above with alkali in constructing the nano-energy water salt production system of the present invention, and the second transfer pipe 20 operating the pump P It is configured to be connected to the salinity control tank 210 of the salinity control unit 200 through.

To this end, the reduction unit 300 is firstly configured with a reduced water storage tank 310 connected to the salinity control tank 210 and the second transfer pipe 20 to receive and store water salt with reference to FIG. 4. .

And the reduced water storage tank 310 is configured to be connected to the mineral transfer unit 400 to be described later through the third transfer pipe (30).

In addition, the reducing unit 300 is configured with a reducing water device 320 that circulates and alkalizes the water salt stored in the reduced water storage tank 310.

At this time, the reduction water tank 320 is composed of a reduction tank 330 that circulates and reduces water salt first, with reference to FIG. 5, and the reduction tank 330 circulates between the reduced water storage tank 310 and the bottom. It is connected to the supply pipe 331 and is connected to the reduced water storage tank 310 through a circulation discharge pipe 332 at the top, so that water salt can circulate the reduced water storage tank 310 and the reduction tank 330.

In addition, the reduction water tank 320 includes a magnetization treatment unit 340 for alkalinizing water salt filled in the reduction tank 330 and supplied to the reduction tank 330 by magnetization.

In this case, in the present invention, the magnetization treatment unit 340 is configured to magnetize water by providing electric force to the water salt circulated as described above.

To this end, the magnetization treatment unit 340 is, first, a mesh body 341, 341 ′ forming a mesh that enables water to communicate with the upper and lower portions of the reduction tank 330 and prevents the ceramic ball 342 from being separated from each other, which will be described later. Is composed of each.

In addition, the magnetization processing unit 340 is filled with a plurality of ceramic balls 342 for transferring potential energy by magnetizing water that substantially provides electrical force between the mesh bodies 341 and 341 ′.

At this time, in the present invention, the ceramic ball 342 is composed of tourmaline to provide electric power, and is composed of tourmaline, which is a tourmaline, to constitute a tourmaline in the present invention.

To this end, in the present invention, the ceramic ball 342 is pulverized by grinding tourmaline, kneading 80% by weight of the powdered tourmaline and 20% by weight of pulverized sawdust to form a ball, and firing the formed ball. It is composed of.

Accordingly, the sawdust of the molded ball is burned during firing. At this time, the ceramic ball 342 in which the sawdust is burned has a plurality of pores formed to have porosity.

On the other hand, tourmaline, as known, releases far-infrared rays and negative ions through electrolysis to alkalinize it. When ingested, tourmaline generates nano-energy that decomposes active oxygen in the body to promote thermal fluid circulation as well as activate cell activity to human body potential. It keeps the balance.

Accordingly, the water salt is made alkaline in the process of passing through the tourmaline ceramic ball 342, and at this time, the porous ceramic ball 342 improves the contact force with the water salt and improves the decomposition rate.

In addition, a vortex fan 350 for providing a flow rate through which the water salt can pass through the magnetization treatment unit 340 by generating a vortex in the water salt supplied to the reduction tank 330 is configured. , The vortex fan 350 is configured at the lower inner side of the reduction tank 330, while being configured to be driven by a motor, and directed upward to the water salt supplied to the lower portion of the reduction tank 330 through the circulation supply pipe 331. A vortex is formed to pass through the ceramic ball 342 of the magnetization treatment unit 340.

In addition, the reduction water device 320 includes an oxygen supply unit 360 for supplying oxygen to the bottom of the reduction tank 330, wherein the oxygen supply unit 360 includes an oxygen supply pipe 361 having a pump 361a. It is configured to be connected to the reduction tank 330 through.

In addition, a plurality of oxygen injection nozzles 370 for providing aeration by injecting the supplied oxygen into the reduction tank 330 are configured in the reducing water device 320.

At this time, the oxygen injection nozzle 370 is formed on the bottom of the reduction tank 330 and is configured to be connected to the oxygen supply pipe 361, and the supplied oxygen is transferred to the water salt from the bottom of the reduction tank 330. The water salt is aerated by high pressure spraying.

That is, in the reduction water tank 320, oxygen is supplied to the water salt supplied to the lower portion of the reduction tank 330 through the circulation supply pipe 331 and aerated to decompose water molecules and the aerated water salt is vortex fan 350. Alkaliization is performed by passing through the magnetization treatment unit 340 through the formation of a vortex. At this time, the supplied oxygen increases the amount of dissolved oxygen in the water salt, while fine bubbles are formed in the process of passing through the pores of the ceramic ball 342 to prevent water and water. It facilitates the mixing of oxygen and promotes alkalization.

The mineral transfer unit 400 is configured to increase minerals in the alkalinized water salt as described above in configuring the nano energy water salt production system of the present invention, and the third transfer pipe 30 operating the pump P It is configured to be connected to the reduced water storage tank 310 through.

To this end, the mineral transfer unit 400 includes a first mineral transfer unit 410, a second mineral transfer unit 420, a third mineral transfer unit 430, and a fourth mineral transfer unit with reference to FIG. 6. It consists of 440.

At this time, the first mineral transfer unit 410 is configured to first transfer minerals by receiving alkali-reduced water salt, and is configured in a hollow cylindrical shape, and is connected to the third transfer pipe 30. , The inside is configured to be filled with silver nano, a mineral that emits minerals.

In addition, the second mineral transfer unit 420 is configured in a cylindrical shape with a hollow inside, is connected to the first mineral transfer unit 410 by a pipe, while the inside is configured to be filled with mica, a mineral that emits minerals. do.

In addition, the third mineral transfer unit 430 is configured in a hollow cylindrical shape, and is connected to the second mineral transfer unit 420 by a pipe, while the inside is configured to be filled with loess, a mineral that emits minerals. do.

In addition, the fourth mineral transfer unit 440 is configured in a cylindrical shape having a hollow inside, is connected to the third mineral transfer unit 430 by a pipe, and is configured to be filled with tourmaline that radiates minerals therein.

In addition, the fourth mineral transfer unit 440 is configured to be connected to the first filtering unit 500 through the fourth transfer pipe 40.

That is, the mineral transfer unit 400 receives minerals contained in the mineral in the process of passing the water salt through the first to fourth mineral transfer units 410, 420, 430, and 440.

The first filtering unit 500 is configured to remove heavy metals, various foreign substances, and odors contained in the water salt to which minerals have been transferred as described above, in configuring the nano energy water salt manufacturing system of the present invention, and the pump (P) It is configured to be connected to the fourth mineral transfer unit 440 of the mineral transfer unit 400 through the operating fourth transfer pipe 40 to receive water salt.

To this end, the first filtering unit 500 is a first filtering housing in the form of a cylindrical body connected to the fourth mineral transfer unit 440 and the fourth transfer pipe 40 to receive water salt, referring to FIG. 7. 510 is constructed.

In addition, the first filtering housing 510 is configured to be connected to the aging unit 600 to be described later through the fifth transfer pipe 50.

In addition, the first filtering unit 500 includes a carbon filter 520 installed inside the first filtering housing 510 and having a porosity capable of filtering while water salt passes.

That is, the first filtering unit 500 receives water salt from the mineral transfer unit 400 and passes through the carbon filter 520 to filter.

The aging unit 600 is configured to mature the first filtered water salt as described above in configuring the nano-energy water salt production system of the present invention, through the fifth transfer pipe 50 operating the pump (P). It is configured to be connected to the first filtering housing 510 of the first filtering unit 500 to receive water salt.

To this end, the maturation unit 600 is first connected to the first filtering housing 510 and the fifth transfer pipe 50 with reference to FIG. 8 to form a maturation tank 610 capable of receiving and storing water salt. .

And the maturation tank 610 is configured to be connected to the second filtering unit 700 to be described later through the sixth transfer pipe (60).

In addition, the aging unit 600 is configured with a vibrating column 620 for imparting micro-vibration to the water salt accommodated in the aging tank 610, wherein a plurality of vibrating columns are vertically installed inside the aging tank 610. It is composed.

And each of the vibrating pillars 620 is configured with a vibrator 621 at the top to impart a vibrating force.

In addition, a plurality of magnet bodies 630 are formed around each of the vibration pillars 620 in the aging part 600.

That is, in the process of receiving and storing water salt, the maturation unit 600 imparts fine vibrations to the water salt to impart fluidity, while the magnet body 630 applies a magnetic force to be magnetized.

The second filtering unit 700 is configured to remove heavy metals and various foreign substances contained in the aged water salt in constructing the nano-energy water salt production system of the present invention, and the sixth pump P operates. It is connected to the aging tank 610 of the aging unit 600 through the transfer pipe 60 and configured to receive water salt.

To this end, the second filtering unit 700 is firstly connected to the aging tank 610 and the sixth transfer pipe 60, and the second filtering housing 710 in the form of a cylindrical body to receive water salt, with reference to FIG. 9. It is made up.

In addition, the second filtering housing 710 is configured to be connected to the sterilization storage unit 800 to be described later through the seventh transfer pipe 70.

In addition, the second filtering unit 700 includes a hollow fiber membrane filter 720 installed inside the second filtering housing 710 and capable of filtering while water salt passes.

That is, the second filtering unit 700 receives water salt from the aging unit 600 and passes through the hollow fiber membrane filter 720, and in the process of passing through the hollow fiber membrane filter 720, the heavy metal Various foreign substances such as etc. are removed and mineral components are passed through it as it is.

The sterilization storage unit 800 is configured to sterilize and store the second filtered water salt prior to shipment in configuring the nano-energy water salt production system of the present invention. It is connected to the second filtering housing 710 of the second filtering unit 700 through the transfer pipe 70 and configured to receive water salt.

To this end, the sterilization storage unit 800 is configured with a storage tank 810 connected to the second filtering housing 710 and the seventh transfer pipe 70 to receive and store water salt, referring to FIG. 10. In this case, the storage tank 810 may be configured in plural.

And each storage tank 810 is configured with a discharge valve 811 that enables the discharge of water salt for shipment.

In addition, the sterilization storage unit 800 is configured with a pair of electrodes 820 and 820 ′ that generate ions in water salt when power is applied to each of the storage tanks 810, and each electrode is known as It is composed of silver (Ag) and copper (Cu), respectively, which have sterilizing power.

That is, the sterilization storage unit 800 receives and stores water salt, while sterilizing water salt through silver ions and copper ions during the storage process.

Hereinafter, a method for producing water salt using the nano-energy water salt production system of the present invention having the above configuration will be described.

11 is an overall process diagram showing a water salt manufacturing method using the nano-energy water salt manufacturing system of the present invention.

Referring to Figures 1 to 10, as shown in Figure 11, the water salt production method using the nano-energy water salt production system of the present invention includes a dissolution step (S100), a salinity control step (S200), and a reduction step (S300). Wow, a mineral transfer step (S400), a first filtering step (S500), a aging step (S600), a second filtering step (S700), and a sterilizing storage step (S800) are performed.

First, the dissolution step (S100),

In performing the water salt production method using the nano-energy water salt production system of the present invention, a liquid water salt is obtained by dissolving a solid salt.

To this end, in the dissolution step (S100), referring to FIG. 2, first, 50% by weight of domestic sea salt and 50% by weight of purified water are respectively added to the dissolution tank 110 through the sea salt inlet 111 and the water input valve 112. Put it in.

And it dissolves the added sea salt, which firstly drives the stirrer 120 installed in the dissolution tank 110 to mix and stir evenly, while operating the heater 130 to heat and dissolve.

Meanwhile, in the present invention, it is preferable to dissolve while maintaining the temperature at 70 to 80°C when heated as described above. In this case, maintaining the temperature as above means that minerals contained in salt are destroyed at 80°C or higher. , It is preferable to keep it above 70°C, as it is maintained not to exceed 80°C to prevent the destruction of minerals, and if heated to 70°C or less, the melting time is delayed and the melting power of the salt is lowered.

At this time, in the present invention, it is possible to maintain the above-described temperature by the temperature control unit 150, and the temperature control unit 150 measures the temperature of the water salt dissolved through the temperature sensor 140 and uses the temperature control unit 150. Accordingly, the temperature control unit 150 stops the operation of the heater 130 when the temperature increases, and maintains the temperature by operating when the temperature decreases.

That is, in the dissolving step (S100), the concentrated water salt in which the sea salt is dissolved is obtained by mixing and heating the sea salt and water.

Then, the salinity control step (S200),

In performing the water salt production method using the nano-energy water salt production system of the present invention, the concentrated water salt in which the sea salt is melted is cooled and the salinity is adjusted as described above.

To this end, in the salinity control step (S200), referring to FIG. 3, first, the dissolved water salt is supplied from the dissolution tank 110 through the first transfer pipe 10 and stored in the salinity control tank 210. .

And the salinity is adjusted, but this is possible by diluting by supplying cold water through the cold water supply valve 211.

At this time, in adjusting the salinity in the present invention, the salinity is measured, which is confirmed through the salinity meter 220 installed in the salinity control tank 210 and the amount of water input can be adjusted.

On the other hand, it is preferable that the salinity controlled in the present invention is adjusted to 20 to 30%, which is that if the salinity is set to 30% or more, an excess of sodium components that are not beneficial to the human body may be contained. If it is less than 20%, there is a problem in that the liquid phase is excessively used when cooking food with excessively reduced salinity, and it is preferable to adjust the salinity to 20 to 30%.

That is, in the salinity control step (S200), cold water is supplied to the dissolved concentrated water salt to adjust the salinity by diluting it, while cooling the water salt heated through the cold water is possible.

Then, the reduction step (S300),

In performing the water salt production method using the nano-energy water salt production system of the present invention, the water salt whose concentration is adjusted as described above is alkalized.

To this end, in the reduction step (S300), referring to FIGS. 4 and 5, first, water salt stored in the salinity control tank 210 is supplied through the second transfer pipe 20 and stored in the reduced water storage tank 310. It is done.

And it is reduced to alkaline water by circulating the stored water salt, which is possible in the reduction water tank (320).

First, the water salt of the reduced water storage tank 310 is supplied to the lower portion of the reduction tank 330 through the circulation supply pipe 331.

In addition, the oxygen supply unit 360 generates oxygen and supplies it to the lower portion of the reduction tank 330, and the supplied oxygen is highly mixed and injected through the oxygen injection nozzle 370, and the supplied water salt is aerated. It decomposes water molecules.

Thereafter, the aerated water salt is reduced to alkaline water by passing through the magnetization treatment unit 340 and performing magnetization treatment, but when the vortex fan 350 is driven, a vortex toward the top is formed in the lower portion of the reduction tank 330. , Water salt passes through the magnetization treatment unit 340 and discharges through the circulation discharge pipe 332 by the vortex.

Accordingly, the water salt passing through the magnetization treatment unit 340 is reduced to the alkalinity to which the potential energy (0.06 mA) is transferred in the process of passing through the porous ceramic ball 342 made of tourmaline.

That is, in the reduction step (S300), the water salt stored in the reduced water storage tank 310 is passed through the reduction water tank 320 to alkalize water molecules, and at this time, the amount of dissolved oxygen is increased through oxygen supply and the oxygen injection nozzle 370 is used. Aeration and fine bubbles are formed through the pores of the ceramic ball 342 to facilitate mixing of water and oxygen.

On the other hand, in the present invention, by performing the reduction of water salt through the reduction water device 320 as described above three times, stable alkaline water can be obtained, and the alkali-reduced water salt is stored in the final reduced water storage tank 310. It is done.

Thereafter, the mineral transfer step (S400),

In performing the water salt production method using the nano-energy water salt production system of the present invention, the alkali-reduced water salt as described above is transferred by energy, that is, minerals are transferred.

To this end, in the mineral transfer step (S400), referring to FIG. 6, first, water salt that has been alkalized and stored in the reduced water storage tank 310 is supplied through the third transfer pipe 30 to transfer the minerals to the water salt. , This is made possible through the first to fourth mineral transfer units 410, 420, 430, and 440.

That is, the supplied water salt is first introduced into the first mineral transfer unit 410. At this time, the water salt melts the minerals contained in the silver nano, which is a mineral in the process of passing through the silver nano, to be contained in the water salt.

The water salt is introduced into the second mineral transfer unit 420 again. In this case, the water salt melts the minerals contained in the mineral mica in the process of passing through the mica and is contained in the water salt.

In addition, the water salt is introduced into the second mineral transfer unit 420 again. At this time, the water salt melts the minerals contained in the mineral loess in the process of passing through the loess and is contained in the water salt.

In addition, the water salt is introduced into the second mineral transfer unit 420 again. At this time, the water salt melts the minerals contained in the tourmaline, which is a mineral, and is contained in the water salt in the process of passing through the tourmaline.

Meanwhile, in configuring the mineral transfer unit 400 in the present invention, the application of the first to fourth mineral transfer units 410, 420, 430, and 440 each filled with different minerals is beneficial to the human body. Minerals are made up of various types such as calcium, magnesium, potassium, phosphorus, and zinc, so that various minerals can be provided to water salt through each mineral.

That is, in the mineral transfer unit 400, water salt is passed through the first to fourth mineral transfer units 410, 420, 430, and 440 to supply various minerals included in each mineral.

Thereafter, the first filtering step (S500),

In performing the water salt production method using the nano-energy water salt production system of the present invention, the water salt to which the minerals have been transferred is filtered as described above to remove heavy metals and foreign substances contained in the water salt, and to remove odors.

To this end, in the first filtering step (S500), water salt that has passed through the first mineral transfer unit 410 through the fourth transfer pipe 40 is supplied with reference to FIG. 1 It passes through the inside of the filtering housing 510, and is filtered by the carbon filter 520 in the process of passing.

That is, in the first filtering step (S500), water salt is first filtered by passing through the carbon filter 520, but in the process of passing through the carbon filter 520, various heavy metals, foreign substances, and odors are adsorbed and removed, and mineral components are removed. It will remain as it is.

Thereafter, the aging step (S600),

In performing the water salt production method using the nano-energy water salt production system of the present invention, the first filtered water salt as described above is aged.

To this end, in the aging step (S600), water salt is supplied from the first filtering unit 500 through the fifth transfer pipe 50 with reference to FIG. 8 and stored in the aging tank 610. You will save it for hours.

At this time, in the aging step (S600), the water salt is subjected to magnetization in the storage process as described above. First, the vibration pillar 620 for imparting a vibration force through the vibrator 621 inside the aging tank 610. ) Is configured, and a wave is generated in the water salt due to the vibration of the vibrating column 620 so that it flows evenly.

In addition, the water salt flowing as described above is brought into contact with the magnet body 630 formed on the vibrating column 620, and is subjected to magnetization in the process of contacting the magnet body 630 to decompose water molecules once more. do.

In other words, in the aging step (S600), water salt is aged at room temperature for a certain period of time, while magnetic force is applied during the storage process to decompose water molecules, thereby making the absorption rate faster when ingested.

Thereafter, the second filtering step (S700),

In performing the water salt production method using the nano-energy water salt production system of the present invention, the water salt aged as described above is secondarily filtered to remove heavy metals and foreign substances contained in the water salt.

To this end, in the second filtering step (S700), water salt is supplied from the aging tank 610 through the sixth transfer pipe 60 with reference to FIG. 9, and the second filtering housing 710 of the second filtering unit 700 ) It is passed through the inside, but is filtered by the hollow fiber membrane filter 720 in the passing process.

That is, in the second filtering step (S700), water salt is passed through the hollow fiber membrane filter 720 for secondary filtering, but in the process of passing through the hollow fiber membrane filter 720, various heavy metals and foreign substances are adsorbed and removed, and mineral components are removed. It will remain as it is.

In the sterilization storage step (S800), in performing the water salt manufacturing method using the nano-energy water salt manufacturing system of the present invention, the second filtered water salt is supplied and stored and stored prior to shipment.

To this end, in the sterilization storage step (S800), water salt is supplied through the seventh transfer pipe 70 and stored in the storage tank 810 with reference to FIG. 10.

At this time, in the present invention, sterilization is performed in the process of storing in the storage tank 810 as described above, which is made possible by the electrolysis of the electrodes made of silver (Ag) and copper (Cu).

That is, in the sterilization storage step (S800), water salt is supplied and stored in the storage tank 810, while the silver ions generated in the silver electrode 820 during the storage process prevent the growth of bacteria in water, and copper. By eradicating the copper ions generated in the electrode 820', various algae and bacteria of water salt stored by the silver ions and copper ions are sterilized.

Thereafter, the production of water salt is completed through a series of processes as described above, and the water salt produced and stored in this way is discharged and shipped through the discharge valve 811 formed in the storage tank 810.

As described above, in the present invention, liquid water salt can be prepared through the nano energy water salt production system, and the water salt thus prepared is very convenient to use and store, and in particular, can be easily absorbed into the body when ingested, Due to its alkalized nature, when ingested, it generates nano-energy that decomposes active oxygen in the body to promote thermo-liquid circulation as well as activate cell activity to maintain human potential balance.

100: melting unit 110: melting tank
111: sea salt inlet 112: water inlet valve
120: stirrer 121: stirring blade
122: motor 130: heater
140: temperature sensor 150: temperature control unit
200: salinity control unit 210: salinity control tank
211: cold water supply valve 220: salinity meter
300: reduction unit 310: reduction water storage tank
320: reduction water 330: reduction tank
340: magnetization processing unit 341,341': mesh body
342: ceramic ball 350: vortex fan
360: oxygen supply unit 362: oxygen supply pipe
362a: pump 370: oxygen injection nozzle
400: mineral transfer unit 410: first mineral transfer unit
420: second mineral transfer unit 430: third mineral transfer unit
440: fourth mineral transfer unit
500: first filtering unit 510: first filtering housing
520: carbon filter
600: aging unit 610: aging tank
620: vibrating column 621: vibrator
630: magnet body
700: second filtering unit 710: second filtering housing
720: hollow fiber membrane filter
800: sterilization storage unit 810: storage tank
811: discharge valve 820,820': electrode
S100: dissolution step S200: salinity control step
S300: reduction step S400: mineral transfer step
S500: first filtering step S600: aging step
S700: second filtering step S800: sterilization storage step

Claims (16)

A dissolving unit 100 for obtaining water salt by dissolving the sea salt by receiving water and domestic sea salt and by heating and stirring;
A salinity control unit 200 connected to the dissolving unit 100 and the first transfer pipe 10 having a pump P to receive and cool the water salt in which the sea salt is heated and dissolved, while cooling the salt level control unit 200;
A reduction unit 300 connected to the salinity control unit 200 and a second transfer pipe 20 having a pump P to receive water salt whose salinity is adjusted and to make the water salt alkalized by magnetizing the water salt;
A mineral transfer unit 400 connected to the reduction unit 300 and a third transfer pipe 30 having a pump P to receive alkalized water salt and transfer minerals to the water salt;
A first filtering unit 500 that is connected to the mineral transfer unit 400 and the fourth transfer pipe 40 having a pump P to receive the water salt to which the minerals have been transferred, and filter the heavy metals contained in the water salt first. );
A maturation unit 600 connected to the first filtering unit 500 and a fifth transfer pipe 50 having a pump P to receive the first filtered water salt to be aged;
A second filtering unit 700 connected to the aging unit 600 and a sixth transfer pipe 60 having a pump P to receive the aging water salt and to filter it secondarily to remove residual heavy metals and foreign substances; And
Including; a sterilization storage unit 800 connected to the second filtering unit 700 and a seventh transfer pipe 70 having a pump P to receive the filtered water salt and sterilize before shipment,
The melting part 100,
On one side, a sea salt inlet 111 through which sea salt can be injected and a water inlet valve 112 through which water can be injected are formed, and a dissolution tank 110 connected to the salt control unit 200 and the first transfer pipe 10 ;
A stirrer 120 installed in the dissolution tank 110 to stir the sea salt and water contained therein;
A heater 130 mounted on the dissolution tank 110 to heat water during the stirring process;
A temperature sensor 140 mounted on the dissolution tank 110 to measure the temperature of heated water; And
Includes; a temperature controller 150 mounted on the melting tank 110 and controlling the heater 130 to maintain a set heating temperature based on the temperature measured by the temperature sensor 140,
The salinity control unit 200,
A cold water supply valve 211 for receiving and storing water salt from the melting unit 100 through the first transfer pipe 10 and supplying separate cold water is formed, and the reduction unit 300 and the second Salinity control tank 210 connected to the transfer pipe 20; And
Includes; a salinity meter 220 mounted on the salinity control tank 210 to measure the salinity of water salt,
The reduction unit 300,
A reduced water storage tank 310 connected to the mineral transfer unit 400 and a third transfer pipe 30 to receive and store water salt from the salinity control unit 200 through the second transfer pipe 20; And
The reduced water storage tank 310 and the circulation supply pipe 331 and the circulation discharge pipe 332 are connected to the reduced water tank 320 for generating alkaline reduced water by circulating and magnetizing the water salt stored in the reduced water storage tank 310; Including,
The reducing water device 320,
A reduction tank 330 through which water salt is circulated by being connected to the reduced water storage tank 310 and the circulation supply pipe 331 and the circulation discharge pipe 332;
A magnetization treatment unit 340 for magnetizing water salt that is charged and circulated in the reduction tank 330;
A vortex fan 350 that is formed in the reduction tank 330 and generates a vortex in the water salt supplied through the circulation discharge pipe 332 to force the water salt to pass through the magnetization treatment unit 340;
An oxygen supply unit 360 connected to the reduction tank 330 and an oxygen supply pipe 361 having a pump 361a to supply oxygen to the reduction tank 330; And
Including; a plurality of oxygen injection nozzles 370 for aeration of water salt by high-pressure injection of oxygen supplied by being connected to the oxygen supply pipe 361 from the inner bottom of the reduction tank 330 to the inside of the reduction tank 330 and aeration; and ,
The first filtering unit 500,
A first filtering housing 510 that receives water salt from the fourth mineral transfer unit 440 through the fourth transfer pipe 40 and is connected to the aging unit 600 through a fifth transfer pipe 50 ; And
Includes; a carbon filter 520 installed inside the first filtering housing 510 to adsorb heavy metals and remove odors during the passage of water salt,
The aging part 600,
Water salt, which is first filtered by the first filtering unit 500 through the fifth transfer pipe 50, is supplied and stored, and connected to the second filtering unit 700 through the sixth transfer pipe 60. Aging tank 610;
A plurality of vibrating pillars 620 vertically formed in the aging tank 610 and having a vibrator 621 formed at an upper end thereof; And
Includes a plurality of magnet bodies 630 formed around each of the vibration pillars 620; And,
The second filtering unit 700,
A second filtering housing 710 supplied with aged water salt from the aging unit 600 through the sixth transfer pipe 60 and connected to the sterilization storage unit 800 through the seventh transfer pipe 70; And
And a hollow fiber membrane filter 720 installed inside the second filtering housing 710 to filter heavy metals during the passage of the water salt. delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete

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