KR20210014471A - Apparatus manufacturing salt water - Google Patents

Abstract

The present invention provides an apparatus for producing salt water, which includes: an evaporation container including a seawater inlet to introduce seawater, a seawater outlet to discharge concentrated seawater, an air inlet to introduce external air, and an air outlet to discharge internal air, wherein the seawater is concentrated, as water is evaporated from the introduced seawater; a curved support to support evaporation containers such that the evaporation containers are stacked in a vertical direction; a filter provided in the air inlet; a plasma generator to allow the seawater discharged from the seawater outlet to pass therethrough; and a top plate formed of a transparent material and provided at an upper portion of the evaporation container to seal an inner portion and an outer portion of the evaporation container. In the evaporation containers stacked in the vertical direction, an upper evaporation container is stacked while being spaced apart inward from a lower evaporation container by a specific distance (d).

Description

Salt water production equipment {APPARATUS MANUFACTURING SALT WATER}

The present invention relates to a device for producing salt by heating deep sea water to evaporate and separate moisture, and specifically, to evaporate moisture in a closed space to produce brine, which is a concentrated sea water with increased salinity. It relates to a clean brine production device that prevents external pollutants such as fine dust from being contained in brine by blocking contact with the outside during the production process.

In general, in order to obtain salt, seawater is introduced from a salt field and trapped in a storage tank and dried naturally with solar heat and wind to obtain salt crystals, or salt water is evaporated by heating the pot to produce salt. have.

Salt produced in salt fields is naturally evaporated and the production period is long, so production disruptions are severe due to weather changes such as rain and snow, and it takes up a large area of land to produce salt. In addition, producing salt by heating a large pot with fossil fuel is a method used by ancestors in the past, which is used for heating, and the seawater contained in the large pot is heated to about 600°C using fossil fuel to evaporate the moisture. Get In modern times, this method is not desirable because of the cost of fossil fuels and secondary loss of environmental pollution due to the use of fossil fuels, and it is not appropriate because of the large amount of time required. In addition, since lump salt is generated when seawater is heated with high heat of 600°C, additional processes such as grinding or grinding the lump of salt may be required.

As described above, in the prior art, there is a problem in that the efficiency of producing salt is inferior depending on the external environment, and contaminants such as fine dust, which have become a social issue in recent years, are contained in seawater and are included in the produced salt. there was.

In addition, in order to produce salt, the process of making brine (heavy water) by sufficiently evaporating moisture from seawater is difficult and complicated, and it takes a lot of time and energy.

In addition, when looking at the existing heavy water production process, there is a problem that pollutants may be included in heavy water in the atmosphere as moisture evaporates by sunlight in an open space.

The present invention aims to provide a technology for efficiently producing brine (concentrated water) while preventing pollutants from outside air from entering seawater in order to obtain high quality salt using uncontaminated deep sea water. .

In addition, the present invention provides a technique for producing brine, but sterilizing the produced brine using a plasma device.

In the present invention, a seawater inlet through which seawater is introduced, a seawater outlet through which concentrated seawater is discharged, an air inlet through which external air is introduced, and an air outlet through which internal air is discharged are provided, so that water is evaporated from the introduced seawater. Evaporation container in which seawater is concentrated; A curved support for supporting the evaporation container to be stacked up and down; A filter provided in the air inlet; A plasma generator through which seawater discharged from the seawater outlet passes; Including, the evaporation container stacked up and down is provided on the top of the evaporation container and is spaced by a predetermined distance (d) inside the evaporation container on the upper side than the evaporation container on the lower side. It provides a salt water production apparatus characterized in that the lamination.

It further comprises a transparent closed space for accommodating the support and the evaporation container therein, the support is provided with a ladder, the convex portion formed convexly on the upper plate to refract transmitted sunlight to focus on a specific point of the evaporation container A solar cell disposed on the side; It further includes a fan provided in the air outlet, and it is preferable to drive the fan with electric power generated by the solar cell.

According to the present invention, an effect of efficiently producing brine water while preventing pollutants in the outside atmosphere from flowing in, and producing brine using only solar energy is generated without requiring external energy in the brine concentration process.

1 is a schematic view of an evaporation container, which is a configuration of a brine production apparatus according to the present invention,
2 is a view of the upper plate of the evaporation container shown in FIG. 1,
3 is a partial detailed view of the upper plate shown in FIG. 2,
4 is a schematic perspective view of a salt water production apparatus according to the present invention,
5 is a schematic perspective view of another form of the brine production apparatus according to the present invention,
Figure 6 is a state in which a plurality of salt water production apparatuses according to the present invention are arranged in front and rear, left and right, but arranged in a closed space.

Objects, specific advantages and novel features of the present invention will become more apparent from the following detailed description and preferred embodiments in conjunction with the accompanying drawings. In addition, the terms used are terms defined in consideration of functions in the present invention, which may vary according to the intention or custom of the user operator. Therefore, definitions of these terms should be made based on the contents of the present specification.

1 is a schematic view of an evaporation container, which is a configuration of a brine production apparatus according to the present invention, FIG. 2 is a view of the top plate of the evaporation container shown in FIG. 1, and FIG. 3 is a partial detailed view of the top plate shown in FIG. 4 is a schematic perspective view of a salt water production apparatus according to the present invention, FIG. 5 is a schematic perspective view of another form of a salt water production apparatus according to the present invention, and FIG. 6 is a front and rear view of a plurality of salt water production apparatuses according to the present invention. It is arranged left and right, but in a closed space.

[Evaporation container sealing structure]

The brine production apparatus according to the present invention, largely, the evaporation container 100 and the evaporation container 100 for producing concentrated concentrated water (hereinafter, also referred to as brine or heavy water) through which seawater (deep sea water) flows in and evaporates moisture. It includes a plasma generator 200 that sterilizes the concentrated water with plasma.

The evaporation container includes a seawater inlet 110 through which seawater, which is deep ocean water, is introduced, a seawater outlet 120 through which moisture is evaporated and concentrated seawater, and an air inlet 130 through which outside air is introduced, and internal air. An exhausted air outlet 140 is provided. A supply pipe P1 for supplying seawater is disposed at the seawater inlet 110, and a discharge pipe P2 for discharging the concentrated seawater to the outside is disposed at the seawater outlet 120.

Since the inside and outside of the evaporation container are sealed, it is possible to block seawater introduced into the inside from being contaminated by external pollutants or from containing fine dust in the outside atmosphere. Through this, the present invention is able to maintain the state of deep ocean water as it is by flowing into the evaporation container 100 through the seawater inlet 110 without being contaminated.

Deep ocean water is seawater at a depth of 200m or more where sunlight does not reach. Deep water in a strict sense means that the water whose temperature is about 2℃ is not actively mixed with the warm water near the surface above it. Like oil and oil, they exist while maintaining boundaries. Since it is not exposed to sunlight, it does not perform photosynthesis, does not consume nutrients, and contains abundant inorganic nutrients such as nitrogen, phosphorus, and silicon compared to surface water. Recently, various fields such as fisheries, food, beverage, cosmetics, medicine, etc. It is in the spotlight as its usage and importance increase. Deep ocean water is rich in minerals, has a fresh taste, and has very few bacteria, which promotes fermentation, and contains antioxidants through the action of various enzymes.

The present invention is capable of preventing contamination due to exposure to the atmosphere by producing concentrated water in an evaporation container with an inner and outer sealed evaporation container while producing salt from deep sea water. In addition, in preparation for the occurrence of some contamination inside the evaporation container, a sterilization process is performed in the plasma generator at a later stage.

The evaporation container 100 of the present invention maintains a sealed state, but since moisture is evaporated from the inside and discharged to the outside, air inflow and discharge must be made. To this end, a fan 145 is provided in the air outlet 140 to discharge air from the inside. In addition, a filter (not shown) is provided in the air inlet 130 to block the introduction of other pollutants such as fine dust into the air introduced from the outside into the evaporation container.

In addition, a solar cell 150 is positioned on the side of the evaporation container to generate power to drive the fan 145 provided at the air outlet. The solar cell 150 is preferably properly disposed on the side of the evaporation container so that sunlight heating the inside of the evaporation container does not interfere with heating the inside of the container.

The evaporation container may be composed of a hexahedral body portion with a developed upper portion and a top plate 160 sealing the upper portion of the body portion. The upper plate is provided on the evaporation container to seal the inside and the outside, and is made of a transparent material to allow sunlight to pass through to heat the inside of the evaporation container. Further, the upper plate 160 of the present invention has a convex portion 165 formed to be convex upward. The convex part 165 has a convex lens shape that is convex upwards and/or downwards, so it refracts the transmitted sunlight to concentrate it at a specific point, thereby efficiently reducing the seawater contained in the evaporation container 100 It serves to heat.

In addition, the present invention further includes a plasma generator 200 through which seawater discharged from the seawater discharge port of the evaporation container passes, and the possibility of contamination in the process of condensing seawater while evaporating water from the evaporation container 100 is completely eliminated. It is difficult to exclude, so it acts to sterilize contaminants. That is, the concentrated water discharged from the evaporation container flows through the plasma generator and undergoes a continuous sterilization process. Since water sterilization using a plasma generator is a conventional technique, a description of the plasma generator and the plasma principle will be omitted.

[Evaporation container stacked structure]

4 is a schematic perspective view of the brine production apparatus according to the present invention, and shows a support 250 for supporting the container in a vertically stacked state together with an evaporation container 100 in the configuration of the brine production apparatus shown in FIG. have. In FIG. 4, the remaining configurations except for the evaporation container in the configuration of FIG. 1 are excluded from the figure for convenience of explanation. The support is not a straight line, but a curved shape of an arc shape as a whole.

A plurality of the evaporation containers 100 are arranged up and down in a state coupled to the support 250, but stacked while being shifted by a certain amount so that the upper evaporation container is not positioned directly above the lower evaporation container (in an offset state) It looks like it has become. The side of the evaporation container is fixed by being coupled to the curved support. In addition, a seawater inlet 110 through which deep ocean water is introduced into the evaporation container, a seawater outlet 120 through which concentrated seawater is discharged, an air inlet 130 through which external air is introduced, and an air outlet through which internal air is discharged. It is the same as in FIG. 1 that 140, a supply pipe P1 for supplying seawater, and a discharge pipe P2 for discharging concentrated seawater to the outside are provided.

The evaporation container is coupled in an arc shape as viewed from the side to the support 250 having an arc shape. That is, if the evaporation container positioned at the lower side of the evaporation containers stacked up and down is referred to as the first evaporation container, and the evaporation container positioned at the upper side is the second evaporation container, the front surface 111 of the second evaporation container is the first evaporation container. It is a structure that is spaced apart from the front surface 111 of the container by a predetermined distance (d).

In this way, the evaporation containers are arranged vertically but stacked in an offset state by a predetermined interval (d) in order to efficiently utilize the space. That is, the conventional salt farm has a spatial limitation in that the floor produces salt only in a certain area, but the present invention is stacked up and down to overcome this so that the upper space can be utilized, and at the same time, in order to receive sunlight efficiently It is arranged to be spaced slightly inward to utilize the upper space.

Figure 5 is a schematic perspective view of another form of the salt water production apparatus according to the present invention, the difference from Figure 4 is a structure coupled to the support 250. In FIG. 4, two supports are combined on both sides of the evaporation container, but in FIG. 5, the supports are coupled to both sides of the evaporation container, but one support 250 is disposed on one side. That is, in FIG. 5, the structure is simplified by combining only one of the supports 250 on the central side of the evaporation container 100. Connecting the support to the side of the evaporation container can be combined using general mechanical elements such as bolts. In addition, the support is provided with a ladder 280 so that the operator can perform the necessary work for the evaporation container while climbing the ladder 280.

6 is a view in which a plurality of salt water production apparatuses according to the present invention are arranged in front and rear, left and right, but arranged in a closed space. In FIG. 6, a plurality of salt water production devices shown in FIGS. 4 to 5 are arranged, and they are located in a transparent enclosed space 300 such as a green house or a greenhouse. Placing the salt water production device in such a transparent closed space provides the following advantages.

A space such as a green house or a greenhouse has an advantage that the evaporation of seawater inside the evaporation container can be further accelerated since the internal temperature is easily increased by absorbing solar energy in a closed space to maintain a high temperature. And, since the evaporation container 100 is a closed space and is located in a closed space 300 such as a vinyl house or greenhouse, it forms a double sealed space consisting of an evaporation container and a closed space, so that seawater is contaminated from external pollutants such as fine dust. There is a double effect that can prevent it.

Although the preferred embodiments of the present invention have been described in detail above, the scope of the present invention is not limited thereto, and various modifications and improvements by those skilled in the art using the basic concept of the present invention defined in the following claims are also present. It belongs to the scope of rights of

Claims (4)

A seawater inlet through which seawater flows in, a seawater outlet through which concentrated seawater is discharged, an air inlet through which external air is introduced, and an air outlet through which internal air is discharged are provided, and the seawater is concentrated by evaporation of water from the introduced seawater. Evaporation container;
A curved support for supporting the evaporation container to be stacked up and down;
A filter provided in the air inlet;
A plasma generator through which seawater discharged from the seawater outlet passes;
Includes; a transparent material top plate provided on the evaporation container to seal the inside and outside,
The evaporation container stacked up and down, characterized in that the evaporation container on the upper side of the evaporation container is stacked at a predetermined interval to the inside of the lower evaporation container. The method of claim 1,
Salt water production apparatus, characterized in that it further comprises a transparent closed space accommodating the support and the evaporation container therein. The method of claim 2,
The support is coupled to the side of the evaporation container,
Salt water production apparatus, characterized in that the ladder is provided on the support. The method of claim 1,
A convex portion formed convexly on the upper plate to refract transmitted sunlight to focus on a specific point;
A solar cell disposed on the side of the evaporation container;
A fan provided in the air outlet; further includes,
Salt water production apparatus, characterized in that driving the fan with the power produced by the solar cell.

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