KR101541183B1 - salt manufacture method - Google Patents

Abstract

The present invention relates to an apparatus for manufacturing a salt, which is a traditional salt using solar energy, and it requires a lot of work force in the process of making a function as a waste and a slag and a lot of firewood in boiling a function, In this case,
By using the power generated from the solar cell using solar energy, the salinity of the seawater is increased to make the function, the function is boiled to produce the salt, the production cost such as the labor force and the fuel cost is reduced, And provides a self-generated flame producing apparatus with a quality.

Description

{Salt manufacture method}

The present invention relates to an apparatus for producing salt, which is a traditional salt of Korean made by boiling seawater, and is a power generated from a solar cell using solar energy. The water is evaporated from seawater to obtain a salinity function, The present invention also relates to a self-sustaining apparatus for producing the self-sustaining apparatus.

In the conventional salt production, it is possible to reduce the labor force required by the high-salinity water, and it is possible to reduce the production cost by not using combustible fuel such as firewood when boiling the function, Which is capable of producing a flame retardancy.

Salt is salty white crystals mainly composed of sodium chloride (NaCL), and is widely used for food, medicine, and industrial use.

In the way of obtaining such salt, the past sea was transformed into terrestrial land, and the seawater was evaporated, and salt, salt and salt, which are generated from the rock salt, and solar and wind, It can be divided into remediation made by reprocessing process, and salt form which is made by electrolysis of seawater, and the salt which is the traditional salt of Korea which boils seawater.

In the process of making the flaming salt, the seawater is introduced only when it is sari, and the puddle is formed in the tidal flats where the seawater does not enter for about 7 to 8 days a little before, and the adulterate which collects the function is formed. The tidal flat soil is dug and crushed, and the soil is buried with dry soil, and the salt water is passed through the soil to obtain a function of increased saltiness in adulthood. This is a way to get a lot of salt with less fuel.

After pouring the obtained function into a cauldron, the fire is cooked in the fireplace. At this time, the bitterness and bitter taste disappearing from the rising bubbles, and the salt of the mild taste with low saltiness is formed.

In the production of salt, which is a conventional salt, the spring and autumn weather can make a function at a little time, so it is influenced by the climate, and in the process of making a function as a waste and a slurry, There is a problem that the production cost is high because a lot of firewood is needed.

In connection with the self-smoothing, it is necessary to collect seawater from the tidal flats in which the seawater flows in the case of "Salt Production Apparatus" of Korean Patent No. 10-0436222, and "Method of Manufacturing Self- It describes how to produce salt using heat when incinerating.

KR10-043622 01 Summary, see Figures 1-5 KR10-0535229 02 See FIGS. 1 to 2

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems,

By using the power generated from the solar cell using solar energy, water is evaporated from the seawater to create a salinity function, and boiling function is produced to reduce production cost such as labor and fuel cost, The present invention provides a decontamination apparatus which continuously produces a flame having a constant taste and quality.

In order to achieve the above object, a self-generated potion manufacturing apparatus using solar energy is provided with a primary storage tank 110 for storing seawater 100 and raising the salinity to make a function and a function of salinity increased in the primary storage tank 110 A solar cell 210 that generates electricity by solar light 200, and a solar cell 210 that converts electricity obtained from the solar cell 210 into a constant voltage The power stabilizer 220 supplies power controlled by the power stabilizer 220 to the electric heater of the primary storage 110 and the evaporator 120 to control the salinity and the temperature of the seawater and the function And a control unit 230 having a function of controlling the display unit.

The primary storage tank 110 collects and stores seawater, and heats it with a heater 113 to make a function. And a function of sending a signal for controlling and cutting off the power to the control unit 230 when the salinity and the temperature reach the predetermined salinity and temperature, respectively, including a temperature sensor and a salinity sensor.

The evaporator 120 includes an evaporation vessel which is supplied with a function of salinity increased in the primary storage tank 110 and boiled into an electric heater to produce salt. And a function of sending a signal to the controller 230 so as to control the temperature of the evaporation vessel, including a temperature sensor capable of sensing the temperature of the evaporation vessel.

The DC stabilization circuit 220 includes a battery for converting a voltage that varies depending on weather and season in a solar cell 210 to a controller 230 and storing the power, But also includes a function of supplying basic power.

The control unit 230 supplies the controlled power to the primary storage 110 and the electric heater of the evaporator 120 with the power supplied from the DC stabilization circuit 220. And a function of supplying controlled power for maintaining the primary storage tank 110 at a predetermined temperature, and includes a function of shutting off power when the seawater reaches a predetermined salinity. It also includes a function of supplying controlled electric power to the electric heater of the evaporator 120 and controlling the temperature of the evaporator 120.
According to an aspect of the present invention, there is provided a method for preparing a water-soluble salt solution, comprising: a primary storage tank for collecting and storing seawater to evaporate water to increase salinity; A distillation unit which is supplied with a function of salinity of high salinity and boils to make salt; A solar cell unit that receives electricity from the sun; A battery for storing electric power generated by the solar battery unit; A DC stabilization circuit part for supplying a constant voltage; And a control unit that receives power from the DC stabilization circuit unit and supplies controlled electric power to the electric heater according to the salinity and temperature of the primary storage tank and the distillation unit,
Wherein the control unit includes: a reference voltage circuit unit for supplying a reference voltage to the control unit; A temperature control comparator for comparing a voltage from a temperature sensor of the primary reservoir with a reference voltage; A salinity control comparator that compares the voltage from the salinity sensor of the primary reservoir with a reference voltage; A primary storage control element for controlling controlled power to be supplied to the electric heater of the primary storage; A distillation section temperature control comparator for comparing a voltage from the temperature sensor of the distillation section with a reference voltage; And a distillation section control element for controlling the controlled power to be supplied to the electric heater of the distillation section, wherein an output signal of the temperature control comparison detector and the salinity control comparison detector is combined with an OR circuit to send a signal to the primary storage control element Wherein the primary storage control element supplies controlled power to an electric heater of a primary storage tank, the distillation section temperature control comparator sends a signal to the distillation section control element, and the distillation section control element sends controlled power Is supplied to an electric heater of the distillation section.

The representative is a schematic block diagram according to the present invention.
1 is a configuration diagram of a power supply system of a control unit according to the present invention;

In order to accomplish the above object, the present invention is directed to a method of preparing a salt water storage tank, comprising: a primary storage tank (110) for collecting and storing seawater (100) and evaporating water to raise a salinity to make a function; A distillation unit 120, a solar cell 210 that receives solar light 200 to produce electric power, and a battery that stores electric power generated in the solar cell, and includes a DC stabilization unit And a control unit 230 for supplying controlled power to the electric heater according to the salinity and temperature of the primary storage tank 110 and the distillation unit 120.

In the process of making the seawater 100 into salt, the primary storage tank 110 collects the seawater flowing into the tidal flats and raises the temperature of the seawater 100 to an electric heater to evaporate water.

  The salinity of general seawater is about 3%. It is desirable to increase the salinity of the seawater first rather than directly boil the seawater. A temperature sensor is included for the purpose of preventing seawater from boiling due to a temperature rise by an electric heater in the course of raising the saltwater salinity of the primary storage tank 110 and maintaining the temperature at a predetermined temperature, And a salinity sensor is included to maintain the predetermined salinity.

The distillation unit 120 is supplied with a function of seawater whose salinity is increased in the primary storage tank 110, and heat is supplied to an electric heater to boil water to evaporate water to produce salt. At this time, the process of removing the bubbles from the seawater boils, and low salt makes alkaline salt. The salt, which is made through this process, is not only salty and salty, it also contains a higher calcium content than the sun salt, and free amino acids make many excellent salts.

The solar cell 210 generates electric power from sunlight.

Solar energy is divided into infrared (52% of thermal), visible (43% of light and photovoltaic) and ultraviolet (5% of sterilization and photochemical) depending on the wavelength range.

 Solar power generation using the solar cell 210 is calculated by calculating the electric power per unit area by applying the visible light portion. The solar energy irradiation intensity is 1000 W / ㎡. * Solar efficiency (visible light power generation efficiency) 43% Module) Depending on the power generation efficiency ~ 22%, about 95W per ㎡ power can be obtained. Accordingly, the installation area of the solar cell is calculated to obtain necessary power with reference to the change of the solar radiation amount depending on weather and season.

The DC stabilization circuit unit 220 includes a storage battery for storing power generated by the solar cell 210. The DC stabilization circuit unit 220 receives the power generated by the solar cell 210 and maintains the stabilized voltage.

The power generated by solar cells varies according to the season. According to the monthly data of the metropolitan area, the power generated by the solar cell 210 varies depending on the season and the weather, from 2000Kcal to 2500Kcal per 1m2, from 3800Kcal to 4500Kcal during the summer, and to 3385Kcal on an average. Accordingly, the DC stabilization circuit unit 220 includes a function of converting the voltage fluctuation due to the irradiation dose change to a constant voltage including the DC-DC converter circuit and stabilizing it. In addition, the battery for storing the power generated by the solar cell 210 measures the voltage of the battery when the power is stored. When the voltage reaches the set reference voltage, the battery stops charging to prevent overcharging. When the battery uses power, And a circuit for shutting down the battery when the voltage of the side cell is discharged to a certain voltage or less.

The control unit 230 receives power from the DC stabilization circuit unit 220 and supplies controlled power according to salinity and temperature of the seawater to the primary storage tank 110 to prevent overheating of the distillation unit 120 And supplies controlled power according to temperature.

1 is a power supply system configuration diagram of the control unit 230. As shown in FIG.

1, the power supply system includes a reference voltage circuit unit 231 for supplying a reference voltage to the control unit 230, and a temperature control unit 231 for comparing the voltage output from the temperature sensor 112 of the primary storage unit with a reference voltage. A comparator detector 233 for comparing the voltage from the salinity sensor 111 of the primary storage tank with a reference voltage for comparing the voltage from the salinity sensor 111 of the primary storage tank with the reference voltage, The signal is sent to the primary storage control element 235 by the OR circuit 234 and the primary storage control element 235 supplies the controlled power to the electric heater 113 of the primary storage.

 A temperature control comparator 236 compares the voltage from the distillation section temperature sensor 121 with a reference voltage. The temperature control comparison detector 236 sends a signal to the distillation section control element 237, (237) is characterized in that the controlled electric power is supplied to the electric heater (122) of the distillation section.

 In order to prevent salt crystals from becoming too high in the salinity of the primary reservoir 110, the primary storage salinity control comparator 232 of the control unit receives a signal from the salinity sensor 111 of the primary reservoir and reaches a reference salinity The primary storage tank temperature comparative detector 233 of the control unit receives a signal from the temperature sensor 112 of the primary storage tank and keeps it at a constant temperature And a function for supplying controlled electric power to the electric heater to prevent seawater from boiling and generating bubbles.

The distillation unit temperature control comparator 233 of the control unit includes a function of receiving a signal from the distillation unit temperature sensor 121 and supplying the controlled electric power to the electric heater to prevent overheating.

 When boiling the function, the bitterness and bitter taste disappear from the bubbles, and salt of the mild taste with low salinity is produced.

The present invention is not limited to the above-described embodiments, and various changes and modifications may be made without departing from the scope of the present invention.

100: Saltwater 110: Primary storage
120: Distillation part 120: Salt (Charcoal)
200: Solar light 210: Solar cell
220: DC stabilization circuit 230:
111: primary storage tank salinity sensor 112: primary storage tank temperature sensor
113: Primary reservoir heater 121: Distillation section temperature sensor
122: Distillation unit electric heater 231: Reference voltage circuit part
232: primary reservoir salinity control comparator
233: primary reservoir temperature control comparator
234: OR circuit 235: primary reservoir control element
236: distillation section temperature control comparison detector 237: distillation section control element

Claims (2)

delete A primary reservoir for collecting and storing seawater to evaporate water to raise the salinity to make a function;
A distillation unit which is supplied with a function of salinity of high salinity and boils to make salt;
A solar cell unit that receives electricity from the sun;
A battery for storing electric power generated by the solar battery unit;
A DC stabilization circuit part for supplying a constant voltage;
And a control unit that receives power from the DC stabilization circuit unit and supplies controlled electric power to the electric heater according to the salinity and temperature of the primary storage tank and the distillation unit,
Wherein,
A reference voltage circuit unit for supplying a reference voltage to the control unit; A temperature control comparator for comparing a voltage from a temperature sensor of the primary reservoir with a reference voltage; A salinity control comparator that compares the voltage from the salinity sensor of the primary reservoir with a reference voltage; A primary storage control element for controlling controlled power to be supplied to the electric heater of the primary storage; A distillation section temperature control comparator for comparing a voltage from the temperature sensor of the distillation section with a reference voltage; And a distillation section control element for controlling the controlled power to be supplied to the electric heater of the distillation section,
The output signal of the temperature control comparator and the salinity control comparator is combined with an OR circuit to send a signal to the primary storage control element, and the primary storage control element supplies the controlled electric power to the electric heater of the primary storage ,
Wherein the distillation section temperature control comparator sends a signal to the distillation section control element and the distillation section control element supplies the controlled electric power to the electric heater of the distillation section.

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