KR100962705B1 - Mineral possibility processing unit and the method - Google Patents

Abstract

PURPOSE: A mineral water processing unit and a method thereof are provided to keep constant content of mineral components of processing water, and to supply strong alkaline water with high mineral components of processing water. CONSTITUTION: A mineral water processing unit comprises the following: a raw water feeding pipe(1); an electrolytic bath(2) which electrolyzes raw water flowing in by using a + electrode(21) and a - electrode(22); a treatment tank(3) which spills current from one side to other side, measures electric conductivity passing through the processing water with a mineral component detector and sensor(31) detecting a mineral component of the processing water on both outer wall; an exhaust line(4) discharging drain water electrolyzing raw water; a control unit(5) supplying current to the + electrode and the - electrode based on a measured value of a mineral component detector and sensor. An inlet tube includes a flowmeter(11) measuring a supply quantity of a raw water flowing in and, a pH sensor measuring a pH of a raw water flowing.

Description

Mineral water processing unit and its method

The present invention relates to an apparatus for producing mineral water, and more particularly, electrolysis by controlling electricity to control the mineral content of the treated water in a constant manner, applying electricity to the treated water, and measuring the height of the conductivity and the height of the mineral content. It relates to a mineral water production apparatus for providing a mineral water having a constant mineral content by adjusting the current.

Conventionally used mineral water treatment apparatus was provided by electrolyzing raw water flowing in the electrolytic cell with a constant current. However, the amount of current for electrolysis is constant, but the treated water electrolyzed according to the inflow of raw water and the pH of the raw water does not have a constant mineral content.

Since the above-mentioned treated water is treated only with the current which electrolyzed in the electrolyzer according to the raw water, as described above, when the inflow of raw water increases, the mineral content of the treated water is lowered, and the mineral is the same as before when the pH of the raw water is strongly acidic. There was a problem that the content is lowered.

When only a constant current is supplied to the electrolyzer, there is a problem that the treated non-mineral mineral content that varies according to the raw water cannot be kept constant, and the reliability of the supplied treated water is lowered because the mineral content of the treated water is not measured.

Accordingly, the present invention was created to solve the above problems, the object of the present invention is as follows.

First, the present invention is to provide a constant mineral content of the treated water.

Second, it is an object of the present invention to provide a treated water having the same mineral content regardless of the amount of raw water and the pH of the raw water.

Third, the present invention is to provide a strong alkali.

As described above, technical means for achieving the object of the present invention is as follows.

An inlet pipe for introducing raw water; An electrolytic cell which forms an inlet pipe on one side and electrolyzes the introduced raw water using the + electrode and the-electrode; A treatment tube for supplying treated water by electrolyzing raw water to the other side of the electrolytic cell; Treatment tube is a mineral content detection sensor for detecting the mineral content of the treated water by measuring the amount of conduction passing through the treated water by flowing a current from one side to the other side on both sides of the outer wall; And a controller for supplying current to the + electrode and the-electrode of the electrolytic cell based on the measured value of the mineral-impacted detection sensor.

The other side of the electrolytic cell is characterized in that it further comprises a discharge pipe for discharging the discharged water treated by electrolysis of raw water.

The inlet pipe further has a flow rate sensor for measuring the supply amount of raw water flowing into one side, and provides the supply amount of raw water passing through the inlet pipe to the control unit so that the control unit supplies the + electrode and the-electrode of the electrolyzer according to the supply amount of raw water. It is characterized by controlling the supply of current.

The inlet pipe further includes an acidity measurement sensor for measuring the pH of the raw water flowing into one side, and provides the pH of the raw water passing through the inlet pipe to the controller so that the controller controls the current at the + electrode and the-electrode of the electrolytic cell according to the pH of the raw water. It characterized in that to control the supply.

The inlet pipe is located between the + electrode and the-electrode of the electrolytic cell, the processing pipe is located at the + electrode side, and the discharge pipe is located at the-electrode side, but the inlet pipe, the + electrode, the-electrode, the treated water and the discharge pipe are listed on the horizontal line. It features.

Introducing raw water into the electrolyzer; Measuring the supply amount of raw water flowing into the inflow pipe and the pH of the raw water, and controlling the electrolysis of the raw water by supplying a current to the + electrode and the-electrode of the electrolytic cell; Supplying the electrolyzed treated water to the treatment pipe and discharging the electrolyzed discharge water to the discharge pipe; Supplying raw water supplied from the flow rate sensor of the inflow pipe, acidity of the raw water provided from the acidity measurement sensor of the inflow pipe, and passing the current through the treated water in the mineral content detection sensor of the processing pipe to detect and provide the provided mineral content to the controller ; The control unit controls the current supplied to the + electrode and the-electrode of the electrolytic cell according to the supply amount of the raw water, the acidity of the raw water and the conductivity of the treated water.

The treated water is characterized by being strong alkaline water of 10 pH.

As mentioned above, the effect of this invention is as follows.

First, by adjusting the amount of raw water and the electrolysis current according to the pH of the raw water, there is an effect of making the mineral content of the treated water constant.

Second, the present invention has the effect of providing a strong alkaline water of the treated water to have a strong alkalinity of the treated water.

Third, the present invention measures the mineral content of the supplied treated water and supplies it to the user, thereby providing the user with confidence.

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

<Configuration and operation according to the present invention>

1 is a schematic configuration diagram showing a mineral water treatment apparatus according to the present invention. As shown in FIG. 1, the mineral water treatment apparatus according to the present invention includes an inlet tube 1, an electrolyzer 2, a treatment tube 3, an outlet tube 4, and a controller 5.

The inflow pipe 1 is installed at one side of the electrolytic cell 2, and supplies raw water to the electrolytic cell 2.

The electrolyzer 2 electrolyzes the introduced raw water using the + electrode 21 and the-electrode 22. In other words, when the raw water is electrolyzed, alkaline ionized water (called "reduced water") is produced on the electrode side, and acidic water (also called "oxidized water") is formed on the electrode.

As described above, the ion refers to an atom or group of atoms that are charged with electricity. Representative constituents of minerals mixed in water include calcium ions, magnesium ions, and minerals such as sodium ions, iron ions, and manganese in water. .

The present invention is to provide a user with treated water of a certain mineral content by using the propensity to move ions when the water is electrolyzed.

The treatment tube 3 supplies the treated water treated in the electrolytic cell 2. At this time, since the treatment tube 3 is adjacent to the -electrode 22 of the electrolytic cell 2, the treated water contains a lot of mineral content. In other words, the treated water is alkaline ionized water having a large amount of + ions.

The discharge pipe 4 discharges the discharged water treated in the electrolytic cell 2. At this time, since the discharge pipe 4 is adjacent to the + electrode 21 of the electrolytic cell 2, the discharge water is acidic water having a lot of negative ions.

The controller 5 supplies current to the electrodes 21 and 22 of the electrolytic cell 2 to electrolyze raw water. At this time, the amount of raw water that is electrolyzed increases according to the strength of the current supplied to the electrodes 21 and 22. By using the same principle, it is possible to provide a treated water having a constant mineral content.

The processing tube 3 has mineral content detection sensors 31 on both outer walls. At this time, the mineral content detection sensor 31 detects the mineral content of the treated water by measuring the amount of conduction passing through the treated water by passing a current from one side to the other side, and transmitting the measured value of the detected conductivity to the controller 5. do.

As described above, the amount of electric current varies depending on the pH of the treated water. Accordingly, the controller 5 may maintain the mineral content of the treated water by adjusting the intensity of the current to the electrodes 21 and 22 of the electrolytic cell 2 according to the conductivity of the treated water.

The inlet pipe 1 further includes a flow rate measuring sensor 11 for measuring a supply amount of raw water flowing in and an acidity measuring sensor 22 for measuring pH of the raw water. In this case, the flow rate measuring sensor 11 and the acidity measuring sensor 12 transmit the measured values to the control unit 5 to control the current supplied from the control unit 5 to the electrodes 21 and 22 of the electrolytic cell 2.

As described above, the control unit 5 simultaneously uses the measured values of the flow rate measurement sensor 11 and the acidity measurement sensor 22 of the inlet pipe together with the mineral content detection sensor 31 of the processing tube 3. By controlling the current supplied to the electrodes 21 and 22 of 2), a constant mineral content of the treated water can be expected.

As described above, in order to obtain the treated water having the desired mineral content after electrolysis in the electrolytic cell 2, the inlet tube 1 is located between the + electrode and the-electrode of the electrolytic cell 2, and the process tube 3 is + Located on the electrode side, the discharge pipe (4) is located on the electrode side, it is preferable that the inlet pipe (1), the + electrode, the-electrode, the treated water and the discharge pipe (4) are arranged on the horizontal line.

As described above, in view of the principle that different electrons are collected according to the electrodes 21 and 22 by electrolysis in the electrolytic cell 2, the discharge tube 4 is installed on the + electrode side and the processing tube 3 is installed on the-electrode side. will be.

<Method according to the present invention>

2 is a flow chart illustrating a mineral water treatment method according to the present invention. As shown in Figure 2, the mineral water treatment method according to the invention step of introducing the raw water into the electrolytic cell (S100), by measuring the supply amount of raw water flowing into the inlet pipe and the pH of the raw water, the control unit + electrode and Supplying a current to the electrode to electrolyze the raw water (S200), the electrolyzed treated water is supplied to the treatment pipe and the electrolyzed discharge water is discharged to the discharge pipe (S300), provided by the flow measurement sensor of the inlet pipe Supplying raw water, acidity of raw water provided by the acidity measuring sensor of the inlet pipe and the mineral content detection sensor of the processing pipe passes the current through the treated water to detect the provided mineral content and provide it to the control unit (S400) and supply of raw water, The control unit controls the current supplied to the + electrode and the-electrode of the electrolytic cell according to the acidity of the raw water and the conductivity of the treated water (S500).

Such a controller finally controls the electrode of the electrolytic cell by measuring the mineral content of the treated water, thereby receiving a treated water having a reliable constant mineral content.

The treated water according to the present invention described above is a strong alkaline water of 10pH.

As described above, those skilled in the art will understand that the present invention can be implemented in other specific forms without changing the technical spirit or essential features. It is therefore to be understood that the above-described embodiments are to be considered in all respects as illustrative and not restrictive. The scope of the present invention is defined by the appended claims rather than the detailed description and all changes or modifications derived from the meaning and scope of the claims and their equivalents should be construed as being included within the scope of the present invention.

The following drawings, which are attached in this specification, illustrate the preferred embodiments of the present invention, and together with the detailed description thereof, serve to further understand the technical spirit of the present invention, and therefore, the present invention is limited only to the matters described in the drawings. It should not be interpreted.

1 is a schematic configuration diagram showing a mineral water treatment apparatus according to the present invention.

Figure 2 is a flow chart illustrating a mineral water treatment method according to the present invention.

<Explanation of symbols for the main parts of the drawings>

1: inlet pipe 11: flow measurement sensor

12: acidity sensor 2: electrolytic cell

21: + electrode 22:-electrode

3: process tube 31: mineral content detection sensor

4: discharge pipe 5: control unit

Claims (7)

An inlet pipe for introducing raw water; An electrolytic cell which forms the inlet pipe on one side and electrolyzes the introduced raw water using a + electrode and a-electrode; A treatment tube for supplying treated water by electrolyzing raw water to the other side of the electrolytic cell; The treatment pipe is a mineral content detection sensor for detecting the mineral content of the treated water by measuring the amount of conduction passing through the treated water by flowing a current from one side to the other side on both sides of the outer wall; And And a controller configured to supply current to the + electrode and the − electrode of the electrolytic cell based on the measured value of the mineral content detection sensor. A discharge pipe for discharging the discharged water by electrolyzing raw water on the other side of the electrolytic cell; The inlet pipe further includes a flow rate sensor for measuring a supply amount of raw water flowing into one side, and provides the supply amount of raw water passing through the inlet pipe to the control unit so that the control unit + electrode of the electrolytic cell according to the supply amount of raw water And controlling the current supplied to the electrode; The inlet pipe further includes an acidity measurement sensor for measuring the pH of the raw water flowing into one side, and provides the pH of the raw water passing through the inlet pipe to the control unit so that the control unit + electrode of the electrolytic cell according to the pH of the raw water And controlling the current supplied to the electrode; The inlet pipe is located between the + electrode and the-electrode of the electrolytic cell, the processing pipe is located to the + electrode side, the discharge pipe is located to the-electrode side, the inlet pipe, the + electrode, the-electrode , Mineral water treatment apparatus, characterized in that the treatment pipe and the discharge pipe is arranged on the horizontal line. delete delete delete delete Introducing raw water into the electrolyzer; Measuring the supply amount of raw water flowing into the inflow pipe and the pH of the raw water, and controlling the electrolysis of the raw water by supplying a current to the + electrode and the-electrode of the electrolytic cell; Supplying the electrolyzed treated water to a treatment tube and discharging the electrolyzed discharged water to a discharge tube; The control unit detects the supply amount of raw water provided by the flow measuring sensor of the inlet pipe, the acidity of raw water provided by the acidity measuring sensor of the inlet pipe, and the mineral content provided by passing a current through the treated water in the mineral content detecting sensor of the processing pipe. Providing to; Controlling the current supplied to the + electrode and the-electrode of the electrolytic cell according to the supply amount of the raw water, the acidity of the raw water, and the conduction amount of the treated water; wherein the treated water is a strong alkaline water having a pH of 10 Mineral water treatment method characterized in that. delete

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