KR200410857Y1 - Cold water ionizer - Google Patents

Abstract

The present invention relates to a cold ionizer for separating water into acidic water and alkaline water by electrolyzing water, the cold water tank for cooling the introduced water; An electrolytic cell including a positive electrode and a negative electrode for electrolyzing water introduced from the cold water tank; An alkaline water drain line for draining alkaline water electrolyzed and separated from the electrolytic cell; An acidic water drain line for draining the acidic water electrolyzed and separated from the electrolytic cell; And an acidic water pressurized pumping means disposed in the acidic water draining line to pump acidic water drained from the electrolytic cell along the acidic water draining line.

Description

Cold water heater {COLD WATER IONIZER}

1 is a block diagram schematically showing the structure of a conventional cold water heater,

2 is a block diagram showing an embodiment of a cold water heater according to the present invention,

3 is an exploded perspective view showing an electrolytic cell composed of a mesh type electrode;

4 is an assembled sectional view showing the electrolytic cell shown in FIG. 3 along the line A-A ',

Figure 5 is a block diagram showing another embodiment of a cold water heater according to the present invention,

6 is a cross-sectional view illustrating in detail the water collecting tank shown in FIG. 5.

-Explanation of terms for main parts of attached drawings-

10; Cold water tank 20; Alkaline water drainage line

30; Acidic water drainage line 40; Bypass

50; Drain pump 51; Acid water pressurized pumping means

52; Alkaline water pressurized pumping means 60; Sump

61; Switch 100; Electrolyzer

The present invention relates to a cold ionizer that separates the acidic and alkaline water by electrolytic water.

With the benefits of living and the economic margins, people's attention is focused on quality of life and health, rather than on basic ritualism.

This trend has required the improvement of water quality, which is the basis of food and the most important for life activities. Especially, due to the distrust of water and environmental pollution provided by public institutions, people have no choice of At the same time, water was purchased from a reliable drinking water company.

On the other hand, in purified water, it is not satisfied that it is simply clean water, but attention was focused on supplying water which is healthier, and ionized water of an alkali component was introduced.

According to the academic community, ionized water, especially alkaline water, is known to have the effect of removing free radicals in the body, improving intestinal fermentation, inhibiting the generation of toxins and wastes in the body, and inhibiting sterilization and bacterial growth.

This effect has led to the development of ionizers that allow the separation of alkaline water from water in ordinary households.

On the other hand, in order to increase the benefits of the ionizer, the function of separating the water supplied from the hot water and cold water was added, and the separated cold water was to be directly drained as alkaline water through electrolysis.

1 is a block diagram schematically showing the structure of a conventional cold water heater, which will be described with reference to this.

The conventional cold ion water heater includes a cold water tank 10 for storing the water to cool the water supplied from the constant water, and an electrolytic cell 100 for electrolyzing the water introduced from the cold water tank 10. The cold water tank 10 is to lower the temperature of the water through a cooling function while storing a certain amount of water, and allows the user to drink cool alkaline water by introducing low temperature water into the electrolytic bath 100.

On the other hand, as is widely known, the water passed through the electrolytic cell 100 is separated into acidic water and alkaline water, and the alkaline water and the acidic water are respectively connected with the alkaline water drainage line 20 and the acidic water drainage line 30. Is discharged through).

However, in the case of the cold ionizer, due to the limitation of having a separate cold water tank 10 for cooling the water, unlike the general ionized water in which a constant provided at a relatively high water pressure is directly introduced into the electrolytic cell, the alkaline water drainage line 20 ) And the water pressure of the alkaline water and the acidic water having to pass through the acidic water drainage line 30, respectively. In particular, in the case of the alkaline water drainage line 20, since a valve (not shown) opened and closed by the user is adjacent to the electrolyzer 100, the drainage rate due to insufficient water pressure may not be a big problem, while acid water drainage Since the line 30 is formed relatively longer than the alkaline water drainage line 20, a certain amount of water pressure is required for draining the acidic water. Of course, although the length of the acidic water drainage line 30 may be shortened, since the acidic water that is unnecessary in reality must be connected to a sewer at a remote location, the above-described problem has been substantially overcome.

Subsequently, when the drainage of the acidic water through the acidic water drainage line 30 is not smooth, the acidic water to be discharged to the acidic water drainage line 30 even though a separate pump is installed at the front end of the electrolytic cell 100. As the drainage flows into the smooth alkaline water drainage line 20, the pH of the alkaline water discharged through the alkaline water drainage line 20 is lowered, resulting in a problem that the cold ionizer does not function. Therefore, in the case of the ready-made cold water ionizer which must keep the production ratio of acidic water and alkaline water constant, the above-mentioned problem became a big obstacle in supplying high quality alkaline water.

Accordingly, the present invention has been made to solve the above problems, and the technical problem is to provide a cold water ionizer to smoothly discharge the alkaline and acidic water electrolyzed from the electrolytic cell, so that the alkaline water can be efficiently supplied without qualitative degradation. .

The present invention to achieve the above technical problem,

A cold water tank for cooling the introduced water;

An electrolytic cell including a positive electrode and a negative electrode for electrolyzing water introduced from the cold water tank;

An alkaline water drain line for draining alkaline water electrolyzed and separated from the electrolytic cell;

An acidic water drain line for draining the acidic water electrolyzed and separated from the electrolytic cell; And

An acidic water pressurizing pump disposed in the acidic water draining line to pump acidic water drained from the electrolytic cell along the acidic water draining line;

Cold ionizer comprising a.

In the cold water heater in order to achieve the above technical problem,

Disposed in the acidic water drainage line to store acidic water flowing from the electrolytic cell, and detecting a change in the level of the stored acidic water and generating a signal when detected above a predetermined level, wherein the stored acidic water is It further comprises a water collecting tank discharged by the acidic water pressurized pumping means that is ON / OFF in accordance with the signal of the switch.

In the cold water heater in order to achieve the above technical problem,

It further comprises a bypass connecting the alkaline water drainage line and the acidic water drainage line.

In the cold water heater in order to achieve the above technical problem,

While interlocking with a valve that controls the opening and closing of the alkaline water draining line, when the valve is opened, the alkaline water in the alkaline water draining line is pumped, and when the valve is closed, the alkaline water in the alkaline water draining line is pumped for a predetermined time while the acid is passed through the bypass. It further comprises an alkaline water pressurizing pump means for draining to the water drain line.

In the cold water heater in order to achieve the above technical problem,

The positive electrode and the negative electrode of the electrolytic cell are holes formed so that water can pass through.

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

Figure 2 is a block diagram showing an embodiment according to the cold water heater according to the present invention, will be described with reference to this.

The acidic water drainage line according to the present invention further includes a pressurized pumping means 50 to solve the problem that the acidic water electrolyzed in the electrolytic cell 100 loses its discharge power due to the water pressure drop due to the provision of the cold water tank 10. It is.

The pressurized pumping means 50 forcibly pushes out the remaining acidic water stagnant in the acidic water drainage line 30, and smoothly discharges the water in the electrolytic cell 100.

On the other hand, the bypass 40 for connecting the alkaline water drainage line 20 and the acidic water drainage line 30 may be further included. In general, a valve (not shown) for opening and closing the discharge of alkaline water is located at the end of the alkaline water drain line 20. Accordingly, when the valve is closed, alkaline water that has not been drained remains in the alkaline water drainage line 20. Alkaline water is water containing hydroxide ions. The hydroxide ions in an unstable state disappear through reaction when left for a long time. Therefore, when the user operates the valve for drinking, the pH is lowered while mixing with freshly electrolyzed alkaline water in the electrolytic cell 100.

The bypass 40 provided for solving such problems communicates the acidic water drainage line 30 and the alkaline water drainage line 20 according to the present invention so that the alkaline water remaining in the alkaline water drainage line 20 is discharged. do.

On the other hand, the electrode embedded in the electrolytic cell 100 is roughly divided into a general plate type and a mesh type. Of course, the acidic water and the alkaline water electrolyzed and separated in the electrolytic cell 100 without being divided into a plate type and a mesh type are drained to the acidic water drainage line 30 and the alkaline water drainage line 20, respectively. However, the poor drainage in the acidic water drainage line 30 due to the shape difference of the electrode has an adverse effect on the mesh type electrode compared to the flat type electrode.

This is because the mesh type electrode does not partition the space in the electrolytic cell 100, unlike the flat type electrode, so that the water introduced into the electrolytic cell 100 can flow through the mesh type electrode, so that the acidic water drainage line 30 If the drainage state of the) is not good because acidic water in the electrolytic cell 100 can be introduced directly into the alkaline water drainage line (20).

3 is an exploded perspective view showing an electrolytic cell composed of a mesh type electrode, and FIG. 4 is an assembled cross-sectional view of the electrolytic cell shown in FIG. 3 along the line A-A '.

The electrolytic cell 100 is based on the electrolysis of water by the positive electrode plate 131 and the negative electrode plate 141 to which power is applied, and the first and second housings 110 formed to have a constant space 112 therein. , 120 having a basic shape, including an inflow path 117 through which water flows into the space 112, and an inflow groove 115 communicating the inflow path 117 and the space 112. In addition, the positive electrode plate 131 and the negative electrode plate 141 are mounted to the space 112 and provided with an electrode inlet 114 to be drawn out.

On the other hand, the positive electrode plate 131 and the negative electrode plate 141 may be a flat plate structure, as shown in Figure 1 and 2 may be a mesh (lattice) type. Here, the mesh type is not limited to the mesh type, and a plurality of holes may be punched in the flat plate. In the detailed description according to the present invention, the perforated plate-shaped electrode is collectively referred to as a mesh type.

The mesh type electrode is advantageous to facilitate the flow of water and the electrolytic reaction in the spaces 112 in the 1,2 housings 110 and 120, and thus an attempt has been made to apply the mesh type electrode to the ionizer.

The positive and negative electrode plates 131 and 141 illustrated in FIGS. 3 and 4 are included in the mesh electrodes 130 and 140, and spaced apart means 150 is provided so that the positive electrodes 130 and 140 do not contact each other.

As shown in FIG. 4, the mesh type electrodes 130 and 140 flow current into water introduced into the space 112 through the inflow path 117 and the inflow groove 115 to cause electrolysis. The water decomposes into acidic water and alkaline water in the space 112 while flowing through the mesh type electrodes 130 and 140 and flowing through the first space a, the second space b, and the third space c. .

As is widely known, acidic water is formed in the mesh type positive electrode 130 as water containing hydrogen ions, and alkaline water is formed in the mesh type negative electrode 140 as water containing hydroxide ions.

The acidic water and the alkaline water decomposed in this way are respectively acidic water drain line 111 and the alkaline water drain line 111 adjacent to the mesh-type positive electrode 130 and the alkaline water drain line 121 adjacent to the mesh-type negative electrode 140 Separately discharged to the drain line (20).

The electrolytic cell 100 of the mesh type electrode having the above-described structure will be required to acidic water drain line 30 according to the present invention.

Figure 5 is a block diagram showing another embodiment of a cold ion water purifier according to the present invention, Figure 6 is a cross-sectional view showing a detail of the sump tank shown in Figure 5, it will be described with reference to this.

The electrolyzer 100 generates a gas such as oxygen and hydrogen in addition to hydrogen ions and hydroxide ions while electrolyzing the introduced water. The gas generated in this way may flow into the pressure pumping means 50 to stop the pressure pumping means 50.

On the other hand, the acidic water drain line 30 may vary in length depending on the location and the interior structure of the cold ion water heater. Of course, the length of the acidic water drain line 30 is proportional to the magnitude of the water pressure required to smoothly drain the acidic water in the electrolytic cell. By the way, it is practically difficult to adjust the strength of the pressure pumping means 50 pre-installed in the cold water heater according to the length of the drainage line 30, and the pressure pumping means is automatically adjusted in accordance with the water pressure. It is difficult to economically.

Therefore, it is not necessary to adjust the operating strength of the pressurized pumping means 50 by maintaining the length of the acidic water drainage line 30 irrespective of the spatial characteristics in which the cold water ionizer is installed, and also generated in the electrolytic cell 100. A structure may be required to prevent the pressurized pumping means 50 from stopping due to the gases.

To this end, another embodiment of the acidic water drainage line of the cold ion water purifier according to the present invention further includes a collecting tank 60 in which the acidic water discharged from the electrolytic cell 100 is temporarily stored, and the acidic water pressurizing pump 51 is provided. It is disposed in the drain 63 is in communication with the lower end of the sump (60). At this time, the switch 61 for controlling the ON / OFF of the acidic water pressure pumping means 51 so that the acidic water pressure pumping means 51 can operate only when the acidic water collected in the water collection tank 60 is a predetermined amount or more. It may further include. As shown in the figure, the switch 61 may include a buoyancy body 61a that moves up and down depending on the water level and a guide bar 61b for guiding the buoyancy body 61a while floating on the surface of acidic water. . Therefore, the above-described switch 61 sends a signal to the acidic water pressurizing pumping means 51 when the buoyancy body 61a moves up and down as the water level changes and rises above a predetermined height so that the pressurizing pumping means 51 operates. .

The switch 61 is not limited to the above-described configuration. If the switch 61 is capable of controlling ON / OFF of the acidic water pressurized pumping means 51 after sensing the level of acidic water in the sump 60, the following claims are made. Various modifications may be made without departing from the scope thereof.

Meanwhile, as shown in FIG. 5, the alkaline water pressurizing pump 52 may be further included as the alkaline water drainage line 20. That is, when the user opens the valve to drink the alkaline water, the alkaline water pressure pumping means 52 operates, pumping the alkaline water in the electrolytic cell 100, and discharging it through the valve. When the valve is closed, the bypass is operated for a predetermined time. The alkaline water remaining in the alkaline water drainage line 20 is discharged to the water collecting tank 60 through 40.

Unexplained withdrawal sign '62' is an inlet of the sump 60, is connected to a portion of the acidic water drain line 30, so that the acidic water flowing from the electrolytic cell 100 flows into the sump (60). .

According to the present invention as described above, while the alkaline water and the acidic water electrolytically separated from the electrolytic cell is drained through the alkaline water drainage line and the acidic water drainage line, the acidic water is not smoothly drained by the water pressure in the acidic water drainage line and mixed with the alkaline water while refluxing. There is an effect that it is possible to prevent high water, and to supply high quality alkaline water.

Claims (5)

A cold water tank for cooling the introduced water; An electrolytic cell including a positive electrode and a negative electrode for electrolyzing water introduced from the cold water tank; An alkaline water drain line for draining alkaline water electrolyzed and separated from the electrolytic cell; An acidic water drain line for draining the acidic water electrolyzed and separated from the electrolytic cell; And An acidic water pressurizing pump disposed in the acidic water draining line to pump acidic water drained from the electrolytic cell along the acidic water draining line; Cold ion water heater comprising a. The method of claim 1, Disposed in the acidic water drainage line to store acidic water flowing from the electrolytic cell, and detecting a change in the level of the stored acidic water and generating a signal when detected above a predetermined level, wherein the stored acidic water is And a water collecting tank discharged by the acidic water pressurized pumping means which is ON / OFF according to a signal of a switch. The method according to claim 1 or 2, And a bypass connecting the alkaline water drainage line and the acidic water drainage line. The method of claim 3, wherein While interlocking with a valve that controls the opening and closing of the alkaline water draining line, when the valve is opened, the alkaline water in the alkaline water draining line is pumped, and when the valve is closed, the alkaline water in the alkaline water draining line is pumped for a predetermined time while the acid is passed through the bypass. Cold water ionizer, characterized in that it further comprises an alkaline water pressure pump means for draining to the water drain line. The method according to any one of claims 1, 2 or 4, The positive electrode and the negative electrode of the electrolytic cell is a cold ion water heater, characterized in that the hole is formed so that water can pass.

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