KR100981585B1 - Structure for multi type electrolytic cell - Google Patents

Abstract

The present invention relates to a multi-type electrolytic cell structure in which a plurality of electrolyzers can be installed in a limited space, and strong alkaline water and strong acidic water can be obtained by electrolyzing the introduced raw water over the first and second times.
The present invention for realizing this is at least two water inlet is formed in the front upper side, the body housing is formed in the outlet on the rear lower side corresponding to the number of the inlet; A first electrolyte tank in which two or more electrode plates having different polarities are sequentially connected in series so as to firstly electrolyze raw water introduced through the water inlet to generate acidic water and alkaline water; A second electrolytic tank in which two or more electrode plates having different polarities are sequentially connected in series so as to electrolytically electrolyze the electrolyzed water generated through the first electrolytic tank to generate strong acidic water and strong alkaline water; A flow path switching diaphragm interposed between the first electrolyte tank and the second electrolyte tank to convert the flow path of the electrolyzed water generated and discharged through the first electrolyte tank from the lower side to the upper side, and connected in series with the second electrolyte tank; And a power supply unit electrically connected to the electrode plate to supply DC power.

Description

Structure for multi type electrolytic cell

The present invention relates to a multi-type electrolytic cell structure, and more particularly, to a multi-type electrolytic cell structure capable of obtaining strong alkaline water and strong acidic water by electrolyzing raw water.

Generally, preferred drinking water is water containing various heavy metals, harmful substances and bacteria, and an appropriate amount of minerals, and it is known that bottled water containing alkaline Ca + or Na + is most ideal.

To this end, an electrolytic water generating device has been developed to electrolyze water to separate and discharge the alkaline water (cathode water), which is a mineral water of + ions, and the acidic water (anode water), which is non- drinking water. A water purification system having a water purification function, which is equipped with all electrolytic functions and is configured to discharge water having purified water through an electrolytic cell, has been released.

For example, in the electrolytic cell, water is poured into a body in which a diaphragm is installed between an electrode plate composed of an anode and a cathode, and then a direct current is flowed. In the cathode, calcium (Ca), potassium (K), magnesium (Mg), sodium ( Alkaline water is generated while metal alkaline cations such as Na) and hydrogen cations are attracted, and anions such as chloride ions, carbonate ions, lactic acid ions and nitrate ions are attracted to the anode to generate acidic water.

As an example of the water purifier provided with such an electrolytic cell, the registration room No. 0392681 "electrolytic water purification system", the registration room No. 0412166 "a water purifier type ionizer" etc. are proposed conventionally.

The conventional electrolytic cell has a structure in which the volume of the electrolytic cell is large and the longitudinal direction of the electrolytic cell is installed in parallel with the gravity direction as shown in the drawing. That is, a large space must be secured separately for installation, and the installation method is also limited.

In addition, it is necessary to adjust the quantity of the electrode plate in order to discharge the appropriate level of ions according to the capacity of the water purifier, the conventional electrolytic cell is not possible to control the quantity of the electrode plate, so that the capacity of the electrolytic cell is increased accordingly Should be increased.

However, in this case, the manufacturing process is increased, there is a problem that the size and manufacturing cost of the device increases.

The present invention has been made to solve the above problems, it is possible to install a plurality of electrolytic cell in a limited space, multi-type to obtain a strong alkaline water and strong acidic water by electrolyzing the incoming raw water over the first and second The purpose is to provide an electrolyzer structure.

Multi-type electrolytic cell structure of the present invention for realizing the object as described above, at least two inlet port is formed on the front upper side, the body housing is formed in the rear lower side corresponding to the number of the inlet port; A first electrolyte tank in which two or more electrode plates having different polarities are sequentially connected in series so as to firstly electrolyze raw water introduced through the water inlet to generate acidic water and alkaline water; A second electrolytic tank in which two or more electrode plates having different polarities are sequentially connected in series so as to electrolytically electrolyze the electrolyzed water generated through the first electrolytic tank to generate strong acidic water and strong alkaline water; A flow path switching diaphragm interposed between the first electrolyte tank and the second electrolyte tank to convert the flow path of the electrolyzed water generated and discharged through the first electrolyte tank from the lower side to the upper side, and connected in series with the second electrolyte tank; And a power supply unit electrically connected to the electrode plate to supply DC power.

In this case, the electrode plate, at least two through holes are formed in the upper and lower portions so as to be used as a flow path for the inlet or discharge of the raw water, the upper side, the lower side is provided with an opening formed in selective communication with any one of the through holes block; An electrode member coupled to the opening and configured to electrolyze the introduced raw water by receiving a positive (+) or (−) polar current; And a fixing member for fixing the electrode member to the body block.

In addition, the first electrode plate, the first electrode plate disposed in the upper and lower through holes of the upper left and the lower right through holes of the communication with the opening to form a first flow path, and then The electrode plate is disposed, the through hole in the upper right and the lower left through hole is in communication with the opening is repeatedly connected in a manner to form a second flow path, the raw water introduced through the inlet is the first flow path and the second It is characterized in that the electrolysis can be made in a separate flow according to the (+), (-) polarity through the flow path.

In addition, a packing is further interposed between the electrode plate and the electrode plate to maintain the airtightness.

In addition, the flow path switching diaphragm is a pair of the first panel and the second panel of the same size as the electrode plate is made of a joint with each other, two inlets connected to the first and second flow paths on the lower side of the first panel Is formed through, the upper one side of the second panel is formed with two outlets, the first and the second panel includes a joining surface formed with a flow path groove connecting the inlet and outlet.

In the multi-type electrolytic cell structure according to the present invention having the above-described configuration, a plurality of electrolyzers can be easily installed in a limited space by using a flow path switching diaphragm, and by electrolyzing the electrolytic water firstly electrolyzed secondly again There is an advantage that strong alkaline water and strong acidic water can be obtained.

1 is a perspective view of a multi-type electrolytic cell structure according to the present invention,
2 is an exploded perspective view of a multi-type electrolytic cell structure according to the present invention;
3 is an exploded perspective view of the first and second electrolytic baths according to the present invention;
4 is an exploded perspective view showing the configuration of an electrode plate according to the present invention;
5 is a front view showing a flow path formed in the electrode plate according to the present invention,
6 is an exploded perspective view showing a packing interposed between the positive electrode plate and the negative electrode plate according to the present invention,
7 is an exploded perspective view of the flow path switching diaphragm according to the present invention.

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

Here, in adding reference numerals to the components of each drawing, it should be noted that the same reference numerals are denoted by the same reference numerals as much as possible even if displayed on the other drawings.

1 is a perspective view of a multi-type electrolytic cell structure according to the present invention, FIG. 2 is an exploded perspective view of the multi-type electrolytic cell structure according to the present invention, and FIG. 3 is an exploded perspective view of the first and second electrolytic cell according to the present invention.

1 and 2, the multi-type electrolytic cell structure according to the present invention is the main body housing 10, the first electrolytic cell 20, the second electrolytic cell 30, the flow path switching diaphragm 40 and the power supply unit 50 It is configured to include.

Referring to the configuration of the present invention in detail as follows.

The main body housing 10 constitutes a main body of the multi-type electrolytic cell 1, and the main body housing 10 includes a front cover 11 and a rear cover 13. In this case, at least two water inlets 12 are formed at an upper side of the front cover 11 so that raw water (tap water, fresh water, sea water, groundwater, etc.) can be obtained, and at the lower side of the rear cover 13, water can be obtained. The outlet 14 is formed so that the generated raw water is discharged after the predetermined raw water passes through a predetermined electrolysis process.

Referring to FIG. 3, the first electrolytic bath 20 is installed inside the main body housing 10 to electrolyze raw water introduced into the upper portion through the inlet 12 to generate acidic and alkaline water. One electrolytic bath 20 is arranged two or more, preferably three electrode plates 100 side by side, but the polarity is arranged differently from the adjacent electrode plate 100.

For example, when a direct current of negative polarity is applied to the first electrode plate 100, a positive current is applied to the second electrode plate 100, and the third electrode is arranged. The plate 100 is again subjected to a negative polarity current.

Here, preferably, the inlet 12 and the outlet 14 are each formed in two, and the raw water introduced through the inlet 12 may have a separate flow according to the polarity of the first passage 12a. And a second flow passage 12b. Referring to the structure of the electrode plate 100 as follows.

Figure 4 is an exploded perspective view showing the configuration of the electrode plate according to the present invention, Figure 5 is a front view showing a flow path formed in the electrode plate according to the present invention.

Referring to FIG. 4, the electrode plate 100 has at least two through holes 111 formed at an upper side and a lower side thereof, respectively, so that the electrode plate 100 can be used as an inflow or discharge path of raw water. The body block 110 is provided with an opening 113 formed in communication with any one of the one and the body block 110 is coupled to the opening 113 to electrolyze the incoming raw water by receiving a positive (+) or (-) polar current It comprises an electrode member 120 and a fixing member 130 for fixing the electrode member 120 to the body block 110.

In this case, the electrode member 120 coupled to the opening 113 forms a predetermined space for accommodating the raw water introduced through the through hole 111, and increases the residence time of the raw water, thereby effectively electrolysis is achieved. It is formed in the form of a mesh to be made. Here, preferably, the electrode member 120 is formed of platinum titanium material to facilitate the electrolysis. The electrode member 120 is electrically connected to the power supply unit 50 to be described later protruding portion 121 formed in the upper side is supplied with a DC current.

On the other hand, the raw water introduced by the communication structure of the through hole 111 and the opening 113 formed on the upper and lower portions of the electrode plate 100 to form different flows according to the (+), (-) polarity do. For example, as shown in (a) of FIG. 5, the first electrode plate 100 disposed may include a through hole 111a on the upper left side of the two through holes 111 formed on the upper and lower portions, respectively. The through hole 111d on the lower right side communicates with the opening 113 to form the first flow passage 12a. As shown in FIG. 5B, the electrode plate 100 disposed next to the through hole 111b of the upper right side and the through hole 111c of the lower left side communicate with the opening 113. The two passages 12b are repeatedly connected in a manner to form.

As the plurality of electrode plates 100 are sequentially coupled in this manner, the raw water introduced through the inlet 12 may have positive and negative polarities through the first channel 12a and the second channel 12b. It is possible to form the first electrolytic bath 20 so that the electrolysis can be made in a separate flow. That is, the first passage 12a passes through only the (-) electrode plate 100, and the second passage 12b passes through only the (+) electrode plate 100, whereby electrolysis is performed. And acidic water.

6 is an exploded perspective view showing a packing interposed between the positive electrode plate and the negative electrode plate according to the present invention, Figure 7 is an exploded perspective view of the flow path switching diaphragm according to the present invention.

Referring to FIG. 6, a packing 140 is interposed between the electrode plate 100 and the electrode plate 100 to maintain airtightness. Taking the case of the electrode plate 100 having the second flow path 12b as an example, the packing 140 has an upper right side among the two through holes 111 provided in the upper and lower portions of the electrode plate 100, respectively. The through-hole 111b and the lower left through-hole 111c and the opening 113 are connected in a closed curve shape, and the upper left through-hole 111a and the lower right through-hole 111d are separately wrapped. .

In addition, the packing 140 interposed in the electrode plate 100 on which the first flow path 12a is formed is formed in a shape symmetrical with the case of the packing 140 interposed in the second flow path 12b, thereby forming an electrode plate ( Interposed between 100).

Meanwhile, referring back to FIG. 2, a second electrolytic bath 30 is further provided to the rear of the first electrolytic bath 20.

The second electrolytic bath 30 electrolytically decomposes electrolytic water firstly electrolyzed through the first electrolytic bath 20 to generate strong acidic water and strong alkaline water, and the second electrolytic bath 30 is a first electrolytic bath. Like 20, two or more electrode plates 100 having different polarities are sequentially arranged side by side.

In this case, the alkaline water electrolyzed in the negative electrode plate 100 of the first electrolytic cell 20 is transferred to the negative electrode plate 100 of the second electrolytic cell 30 through the first flow passage 12a. The acidic water electrolyzed in the positive electrode plate 100 of the first electrolytic cell 20 flows into the positive electrode plate 100 of the second electrolytic cell 30 through the second flow passage 12b. In this way, the strong acidic water and the strong alkaline water introduced into the second electrolytic bath 30 through the second electrolytic process are discharged and stored to the outside through the two outlets 14.

The first and second electrolytic baths 20 and 30 having such a structure are connected to each other in a limited space through the flow path switching diaphragm 40.

Referring to FIG. 7, the flow path switching diaphragm 40 converts the flow path of the electrolyzed water generated and discharged through the first electrolyte tank 20 from the lower side to the upper side, and connects in series with the second electrolyte tank 30. It's a kind of connection. The flow path switching diaphragm 40 is formed by bonding a pair of first panel 41 and second panel 43 of the same size as the electrode plate 100. In this case, two inlets 41a connected to the first and second flow paths 12a and 12b are respectively formed at one lower side of the first panel 41, and two at one upper side of the second panel 43. Outlets 43a are formed through. In addition, flow path grooves 43b connecting the inlets 41a and the outlets 43a are formed at the joint surfaces of the first and second panels 41 and 43.

Here, the flow path switching diaphragm 40 is an example of switching the flow path from the bottom to the top, but in some cases, the structure can be changed so that the flow path can be switched from the upper side to the lower side.

On the other hand, the multi-type electrolytic cell 1 is provided with a power supply unit 50 for supplying a DC power of different polarity to the plurality of electrode plates 100 interpolated in the first electrolytic cell 20 and the second electrolytic cell 30. .

The procedure of assembling the multi-type electrolytic cell 1 of such a structure is as follows. First, the first and second electrolytic baths 20 and 30 are formed in a form in which the rubber packing 140 for airtightness aligns the plurality of electrode plates 100 interposed therebetween, respectively, After the flow path switching diaphragm 40 for switching the flow path between the electrolytic cells 20, 30, the front cover 11 and the rear of the front and rear of the first and second electrolytic baths 20, 30, Placing the cover 13 as well as fastening it using a fastening means (not shown), the assembly of the multi-type electrolytic cell 1 is completed.

On the other hand, it is also possible to configure two or more electrolyzers by combining another electrolytic cell (not shown) in series to the rear of the second electrolytic cell 30 by using the flow path switching diaphragm 40. .

Then, the operation of the multi-type electrolytic cell structure of the present invention having the above configuration will be described.

First, raw water introduced into the first electrolytic cell 20 through the inlet 12 passes through two or more electrode plates 100 having different polarities through the first and second flow paths 12a and 12b. The first step is electrolysis.

In this case, the raw water passing through the negative polarity of the first passage 12a is positively attracted to the cathode by cations such as calcium (Ca), magnesium (Mg), potassium (K), and sodium (Na) ions. Hydrogen ions (OH-) and dissolved hydrogen (H ₂ ) increase as the electrode member 120 is polarized to generate alkaline alkaline water having a pH of 7 or more.

In the case of raw water passing through the second flow passage 12b having a positive polarity, anions such as chloride, carbonic acid, lactic acid, and nitrate ions are attracted to the positive electrode, and the positive electrode electrode 120 As it is decomposed, hydrogen ions (H +), anions and dissolved oxygen (O ₂ ) are increased, and acidic acidic water having a pH of 7 or less is produced.

As such, the electrolyzed water (alkali water and acidic water) produced by the first electrolysis through the first electrolytic cell 20 is introduced again to the upper side of the second electrolytic cell 30 by the flow path switching diaphragm 40 and secondarily supplied with electricity. It goes through a decomposition process.

After the raw water flows through the first and second electrolysis processes as described above, strong alkaline water of pH 10.5 or more and strong acidic water of pH 4 or less can be obtained. Strong acidic water and strong alkaline water generated by this process are discharged and stored to the outside through the two outlets (14).

In the above, the multi-type electrolytic cell 1 of the present invention forms the first and second flow paths 12a and 12b in a structure that moves the raw water introduced through the inlet 12 from the upper side to the lower side, but retains the obtained raw water. Of course, the first and second flow paths 12a and 12b may be formed in a structure that moves the raw water from the lower side to the upper side so that more efficient electrolysis is achieved by increasing the time.

In addition, the number of the electrode plates 100 constituting the first and second electrolytic baths 20 and 30 may be further combined and used as necessary.

As such, the present invention is not limited to the above embodiments, and various changes and modifications are possible by those skilled in the art to which the present invention pertains without departing from the technical spirit of the present invention.

1: multi-type electrolytic cell 10: main body housing
11: front cover 12: inlet
12a: first euro 12b: second euro
13 rear cover 14 outlet
20: first electrolyte tank 30: second electrolyte tank
40: flow path conversion diaphragm 41: the first panel
41a: Inlet 43a: Outlet
43b: Eurohome 50: Power supply
100: electrode plate 110: body block
111 through hole 113 opening
120: electrode member 130: fixed member

Claims (5)

A main body housing having at least two water inlets formed at the front upper side, and water outlets formed at the rear lower side corresponding to the number of the water inlets;
A first electrolyte tank in which two or more electrode plates having different polarities are sequentially connected in series so as to firstly electrolyze raw water introduced through the water inlet to generate acidic water and alkaline water;
A second electrolytic tank in which two or more electrode plates having different polarities are sequentially connected in series so as to electrolytically electrolyze the electrolyzed water generated through the first electrolytic tank to generate strong acidic water and strong alkaline water;
A flow path switching diaphragm interposed between the first electrolyte tank and the second electrolyte tank to convert the flow path of the electrolyzed water generated and discharged through the first electrolyte tank from the lower side to the upper side, and connected in series with the second electrolyte tank; And
And a power supply unit electrically connected to the electrode plate to supply DC power.
The electrode plate is a body block having at least two through-holes formed in the upper and lower portions, respectively, so that the electrode plate can be used as an inflow or discharge path of raw water, the upper side and the lower side of which is provided with an opening formed in selective communication with any one of the through-holes; The electrode member of the platinum titanium material and the electrode member is coupled to the opening and formed in a mesh form so as to electrolyze the incoming raw water by receiving a positive (+) or (-) polarity current to increase the residence time of the raw water, It is configured to include a fixing member for fixing to the body block,
The flow path switching diaphragm is formed by bonding a pair of first panel and a second panel having the same size as the electrode plate to each other, and two inlets connected to the flow path are formed at a lower side of the first panel. And, the upper one side of the second panel is formed with two outlets, the first and second panels of the multi-type electrolytic cell structure comprising a flow path groove formed to connect the inlet and the outlet is formed. delete The method of claim 1,
The electrode plate,
In the first electrode plate disposed, a through hole on the upper left side and a through hole on the lower right side of the two through holes formed in the upper and lower portions communicate with the opening to form a first flow path.
The electrode plate that is disposed next includes the through holes on the upper right side and the through holes on the lower left side which are repeatedly connected in a manner of communicating with the opening to form the second flow path.
Multi-type electrolyzer structure, characterized in that the raw water introduced through the inlet to the electrolysis can be made in a separate flow according to the (+), (-) polarity through the first channel and the second channel. The method of claim 3,
Multi-type electrolytic cell structure further comprising a packing interposed between the electrode plate and the electrode plate to maintain the airtight. delete

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