KR200478290Y1 - Purifier having extendable electrolytic bath module of hydrogen water - Google Patents

Abstract

The present invention can stack electrolytic cells in a module form by stacking an expansion set made in a block shape in accordance with the electrolytic capacity of the electrolytic cell which varies according to the treatment capacity of a water purifier and the like, The present invention provides an electrolytic cell module which is easy to expand and which can obtain a desired processing capacity by stacking an expansion set.
In the present invention, in the filter using the reverse osmosis filter, the discharged water is once again filtered by the reverse osmosis filter, thereby reducing the amount of water discharged compared to the amount of water supplied, thereby minimizing the unnecessary configuration, Another object of the present invention is to provide a water purifier equipped with a water electrolytic cell module which is easy to expand and which can improve filtration performance.
Another object of the present invention is to provide a water purifier equipped with a water electrolytic cell module which is easy to expand so that acidic oxidized water or acidic reduced water can be obtained according to the polarity of an applied power source.

Description

TECHNICAL FIELD [0001] The present invention relates to a purifier having an electrolytic module,

More particularly, the present invention relates to a water purifier provided with a small-capacity electrolytic cell module that is easy to expand, and more particularly, to a water purifier having a capacity of an electrolytic cell assembled in a modular form according to the required water capacity, Also, the present invention relates to a water purifier capable of improving filtration efficiency by minimizing drainage by re-filtering wastewater filtered and disposed in a filter.

Generally, a water purifier is configured to receive raw water (for example, tap water) from the outside and filter it through a filter or the like and then drink it. Recently, a water purifier that provides various functions with various functions according to the demand of the consumer has appeared.

Patent document 1 discloses such a water purifier. The water purifier includes a filtration section for filtering the incoming water, a storage section including a first tank connected to the filtration section to store the filtered water in the filtration section and a second tank connected to the first tank, And a sterilizing unit connected to the tank for circulating and sterilizing the water in the second tank, so that circulation and sterilization are possible.

However, the existing water purifier had the following problems.

(1) When the purifier capacity increases according to the processing capacity of the purifier, the size of the hydrogen generator (electrolyzer) must be increased to handle the purifier capacity. Therefore, it is troublesome to re-manufacture the electrolytic cell according to the capacity of the water purifier required.

(2) Because of this inconvenience, the increase in the number of processings due to the production of the water purifier, etc., not only lowers the manufacturing efficiency but also increases the manufacturing cost.

(3) On the other hand, in the case of a water purifier equipped with such an electrolytic cell, a reverse osmosis filter is used as one method for improving the filtration performance. However, in the case of the reverse osmosis filter, a large amount of discharged water is discharged to the outside after filtering.

(4) As the amount of water discharged from the filter increases, the more raw water is required to obtain the desired water number.

(5) In addition, since a large amount of drainage is required, a separate drainage facility must be provided for this, so that the construction is complicated. In addition, there is a need to frequently drain the drainage tank when there is no drainage facility.

Korean Patent Laid-Open No. 10-2011-0060998 (published on June 06, 2011)

The present invention has been made in consideration of this point, and it is possible to assemble an electrolytic cell into a module form by stacking an expansion set made in a block shape according to the electrolytic capacity of an electrolytic cell, And an electrolytic bath which is different according to the electrolytic bath of the electrolytic cell, is manufactured by stacking the expansion sets without separately preparing an electrolytic bath.

In the present invention, in the filter using the reverse osmosis filter, the discharged water is once again filtered by the reverse osmosis filter, thereby reducing the amount of water discharged compared to the amount of water supplied, thereby minimizing the unnecessary configuration, Another object of the present invention is to provide a water purifier equipped with a water electrolytic cell module which is easy to expand and which can improve filtration performance.

Another object of the present invention is to provide a water purifier equipped with a water electrolytic cell module which is easily expandable so as to obtain oxidized water or reduced water according to the polarity of an applied power source.

In order to achieve the above object, the present invention provides a water purifier including a water electrolytic cell module having a simple expansion function, comprising: a filter for filtering raw water supplied through a raw water pipe; A pump for feeding the filtered raw water; A water electrolytic cell module for converting the raw water supplied from the water supply unit into hydrogen water; And a rapid cooler for cooling and discharging the hydrogenated water to the outside, wherein a reaction chamber is formed on each side of each of the reaction chambers, each of the reaction chambers has an inlet / outlet port and a second electrode A reaction chamber block; A pair of finishing blocks each having a third electrode on a surface facing each of the reaction chambers and closing both sides of the reaction chamber block so that each of the reaction chambers is partitioned; And an ion exchange membrane mounted between the reaction chamber block and the finishing block so as to be positioned between the second electrode and any one of the third electrodes, wherein the second electrode and the third electrode, which face the ion exchange membrane, And the third electrode is applied with the same polarity as that of the second electrode, and the filter includes a composite filter which is supplied with raw water, and a raw water which is pressure-fed by the pump, A first reverse osmosis filter and a second reverse osmosis filter, and the wastewater generated from the first reverse osmosis filter is supplied to the second reverse osmosis filter to be re-filtered.

Particularly, the water purifier provided with the water electrolytic cell module which is easy to expand according to the present invention includes: a filter for filtering the raw water supplied through the raw water pipe; A pump for feeding the filtered raw water; A water electrolytic cell module for converting the raw water supplied from the water supply unit into hydrogen water; And a rapid cooler for cooling and discharging the hydrogenated water to the outside, wherein the hydrogen-containing electrolytic cell module has reaction chambers formed on both sides thereof, each of the reaction chambers being provided with an inlet / outlet port, A reaction chamber block having a second electrode; And a pair of finishing blocks each having a third electrode on a surface facing each of the reaction chambers and closing both sides of the reaction chamber block so that each of the reaction chambers is partitioned, Wherein at least one expansion set including a separation block and a reaction chamber block each having a first electrode on both sides thereof is further installed between the first electrode and the second electrode, The electrodes arranged on both sides of the ion exchange membrane are applied with different polarities to the first electrode, the second electrode and the third electrode, and the same polarity is applied to the electrodes arranged opposite to each other without the ion exchange membrane; The filter includes a first reverse osmosis filter and a second reverse osmosis filter for sequentially filtering reverse osmosis and filtering the raw water that has been pumped by the pump, The wastewater generated from the osmotic pressure filter is characterized in that the material to be filtered is supplied to the second reverse osmosis filter.

In particular, an anode is applied to the first electrode, and a cathode is applied to the second electrode and the third electrode.

The first electrode is applied with a cathode, and the second electrode and the third electrode are applied with an anode.

According to the water purifier provided with the hydrogen-reduced electrolytic cell module of which the present invention can be easily expanded, the following effects can be obtained.

(1) By simply adding and assembling an extension set in the form of a block according to the required capacity of the electrolytic cell, the structure can be easily and quickly assembled and used according to the required small water capacity, so that it can be easily expanded Can be used.

(2) The waste water drained from the reverse osmotic filter after filtration is filtered once again, thereby minimizing the amount of drainage, and improving the utilization efficiency of the purified water.

(3) Since the components are assembled in blocks, they can be easily assembled and assembled quickly, and the capacity of the desired electrolytic cell can be assembled and used.

(4) The oxidized water can be obtained or the reduced water can be easily obtained through the polarity of the power source applied to the water electrolytic cell module.

(5) Even if a fault occurs during use, it is advantageous to replace only the failed block, which is more advantageous than the conventional electrolytic cell in which the entire electrolytic cell needs to be replaced in terms of maintenance.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a schematic view showing a configuration for showing an overall configuration of a water purifier according to a first embodiment of the present invention; FIG.
2 is a block diagram showing a configuration of a filter according to a first embodiment of the present invention;
FIG. 3 is an exploded perspective view of the electrolytic cell module according to the first embodiment of the present invention. FIG.
FIG. 4 is a cross-sectional view illustrating a combined state of the hydrogen-containing electrolytic cell module according to the first embodiment of the present invention; FIG.
FIGS. 5 and 6 are schematic views showing a state where power is applied to the hydrogen-water electrolytic cell module of FIG. 4 according to the first embodiment of the present invention. FIG.
FIG. 7 is a cross-sectional view illustrating a combined state of a hydrogen-water electrolytic cell module according to a second embodiment of the present invention; FIG.
FIG. 8 is a cross-sectional view showing a combined state of a hydrogen-water electrolytic cell module according to a third embodiment of the present invention; FIG.

Hereinafter, preferred embodiments of the present invention will be described in more detail with reference to the accompanying drawings. Prior to this, terms and words used in the present specification and claims should not be construed as limited to ordinary or dictionary meanings, and the inventor may appropriately design the concept of the term appropriately to describe its own design in the best way possible. It should be interpreted as a meaning and a concept consistent with the technical idea of the present invention based on the principle that it can be defined.

Therefore, the embodiments described in the present specification and the constitutions shown in the drawings are merely the most preferred embodiments of the present invention and do not represent all the technical ideas of the present invention. Therefore, various equivalents It should be understood that water and variations may be present.

As shown in Figs. 1 to 6, the water purifier according to the present invention includes a filter 10 for filtering the purified water, a pump 20 for feeding the filtered purified water, A water electrolytic cell module M, and a rapid cooler 50 for cooling the water before draining water.

In particular, the water electrolytic cell module M can be assembled and used in the form of a block in accordance with the processing capacity of the small water according to the capacity of the water purifier, so that the structure is simple and can be easily and quickly adjusted to the desired water- So that a small number of electrolytic module can be assembled and used.

In addition, the filter 10 includes at least two reverse osmosis filters, and the water drained to the outside of the water purifier by the reverse osmosis function is filtered by the reverse osmosis filter once again, thereby minimizing the amount of water discharged to the outside of the water purifier I can do it.

Hereinafter, this configuration will be described in more detail as follows.

The filter (10) is connected to the raw water pipe (11) to supply the raw water from the outside of the water purifier to filter it. Such a filter 10 can be used as long as it is conventionally used in a water softener. In a preferred embodiment of the present invention, the filter 10 is illustratively made up of a composite filter 12, a first reverse osmosis filter 13 and a second reverse osmosis filter 14.

As shown in FIG. 2, the drainage pipe 13a for discharging the drainage water generated in the first osmotic pressure filter 13 is connected to the second osmotic pressure filter 13, (14) so that the drainage can be filtered again, thereby minimizing the amount of drainage.

The pump 20 uses a normal driving pump used in the purifier. Illustratively, such a pump 20 may be a booster pump.

It is preferable that the pump 20 is configured to feed raw water that has passed through the composite filter 12 as shown in Fig. 2 so that no driving loss or the like occurs due to foreign substances or the like. That is, the pump 20 is installed between the composite filter 12 and the first osmotic pressure filter 13 so that the raw water filtered by the composite filter 12 can be transported to the first osmotic pressure filter 13 side.

As shown in FIGS. 3 to 6, the hydrogen-containing electrolytic cell module M includes reaction chambers 210a and 210b on both sides thereof to supply and drain water from the outside, and one of the reaction chambers 210b, A reaction chamber 200 having a reaction chamber 200 and an expansion set ES stacked with the reaction chamber 200 and a third electrode 310 are provided in the reaction chamber 210a, And a pair of finishing blocks 300 for finishing the set ES.

The reaction chamber block 200 has reaction chambers 210a and 210b opened on both sides thereof. The reaction chambers 210a and 210b are supplied with raw water from the outside, A receiving port 211 is provided. 3, the inlet / outlet ports 211 are formed at both ends of the reaction chamber block 200, but they may be formed on the upper surface and the lower surface of the reaction chamber block 200 in FIG. 3, have.

3 and 4, the reaction chamber block 200 is provided with a mounting portion 230 at a position corresponding to the mounting portion 110 described above on the outer peripheral surface. Mounting holes 231 are formed in the mounting portions 230 at positions corresponding to the mounting holes 111, respectively. The reaction chamber block 200 is installed so as to face the partition block 100. In this case, the mounting holes 111 and 231 are stacked so as to overlap with each other.

In the reaction chamber block 200, the second electrode 240 is provided in one of the reaction chambers 210b.

The extension set ES includes a separation block 100 having first electrodes 120 on both sides thereof and a reaction chamber block 200 'stacked on the outer side of the separation block 100. These extension sets allow a plurality of stacks to control the processing capacity. Here, since the reaction chamber block 200 'is the same as that of the reaction chamber block 200' described above, detailed description thereof will be omitted here.

The partition block 100 is a nonconductive block body for forming a reaction chamber by partitioning the reaction chamber block 200 to be described later.

Particularly, in the division block 100, the first electrode 120 is provided on each side of the reaction chamber block 200 on both sides thereof. At this time, the first electrode 120 is applied with "+" as shown in FIG. 5 or "-" as shown in FIG.

3, the mounting block 110 is protruded from the outer circumferential surface of the block 100 and the mounting hole 111 is formed in the mounting block 110 in the width direction of the block 100 do.

The finishing block 300 is a block for finishing the open reaction chambers 210a and 210b of the respective reaction chamber blocks 200 stacked on the partition block 100. [

In the finishing block 300, a plurality of mounting portions 320 are formed at the same positions as the mounting portions 110 on the rims, respectively, through which the mounting holes 321 are penetrated.

The third electrode 310 having the same polarity as the second electrode 240 applied to the reaction chamber block 200 is provided in the finishing block 300. 4, the third electrode 310 and the second electrode 240 may be supplied with power from the outside.

The ion exchange membrane 220 is installed between the first electrode 120 and the second electrode 240, respectively. The ion exchange membrane 220 separates anions and cations electrolyzed by a power source applied to each electrode.

The ion exchange membrane 220 may be disposed between the separation block 100 and the reaction chamber blocks 200 and 200 ', or may be installed in any one of the reaction chambers 210b as shown in the figure.

In the electrolytic bath module M according to the first embodiment of the present invention, the components are stacked and fixed with the fixing bolts B through the mounting holes 111, thereby completing the electrolytic bath module.

The polarity applied to each electrode of the electrolytic cell module M according to Example 1 of the present invention is such that the electrodes facing the ion exchange membrane 220 have different polarities and the electrodes facing each other without the ion exchange membrane 220 are the same Polarity is applied. As shown in FIG. 5, when "+" is applied to the first electrode 120 and "-" is applied to the second electrode 240 and the third electrode 310, + "To the second electrode 240 and the third electrode 310, acidic or reduced water can be obtained. At this time, reduced water can be obtained on the cathode side and oxidized water can be obtained on the anode side. The polarity of the power supply is selected according to the type of water to be obtained from the electrolyzer module (M).

1, reference numeral 11a denotes a pressure reducing valve for reducing the pressure of the raw water introduced from the outside through the raw water pipe 11, 22 denotes a pressure reducing valve for reducing the pressure of the filtered water flowing into the water electrolytic cell module M A flow control valve for controlling the flow rate is denoted by 31, a carbon filter for filtering the wastewater generated by the water electrolytic cell module M, and a numeral 40 represents a solenoid valve used for wastewater and water out, respectively . 2, a reference numeral 14a denotes a drain pipe for draining water from the second osmotic pressure filter 14, and a reference numeral 21 denotes a solenoid valve for shutting off the raw water flowing from the filter 10, respectively.

The rapid cooler 50 is a cooler for cooling the hydrogen generated in the electrolyzer module M. In particular, in the present invention, since the water is generated immediately from the electrolyzer module M without providing a separate storage tank, the water is cooled before heading, and then the water is taken out.

The electrolytic cell module M 'according to the second embodiment of the present invention is constructed by adding an extension set ES' as shown in Fig. 7 in order to increase the decomposition capacity in comparison with the first embodiment.

That is, in the second embodiment, another extension set ES 'is further added between the extension set ES described in the first embodiment and the finishing block 300. Here, the added extension set ES 'has the same configuration as the above-described extended set (ES), and a detailed description thereof will be omitted here.

Thus, in the case of Example 2, the number of reaction chambers is increased as compared with Example 1, and as a result, a larger number of hydrogenated water can be obtained as many as the number of reaction chambers.

The water purifier according to the third embodiment of the present invention differs from the first embodiment only in the configuration of the water electrolytic cell module M '' as shown in Fig. 8. Here, do.

8, the electrolytic cell module M "according to the third embodiment has a structure in which the extension set ES is omitted in comparison with the first embodiment. In this case, The third electrode 310 of the first electrode 310 has the same polarity and the third electrode 310 'facing the second electrode 240 disposed with the ion exchange membrane 220 sandwiched therebetween. .

As described above, the present invention can be easily and quickly assembled and used in accordance with the decomposition ability to be electrolyzed by using the extension set made of the block-shaped partition block and the reaction chamber block, will be.

In addition, by draining the water drained by the first reverse osmosis filter through the second reverse osmosis filter, the drainage amount discharged to the outside of the water purifier can be minimized.

10: Filter
11: raw water pipe
12: Composite filter
13: first osmosis filter
13a: Water pipe
14: Second osmosis filter
20: Pump
21: Solenoid valve
22: Flow control valve
100: Separation block
110:
111: Mounting hole
200: reaction chamber block
210a, 210b:
230:
231: Mounting hole
300: Finishing block

Claims (4)

delete A filter 10 for filtering the raw water supplied through the raw water pipe 11; A pump 20 for feeding the filtered raw water by pressure; A hydro-alcohol electrolytic module (M) for receiving and feeding the pressurized raw water; And a rapid cooler (50) for cooling the molten water to be drained to the outside,
Each of the reaction chambers 210a and 210b is provided with an inlet and an outlet port 211 and one of the reaction chambers 210a and 210b is connected to the reaction chambers 210a and 210b, A reaction chamber block 200 provided with a second electrode 240; And a pair of third electrodes 310 provided on the surfaces of the reaction chambers 210a and 210b facing each other and closing both sides of the reaction chamber block 200 so that the reaction chambers 210a and 210b are partitioned A finishing block 300,
At least one extension set consisting of a separation block 100 and a reaction chamber block 200 having a first electrode 120 on each side of the reaction chamber block 200 and one of the finishing blocks 300, Further,
An ion exchange membrane 220 is provided between the first electrode 120 and the second electrode 240,
The first electrode 120, the second electrode 240 and the third electrode 310 are respectively provided with polarities different from each other on the opposite sides of the ion exchange membrane 220. The ion exchange membrane 220, The same polarity is applied to the oppositely arranged electrodes;
The filter (10) comprises a composite filter (12) supplied with raw water and a first reverse osmosis filter (13) and a second reverse osmosis filter (13) which sequentially filter the raw water sent by the pump Osmotic pressure filter (13), and the wastewater generated from the first reverse osmosis filter (13) is supplied to the second reverse osmosis filter (13) to be re-filtered. Equipped water purifier.
3. The method of claim 2,
The first electrode 120 is applied with an anode,
Wherein the second electrode (240) and the third electrode (310) are applied with a negative electrode.
3. The method of claim 2,
The first electrode 120 is applied with a cathode,
Wherein the second electrode (240) and the third electrode (310) are applied with an anode.

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