KR101145975B1 - Water Purifier - Google Patents

Abstract

The present invention relates to a water purifier, and more particularly, to a water purifier composed of a low-level sterilization tank for sterilizing water using an underwater discharge cell, and a high-level water purification tank for storing the sterilized purified water and circulating a portion thereof to a low-level sterilization tank. will be.

Water purifier according to the present invention, the raw water inlet and the outlet is formed sterilization tank; A discharge cell for discharging water in the sterilization tank underwater; A water purification tank formed with an inlet and an outlet through which water of the sterilization tank is introduced; A separating plate separating the sterilization tank and the water purification tank so that the water level of the water purification tank is maintained higher than the level of the sterilization tank; It is installed on the separator is characterized in that it comprises a circulation port for allowing the water of the purified water flow into the sterilization tank.

The water purifier according to the present invention is connected to the sterilization tank with a discharge cell and the water purification tank is connected to the circulation port to remove organic and inorganic materials without using a precipitant, and to provide water containing minerals and at the same time to discharge the sterilizing ionized water The present invention relates to a water purifier capable of continuously purifying water while circulating water to prevent bacteria from growing and providing safer and more hygienic water purification, minimizing the use of the filter element or extending its life.

Discharge, water purification, water level

Description

Water Purifier

The present invention relates to a water purifier, and more particularly, a water purifier composed of a low level sterilization tank for sterilizing and purifying water using an underwater discharge cell, and a high level water purification tank for storing the sterilized purified water and circulating a portion thereof to a low level sterilization tank. It is about.

In general, water purifiers provide safe and hygienic beverages by filtering various toxic or harmful substances contained in tap water or groundwater by various filters installed therein.

1 illustrates a water purification process of a conventional general water purifier.

1, in order to remove foreign substances, harmful substances, odors, and the like contained in the tap water or ground water (hereinafter referred to as 'raw water'), which are obtained inside the water purifier, the suspended solids are first filtered to increase the water purification effect. A filter (2), a sediment filter (4) for removing debris, rust, and sediment of 5 microns or more, and a sun carbon filter (6) which adsorbs and removes chlorine, organic chemicals, etc., consisting of carbon treated with high heat (6). ).

Next, referring again to Figure 1, raw water passed through the sun carbon filter (6) is a forced formula of the reverse osmosis method through the ultra-precision semi-permeable membrane (0.0001 micron) all foreign substances having a molecular weight of 200 or more, such as heavy metals, bacteria, viruses, organic chemicals Membrane filter 8 to sterilize (pressure of the pump (not shown)), fucarbon filter 10 to remove gas components and odor contained in the raw water, sterilization lamp 12 to remove the odor and sterilization Rough

The wastewater separated from the membrane filter 8 is discharged as it is to the sewer, and the purified water passed through the sterilization lamp 12 is introduced into the purified water tank 14 and the cold / hot water tank 16 and finally provided to the user.

However, the conventional water purifier having such a configuration increases the product price by using various filters repeatedly, and the longer the purification time, the more suspended solids and foreign substances accumulate in the various filters. Increasing costs, there is a problem that the organic material filtered inside the filter is decomposed to produce a bad smell or harmful bacteria breed.

The present invention has been made to solve the above-described problems, the main object of the present invention is to sterilize and purify water using an underwater discharge cell and to supply the purified water to a high water purification tank, the purified water stored in the high water purification tank By circulating to the low-level sterilization tank, it minimizes the use of the filter member and extends the lifespan, and the germicidal gas generated during the underwater discharge process is filled in the top of the sterilization tank and water purification tank to prevent the growth of bacteria, The purpose is to provide a water purifier that can make safe and hygienic water purification.

Purifier according to the present invention for achieving the above object, the sterilization tank formed with the raw water inlet and outlet; A discharge cell for discharging water in the sterilization tank underwater; A water purification tank having an inlet and an outlet through which water of the sterilization tank is introduced; A separation plate separating the sterilization tank and the water purification tank so that the full water level of the water purification tank is maintained higher than the full water level of the sterilization tank; And a circulation port installed in the separation plate so that water of the purified water tank flows into the sterilization tank.

In the present invention, it is characterized in that the discharge cell installed inside the sterilization tank is installed in the raw water inlet. The discharge cell is characterized in that it comprises a discharge plate and the discharge wire and the separation frame spaced apart from the discharge plate and the discharge wire.

The present invention further includes a reduction filter for reducing the water of the sterilization tank and supplying it to the inlet of the water purification tank, and an adsorption eliminator for filtering the water of the sterilization tank and supplying the water to the inlet of the purification tank.

In addition, the sterilization tank and the water purification tank of the present invention, respectively, the water level sensor is installed, the first water level sensor installed in the sterilization tank is installed lower than the second water level sensor installed in the water purification tank so that the level of the sterilization tank is always higher than the water level of the water purification tank Keep it low.

In addition, the second water level sensor is characterized in that installed in the same or lower than the lower end of the circulation port installed in the separation plate.

The sterilization tank and the water purification tank are each provided with a lid, but an exhaust port is formed in the lid installed in the water purification tank to sterilize the gas generated during the discharging process of the sterilization tank so as to fill the sterilization tank and the water purification tank.

In addition, the water purifier according to the present invention comprises a transparent ionized water pipe for temporarily storing the water discharged from the sterilization tank flows into the water purification tank; At least one LED installed outside the transparent ion water pipe to indicate an operating state of the water purifier by illumination; Characterized in that it further comprises a reflector installed on the rear of the transparent tube.

An auxiliary discharge cell interlocked with the discharge cell installed in the sterilization tank is further provided inside the transparent ion water pipe.

According to the water purifier of the present invention as described above, there are the following effects.

The sterilization tank ionizes the water by discharging it underwater using a discharge cell, and the sterilization tank and the purification tank are connected to the circulation port to return the water and the suspended matter to the sterilization tank to remove the organic and inorganic substances without using chlorine ions or precipitants. It can provide water containing minerals and at the same time can extract the sterilizing ionized water, and the water is circulated continuously to circulate the water to prevent the accumulation of bacteria by breeding the water to make water purification more effective. The life of the filter member can be extended.

The sterilization tank is formed with a raw water inlet through which raw water is introduced, and a discharge cell is installed at the raw water inlet so that all the incoming water can be effectively discharged in water and purified.

In addition, the sterilization tank is formed with a water outlet for discharging the water introduced through the raw water inlet, discharge cells are installed in the water outlet, it can effectively discharge all the raw water discharged by water discharge.

The discharge cell includes a discharge plate, a discharge wire, and a separation frame spaced apart from the discharge plate and the discharge wire, and the discharge efficiency is increased due to the area being enlarged. One electrode is a wire and one electrode is a plate. This makes it easy to manufacture.

Further, by reducing the water of the sterilization tank further comprises a reducing filter for supplying the inlet of the water purification tank, it is possible to provide drinking water containing minerals.

The control unit alternately applies the electrodes of the discharge cells, and heavy metal oxide products generated at the anode when the electrodes are alternately applied may be removed through an adsorption eliminator installed before the water of the sterilization tank flows into the purification tank to effectively purify the water. In addition, wastewater is not generated, which saves water and increases water purification efficiency.

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

Among the configurations of the present invention to be described below, the same configurations as the prior art will be referred to the above-described prior art, and a detailed description thereof will be omitted.

Figure 2 is a schematic view showing the configuration of a water purifier according to a preferred embodiment of the present invention, Figure 3 is a perspective view of the tank in which the discharge cell of Figure 2 is installed, Figure 4 is a perspective view of the tank in which the discharge cell is removed, 5 is a cross-sectional view of a water tank in which discharge cells are installed.

First, as shown in Figures 2 to 4, the water purifier according to an embodiment of the present invention, the sterilization tank 410, the discharge cell 520 for discharging the water of the sterilization tank 410 in water, The sterilization tank 410 is composed of a water purification tank 420 for storing the sterilized and purified water provided to the user. Preferably, the sterilization tank 410 and the water purification tank 420 is composed of one water tank (400).

The sterilization tank 410 is provided with a raw water inlet 412 through which raw water is introduced and a first outlet 413 and a second outlet 414 through which water from the sterilization tank 410 is discharged. The water purification tank 420 is formed with an inlet 423 into which the water of the sterilization tank 410 flows and an outlet 422 through which the water of the water purification tank 420 is discharged to the user.

Preferably, the sterilization tank 410 and the water purification tank 420 of the water tank 400 are physically separated by the separating plate 430, the water of the water purification tank 420 is sterilization tank in the separation plate 430. A circulation port 431 is formed to flow to 410.

In the present invention, the water tank 400 in which the sterilization tank 410 and the water purification tank 420 are physically separated by the separating plate 430 is illustrated, but the separation of the sterilization tank 410 and the water purification tank 420 is illustrated. The structure is also possible by other means. For example, the sterilization tank 410 and the water purification tank 420 may be configured as separate small tanks, and two tanks may be connected by using pipes. Therefore, the water purifier of the present invention is not limited to the water tank 400 including the separator 430 and the separator 430 shown in the drawing.

Referring back to FIG. 2, the turbidity controller 100, the water pressure sensor 200, and the solenoid valve 330 are installed at the front end of the water tank 400. The turbidity remover 100 is a kind of filtration filter. In the water purifier of the present invention, general surface water or groundwater or tap water is introduced into raw water. In addition, the introduced raw water passes through the turbidity remover 100 to remove turbidity. Since the turbidity remover 100 is widely used in the industrial field of the present technology, a detailed description thereof will be omitted. In one embodiment of the present invention has been shown that it is possible to minimize the use of the filter by installing one turbidity remover 100, of course, it is also possible to increase according to the quality of the raw water.

Subsequently, the raw water from which the turbidity is removed is controlled to flow into the sterilization tank 410 through the solenoid valve 300. Furthermore, a hydraulic pressure sensor 200 for measuring the hydraulic pressure of the flow path between the turbidity remover 100 and the solenoid valve 300 may be further provided.

The first water level sensor 411 is installed above the inner wall of the sterilization tank 410. A raw water inlet 412 (FIG. 4) through which raw water flows is formed in the bottom surface of the sterilization tank 410, and the first outlet 413 and the second outlet 414 through which the water of the sterilization tank 410 is discharged. Is formed through. The sterilizing ionized water is discharged through the second water outlet 414.

The discharge cell 520 is installed at the bottom of the sterilization tank 410. The discharge cell 520 is disposed in the sterilization tank 410 by being installed at the raw water inlet 412 to sterilize the water of the sterilization tank 410.

Hereinafter, with reference to the accompanying drawings will be described an embodiment of a discharge cell used in the water purifier of the present invention.

6 is a perspective view showing a discharge cell according to the present embodiment, the discharge cap is removed, Figure 7 and Figure 8 is a top and bottom perspective view of the discharge cap installed in the discharge cell of FIG.

Referring to FIG. 6, the structure of the discharge cell 520 will be described in detail. The discharge cell 520 includes a discharge plate 521, a discharge wire 522, the discharge plate 521, and the discharge wire. And a spaced frame 523 spaced apart from the spaces 522.

The discharge plate 521 is plated with platinum and formed in a plate shape, and protrusions 528 are formed at upper and lower sides thereof, respectively. The spaced frame 523 is fixed through the protrusion 528.

The discharge wire 522 is formed in a linear shape of the platinum material (diameter 0.12mm), it is wound multiple times at regular intervals between the two spaced frame 523 can be double-sided discharge.

The spaced frame 523 is vertically disposed on both sides of the discharge plate 521 in the vertical direction. An insertion hole (not shown) into which the protrusion 528 is inserted is formed in the spaced frame 523. The discharge cell 520 has a through part 529 formed at predetermined intervals between the spaced frame 523 and the discharge plate 521 on both sides.

In addition, the protrusions 525 are formed on the outer circumferential surface of the spaced frame 523 at regular intervals so that the protrusions 525 are disposed between the discharge wires 522 that are wound to maintain the gap between the discharge wires 522. Preferably, the distance between the discharge plate 521 and the discharge wire 522 is maintained at 1mm.

The discharge cell 520 is fixed to the connector 530 is installed in the sterilization tank (410).

The connector 530 is formed in a disc shape and is installed to be inserted into the raw water inlet 412 of the sterilization tank 410, and a threaded portion 531 is formed on an outer circumferential surface thereof. In addition, the outer peripheral surface of the connector 530 is provided with a sealing member 532 such as an O-ring is sealed between the sterilization tank 410 and the connector 530.

In the center of the connector 530, a raw water inlet pipe 527 through which raw water flows into the discharge cell 520 is installed. In addition, the first electrode pin 524 connected to the discharge plate 521 and the second electrode pin 526 connected to the discharge wire 522 pass through both sides of the raw water inlet pipe 527 of the connector 530. do. Power is applied to the discharge cell 520 through the first electrode pin 524 and the second electrode pin 526.

7 and 8, the discharge cap 510 surrounds the discharge cell 520 to prevent the discharge cell 520 from being damaged and to discharge the incoming water sufficiently under water.

The discharge cap 510 has a lower opening and a first cap inlet 514 communicating with the raw water inlet pipe 527 is formed, and a thread is formed on the lower inner wall so that the discharge cap 510 is fastened to the connector 530. It is. The discharge cap 510 has a cell insertion part 512 into which the discharge cell 520 is inserted. The cell insertion part 512 is formed so that the horizontal cross-sectional area is smaller than the lower portion so that the user can use it as a handle when the discharge cap 510 is detached, so that the horizontal cross-sectional shape is formed in a rectangular shape. In addition, a cap outlet 511 through which water discharged underwater flows is formed at an upper end of the cell insertion part 512. The second cap inlet 513 is formed at the lower side of the discharge cap 510 so as to be disposed at both sides of the cell insertion unit 512. For this reason, the second cap inlet 513 is disposed below the cap outlet 511 and is disposed to be close to the bottom surface of the sterilization tank 410. Therefore, the water in the sterilization tank 410 circulates through the second cap inlet 513.

Furthermore, when assembling the discharge cap 510 to the sterilization tank 410, it is preferable that the first outlet 413 and the second outlet 414 and the second cap inlet 513 are arranged to be alternated.

As such, the discharge cap 510, the discharge cell 520, and the connector 530 are modularized into one and can be directly installed in various water purifiers, and are easily assembled. The auxiliary discharge cell 620 which will be described later in this specification also has the same structure.

Referring back to FIG. 2, the ionized water discharged from the sterilization tank 410 becomes weak alkali through the reduction filter 600 installed at the rear end thereof. At this time, ORP (Oxidation Reduction Potential) of the reduced water is -100mV or more water is a very beneficial reducing water to the human body. The reduction filter 600 is installed to be connected to the first outlet 413 of the sterilization tank (410). In addition, a transparent ion water pipe 610 (see FIG. 12) may be installed at the front end of the reducing filter 600 to temporarily store the ionized water discharged from the first outlet 413 of the sterilization tank 410.

Subsequently, the reduced water reduced through the reduction filter 600 is transferred to the inlet 423 of the water purification tank 420 through the circulation pump 700 installed at the rear end thereof. A rear end of the reducing filter 600 may be further provided with a reducing water pipe 620 for temporarily storing the reducing water.

Adsorption remover 800 may be installed at the rear end of the circulation pump 700 to remove heavy metals transferred from the sterilization tank 410 through the adsorption remover 800 before the reducing water is introduced into the inlet 423. The adsorption eliminator 800 is a kind of filtration filter.

The water purification tank 420 is formed on the other side of the water tank 400, it is formed so that the low capacity is larger than the sterilization tank (410). Naturally, the water purification tank 420 may be configured as a separate water storage tank separated from the sterilization tank 410.

The separating plate 430 that physically separates the sterilization tank 410 and the water purification tank 420 is provided with a circulation port 431 to allow the water of the purification tank 420 to flow into the sterilization tank 410. Preferably, the circulation port 431 is disposed above the inlet 423 and is formed to communicate with the sterilization tank 410. The circulation port 431 is formed through the separation plate 430 and may be formed in various shapes such that the cross-sectional area becomes smaller toward the bottom, such as a circle or a triangle.

In addition to the sterilization tank 410, the second water level sensor 421 is installed on the inner wall of the water purification tank 420.

At this time, as shown in FIG. 5, the second water level sensor 421 of the water purification tank 420 is installed at a higher level than the first water level sensor 411 of the sterilization tank 410. That is, the highest water level of the water purification tank 420 is higher than the highest water level of the sterilization tank 410.

In addition, the installation height of the circulation port 431 formed in the separation plate 430 is higher than the highest level of the sterilization tank 410. In addition, the second water level sensor 421 is installed to coincide with or be located at the bottom of the circulation port 431 penetrated through the separation plate 430, that is, the lower end of the circular or V-type through hole. Therefore, the second water level sensor 421 is operated before the maximum water level of the water purification tank 420 is reached.

When the water level of the water purification tank 420 exceeds the highest water level, the water of the water purification tank 420 flows into the sterilization tank 410 through the circulation port 431. In addition, when the water purification tank 420 is at the maximum water level, oil and inorganics floating on the water surface are automatically moved to the sterilization tank 410 through the circulation port 431. This results in continuous discharge or sterilization.

The first water level sensor 411 detects whether the level of the sterilization tank 410 reaches the highest level and controls the inflow of raw water. The second water level sensor 421 detects whether the water level of the water purification tank 420 reaches the highest level and controls the inflow of purified water after a predetermined time.

 As such, the present invention is installed in the sterilization tank 410 and the water purification tank 420, respectively, the first water level sensor 411 installed in the sterilization tank than the second water level sensor 421 installed in the water purification tank It is installed low, the bottom surface of the second water level sensor 421 is characterized in that the same or lower than the lower end of the circulation port.

The water purification tank 420 has an inlet 423 into which the water of the sterilization tank 410 flows and an outlet 422 through which the water of the water purification tank 420 is discharged to the user is formed at the bottom of the water purification tank 420. . Preferably, the outlet 422 and the inlet 423 are formed to be far apart. For example, an inlet 423 is formed at the center of the bottom surface of the water purification tank 420, and an outlet 422 is formed at the edge of the bottom surface.

Meanwhile, lids 441 and 442 are installed in the sterilization tank 410 and the water purification tank 420. Therefore, hydrogen ions and chlorine ion gas generated by underwater discharge in the sterilization tank 410 are filled into empty spaces of the sterilization tank 410 and the water purification tank 420, and a part of the filled gas is purified water ( It is discharged to the outside through the exhaust pipe 443 formed in the lid 442 of the 420. Preferably, the lid 441 and 442 of the sterilization tank 410 and the water purification tank 420 may be formed of one lid.

Furthermore, the present invention further includes a control unit 900 for controlling supply of power to the discharge cells 520. The controller 900 alternately applies the electrodes of the discharge cell 520. In the present invention, when the first purification of the sterilization tank 410 through the discharge cell 520, -polarity is applied to the discharge plate 521, + electrode is applied to the discharge wire 522, the sterilization tank 410 In the second purified water circulating in the water purification tank 420, the + electrode is applied to the discharge plate 521, and the-electrode is applied to the discharge wire 522 to alternately apply voltage to the oxidation of organic and inorganic substances. Promote In addition, by separating the heavy metal oxide product from the positive electrode (discharge plate 521) at the time of secondary water purification and supplying it to the water purification tank 420, it is possible to effectively remove water through the adsorption eliminator 800.

In addition, the controller 900 may control the solenoid valve 300 or control the circulation pump 700 by receiving a signal from the water pressure sensor 200 and the first water level sensor and the second water level sensor. For example, in the present invention, the circulation pump 700 controls to operate more than the time it takes for the water purification tank 420 to reach the full water level. Therefore, the water of the water purification tank 420 and the floating floating on the water surface is circulated to the sterilization tank 410.

Next, another embodiment of the water purifier according to the present invention will be described with reference to FIGS. 9, 10, and 11.

9 is a perspective view of the tank in which the discharge cell is installed in accordance with the present embodiment, FIG. 10 is a cross-sectional view of the tank in which the discharge cell of FIG. 9 is installed, and FIG. 11 is a perspective view of the discharge cell in accordance with the present embodiment.

As shown, the water purifier according to the present embodiment is a sterilization tank 410, a discharge cell 720 for discharging the water of the sterilization tank 410 in water, and the sterilized and purified water in the sterilization tank 410 The configuration of the water purification tank 420 which is stored and provided to the user is the same as the above-described embodiment. Therefore, detailed description of this configuration will be omitted.

However, the water purifier according to the present embodiment, the raw water inlet 712 through which the raw water is introduced is installed on the upper side of the sterilization tank 410, the outlet port 713 for the water of the sterilization tank 410 is the sterilization tank ( The point of installation at the bottom of 410 is very different. The discharge cell 720 is horizontally installed at the bottom of the sterilization tank 410 in which the outlet port 713 is formed.

In this case, a first water level sensor 411 having a water level adjustment function is installed at the raw water inlet 712. Preferably, the first water level sensor 411 has a valve body 716 which communicates with the raw water inlet 712. It consists of an air ball 717 fixed by a connecting rod to the valve body 716. At this time, the air ball 717 is in contact with the water surface and moved in accordance with the change in the water level to open and close the valve body 716 by the raw water inlet ( By controlling the inflow of raw water through the 712, the level of the sterilization tank 410 is kept constant.

Meanwhile, the first water level sensor 411 is installed at a position lower than the second water level sensor 421 of the water purification tank 420 so that the water level of the sterilization tank 410 is lower than the water level of the water purification tank 420.

The discharge cell 720 is installed on the water outlet 713 of the sterilization tank 410. Therefore, the raw water introduced through the raw water inlet 712 passes through the discharge cell 720 during the convection process and discharges underwater or discharges through the discharge cell 720 when the water is discharged into the water purification tank 420 through the outlet 713. It is discharged underwater.

11 is a perspective view illustrating an example of a discharge cell 720 horizontally installed on the bottom of the sterilization tank 410 according to the present embodiment.

As shown, the discharge cell 720 of the present embodiment has a cell insulated body 723 having a plurality of through holes 729 formed in the center and protruding jaws 721 at both sides thereof, and the cell insulated body 723. And a discharge wire 722 wound on the left, right, and front and rear directions. In this case, the cell insulating body 723 is made of an insulator (eg, polycarbonate), and the wires 722 wound in the left and right directions and the front and rear directions are spaced apart from each other. Preferably, the wires 722 are spaced apart by about 1 mm.

The discharge wire 722 is formed in a linear shape of a platinum material (diameter 0.12mm), and is wound several times on both sides of the cell insulating body 723 at regular intervals to enable double-sided discharge. In addition, protrusions are formed at edges of the cell insulation body 723 at predetermined intervals so that the protrusions are disposed between the discharge wires 722 which are wound.

The discharge cell 720 is installed at the bottom of the sterilization tank 410 by passing the fastening bolt 731 through the boss 730 formed integrally with the cell insulating body 723.

As described above, the discharge cell 720 according to the present exemplary embodiment has a through hole 729 formed therein so that water flowing from the top to the bottom thereof passes through the discharge cell 720, and is installed on the outlet 713 of the sterilization tank 410. ) To discharge all the water discharged through.

Next, another embodiment of the water purifier according to the present invention will be described with reference to FIGS. 12 and 13. As shown, a transparent ionized water pipe 610 for temporarily storing ionized water is connected to the first outlet 413 of the sterilization tank 410. A part of the transparent ion water pipe 610 is installed to be exposed to the outside of the water purifier body 11. In addition, one or more LEDs 630 are installed in the transparent ion water pipe 610 to show the operating state of the water purifier, in particular, the operating state of the discharge cell 520 in various colors.

In addition, an inlet pipe 641 communicating with the first outlet 413 of the sterilization tank 410 and an outlet pipe 642 communicating with the reducing filter 600 are installed at an upper end of the transparent ion water pipe 610. Preferably, the inlet pipe 641 and the outlet pipe 642 is installed on the lid 640 of the transparent ionized water pipe 610. In addition, the water inlet pipe 641 may be further extended to the lower side than the water outlet pipe (642).

An auxiliary discharge cell 620 is installed on an inner bottom surface of the transparent ion water pipe 610. The auxiliary discharge cell 620 is smaller than the above-described discharge cell 520 but has the same function. In addition, the auxiliary discharge cell 620 is operated in conjunction with the discharge cell 520 installed in the above-described sterilization tank 410.

The auxiliary discharge cell 620 shows the operating state of the discharge cell 520 by generating bubbles in conjunction with the discharge cell 520. In addition, the auxiliary discharge cell 620 removes the inorganic material introduced through the water inlet pipe 641 through the underwater discharge. The removal method is the same as that of the discharge cell 520. Preferably, the auxiliary discharge cell 620 is used without the discharge cap 510.

In addition, a reflector 650 is installed behind the transparent ionized water pipe 610. The reflector 650 reflects light from the outside and light emitted from the LED 630. Preferably, the LED 630 is composed of a plurality of LED chips to represent colors such as red, blue, white.

For example, the LED 630 shows an operating state of the discharge cell 520.

That is, while the discharge cell 520 and the auxiliary discharge cell 620 are in operation (sterilization step), the LED 630 emits red light. On the contrary, while the discharge cell 520 and the auxiliary discharge cell 620 do not operate, the light emits blue. The red color indicates the sterilization process and indicates that it is not available for drinking. Blue indicates that it is drinkable. In addition, when the water level of the water purification tank 420, the water of the water purification tank 420 is displayed in purple while circulating to the sterilization tank (410). In this circulation process, since the discharge cell 520 and the auxiliary discharge cell 620 are operated, it indicates that purple is not drinkable.

The operation of this embodiment having the above-described configuration will be described below.

The raw water is introduced into the raw water inlet pipe 527 through the solenoid valve 300 after the turbidity is removed via the turbidity remover 100. At this time, the operation of the solenoid valve 300 is controlled by the pressure sensor 200. The introduced raw water becomes vaporized ionized water by discharge of the discharge wire when passing through the discharge cell 520. Therefore, the obtained raw water is sterilized by the high temperature of 100 ℃ and at the same time lowered the specific gravity to generate convection inside the sterilization tank (410). This results in a primary integer. The primary water disinfects the water obtained and at the same time decomposes organic and inorganic matters. Convection by the temperature difference induces the raw water to repeatedly flow into the discharge cell 520.

The operation of the discharge cell 520 will be described in detail as follows.

Water introduced into the discharge cap 510 is evaporated at a high temperature (about 100 degrees to several thousand degrees) of the cathode (Cathode) to generate bubbles. The greater the pollution (electric conductivity) of water, the more bubbles (vaporization) are generated. At this time, part of the water is ionized to become anionic gas (hydrogen ion, chlorine ion) having a low specific gravity, and part of the water is continuously vaporized containing a high specific gravity cationic material (metal, mineral, etc.) to generate ionized water. Active ions generated at this time have a strong bactericidal power and generate metal oxides within a short time. However, minerals (Na, Ca, Mg, K) are dissolved in water and preserved.

Raw water introduced into the sterilization tank 410 through this process is converted into ionized water through the discharge cell 520 and generates active ions and hydrogen gas. Active ions generated in the sterilization tank 410 oxidizes bacteria and organic matter contained in the raw water, changes the structure of the inorganic material, and hydrogen ions and chlorine ion gas generated in the sterilization tank 410 are sterilization tank 410. The empty space of the water purification tank 420 is filled. This anion gas serves to prevent the growth of bacteria.

Subsequently, the circulation pump 700 is operated to introduce the ionized water into the reduction filter 600 through the first outlet 413 to convert the ionized water into the reduced water. Subsequently, the reduced water passes through the adsorption eliminator 800 and is then transferred to the inlet 422 of the water purification tank 420.

When the water level of the water purification tank 420 becomes the height of the circulation port 431, the water of the water purification tank 420 is moved to the sterilization tank 410 through the circulation port 431. At this time, the oil floating on the water surface of the purified water tank 420, the inorganic suspended matter is transferred to the sterilization tank 410, the water of the purified water tank 420 maintains a purified state, the oil introduced into the sterilization tank 410, Inorganic organics are oxidized again and slowly precipitate in the sterilization tank 410 as a solid. This results in a second integer and this water purification process is repeated.

On the other hand, the discharge cell 520 applies -polarity to the discharge plate 521 at the first purified water, and + electrode applied to the discharge plate 521 at the second purified water, and alternately applies a voltage to the inorganic material. Promote specific gravity separation oxidation.

The vaporized water is sterilized by alternating the power of the discharge cells 520 and discharging it under water, and at the same time, heavy metal oxide products are separated from the anode and removed through the adsorption remover 800.

In addition, the discharge cap 510 has a second cap inlet 513 is disposed below the cap outlet 511, the foreign matter precipitated in the water of the sterilization tank 410 and the water having a high specific gravity second cap inlet 513 Into the discharge cell 520 again to allow continuous convection discharge underwater.

As described above, although described with reference to a preferred embodiment of the present invention, those skilled in the art various modifications or variations of the present invention without departing from the spirit and scope of the invention described in the claims below Can be carried out.

1 is a block diagram showing a water purification process in a conventional water purifier.

2 is a schematic view showing the configuration of a water purifier according to a preferred embodiment of the present invention;

3 is a perspective view of a tank in which the discharge cell of FIG. 2 is installed;

4 is a perspective view of the tank in which the discharge cell is removed,

5 is a sectional view of a water tank in which discharge cells are installed;

6 is a perspective view showing a discharge cell according to the present embodiment,

7 and 8 are a perspective view of a discharge cap installed in the discharge cell of Figure 6,

9 is a perspective view of a tank in which a discharge cell is installed according to another embodiment of the present invention;

10 is a cross-sectional view of the tank in which the discharge cell of FIG. 9 is installed;

11 is a perspective view showing a discharge cell according to another embodiment of the present invention,

12 is a front view showing a water purifier installed with a transparent ionized water pipe according to another embodiment of the present invention,

FIG. 13 is a perspective view illustrating an embodiment of the transparent ionized water pipe of FIG. 12.

DESCRIPTION OF REFERENCE NUMERALS

100: turbidity remover 200: water pressure sensor

300: solenoid valve 400: reservoir

410: sterilization tank 411: first water level sensor

412, 712: Raw water inlet 413: Outlet 1

420: water tank 421: second water level sensor

422: inlet 423: outlet

430: separator 431: circulation port

510: discharge cap 511: cap outlet

512: cell insertion portion 513: second cap inlet

514: first cap inlet 520, 720: discharge cell

521: discharge plate 522: discharge wire

523: spaced frame 524: first electrode pin

525: projection 526: second electrode pin

527: raw water inlet pipe 528: protrusion

529: penetrating portion 530: connector

531: thread portion 532: sealing member

600: reduction filter 700: circulation pump

800: adsorption eliminator 900: control unit

Claims (15)

delete delete delete Sterilization tank in which raw water inlet and outlet are formed; A discharge cell installed at the raw water inlet of the sterilization tank for discharging water introduced into the sterilization tank underwater; A water purification tank having an inlet through which the ionized water of the sterilization tank flows in and an outlet through which the purified water flows out; A circulation pump installed to transfer the ionized water of the water spray tank to the inlet of the water purification tank through the water outlet installed at the bottom of the sterilization tank; A separation plate separating the ionized water of the sterilization tank and the purified water of the purification tank so as not to be mixed with each other; Gas generated in the sterilization tank is supplied to the purified water tank and the circulation port provided in the separation plate so that the water of the purified water flows into the sterilization tank by gravity; A lid having an exhaust port formed only in an upper portion of the water purification tank so that the gas generated in the sterilization tank may fill the interior of the sterilization tank and the water purification tank; A first level sensor installed in the sterilization tank to measure the full water level of the sterilization tank; A second water level sensor installed in the water tank but installed at a position higher than the first water level sensor to measure the full water level of the water tank; And a control unit connected to the first water level sensor and the second water level sensor to control the flow of raw water flowing into the sterilization tank and the ionized water supplied to the purification tank, and controlling the operation of the discharge cell. The water level of the water purification tank is always maintained higher than the water level of the sterilization tank, and the control unit sterilizes the floating material floating on the surface of the water purification tank by stopping the operation of the circulation pump and the discharge cell after a certain time when the water level of the water purification tank reaches the water level. A water purifier, characterized in that it is circulated in a tank and discharged again. delete The method of claim 4, wherein The discharge cell includes a cell insulated body having a plurality of through holes formed in the center thereof and protruding jaws formed on both sides thereof, and discharge wires wound on the cell insulated body spaced apart from each other in left and right directions. Water purifier. The method of claim 4, wherein Water purifier characterized in that it further comprises a reducing filter for reducing the water of the sterilization tank to supply to the inlet of the water purification tank. 8. The method of claim 7, Water purifier, characterized in that passing through the adsorption eliminator before the water of the sterilization tank flows into the water purification tank. delete delete delete delete The method of claim 4, wherein A transparent ionized water pipe temporarily storing ionized water discharged from the sterilization tank; An auxiliary discharge cell installed on an inner bottom of the transparent ion water pipe; Water purifier, characterized in that it further comprises at least one LED installed on the outside of the transparent ion water pipe to indicate the operating state of the discharge cell installed in the sterilization tank by illumination. delete delete

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