KR20070098137A - Water purifier for supplying oxygen-enriched water - Google Patents

Abstract

An apparatus for purifying water is provided to enable the direct installation on a water supplying pipe in a small-sized facility, thereby conveniently using the apparatus and easily managing the apparatus. A water tank(100) is connected to a water supplying pipe(P1) through a water inflow pipe(P1) having a purifying filter(110). A circulating pump(200) is connected to a first divergence pipe(P3) diverged from the water input pipe. A pressure reducing valve(210) is installed on the first divergence pipe to reduce pressure of water. An oxygen dissolving part(300) is disposed between an output terminal of the circulating pump and the water tank, wherein the oxygen dissolving part has a structure of a circularly winding pipe. An oxygen generator(400) is connected to a second divergence pipe(P4) diverged from the water inflow pipe. An oxygen supplying pipe(P5) transfers high-concentration oxygen to the first divergence pipe between the pressure reducing valve and the circulating pump. A water outputting pipe(P6) is connected to the water tank, wherein the water outputting pipe has an electronic control type open-shut valve(600). A sensor(710) is positioned adjacently to a front end of the water outputting pipe to sense the presence or absence of a container in a non-contact type. A control unit(500) controls the open-shut valve, the circulating pump, and the oxygen generator in response to signals transferred from the sensor.

Description

High concentration oxygen dissolved water purifier {Water purifier for supplying oxygen-enriched water}

1 is a view briefly showing the overall configuration of a high concentration oxygen dissolved water purification apparatus of the present invention,

2 is a view showing a preferred example of the oxygen generator in the high concentration oxygen dissolved water purification apparatus of the present invention,

3 is a view showing an example of a sink to which a high concentration oxygen dissolved water purifier of the present invention is applied;

4 is a view showing an example of a cooling apparatus for maintaining a water tank at a low temperature in the high concentration oxygen dissolved water purification apparatus of the present invention.

<Explanation of symbols for main parts of the drawings>

100: water tank 110: water filter

200: circulation pump 300: oxygen dissolving unit

400: oxygen generator 500: control unit

600: on-off valve 710: sensor

720: power switch

The present invention relates to a high concentration oxygen dissolved water purification device, and more particularly, to a high concentration oxygen dissolved water purification device provided in a water purification device for providing drinking water, such as drinking water, water purifiers or sinks to provide a high concentration of oxygen dissolved drinking water. will be.

The water you drink every day passes through the stomach and intestines from the mouth to the cells through the blood, and then again through the kidneys from the blood through the kidneys play an essential role in maintaining life.

As environmental pollution becomes more serious and interest in healthy living increases, interest in clean and beneficial water is increasing. As one example, the use of water purifiers in the home is increasing, and devices that can provide various functional water in addition to water purification have been proposed.

In particular, oxygen water dissolved in a high concentration of oxygen can improve the concentration of oxygen in the human body to promote metabolism and improve health, and manufacturing apparatuses for producing such oxygen water have been proposed.

The technical problem to be achieved by the present invention is to provide a high concentration of oxygen water purified directly installed in the water supply pipe for providing drinking water in a small home, such as a general home, outdoor, or public facilities, easy to use and low cost To provide a high concentration oxygen dissolved water purification apparatus that can be installed as.

The high concentration oxygen dissolved water purifying apparatus of the present invention is a device for purifying water supplied to a demand through a water supply pipe at a predetermined water pressure or higher and dissolving high concentration of oxygen. A water tank connected to the; A circulation pump connected to the first branch pipe branched from the water supply pipe; A pressure reducing valve installed in the first branch pipe to reduce water pressure; An oxygen dissolving unit provided between the output end of the circulation pump and the water tank while having a circularly wound pipe structure; An oxygen generator connected to the second branch pipe branched from the water supply pipe, and configured to generate high concentration oxygen by electrolyzing water; An oxygen supply pipe for transferring oxygen generated in the oxygen generator to a first branch pipe between the pressure reducing valve and the circulation pump; An outlet pipe having an electronically controlled on / off valve connected to the water tank; A sensor positioned adjacent to the tip of the outlet pipe for non-contact sensing of the presence or absence of a container; Technical features of the control unit for controlling the operation of the electronically controlled on-off valve, the circulation pump and the oxygen generator in accordance with the signal transmitted from the sensor.

An embodiment of the present invention will be described in detail with reference to the accompanying drawings.

Referring to FIG. 1, the water supply pipe P1 is connected to the water tank 100 through an inlet pipe P2 provided with a water filter 110.

The water supply pipe P1 is for supplying water to the demand while having a constant water pressure, and may be generally a water pipe connected through a drainage pipe and a drain pipe, or may be connected to a drinking water tank equipped with a pressure pump. In the following description, an embodiment applied to a water pipe is described.

The water pipe P1 connected through the drainage pipe and the drain pipe supplies tap water to each demand price, and a water filter 110 is provided between the water pipe P1 and the inlet pipe P2 to purify the tap water.

The water purification filter 110 may be a well-known filter for water purification, and such a well-known water purification filter may be used an activated carbon filter, reverse osmosis or hollow fiber membrane membrane filter. In addition, in the present invention, the water filter may be used in combination of two or more kinds of filters.

The first branch pipe P3 branched from the inlet pipe P2 is connected to the input end of the circulation pump 200.

On the other hand, the pressure reducing valve 210 is installed in the first branch pipe P3, and the tap water passing through the first branch pipe P3 is reduced in the pressure reducing valve 210 to a predetermined pressure or less. This is to allow the oxygen gas generated in the oxygen generator 400 to be smoothly supplied together with the tap water introduced into the circulation pump 200. That is, in the case of obtaining oxygen gas by electrolyzing water in the oxygen generator, when the water pressure of the tap water flowing through the first branch pipe P3 is large, the oxygen gas generated in the oxygen generator 400 becomes the first branch pipe P3. It may not be delivered to the) side and the internal pressure of the oxygen generator 400 may be increased.

Therefore, in consideration of the pressure of the oxygen gas generated in the oxygen generator 400, the water pressure of the tap water flowing through the first branch pipe needs to be appropriately reduced. In general, the water supply pressure of the demand pipe can be severely varied depending on the region (approximately 4 ~ 8kgf / ㎠), in the embodiment of the present invention in consideration of the pressure of the oxygen gas generated in the oxygen generator 400 The water pressure of the tap water passing through the pressure reducing valve of the first branch pipe is preferably reduced to about 1 kgf / cm 2.

An oxygen dissolution unit 300 is connected to an output end of the circulation pump 200, and the oxygen dissolution unit 300 is connected to the water tank 100.

On the other hand, the water and oxygen flowing along the first branch pipe (P3) by the operation of the circulation pump 200 is discharged with a predetermined pressure by the circulation pump 200 to pass through the oxygen dissolving unit (300). .

The water pressure reduced to about 1 kgf / cm 2 while passing through the pressure reducing valve 210 becomes about 7 kgf / cm 2 while passing through the circulation pump 200. Oxygen is dissolved in water.

In the present invention, the oxygen dissolving unit 30 is provided by a pipe structure in which a diameter is wound around a hose or pipe. In an embodiment of the present invention, the diameter of the pipe may be a hose or pipe of about several millimeters, and the length may vary depending on the diameter of the pipe and the capacity of the circulation pump, but within a range in which oxygen can be sufficiently dissolved in water. It is preferable to make it long enough.

Therefore, the high concentration of oxygen discharged through the oxygen supply pipe P5 is dissolved in the tap water while passing through the oxygen dissolving unit 300 through the circulation pump 200 together with the purified tap water flowing along the first branch pipe P3. The amount of oxygen is greatly increased, and water in which oxygen is dissolved is stored in the water tank 100.

Once the oxygen water stored in the water tank 100 is circulated again along the inlet pipe P2 and the first branch pipe P3 while the circulation pump 200 is operating, the dissolved oxygen amount of the water increases to a saturation state.

Next, an oxygen generator 400 is connected to the second branch pipe P4 branched from the water supply pipe P2 to generate high concentration oxygen by electrolysis by receiving water.

Figure 2 is a view showing a preferred embodiment of the oxygen generator in the high concentration oxygen dissolved water purification apparatus of the present invention.

Referring to FIG. 2, the oxygen generator 400 according to the present exemplary embodiment includes an upper case 410, a water level control unit 413, an electrolysis unit 420, an airtight member 430, and a lower case 440. do.

The upper case 410 is provided with an inlet pipe 411 and the oxygen outlet 412.

The inlet pipe 411 is connected to the second branch pipe P4 and water is supplied into the upper case 410. On the other hand, a well-known ion exchange resin filter 401 is provided in front of the water inlet pipe 411 to lower the hardness of the water.

The oxygen outlet 412 is an exhaust port through which oxygen generated by electrolysis is discharged, and the oxygen outlet 412 is connected to the first branch pipe P3 through the oxygen supply pipe P5.

The water inlet pipe 411 side of the upper case 410 is provided with a water level control unit 413 for adjusting the water level of the stored water.

The water level control unit 413 may be provided by a sensor for detecting the water level of the water, and a solenoid valve for opening and closing the water inlet pipe 411 according to the sensor. Another example may be provided by a float floating along the surface of the water and a valve arrangement that mechanically opens and closes the inlet pipe according to the height of the float.

By the operation of this level control portion, a constant volume of water is always maintained in the water tank.

The lower part of the upper case 410 is provided with an electrolysis unit 420 for electrolyzing water.

Specifically, the electrolysis unit 420 is configured by sequentially stacking the porous anode 421, the electrode assembly membrane 422, and the porous cathode 423 from the top.

The electrolytic unit 420 is firmly fixed to the fixing plate 441 fixed in the transverse direction between the upper case 410 and the lower case 440 by the bolt 451 and the nut 452. On the other hand, it is preferable that a rubber sealing member 430 for airtightness is further inserted between the anode 421, the electrode assembly film 422, and the cathode 423.

A typical platinum plate may be used for the anode 421 and the cathode 423, and iridium oxide and tin oxide may be coated on the anode and the cathode, respectively.

The electrode assembly membrane 422 is an ion exchange membrane for exchanging cations, and is coated with an anode catalyst facing the anode 421 on one side between membranes through which cations are permeated, and facing the cathode 423 on the other side. The cathodic catalyst is coated.

The lower case 440 is fixed to the lower portion of the upper case 410, the hydrogen outlet 442 is formed so that the hydrogen generated in the electrolytic unit 420 is discharged.

In the oxygen generator 400 configured as described above, since DC power is applied to the anode 421 and the cathode 423, water is decomposed into oxygen gas, hydrogen ions, and electrons in the anode catalyst of the electrode assembly membrane. It is discharged through the oxygen outlet 411.

On the other hand, in the cathode 423, hydrogen ions generated from the anode catalyst of the electrode assembly film move to the cathode catalyst and react with electrons to generate hydrogen gas. In addition, a portion of the water in the upper case 410 is passed through the electrode assembly membrane, a small amount of water that has passed through the electrode assembly membrane is collected in the lower case 440 together with hydrogen gas.

On the other hand, the hydrogen collected in the lower case 440 may be exhausted to the outside through the outlet 442 in a gaseous state, if the water discharged through the outlet 442 is accumulated in the device, such as contaminating the inside of the device, etc. There is concern. Therefore, it is desirable to properly treat the water generated during the electrolysis process to prevent water from accumulating in the apparatus.

To this end, a drainage hole 443 is further formed in the lower case 440 under the hydrogen discharge port 442, and water discharged through the discharge hole 443 by connecting a hose to the drainage hole 443 is connected to the upper case ( 410 or in the water tank 100 can be made.

Accordingly, hydrogen gas generated in the lower case 440 during the electrolysis of water is exhausted outward through the hydrogen outlet 442 and water is introduced into the upper case 410 or the water tank through the drain hole 443.

Referring back to FIG. 1, oxygen generated from the oxygen generator 400 is connected to the first branch pipe P3 through the oxygen supply pipe P5. An activated carbon filter 402 may be provided in the oxygen supply pipe P5, and the activated carbon filter 402 filters foreign substances that may flow into the tap water together with oxygen gas.

Water tank 100 is provided with an electronically controlled on-off valve 600, such as a solenoid valve is connected to the outlet pipe (P6). The electronically controlled open / close valve 600 is opened and closed by an electrical control signal transmitted from the control unit 500.

In the embodiment of FIG. 1, the water outlet pipe P6 is illustrated as branching from a pipe between the water tank 100 and the oxygen dissolving unit 300, but the installation position of the water outlet pipe P6 is located at the water tank 100. It may be connected directly.

The control unit 500 controls the open / closed state of the electronically controlled on / off valve 600, and the control unit 500 is located adjacent to the tip of the outlet pipe P6 to detect the presence or absence of a cup or a container in a non-contact manner. The sensor 710 for transmitting the is connected.

As the sensor 710, a pyroelectric sensor that detects an infrared signal of a human body and generates an electrical signal may be used.

In addition, the control unit 500 is connected to directly control the circulation pump 200 and the oxygen generator 400, the control unit 500 is the circulation pump 200 and oxygen so that the entire apparatus can operate efficiently Generator 400 is controlled.

In particular, in the present invention, the control unit 500 includes a counter circuit unit for counting the on / off operation of the sensor 710, and the oxygen generator 400 and the circulation pump 200 for each set count value for a set time. It is characterized by only operating.

That is, the control unit 500 does not continuously operate the oxygen generator 400 and the circulation pump 200, but estimates the amount of water used by counting the number of on / off operations of the sensor 710. This is typically empirically determined once the water consumption is stored in the control unit 500 as a set value, it is also possible to determine the water usage for the number of operations of the sensor 710.

For example, when the control unit 500 is set to operate the oxygen generator 400 and the circulation pump 200 for a predetermined time when the sensor 710 is operated five times, the water in the water tank is used for five times. Since the amount of dissolved oxygen is lowered, the oxygen generator 400 and the circulation pump 200 are operated to increase the amount of dissolved oxygen of water in the water tank.

Therefore, when it is determined that the control unit 500 uses more than a certain amount of water, the control unit 500 operates the oxygen generator 400 and the circulation pump 200 for a set time to increase the amount of dissolved oxygen in the tap water.

Similarly, the operating time of the oxygen generator and the circulation pump may be stored as a set value in the control unit 500 after being empirically or experimentally determined according to the capacity of the water tank.

On the other hand, the control unit 500 may be connected to the power switch 720 so that the user can directly control whether the operation of the circulation pump 200 and the oxygen generator 400. That is, the user may stop the operation of the circulation pump 200 and the oxygen generator 400 by operating the power switch 720 when the use of oxygen dissolved tap water is unnecessary.

Since the power switch 720 controls only the circulation pump 200 and the oxygen generator 400, the on / off operation of the on / off valve 600 by the signal of the sensor 710 is independent of the operation of the power switch 720. Is done the same.

3 is a view showing an example of a sink to which the high-concentration oxygen-dissolved water purifier of the present invention is applied, wherein a water tank, a circulation pump, and other control units, which are components of the present invention, are installed in the lower part of the sink, and the discharge pipe (P6) is shown. ) Is only exposed to the outside.

On the other hand, a housing 700 for fixing the water outlet pipe P6 to the sink 10 may be installed below the water outlet pipe P6, and when such a housing is installed, the sensor 710 is fixed to the housing 700. It is desirable to be.

The sensor 710 fixed to the housing 700 is close to the cup or container near the outlet pipe P6 in order to receive water, and the signal detected by the sensor 710 is transmitted to the control unit 500. The control unit 500 releases the oxygen water stored in the water tank 100 by opening the electronically controlled on / off valve 400.

The power supply 720 may be installed together in the housing 700, and the first LED lamp 701 displaying the on / off state of the power switch 720 and the agent displaying the on / off state of the sensor 710. 2 LED lamps 702 can be installed.

The first and second LED lamps 701 and 702 are turned on / off by the control unit 500 according to whether the power switch 720 and the sensor 710 are operated.

4 is a view showing an example of a cooling apparatus for maintaining the water tank at a low temperature in the high concentration oxygen dissolved water purification apparatus of the present invention, the compressor 810, the condenser 820, the expansion valve in the vicinity of the water tank 100 A cooling device 800 composed of a 830 and an evaporator 840 is installed, and the cooling device 800 is controlled by the control unit 500.

On the other hand, the evaporator 840 may be located adjacent to the water tank 100 to cool the water tank 100, but may be a form in which a refrigerant pipe, which is a conventional evaporator form, is directly wound on the outside of the water tank. The cooling fins may be further fixed directly to the outer circumferential surface.

In addition, the temperature sensor 900 for detecting the water temperature is installed on the outside or inside of the water tank 100, the temperature sensor 900 transmits the measured value to the control unit 500. The control unit 500 may maintain the water temperature in the water tank 100 at a temperature that is easy to drink by controlling the cooling device 800 according to the measured value of the temperature sensor 900 transmitted.

The high-concentration oxygen-dissolved water purification device of the present invention as described above has a sealed structure in which the water tank for storing oxygen water is blocked, so that the water stored in the water tank is blocked from the outside air to prevent water from being contaminated from the surrounding environment.

In addition, the water supply pipe of the water tank is connected to the water supply pipe, and since the water supply pipe supplies water while maintaining a constant water pressure, the water tank always has a constant water pressure (approximately water pressure of the water supply pipe). Therefore, the dissolved oxygen amount of the water pressurized and stored in the water tank is always kept constant.

That is, in general, even when oxygen is dissolved in water, dissolved oxygen is released after a certain time elapses, so that the amount of dissolved oxygen is lowered. However, in the present invention, dissolved oxygen is released because the water tank always maintains a constant water pressure. Prevent it.

Therefore, even if the high-concentration oxygen-dissolved water purifier of the present invention is not used for a long time, a constant water pressure always acts on the water tank so that the amount of dissolved oxygen hardly changes. Therefore, it is not necessary to operate the circulation pump and the oxygen generator regularly to maintain the dissolved oxygen amount at a constant level for a long time, thereby minimizing power consumption.

The high-concentration oxygen-dissolved water purification device of the present invention as described above can be directly installed in a water supply pipe for supplying drinking water in a small facility such as a general home, outdoor, or a public facility to provide purified oxygen water. It is an invention that can be easily managed and installed at low cost.

Claims (3)

In the device for purifying the water supplied to the demand through the water supply pipe above a certain water pressure and dissolved in a high concentration of oxygen, A water tank connected to the water supply pipe through an inlet pipe provided with a water filter; A circulation pump connected to the first branch pipe branched from the water supply pipe; A pressure reducing valve installed in the first branch pipe to reduce water pressure; An oxygen dissolving unit provided between the output end of the circulation pump and the water tank while having a circularly wound pipe structure; An oxygen generator connected to the second branch pipe branched from the water supply pipe, and configured to generate high concentration oxygen by electrolyzing water; An oxygen supply pipe for transferring oxygen generated in the oxygen generator to a first branch pipe between the pressure reducing valve and the circulation pump; An outlet pipe having an electronically controlled on / off valve connected to the water tank; A sensor positioned adjacent to the tip of the outlet pipe for non-contact sensing of the presence or absence of a container; High concentration oxygen dissolved water purifier, characterized in that consisting of a control unit for controlling the operation of the electronically controlled on-off valve, the circulation pump and the oxygen generator in accordance with the signal transmitted from the sensor. The method of claim 1, wherein the oxygen generator, An upper case in which water is introduced through an inlet pipe and an oxygen outlet is formed; A water level adjusting unit installed at the water inlet pipe to adjust the water level in the water tank; An electrolysis unit comprising a porous anode positioned below the water tank and in contact with water in the water tank, an electrode assembly membrane positioned below the porous anode, and a porous cathode positioned below the electrode aggregate membrane; ; An airtight member for maintaining the airtightness of the electrolysis unit; A high concentration oxygen dissolved water purifier, which is fixed to the lower part of the water tank and comprises a lower case having a hydrogen discharge port through which hydrogen generated in the electrolysis unit is discharged. The method of claim 1, wherein the control unit comprises a counter circuit for counting the on / off operation of the sensor, the high concentration oxygen, characterized in that for operating the oxygen generator and the circulation pump only for a set time for a set count value Dissolved Water Purifier.

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