KR20090034599A - Water purifier - Google Patents

Abstract

A water purifier is provided to operate electrolytic cell stably by controlling power source applied on the electrolytic cell. A water purifier includes an electrolytic cell sterilization part, a water reservoir(170), a power supply part(300), a control part(400), and a converter(500). A filter part is made by arranging a sediment filter(120), a pre-carbon filter(130), a membrane filter(140), a post-carbon filter(150) successively from a raw water inflow side. The electrolytic cell sterilization part senses size of power source by using the electrolytic cell transferred from the filter part. The power supply part supplies the power source applied to the electrolytic cell sterilization unit.

Description

Water Purifier {WATER PURIFIER}

The present invention relates to a water purifier to prevent contamination of purified water stored in a purified water tank, and more particularly, to a water purifier having an electrolytic sterilization function.

A water purifier installed in a home or office has a basic function of filtering raw water such as tap water or natural water and providing it as warm or cold water.

Water purifiers are generally divided into low-class water purifiers with water purification tanks and direct-type water purifiers without water purification tanks, and remove harmful components, including suspended solids in raw water, and cause waterborne diseases. In order to sterilize the bacteria, a plurality of filters are provided.

That is, a general water purifier is a precipitating filter which removes fine particles or debris from raw water, a pre-carbon filter which adsorbs and removes residual chlorine or odor-causing substances and volatile organic substances, and most ionic substances and microorganisms including heavy metals. It includes filters such as membrane filter to remove oil, post carbon filter to remove odor and water taste.

The direct water purifier supplies the purified water passed through the filters as described above directly to the user through the drainage coke, and the low water purifier stores the purified water through the filters as described above in a water tank of about 5 to 30 liters before draining the water. It is supplied to the user via coke.

On the other hand, the water purification tank provided in the low water purifier is difficult to be completely sealed, there is a fear that bacteria or microorganisms can be proliferated through contact with the atmosphere may lead to secondary pollution of the purified water. In addition, depending on the nature of the incoming raw water may cause the growth of microorganisms in the pre-carbon filter, post carbon filter or the membrane filter itself, the possibility that the proliferation of the microorganisms can be discharged through the purified water can not be excluded. In addition, when the water purifier is not used for a long time there is a problem that the possibility of contamination of the purified water by bacteria and microorganisms can be further increased.

Conventional methods for solving such problems include a method of using a silver-activated carbon filter coated with silver (Ag), which is known to have antimicrobial properties, to activated carbon used in a post carbon filter. The method of supporting it, or the method of installing an ultraviolet (UV) lamp sterilizer at the rear of the post carbon filter is commercially available. However, the method of applying the silver activated carbon filter to the post carbon filter or supporting the ceramic antibacterial ball in the water purification tank guarantees some sterilization and antimicrobial effect. At the end of life, if the neglected or neglected cleaning of the inside of the purified water tank, there is a problem that the secondary pollution is more likely to occur in the purified water stored by the growth of microorganisms and bacteria. In addition, the method of applying the ultraviolet lamp sterilizer 15 to the rear end of the post carbon filter is relatively excellent in the instantaneous sterilization effect on the purified water flowing out of the post carbon filter, but if the contamination in the water purification tank is serious, the secondary of the purified water There is a problem that can not prevent contamination.

Therefore, recently, the effective sterilization performance is realized by passing the purified water filtered in the final filter through the membrane-free electrolytic cell, and the secondary contamination of the purified water by external conditions by maintaining the oxidizing mixture at a constant concentration for a certain period of time. Water purifier with electrolytic sterilization function to prevent the development has been developed.

However, the conventional water purifier having the electrolytic sterilization function has a problem that it is not provided with a function for controlling the voltage and current applied to the electrolytic cell.

That is, the electrolytic cell is in danger of being destroyed when a predetermined voltage or more is applied, and needs to be driven with a constant current. However, a conventional water purifier having an electrolytic sterilization function equipped with an electrolytic cell does not include a separate function for limiting the voltage of the electrolytic cell or applying a constant current to the electrolytic cell, which causes malfunction of the electrolytic cell. As a result, there is a problem that the water purifier malfunctions.

An object of the present invention for solving the above problems, to provide a water purifier having a function to control the voltage applied to the electrolytic cell to perform the function of electrolytic sterilization of the purified water flowing into the purified water tank.

The present invention for achieving the above object, the electrolytic sterilization of the filter unit consisting of one or more filters, the purified water transferred from the filter unit by using an electrolytic cell, while detecting the size of the power applied to the electrolytic cell A cell sterilization unit, a purification tank for storing the electrolytic sterilization purified from the electrolytic cell sterilization unit, a power supply unit for supplying power to be applied to the electrolytic cell sterilization unit, the size of the applied power applied from the electrolytic cell sterilization unit When the outside of the set range of the normal operating power is set, the power supply for changing the applied power to apply to the electrolytic cell sterilization unit and the power control signal of the power control unit by changing the magnitude of the power transmitted from the power supply to the It includes a converter for applying to the electrolytic cell sterilization unit.

The present invention has an excellent effect of stable operation of the electrolytic cell by controlling the intensity of the power applied to the electrolytic cell for electrolytic sterilization of the purified water flowing into the purified water tank.

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

1 is an exploded perspective view of an embodiment of an electrolytic cell applied to the present invention. 2 is a cross-sectional view of the bonding state of the electrolytic cell shown in FIG. 1.

As shown in FIGS. 1 and 2, the electrolytic cells applied to the water purifier according to the present invention are provided in a state where the positive electrode 31 and the negative electrode 32 face each other and are spaced apart from each other at regular intervals. Due to the gap D spaced between the electrodes 31 and 32, a through hole 33 that is opened and penetrated in both directions is provided inside the electrolytic cell 25.

In the electrolytic cell 25, the height of the through hole 33, that is, the gap D between the positive electrode 31 and the negative electrode 32 is provided at regular intervals along the length direction of these electrodes 31 and 32. That is, the height of the through hole 33 is preferably provided with a gap of 0.5 mm or less, more preferably with a gap of 0.2 mm or less, and by maintaining such a gap D, such as a reverse osmosis filtered water in a membrane filter. Even water at very low ionic concentrations (eg, 30 mg / L or less based on TDS concentration) can be effectively electrolyzed.

On the other hand, the positive electrode 31 and the negative electrode 32 is preferably provided in a shape that can effectively conduct electricity to the water (A) flowing along the through-hole 33 therebetween, such electrodes 31, 32 ) May be configured in various forms, such as a disk or a porous structure, as well as a flat type as shown in FIGS. 1 and 2.

In addition, the electrolytic cell 25 applied to the present invention includes an electrode holder 34 for fixing the positive electrode 31 and the negative electrode 32. The electrode holder 34 is preferably composed of a non-conductive material, and a space portion 35 having a predetermined size is formed inside the electrode holder 34, and the positive electrode 31 is formed in the space portion 35. And the negative electrode 32 is provided in a press-fitted or attached form. In addition, both sides of the electrode holder 34 have a form in which connection terminals 36a and 36b extending from the electrodes 31 and 32 pass through and are drawn out to the outside.

An outer cover 37 is coupled to an outer surface of the electrode holder 34 to protect the electrodes 31 and 32 and the electrode holder 34.

In addition, the electrolytic cell 25 according to the present invention may be configured in a form having two or more positive electrodes 31 and negative electrodes 32, respectively, as necessary.

In the electrolytic cell having the configuration as described above, the process of sterilizing purified water is as follows.

Sterilization of purified water using an electrolytic cell is a direct oxidation reaction that directly oxidizes microorganisms at the anode through electrolysis, and various oxidative mixtures (MO: Mixed Oxidants), which may occur at the anode. For example, chlorine, residual chlorine, ozone, OH radicals, oxygen radicals, etc. is a complex indirect oxidation reaction that oxidizes the microorganisms.

In order to effectively generate such various oxides, the electrolytic cell applied to the present invention can generate a sufficient amount of oxidative mixture by applying a minimum cell voltage by minimizing the electrode gap.

On the other hand, in the case of the cell voltage supplied to the electrolytic cell of the present invention, since a voltage of about 3 to 24 V is sufficient in a water purifier to which a general membrane filter is applied, a low-cost electrode using a titanium electrode or a general injection product instead of an expensive platinum electrode for the positive electrode Easy is possible. In this case, even at a cell voltage of 3 to 24 V, an oxidative mixture can be generated at about 0.20 to 0.30 mg / L.

In addition, the potential provided to the electrolytic cell is preferably using a direct current power source.

3 is a configuration diagram of an embodiment of a water purifier according to the present invention. In addition, Figure 4 is a graph showing the voltage / current characteristics in the water purifier according to the present invention.

As shown in FIG. 3, the water purifier according to the present invention includes a sediment filter 120, a pre carbon filter 130, a membrane filter 140, and a post carbon filter 150 sequentially arranged from a raw water inflow side. Electrolytic sterilization of the filter unit, the electrolytic sterilization of the purified water transferred from the filter unit by using an electrolytic cell, the electrolytic sterilization unit 200, for detecting the size of the power applied to the electrolytic cell The water purification tank 170 for storing the purified water, the power supply unit 300 for supplying the power to be applied to the electrolytic cell sterilization unit, the size of the power transmitted from the electrolytic cell sterilization unit is a range of the power set in advance In the case of deviation, the power transmitted from the power supply unit under the control of the power control unit 400 and the power control unit for changing the power applied from the power supply unit to apply to the electrolytic cell sterilization unit By changing the size and is configured to include a converter (500) for applying parts of the electrolytic cell sterilization.

The sediment filter 120 constituting the filter unit is composed of a nonwoven fabric and performs a function of filtering foreign matter of relatively small particles such as sand or mud. The pre carbon filter 130 and the post carbon filter 150 are the same as activated carbon containing carbon as a main raw material and perform a function of removing chlorine component particles and odor contained in raw water. The membrane filter 140 performs a function of removing the fine particles remaining in the water passing through the free carbon filter 130. To this end, pressure is supplied from a pressure pump (not shown) to supply water, and water that does not pass through the reverse osmosis membrane filter is discharged into the wastewater through the wastewater regulator 160. The post carbon filter 150 serves to remove pigments or odors contained in the water passing through the membrane filter 140. Meanwhile, in the present invention, the filter unit may be configured by combining two or more of the filters as described above, or employing a composite filter that performs two or more filter functions in combination. In addition, the present invention may further include a sterilization means by electrolysis between the post carbon filter 150 which is one component of the filter unit and the purified water tank 170.

The electrolytic cell sterilization unit 200 includes an electrolytic cell 25 having a configuration and a function as described with reference to FIGS. 1 and 2, and the electrodes 31 and 32 of the electrolytic cell have a voltage or current. A sensor 210 capable of detecting the intensity is connected. As the sensor, various types of voltage / current sensors currently used may be applied.

The power supply unit 300 performs a function of supplying power to the electrode of the electrolytic cell.

The converter 500 performs a function of transmitting power applied from a power supply unit to the electrolytic cell. When a power control signal is input from the power control unit, the converter 500 changes the power applied from the power supply unit according to the power control signal. It performs the function of transmitting to the electrolysis cell.

The power control unit 400 determines whether the size of the applied power applied to the electrolytic cell through the power supply unit is within the normal operating power range (region 'A' of FIG. 4) of the electrolytic cell, and the applied power And transmits a power control signal to the converter to change the size of the signal. That is, the power control unit stores information on a range of voltage and current (normal operating power supply) in which the electrolytic cell can operate normally, and is applied to the electrolytic cell through a sensor connected to the electrolytic cell. When the magnitude of the applied power is determined to be out of the range of the normal operating power by comparing the magnitude of the two powers with the magnitude of the applied power, the applied power is changed to the range of the normal operating power. It generates a power control signal to transmit to the converter. A PWM signal may be used as the power control signal, and an operating frequency of the PWM signal may be a subaudible frequency of 20 KHz or more.

On the other hand, Figure 4 is a graph of the characteristics of the current and voltage applied to the electrolytic cell. As shown in the figure, the electrolytic cell applied to the present invention should be operated in a current and voltage range (normal operating power range: A) of a specific size, and electrolytic cells outside the normal operating power range (B, C, D). Since the cell may malfunction, the power control unit controls the applied power so as not to exceed the normal operating power range.

That is, when the magnitude of the voltage falls below the minimum driving voltage (V1) (Short) or above the maximum driving voltage (V2) (Open) (C), the power cell may malfunction and the current Since the power supply cell may malfunction even when the magnitude is out of the ranges of the minimum driving current I1 and the maximum driving current I2, the power control unit may supply the applied power applied to the electrolytic cell sterilization unit to the normal operating power supply range. The converter is controlled so as not to deviate from A).

The magnitude of the voltage and the magnitude of the current corresponding to the normal operating power range A may be variously set according to the type, configuration, and function of the electrolysis cell.

Those skilled in the art will appreciate that various changes and modifications can be made without departing from the technical spirit of the present invention. Therefore, the technical scope of the present invention should not be limited to the contents described in the detailed description of the specification but should be defined by the claims.

1 is an exploded perspective view of an embodiment of an electrolytic cell applied to the present invention.

2 is a cross-sectional view of the bonding state of the electrolytic cell shown in FIG.

3 is a configuration diagram of an embodiment of a water purifier according to the present invention.

4 is a graph showing the voltage / current characteristics in the water purifier according to the present invention.

<Description of Major Symbols in Drawing>

120, 130, 140, 150: filter 200: electrolytic cell sterilization unit

300: power supply unit 400: power control unit

500: Converter

Claims (4)

A filter unit composed of one or more filters; An electrolytic cell sterilization unit for electrolytic sterilization of the purified water transferred from the filter unit using an electrolytic cell, and for sensing the size of the power applied to the electrolytic cell; A water purification tank for storing purified water sterilized from the electrolytic cell sterilization unit; A power supply unit for supplying power to be applied to the electrolytic cell sterilization unit; A power control unit for changing the applied power and applying the applied power to the electrolytic cell sterilization unit when the magnitude of the applied power applied from the electrolytic cell sterilization unit is out of a predetermined range of a normal operating power; And And a converter for changing the magnitude of the power transmitted from the power supply unit to the electrolytic cell sterilization unit according to the power control signal of the power control unit. The method of claim 1, The electrolytic cell sterilization unit, An electrolytic cell performing an electrolytic sterilization function; And Water purifier comprising a sensor that can sense the intensity of the voltage or current applied to the electrode of the electrolytic cell. The method of claim 1, The power control signal of the power control unit, Water purifier, characterized in that generated in the inaudible frequency range of 20KHz or more. The method of claim 1, The range of the normal operating power source, Water purifier, characterized in that the variable by at least any one of the type, configuration, function of the electrolytic cell constituting the electrolytic cell sterilization unit.

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