KR100768096B1 - Apparatus for purifying water and method thereof - Google Patents

Abstract

The present invention improves sterilization and water quality by using an electrolysis water treatment device having a bipolar electrode structure, and sterilizes and purifies water in medium and large tanks (pools, bathtubs, building water tanks) and small tanks (home bathtubs). It relates to a water treatment apparatus and a method thereof. According to the present invention, two first and second electrolytic devices are installed in series in parallel with the flow direction of the circulating water, and unreacted salt water contained in the sterilant generated in the first electrolytic device and organic matter present in the circulating water. In order to improve the water quality of the tank circulating water while the chlorine compound passes between the electrodes composed of the bipolar electrode, the pool circulating water is passed between the electrodes of the second electrolytic apparatus, and the organic matter, the combined chlorine in the pool circulating water, and the first electrolytic apparatus are introduced. Effectively removes unreacted salt.

Description

Apparatus for purifying water and method

1 is a schematic diagram showing a state in which a water treatment apparatus according to an embodiment of the present invention is installed in a large tank (swimming pool),

FIG. 2 is an exploded perspective view showing a configuration relationship of a first electrolytic apparatus constituting the water treatment apparatus shown in FIG. 1;

3 is a perspective view illustrating an installation form of the first electrolytic apparatus shown in FIG. 2;

FIG. 4 is an exploded perspective view showing a configuration relationship of a second electrolytic apparatus constituting the water treatment apparatus shown in FIG. 1;

FIG. 5 is a detailed view illustrating an installation form of the second electrolytic apparatus illustrated in FIG. 4.

  ♠ Explanation of symbols on the main parts of the drawing ♠

22: water softener 24: salt water storage tank

25 pump 26 first electrolytic device

28: mixed sterilizer reservoir 29: mixed sterilizer pump

30: second electrolytic apparatus

The present invention improves sterilization and water quality by using an electrolysis water treatment device having a bipolar electrode structure, and sterilizes and purifies water in medium and large tanks (pools, bathtubs, building water tanks) and small tanks (home bathtubs). It relates to a water treatment apparatus and a method thereof.

Water treatment of medium and large tanks is very important and can threaten safety for many users. Therefore, it is necessary to efficiently cope with the sterilization of water, the treatment of dangerous hazardous substances, especially the sudden increase of swimming stream (increase of pollutants).

Sterilization is regulated by law for medium and large sized water tanks (pools, bathtubs, buildings). Among the technologies currently applied, chlorine disinfection is a method of disinfecting with sodium hypochlorite (NaOCl), which is economical and has high residuals. It is widely used for its advantages. However, the treatment produces highly toxic by-products such as trihalomethane (THM) and chloramine, and disinfects when oil, grease or colloidal substances are present in the water. There is a disadvantage.

Judd et al. (SJJudd, chemosphere 51,2003,869-879) reported that contaminants with swimming purposes, generally having 4980 ppm of carbon and 7890 ppm of nitrogen, were introduced into the pool of swimming pools. SKGolfinopoulos (SKGolfinopoulos, Water Research 36,2002, 2856-2868) has shown that the concentration of carbon and the disinfectant sodium hypochlorite may cause trihalomethane (THM). Presented as.

Where R_THM is the rate of trihalomethane (THM) generation, Q (THM) is the amount of trihalmethane (THM) removed, TOC is the concentration of total carbon, NaOCl is the concentration of sodium hypochlorite, ka3, a1, a2 are the experiments Is a constant.

The trihalomethane (THM) produced by the reaction of sodium hypochlorite and organics is heavier than air and is also classified as harmful to humans. Due to these characteristics, there is a cause of the appearance of odor of chlorine near the pool, and there are reports of quantitative analysis thereof. The distribution of trihalomethane (THM) in the pool is 58 micro-gram / m ³ around the pool, 25 micro-gram / m ^{3 around} the pool pool, and the underground machine room for pool water treatment. G. Fantuzzi (G. Fantuzzi et al., The Science of the Total Environment, 264, 2001, 257-265) reported that contamination is 23 micro-gram / m ³ .

In addition, an increase in trihalomethane (THM) is predicted by the rapid increase in swimming flow from Scheme 1, which may further worsen the air quality and water quality in the swimming pool.

As such, swimming pools using chlorine chemicals can solve some of the sterilization purposes, but the increase of by-products has a very serious problem.

In order to solve this problem of chlorine chemicals can be applied to the method of disinfection using electrolysis in the pool. This method sterilizes by supplying the sterilization liquid (sodium hypochlorite, ozone, chlorine dioxide, etc.) generated by electrolysis of the brine into the circulating water of the swimming pool. The main component of the generated sterilization liquid is sodium hypochlorite. Such technologies include Korean Patent Application Nos. 2002-0029093 and 2000-0075734. These techniques aim to increase sterilization efficiency by connecting the first and second electrolytic cells in parallel (parallel), but they can increase the sterilization effect, There is a problem and a problem that cannot be a fundamental solution for the reduction of pollutants and trihalomethane.

Another problem is that the size of the electrolyzer device becomes larger than the economic scale, and this problem will be described by way of example. Residual chlorine concentration is greatly affected by the number of swimmers swimming in the pool, especially when there is a sudden increase in the peak season (summer season). ^{Chlorine-state} of the (HClO, ClO, Cl ₂₎ is determined by the pH value. The pH value of the water quality of a swimming pool pool management standard is pH = 5.8 ~ 8.6, the median value of pH = 7.2 residual chlorine is present in a state of _{x_ HClO ≒ 65%, x_ ClO-} ≒ 35%.

If we assume that 200 swimmers suddenly increase into the pool, about 200 gr of chlorine is needed, and the theoretical amount of current to be supplied to the electrolysis unit can be obtained from Scheme 2.

And in Scheme 2 R_C is a necessary electric charge unit Coulomb, R_ _Cl2 have residual chlorine (gr), M_ _HClO is the molecular weight of HClO, _HClO x_ is the weight fraction of HClO, _ClO M_ has a molecular weight of ClO, _ClO x_ Is the weight fraction of ClO and N_adv is the avogadro number 6.022 x 10 ²³ , C is the charge amount of the electron and quantum is 1.602 x 10 ^-19 .

Here, assuming that the generation efficiency of chlorine with respect to the amount of current supplied is? [%], The amount of current actually required can be obtained from the following reaction formula (3).

The efficiency η is a constant determined by the electrode catalyst of the electrode and the NaCl concentration of the electrolyte and the like, and generally has a value of about 15 [%]. Therefore, the amount of energization (Coulomb) from Scheme 4 is substituted by η = 15. Can be obtained.

Therefore, when the electric current of this quantity flows, the residual chlorine concentration of the water in a pool will average 0.6 [ppm]. In the case of the existing swimming pool of 500 tons, the energization supplied to the electrolysis cell is 252 [A]. Therefore, dividing the value obtained by the reaction equation (Coulomb, Ampare * sec) by the energization current amount 252 [A] gives the reaction time. Can be obtained from 5.

That is, by energizing for about 163 minutes, the residual chlorine concentration increases by electrolysis, and the residual chlorine concentration of the pool can be set to 0.6 [ppm], which is the reference concentration. Therefore, since swimming is required for about two and a half hours from the moment swimming in the swimming pool, it is not possible to adequately cope with the fluctuations in water quality in consideration of the swimming time for swimming around one hour. Therefore, in the case of the above techniques, the coping with appropriate water pollution fluctuations may be delayed.

On the other hand, in the case of increasing the size of the electrolysis device, for example, in the case of increasing the size of the electrolytic cell to correspond to the drastic change in swimming guests within 30 minutes can be obtained from the following reaction equation 6.

If the current density design criterion of the electrolysis device is 0.1 [A / cm ² ], the overall area of the electrolysis device is obtained from the following Reaction Equation 7.

The total area of 13700 [cm ² ] requires about 14 stacked electrode structures when the unit electrolytic cell size (electrode size) is 1000 [cm ² ], and the problems of increased cell energy consumption and installation cost Is generated.

From the point of view of purifying water, a method for electrochemically removing trihalomethane without the use of an electrolyte, such as brine, is described by DE Kimbrougha et al. (David Eugene Kimbrougha, *, IH Suffetb, "Electrochemical removal of bromide and reduction of THM formation potential in drinking water ", Water Research 36 (2002) 4902-906, but the shape, structure and operating conditions of the electrode for commercial application are not shown.

The present invention has been made to address the instantaneous fluctuations in water pollution, efficient sterilization and contaminated water purification, which is a problem of the prior art as described above. By using the second electrolytic device of interest, the organic matter, the combined chlorine, etc. contained in the circulating water of the medium and large water tanks are treated, but unreacted salts that cause corrosion of the pipe generated when the electrolytic device is installed alone are treated. The purpose of the present invention is to provide a water treatment apparatus and a method thereof that can effectively cope with sudden water fluctuations in a reservoir.

The water treatment apparatus according to the present invention is characterized in that it is composed of a first electrolytic means (first electrolytic apparatus) and a second electrolytic means (second electrolytic apparatus) for decomposing and purifying organic matter in water.

The first electrolytic device and the second electrolytic device of the present invention are each provided with a plurality of bipolar electrodes having a double pole and the outermost sides of the plurality of bipolar electrodes so as to easily cope with a contaminant load variation. It characterized in that it has a terminal electrode connected to the +,-terminal.

Bipolar Electrode refers to an electrode which has both oxidation and reduction characteristics when energizing based on one electrode, and a relative concept is that one electrode has only oxidation characteristics or only reduction characteristics, that is, one There is a monopole with only characteristics. Since the single electrode is generally formed as a positive electrode (oxidized electrode) or a negative electrode (reduction electrode), the electrode requires twice as many electrodes as the double electrode in a given environment, thereby increasing the installation cost, and also has a large installation space. have. Therefore, if the double pole design is used, it is easy to effectively cope with the sudden increase in load caused by the increase in the number of passengers.

In addition, according to the present invention, the first electrolytic device electrolyzes an electrocatalyst suitable for electrolyzing about 4% salt water for sterilization purposes, and the second electrolytic device electrolyzes fresh water (salt concentration of 1,000 PPM or less) for the purpose of water purification. It is characterized by having an electrode catalyst suitable for.

In addition, the present invention stores the disinfectant generated in the first electrolytic means when there are few swimmers, and interlocks with the residual chlorine concentration sensor in the tank to supply the disinfectant according to the residual chlorine level in the tank to the second electrolytic means It may further comprise means (storage, pump, etc.).

The bipolar electrode of the first and second electrolytic means may be composed of one base material on which one side undergoes an oxidation reaction and the other side causes a reduction. At this time, the interval between the bipolar electrodes of the first and second electrolytic means is preferably 3 to 10 mm.

The water treatment method according to the present invention uses a water treatment device configured as described above, generating salt water through salt water generating means (salt water saturation tank, storage tank, etc.), and salt water supplied from the salt water generating means in the first electrolytic means. Generating electrolytic disinfectant, storing the disinfectant generated in the first electrolytic means in the disinfectant storage means, and storing the disinfectant generated in the first electrolytic means in the sterilant storage means in water flowing along the branch line branched from the circulation line. The sterilizing agent supplied according to the residual chlorine level of the mixed in the second electrolytic means and characterized in that it comprises the step of sterilizing and purifying water and then returning back to the bath.

Hereinafter, with reference to the accompanying drawings, preferred embodiments of the water treatment apparatus and method thereof according to the present invention will be described in detail.

1 is a schematic diagram showing a state in which a water treatment apparatus according to an embodiment of the present invention is installed in a large tank (swimming pool). As shown in FIG. 1, the water treatment apparatus according to this embodiment is installed in a large water tank such as a pool 10, and includes a first electrolytic apparatus 26 for sterilization purposes and a second electrolytic apparatus for water purification purposes ( 30) and the like. And the pool 10 is provided with the main circulation line s1-s2-s3-s4-s5 which circulates a large amount of water by the circulation pump 16 (double solid line mark in drawing).

The operation sequence of the first electrolytic apparatus 26 according to this embodiment is as follows.

The line s15 branched at the branch point E at the rear end of the heat exchanger 20 installed in the main circulation line s1-s2-s3-s4-s5 passes through the on / off valve b and is present in the circulating water of the swimming pool. The water softener 22 removes the foreign matter. The water line s16 from which the foreign matter is removed from the water softener 22 is branched into two lines s17 and s18 at the branch point C. One line s18 is connected to the brine reservoir 24 to saturate the salt, and the saturated brine is supplied to the first electrolytic apparatus 26 through the brine line s19 by the pump 25. The coalescence is merged at the coalescing point D with the line s17 branched from the rear water line s16 of the water softener 22. The concentration of the brine of the coalesced line (s20) is adjusted to 3 ~ 4% by adjusting the mixing ratio of the water line (s17) and brine line (s19) at about 10: 1. The 3-4% brine is supplied directly to the first electrolyzer 26 along the line s20 to be a mixed fungicide containing chlorine by electrolysis. The resulting mixed sterilizer is supplied to the mixed sterilant reservoir 28 through the discharge line s21 of the first electrolytic device 26. The mixed sterilizer stored in the mixed sterilant storage tank 28 is interlocked with the residual chlorine concentration sensor (not shown) in the pool 10 and is disinfected by the mixed sterilizer pump 29 according to the residual chlorine level in the pool 10. It is supplied to the second electrolytic apparatus 30 via the supply line s22.

On the other hand, as a method for supplying the water to be used for the first electrolytic device 26 may be used a time line (s12) introduced for the purpose of balancing the water in the pool (10). That is, in the water supply line s13 supplied from the water supply line s12 to the balancing tank 12, a part line is branched at the branch point A and the supply line s14 and the valve a connected to the first electrolytic device 26. ) Can be used as water to dissolve salt. However, the method using the water line (s12) has a temperature limit of 10 ° C. or less in the winter, and when used directly in the first electrolytic apparatus 26, the electrolytic efficiency is lowered and thus there is a limitation in use. Preference is given to branching at -s2-s3-s4-s5).

The operation sequence of the second electrolytic apparatus 30 according to this embodiment is as follows.

The line s23 branched at the branch point F at the rear end of the heat exchanger 20 installed in the main circulation line s1-s2-s3-s4-s5 passes through the on / off valve c and then passes through the circulation line s23. It flows into the second electrolytic device 30. At this time, the water circulation line s4 is shut off using the on / off valve e installed in the main circulation line s1-s2-s3-s4-s5.

In addition, the second electrolytic apparatus 30 is supplied with the mixed sterilizer stored in the mixed sterilant reservoir 28 by the mixed sterilizer pump 29, and the sterilant contains about 1% of unreacted salt in addition to the effective chlorine. At this time, the concentration of the brine in the second electrolytic device 30 is about 1,000 ppm by mixing the water of the main circulation line (s1-s2-s3-s4-s5) with the unreacted brine of the first electrolytic device 26. In the swimming pool circulating water introduced into the second electrolytic apparatus 30, organic matter, total nitrogen, and the like are decomposed by electrolysis to purify water. The purified water is coalesced at the coalescing point (G) of the main circulation line (s1-s2-s3-s4-s5) via the on / off valve (d) of the discharge line (s24) of the second electrolytic apparatus (30). 10) is supplied.

The water treatment apparatus according to this embodiment operates as follows. As shown in Fig. 1, the pool 10 is provided with a main circulation line s1-s2-s3-s4-s5 through which a large amount of water is circulated by the circulation pump 16 (double solid line in the drawing). . The water in the pool 10 is circulated by the circulation pump 16, the large contaminants are removed by the screen filter 14, and the contaminants such as fine colloidal organics and the like are removed by the sand filter 18. The water passing through the sand filter 18 is circulated back to the pool 10 after being heated up in the heat exchanger 20.

The first electrolytic device 26 and the second electrolytic device 30 according to this embodiment are provided on both outermost sides of a plurality of bipolar electrodes having a bipolar and a plurality of bipolar electrodes at the time of energization, respectively. It consists of an electrode connected to the + and-terminals of the supply, that is, a terminal electrode. The electrode having the bipolar of this embodiment is composed of one substrate (for example, metal itself, titanium, tantalum, etc.) having one catalyst having an oxidation reaction on one side and a catalyst having a reduction reaction on the other side. . Conventional bipolar electrodes generally comprise electrodes having different properties through physical bonding such as welding or chemical bonding such as explosion welding, but this embodiment is based on a single metal. In the case of constructing a bipolar electrode in which dissimilar metals are combined, the electrode has a non-uniform dimension, resulting in an uneven current distribution, and the uneven distribution causes local reaction unevenness, thereby reducing the overall efficiency.

In the bipolar of the present invention, one side uses an oxidative electrochemical catalyst and the other side a reduction electrochemical catalyst on a base material such as titanium or tantalum. The electrode on the oxidation reaction side where the chlorine reaction or oxygen reaction occurs is coated by high temperature oxidation treatment by appropriately mixing platinum group noble metals such as ruthelium, iridium, platinum, rhodium, palladium, and the negative electrode using its own base material, iron, Metals such as nickel and platinum are suitably mixed and coated by plating or high temperature oxidation treatment. The + terminal electrode connected to the external power source is an oxidizing electrochemical catalyst and coated by high temperature oxidation treatment by appropriately mixing platinum group noble metals such as ruthelium, iridium, platinum, rhodium and palladium, and the terminal electrode using its own base material, Metals, such as iron, nickel, and platinum, are mixed suitably and coated by plating or high temperature oxidation treatment.

FIG. 2 is an exploded perspective view showing the configuration of the first electrolytic apparatus constituting the water treatment apparatus shown in FIG. 1. As shown in FIG. 2, the first electrolytic apparatus is installed at both ends of the bipolar electrode 116 and the terminal electrodes 112 and 117 connected to the + and − terminals of the external power supply are connected to the fluid. Arranged in a direction perpendicular to the moving direction. A plurality of electrode guides 118 are inserted between the terminal electrodes 112 and 117 and the bipolar electrode 116 to adjust the distance between the electrodes, and to adjust the voltage distribution between the electrodes constantly. The terminal electrode 112 has a terminal 106 connected to the + terminal of an external power supply and a brine inflow line 104 into which the brine flows. Reference numeral 114 denotes an electrolytic cell mold having a plurality of bipolar electrodes 116, and reference numerals 110 and 119 denote external molds for holding the terminal electrodes 112 and 117 and the electrolytic cell mold 114. ) Is installed outside the anode side and the cathode side terminal electrodes 112 and 117 to fix the entire component through the bolt hole 119a.

The first electrolytic device 26 is an electrolytic cell for the purpose of producing a disinfectant, and supplies electricity to the terminal electrodes 112 and 117 by connecting with an external power source to cause an electrochemical reaction. When electricity is supplied, oxidation and reduction reactions occur at the anode and cathode, respectively, and fungicides are generated. At this time, the electrochemical reaction occurs as follows.

At the anode, the oxidation reactions of reaction schemes 8, 9 and 10 take place.

In addition, the reduction reaction of Scheme 11 occurs at the negative electrode.

The bipolar of the first electrolytic device provides an electrocatalyst structure for efficiently generating chlorine, a bactericide, as in the above reaction scheme. On one side of titanium, tantalum, and the like, one side applies an oxidative electrochemical catalyst and the other side reduces an electrochemical catalyst. The oxidation electrochemical catalyst is coated by high temperature oxidation treatment by appropriately mixing platinum group noble metals such as ruthelium, tin, iridium, platinum, rhodium, and palladium so that the chlorine reaction can occur efficiently. A base material is used, or metals such as iron, nickel and platinum are appropriately mixed and coated by plating or high temperature oxidation treatment. Preferably, the electrode having a ratio of 70:30 of ruthenium with low chlorine overvoltage and excellent tin-iridium in an oxygen atmosphere is preferably used for the oxidation electrode catalyst electrode, and the reduction catalyst uses a base metal or platinum suitable for hydrogen generation. Plated or high temperature oxidized electrodes are preferred. In the method of manufacturing the electrode, a reduction catalyst precursor is first applied to one side, and the other side is subjected to an oxidation catalyst.

+ Terminal electrode connected to external power is an oxidation electrochemical catalyst on only one side, and platinum group precious metals such as ruthelium, iridium, platinum, rhodium, and palladium are properly mixed and coated by high temperature oxidation treatment. Or a metal such as iron, nickel, platinum or the like is appropriately mixed and coated by plating or high temperature oxidation treatment. Preferred forms of the catalyst are the same as the application of the bipolar.

The potential required for the electrolysis reactions of Schemes 8 to 10 is suitably about 5 to 10 volts DC (direct current) based on a single cell regardless of the shape and structure of the electrode. Above 10 volt, excessive electrolysis energy is consumed to increase the operating cost. At less than 5 volt, the electrolytic reaction efficiency rapidly decreases, thus increasing the number of electrodes and increasing the cost of electrolytic devices. In addition, the current is preferably 0.1 A / cm ² to 1.5 A / cm ² based on the current density. At this time, when the current density is greater than 1.5 A / cm ² , the corrosion rate of the electrode increases, and at 0.1 A / cm ² or less, the current efficiency is low, so that many electrodes are needed. This increases the device cost.

The distance between the electrode and the electrode is appropriately 3 to 10 mm, and if it is smaller than 3 mm, the hardness in the water easily adheres to the electrode and hinders the movement of the current. The risk of fire exists. At this time, the most optimal distance between electrodes is 4 mm.

In addition, the concentration of the brine supplied to the first electrolytic apparatus 26 is 1 to 4% is appropriate. At 1% or less brine concentration, the current efficiency is greatly decreased, voltage is increased, hypochlorite concentration is less than 1000 ppm among the fungicides generated, and the conversion efficiency of salt is reduced to 40% or less. The efficiency of disinfectant generation in E. coli is dramatically reduced. In addition, more than 4% of unreacted salt is discharged into the pipe of the pool can increase the corrosion of the pipe.

As for the temperature of the salt water supplied to the 1st electrolytic apparatus 26, 25 degreeC-32 degreeC is suitable. The conversion efficiency and electrolysis efficiency of the brine is reduced at the brine temperature lower than 25 ℃, the hypochlorous acid concentration is converted to the chloric acid at the brine temperature higher than 32 ℃ to reduce the efficiency of the disinfectant.

FIG. 3 is a perspective view illustrating an installation form of the first electrolytic apparatus illustrated in FIG. 2. The line codes s3, s4, s5, s22, s23, and s24 shown in FIG. 3 are the same as those mentioned in FIG. Line symbol s22 is the inlet of the mixed fungicide and the unreacted brine is present in a weight ratio of about 1%, mixed with the main circulation line (s3-s23-s24-s5) to maintain about 100 ~ 1000 ppm brine.

The electrochemical reaction that occurs in the second electrolytic device 30 is a reaction in which a small amount of salt ions are electrolyzed in a membrane-free state, and the radicals, chlorine, and oxygen compounds generated by this series of reactions have strong oxidizing power. Based on this oxidizing power, various organic substances are oxidatively decomposed. Radicals, chlorine and oxygen compounds which may be present in water are produced by the following reactions.

Scheme 12 relates to a reaction in which electrons generated when water is decomposed move toward an electrode through an external circuit.

Scheme 13 relates to a reaction where the hydroxide ions generated by Scheme 12 are converted to very strong OH radicals.

Scheme 14 relates to a reaction in which oxygen is received at the cathode and reduced.

Scheme 15 relates to the reaction where free radicals H · are formed due to the decomposition of water at the cathode.

Scheme 16 relates to a reaction in which the OH radicals and H radicals generated in the reaction react with each other to generate a series of highly active radicals.

When alkali chlorides and alkaline earth metal chlorides are dissolved, hydroxide is produced at the cathode, and chlorine is produced at the anode, and the generated chlorine is partially separated as in Scheme 17.

Each radical, chlorine, and oxygen compounds generated by a series of reactions such as Schemes 12 to 17 have strong oxidizing power, and various organic substances are oxidatively decomposed based on this oxidizing power. In addition, various metals are mostly present in a cation state in water, and these positively charged heavy metal ions react with the negatively charged electrons and are reduced to neutralization or non-toxic state to remove toxic heavy metal ions. The reaction scheme at this time is as follows.

FIG. 4 is an exploded perspective view showing a configuration relationship of a second electrolytic apparatus constituting the water treatment apparatus shown in FIG. 1. As shown in FIG. 4, the bipolar electrode 222 and the terminal electrodes 218 and 226 installed at both ends and connected to the + and − terminals of an external power supply are formed inside the electrolytic cell 210. 224 is arranged in a direction perpendicular to the moving direction of the fluid. A plurality of electrode guides (not shown) are inserted between the terminal electrodes 218 and 226 and the bipolar electrode 222 to adjust the spacing between the electrodes and to uniformly adjust the voltage distribution between the electrodes. Reference numeral 212 denotes an outer cover constituting the electrolytic cell mold 210. The electrolytic cell frame 210 and the outer cover 212 are fixed to the entire component through the bolt hole (214). The terminal electrodes 218 and 226 have terminals 220 and 228 connected to terminals of an external power supply. Reference numeral 216 denotes a hole for guiding the terminals 220 and 228 of the terminal electrodes 218 and 226, into which the O-ring (not shown) is inserted to prevent leakage.

The second electrolytic device 30 is intended to purify water, and unlike the bipolar of the first electrolytic device 26, the second electrolytic device 30 provides an electrode catalyst structure for efficiently generating oxygen and oxygen radicals for decomposing organic matter. do. That is, one side is applied to the oxidation electrochemical catalyst, the other side is applied to a single base material such as titanium, tantalum and the like. The oxidizing electrochemical catalyst may use the bipolar electrode of the first electrolytic device 26, but may cause problems in durability because oxygen and oxygen radical reactions occur and ruthenium or the like elutes. Therefore, in order to efficiently produce oxygen and oxygen radical reactions, platinum group noble metals such as iridium, tantalum and rhodium are appropriately mixed and coated by high temperature oxidation treatment, and the reduction catalyst uses its own base material or iron, nickel, platinum Metals, such as these, are mixed suitably and are coated by plating or high temperature oxidation treatment. Preferably, the electrode having a ratio of 50:50 of iridium-tantalum having a low oxygen overvoltage is preferably used for the oxidation electrode catalyst electrode, and the reduction catalyst is an electroplated base metal or platinum suitable for hydrogen generation, but an oxide at high temperature. Electrodes of the form are preferred. In the method of manufacturing the electrode, a reduction catalyst precursor is first applied to one side in the same manner as the preparation of the bipolar electrode in the first electrolytic apparatus, and the other side is applied to the oxidation catalyst. The + terminal electrode connected to the external power source installed at the outermost side of the second electrolytic device uses the same electrochemical catalyst used for the oxidation catalyst electrode of only one side, and the terminal electrode is also used for the reduction electrode catalyst of the double electrode. Use it.

The required potential for causing the electrolysis reaction is about 10 to 30 volts DC (direct current) on a unit cell basis regardless of the shape and structure of the electrode. Above 30 volt, the electrolysis energy is excessively consumed, increasing the operating cost, and below 10 volt, the electrolytic reaction efficiency decreases rapidly, so that decomposition of organic matter cannot be performed effectively. The current is preferably 0.01 A / cm ² to 0.2 A / cm ² based on the current density. At this time, when the current density is greater than 0.2 A / cm ² , the corrosion rate of the electrode is increased, and at 0.01 A / cm ² or less, the current efficiency is low, which makes it difficult to decompose organic materials. The distance between the electrode and the electrode is appropriately 3 to 10 mm, and if it is smaller than 3 mm, the hardness in the water easily adheres to the electrode and hinders the movement of the current. If it is larger than 10 mm, the voltage rises and heat is applied to the terminal electrode. The risk of fire exists.

In addition, the concentration of the brine supplied to the second electrolytic apparatus 30 is less than 1%. At 1% or more, the oxidation reaction is more easily performed with chlorine ions than with water decomposition, which limits the decomposition of organic matter. The temperature of the brine supplied to the 2nd electrolytic apparatus 30 is suitable for 32 degrees C or less. At temperatures above 32 ° C., oxygen and radical reactions are unlikely to occur.

FIG. 5 is a detailed view illustrating an installation form of the second electrolytic apparatus illustrated in FIG. 4. As shown in FIG. 5, the arrangement of the electrodes in the second electrolytic apparatus 30 and the shape of the electrodes are as described above. The flanges 302 and 316 in FIG. 5 are for installing a shut-off valve, and reference numerals 304, 306 and 314 are spare nozzles for supplying a cleaning liquid when contaminants are attached to the electrodes in the second electrolytic apparatus 30. . Reference numeral 310 denotes a nozzle supplied by a transfer pump such as a pump in a reservoir storing sterilization liquid generated in the first electrolytic apparatus 26. Reference numerals 308 and 312 denote pipes having the same diameter as the circulation pipe of the swimming pool.

Hereinafter, the water treatment result of the pool in which the water treatment apparatus according to the prior art is installed and the water treatment result of the pool in which the water treatment apparatus configured as described above is installed will be described as an example. However, the scope of the present invention is not limited to this example, and any person having ordinary skill in the art to which the present invention pertains may make various modifications without departing from the gist of the present invention as claimed in the claims. Such changes are intended to fall within the scope of the claims.

[Invention] Water treatment apparatus provided with a first electrolytic device and a second electrolytic device

end. Fabrication of the first electrolytic device

(1) Electrode size (active area): Titanium 1.2mm thick, size 20cm * 30cm

(2) Number of bipolar electrodes: 3

(3) Structure of the electrolytic cell: Fig. 2

(4) Fabrication of Bipolar Electrode

A) Substrate: Titanium 1.2 mm thick, size 30 cm * 40 cm

B) Cathode catalyst and preparation method

Catalyst: Ruthenium-iridium 70: 30 weight ratio

Manufacturing method: repeated high temperature oxidation treatment

C) Cathode catalyst and preparation method

Catalyst: Platinum Coating

Manufacturing method: high temperature oxidation treatment

I. Fabrication of Second Electrolyzer

(1) Size of electrode (active area): Titanium 1.2 mm thick, size 20 cm * 30 cm

(2) Number of bipolar electrodes: 3

(3) structure of the electrolytic cell: Fig. 4

(4) Fabrication of Bipolar Electrode

A) Substrate: Titanium 1.2 mm thick, size 30 cm * 40 cm

B) Cathode catalyst and preparation method

Catalyst: Iridium-tantalum 50: 50 weight ratio

Manufacturing method: repeated high temperature oxidation treatment

C) Cathode catalyst and preparation method

Catalyst: Platinum Coating

Manufacturing method: high temperature oxidation treatment

la. Arrangement of the first and second electrolytic devices

(1) Arrangement method: series array

(2) Installation diagram: Fig 1

(3) presence or absence of sterilizer storage tank of the first electrolytic device: 1 ton liquid storage tank

hemp. Water quality assessment

(1) Evaluation place: 6 locations in Seoul

(2) Measuring position: In the pool (10 in Fig. 1)

(3) The measurement results are shown in the following Table 1 (Results of water quality measurement at 6 swimming pools in Seoul).

Comparative Example General Water Treatment Equipment

A typical water treatment apparatus is shown in FIG. 1 in which the first electrolyzer 26, the second electrolyzer 30, and the associated water softener 22, the brine reservoir 24, the pump 25, the mixed sterilant reservoir 28 and the mixture The sterilant pump 29 and the like have a excluded configuration. The operational relationship of the general water treatment apparatus excluding these components will be described with reference to FIG. 1 as follows.

The pool 10 is provided with a main circulation line s1-s2-s3-s4-s5 through which a large amount of water is circulated by the circulation pump 16 (double solid line in the drawing). The water in the pool 10 is circulated by the circulation pump 16, and large contaminants are removed by the screen filter 14, and contaminants such as fine colloidal organic matter and the like are removed by the sand filter 18. Water passing through the sand filter 18 is circulated back to the pool 10 after being heated up in the heat exchanger 20. Instead of the mixed sterilant storage tank 28 of FIG. 1 for the purpose of sterilizing the pool 10, a 5% sodium hypochlorite storage tank generally used is installed, and in conjunction with a chlorine sensor (not shown) inside the pool, Sodium hypochlorite is then pumped into the main circulation line of the pool. At this time, the water quality evaluation item and method are the same as the invention example. Table 2 below shows the water quality measurement results when using a commonly used water treatment apparatus.

As can be seen in Table 1 and Table 2 above, it can be seen that the invention example is superior to the measured value of the water quality evaluation item compared to the comparative example.

The present invention is a method in which the disinfectant generated in the first electrolytic apparatus passes between the electrodes of the second electrolytic apparatus installed in a series manner, and in the treatment of water in the medium-large tank, the water is always sterilized in the circulation path. As the water quality of the internal water fluctuates, the disinfectant prepared by the first electrolytic apparatus can be additionally supplied to the circulation treatment path when necessary, so that the water can always be maintained in good water quality.

In addition, the present invention by contacting the water directly to the electrochemical reactor, by removing the organic matter, residual chlorine, unreacted salt water present in the water, in the case of swimming pools to induce a good swimming and air quality in swimming pools swimming Provide a comfortable environment.

Claims (11)

A water treatment apparatus comprising a circulation line for circulating to sterilize and purify water stored in a water tank, and sterilization purifying means for sterilizing and purifying water circulated in the circulation line and then returning it to the water tank. The sterilization purification means, Brine generating means for generating brine by using water supplied along branch lines branched from the circulation line; Electrolyzing the brine supplied from the brine generating means to generate a disinfectant, and a plurality of bipolar electrodes having a bipolar (electropolar) when energized, and are installed on each of the outermost side of the plurality of bipolar electrodes, respectively, an external power supply (Power Supply) A first electrolytic means having a terminal electrode connected to the + and-terminals of The water flowing along the branch line branched from the circulation line is mixed with the sterilizing agent supplied from the first electrolytic means and sterilized and purified by water to return to the water tank, and has a bipolar when energized. And a second electrolytic means having a plurality of bipolar electrodes and terminal electrodes respectively provided on both outermost sides of the plurality of bipolar electrodes and connected to + and − terminals of an external power supply. The bipolar electrode of the first and second electrolytic means is a water treatment device, characterized in that the one side is composed of one base material that the oxidation reaction is reduced on the other side. The method according to claim 1, And a sterilant storage means for storing the sterilizer generated by the first electrolytic means and supplying the sterilizer according to the residual chlorine level in the tank to the second electrolytic means in association with the residual chlorine concentration sensor in the tank. Water treatment device, characterized in that. delete The method according to claim 1 or 2, The water treatment apparatus of claim 1, wherein the distance between the bipolar electrodes of the first and second electrolytic means is 3 to 10 mm. As a water treatment method using the water treatment apparatus according to claim 2, Generating brine through the brine generating means; Generating a fungicide by electrolyzing the brine supplied from the brine generating means in the first electrolytic means; Storing the disinfectant produced by the first electrolytic means in the disinfectant storage means, and The sterilant stored in the sterilant storage means in the water flowing along the branch line branched from the circulation line and supplied according to the residual chlorine level in the tank is mixed and electrolyzed in the second electrolytic means to sterilize the water. And purifying and returning to the water tank again. The method according to claim 5, The potential required for the electrolytic reaction of the first electrolytic means is 5 to 10 volts DC (direct current), and the current is 0.1 A / cm ² to 1.5 A / cm ² based on the current density. The method according to claim 6, The concentration of the brine supplied to the first electrolytic means is a water treatment method, characterized in that 1 to 4%. The method according to claim 6 or 7, The temperature of the brine to be supplied to the first electrolytic means is a water treatment method, characterized in that 25 ℃ ~ 32 ℃. delete delete delete

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