KR20190138081A - A chlorine dioxide water producing device - Google Patents

Abstract

The present invention relates to an apparatus for producing a chlorine dioxide solution which can be safely and hygienically used. The apparatus of the present invention comprises: a sodium chlorite aqueous solution storage container for storing a sodium chlorite aqueous solution; a hydrochloric acid aqueous solution storage container for storing a hydrochloric acid aqueous solution; and a mixed solution storage container for mixing and storing the sodium chlorite aqueous solution and the hydrochloric acid aqueous solution.

Description

A chlorine dioxide water producing device

The present invention relates to an apparatus for producing chlorine dioxide, and more particularly, chlorine dioxide gas generated through the reaction of an aqueous sodium chlorite solution and an aqueous solution of hydrochloric acid is supplied to an drinking water supply pipe to provide a fast flow rate of drinking water passing through a venturi tube. It relates to a chlorine dioxide water production apparatus for producing chlorine dioxide water to be used as sterile disinfection water by allowing the chlorine dioxide gas to be dissolved in drinking water by suction.

In general, chlorine disinfectants such as sodium hypochlorite are most widely used as disinfectants.

However, it is pointed out that chlorine disinfectants are not only harmful to the human body due to the generation of carcinogens such as disinfection by-products (THM _S , HAA _S , HAN _S ), but also cause secondary environmental pollution when discharged to sewage. .

In addition, as the pH increases, the disinfectant effect rapidly decreases, and when disinfecting, it reacts with organic compounds to cause substitution reactions and addition reactions in addition to oxidation reactions. It is pointed out that the phenomenon occurs, the inactivation of the protozoa and the removal of heavy metals are not very effective, and in a small lunchroom for distributing food, the chlorine disinfectant must be diluted and used.

In addition, ozone was used as a disinfectant in addition to chlorine disinfectants. However, ozone has been proved to be harmful to the human body and the cold environment by producing a strong and irritating odor and potential carcinogens such as bromate.

Therefore, interest in chlorine dioxide is increasing to replace the disinfectant having the above problems. The chlorine dioxide (ClO ₂ ) is a greenish yellow gas having a unique odor. When cooled, it turns into a yellowish red liquid, and is chemically unstable, and turns into ClO ₂ , ClO ₃ , and Cl, resulting in a strong oxidizing effect as a bactericidal effect.

In addition, the chlorine dioxide has been spotlighted as an alternative to chlorine disinfectants due to environmentally friendly properties that are easily decomposed by light.

According to the Korean Ministry of Environment (No. 1999-173), chlorine dioxide can be used as a disinfectant disinfectant when used under 1ppm under the Drinking Water Management Act, and according to the latest Food and Drug Administration (2007-145) The chlorine dioxide water produced by the manufacturing apparatus and electrolysis is announced that it can be used as a disinfectant for foods such as vegetables and fruits when used below 30ppm.

Looking at the two kinds of methods of preparing the chlorine dioxide water,

First, chlorine dioxide is generated by reacting chlorine with sodium chlorite, and the reaction formula is as follows.

2NaClO ₂ + Cl → 2ClO ₂ + 2NaCl

Second, chlorine dioxide is generated by reacting acid with sodium chlorite, and the reaction formula is as follows.

5NaClO ₂ + 4HCl → 4ClO ₂ + 5NaCl + 2H ₂ O

5NaClO ₂ + H ₂ SO ₄ → 4ClO ₂ + 2Na ₂ SO ₄ + NaCl + 2H ₂ O

Looking at the patent registration No. 10-1162535 of the prior art for producing chlorine dioxide water in the first method as follows.

The prior art 1 (Patent No. 10-1162535) is the first reaction of sodium chlorite and sulfuric acid in the auxiliary reactor, the mixture overflowed in the auxiliary reactor falls in the main reactor, and then supplying an inert gas to the lower surface of the reactor It relates to a chlorine dioxide generating device for inducing a reaction by stirring the mixture in the reactor.

However, the above-described prior art 1 has a problem of falling in the reaction tank because it overflows in a state in which the auxiliary reaction tank is not sufficiently reacted, and further, as the inert gas is supplied to the lower surface of the reaction tank, the mixture separated from the auxiliary reaction tank is not circulated to the bottom of the reaction tank. There is a problem that stirring does not occur vigorously, and thus there is a problem that the amount of generation of chlorine dioxide is significantly reduced.

A patent registration number 10-1092818 of the prior art for preparing chlorine dioxide water in the second method will be described.

The prior art 2 (Patent No. 10-1092818) generates chlorine dioxide by reacting an aqueous solution of sodium chlorite with hydrochloric acid, but cation exchange of the unreacted aqueous solution of sodium chlorite again to solve the problem of lowering the purity of the chlorine dioxide component. The present invention relates to a chlorine dioxide generator that generates acidic chlorine dioxide through a resin.

However, the above-described prior art 2 does not disclose various conditions in which the reaction can occur sufficiently in the reaction tank only to generate chlorine dioxide using unreacted sodium chlorite.

Another prior art 3 proposed to solve the problems appearing in the prior art 1,2 as described above is introduced in Patent Registration No. 10-1824731.

Prior art 3 (Patent No. 10-1824731) describes a first reaction in a reaction tube and a reaction vessel by air bubbles generated in a bubble cap in order to solve the problems described in the above-mentioned prior art 1,2. Secondary reactions and tertiary reactions in which air bubbles rise in the reaction vessel and actively agitate the mixture can produce chlorine dioxide with high production rates and can generate chlorine dioxide water using an aspirator. Looking at this prior art 3 in detail with reference to the Figure 7 as follows.

Prior art 3, as shown in Figure 7, the reaction tank 100, the funnel-shaped reaction tube 140 is inserted into the reaction tube 140 and the bubble cap 160 at the bottom of the reaction tube 14 ), And the sodium chlorite storage unit 200 and the sulfuric acid storage unit 300 formed on the left and right sides of the reaction tank 100, respectively, so as to communicate with the sodium chlorite storage unit 200. The end of the sodium chlorate supply pipe 220 and the end of the sulfuric acid supply pipe 320 connected to communicate with the sulfuric acid storage unit 300 is a funnel shape of the top of the reaction tube 140 installed in the reactor 100, respectively. It is formed to supply sodium chlorite and sulfuric acid, and in the center of the reaction tube 14 to supply outside air to the bubble cap 160 at the bottom through the air supply pipe 180, the reaction tank (100) Chlorine dioxide produced in the It is described that chlorine dioxide water can be generated in a configuration such that it is discharged together with the flow rate flowing rapidly in the spinner 400.

However, in the prior art 3 configured as described above, the diameter of the funnel-shaped reaction tube 140 installed in the reaction tank 100 is formed in a much larger diameter than the sodium chlorite supply pipe 220 and the sulfuric acid supply pipe 320. The chlorine dioxide gas generated in the reaction tank 100 by the suction action generated in the aspirator 400 is sucked into the aspirator 400 through the discharge pipe 110 in the reaction tank 100. Since the degree of vacuum does not increase, the sodium chlorite solution and the sulfate solution stored in each of the sodium chlorite storage unit 200 and the sulfuric acid storage unit 300 are thus sodium chlorite supply pipe 220 and sulfuric acid supply pipe 320. The supply of the funnel to the top of the reaction tube 140 is not made smoothly, the air is not well supplied to the air supply pipe 180 has been shown as a problem.

Therefore, since the prior art 3 cannot generate chlorine dioxide smoothly with the technical contents described in the patent publication, zinc is formed using the air pump 500 in the technical configuration of the prior art 3 as shown in FIG. The first air supply pipe 501 is connected to the sodium chlorite storage unit 200, and the second air supply pipe 502 is sulfuric acid so as to supply air to each of the sodium carbonate storage unit 200 and the sulfuric acid storage unit 300. As a method of connecting to the storage unit 300, the chlorine dioxide water generator is used to improve its structure.

By the way, the chlorine dioxide generator with improved structure as described above is the sodium chlorite storage unit by the air pressure by the air supplied to each of the sodium chlorite storage unit 200 and the sulfuric acid storage unit 300 through the air pump 500 The sodium chlorite solution and the sulfate solution stored in each of the 200 and the sulfuric acid storage unit 300 are supplied in a funnel shape at the top of the reaction tube 140 through the sodium chlorite supply pipe 220 and the sulfuric acid supply pipe 320, respectively. Since the action is excessively made, there is a problem that the chlorine dioxide component generates a chlorine dioxide water of more than 30ppm or more of the allowable limit prescribed by the Food and Drug Administration.

Meanwhile, according to the prior art 2, although the first supply part 240 and the second supply part 340 are respectively formed in the sodium chlorite supply pipe 220 and the sulfuric acid supply pipe 320 in the drawing (see FIG. 7), In addition, a detailed description of how the first and second supply units 240 and 340 perform in what configuration is not disclosed, and the first and second supply units 240 ( The configuration of 340 may not be controlled to supply an appropriate amount of chlorine dioxide gas to drinking water because the supply amounts of sodium chlorite and sulfuric acid could not be adjusted.

Patent Registration Publication No. 10-1162535 (Jun. 28, 2012) Patent Registration Publication No. 10-1092818 (Notice of Dec. 06, 2011) Patent Registration Publication No. 10-1824731 (Jan. 26, 2018)

The present invention has been proposed to solve the above-mentioned problems in the prior art, which is generated by the air supplied to the mixed liquid storage container in a state in which the sodium chlorite aqueous solution and the hydrochloric acid aqueous solution are mixed in the mixed liquid storage container. Chlorine dioxide water used as a disinfectant can be prepared by mixing chlorine dioxide gas generated by the reaction by stirring with air bubbles in drinking water. Especially, chlorine dioxide water having a chlorine dioxide component of 10 ppm or less is produced to be harmless to human body. In order to provide students with lunch at elementary schools, they can disinfect vegetables and sanitarily clean dishes so that students can be sanitarily safe. To make it available It is a leaving invention.

The present invention as a means for pursuing the above object,

In a chlorine dioxide production apparatus consisting of a sodium chlorite solution storage container for storing sodium chlorite solution, a hydrochloric acid solution storage container for storing the hydrochloric acid solution, and a mixed solution storage container for the mixed solution of the sodium chlorite solution and aqueous hydrochloric acid solution In

The chlorine dioxide water production apparatus,

The sodium chlorite solution storage container, the hydrochloric acid solution storage container, and the mixed solution storage container are respectively installed and stored in a lower state inside the case body.

Sodium chlorite aqueous solution pumping diagram pump configured to intermittently pump a predetermined amount of sodium chlorite solution stored in the sodium chlorite aqueous solution storage container to the mixed liquid storage container on the inner upper portion of the case body, and the hydrochloric acid. The hydrochloric acid solution pumping diagram pump for intermittently pumping a certain amount of hydrochloric acid solution stored in the aqueous solution storage container to the mixed solution storage container is installed in a state separated from each other.

The case body is formed in a structure in which a drinking water supply pipe installed to receive drinking water from the outside and a sterilization water discharging pipe installed to discharge chlorine dioxide to the outside are connected in a U shape.

The mixed liquid storage container is connected to a compressor for sucking and compressing external air, and is provided with a supply hose for supplying compressed air, and compressed air supplied from a supply hose at an end of the supply hose installed to be inserted into the bottom of the mixed liquid storage container. Is connected to the two-way air outlet for discharging in two directions,

The drinking water supply pipe and the sterilization water discharge pipe installed to be formed inside the case body are connected to a venturi tube, and the venturi tube sucks chlorine dioxide gas generated from the mixed liquid storage container and flows at a high flow rate through the venturi tube. Characterized in that the injector is connected to the gas discharge hose for mixing the chlorine dioxide gas in the water is formed.

In addition, each of the sodium chlorite solution pumping diagram pump and hydrochloric acid solution pumping diagram pump are operated intermittently, the pumping operation is repeated for 5 to 10 seconds after the operation to stop for 30 to 60 seconds It is characterized in that configured to.

In addition, the suction end of the suction hose connected to the suction port of the sodium chlorite solution pumping diagram pump is connected in a state of being immersed in the sodium chlorite solution stored in the sodium chlorite solution storage container, The discharge end of the discharge hose is characterized in that it is inserted into the upper portion of the mixed solution storage container so as to discharge the sodium chlorite solution from the inner top of the mixed solution storage container.

In addition, the suction end of the suction hose connected to the suction port of the hydrochloric acid solution pumping diagram pump is connected to the state of being immersed in the hydrochloric acid solution stored in the hydrochloric acid solution storage container, the discharge end of the discharge hose connected to the discharge port It is characterized in that the insertion is connected to the inner upper portion of the mixed liquid storage container to discharge the hydrochloric acid solution from the inner upper portion of the mixed liquid storage container.

In addition, a U-shaped connecting portion connecting the drinking water supply pipe and the sterilization water discharging pipe is formed with a solenoid valve for opening and closing the drinking water supply pipe for supplying drinking water, and supplying compressed air to the solenoid valve and the mixed liquid storage container. Compressor for is characterized in that configured to work in conjunction with each other.

According to the present invention, the apparatus for producing chlorine dioxide is configured to repeat the operation of stopping the pumping operation for a certain time after the pumping operation for a certain time intermittently the diagram pump for sodium chlorite aqueous solution pump and the hydrochloric acid solution pumping Therefore, in the mixed liquid storage container, sodium chlorite solution and aqueous hydrochloric acid solution are stored by a certain amount. Also, since the drinking water supply pipe is connected to the water supply pipe, the drinking water supplied to the drinking water supply pipe through the water supply pipe during the opening operation of the solenoid valve. The chlorine dioxide water is produced because the chlorine dioxide gas generated in the mixed liquid storage container is sucked through the gas discharge hose connected to the injector while the flow rate is increased in the venturi tube and mixed with the drinking water passing through the venturi tube. Discrete Manufactured In Device Chlorine water contains only 8 to 10 ppm of chlorine dioxide in drinking water, which is within the limits of the standards prescribed by the Korea Food and Drug Administration. Therefore, it is safe and hygienic. It has the effect of making it available.

In addition, the present invention can sterilize and disinfect the plant cultivated by the method of spraying chlorine dioxide discharged to the disinfectant disinfectant discharge pipe to the plant cultivated in the plant cultivation farm, as a disinfectant disinfectant pipe to protect the grass in golf course By spraying the discharged chlorine dioxide water, it is effective to sterilize the grass of the golf course while protecting the surrounding environment of the golf course.

1 is a front view of an apparatus for producing chlorine dioxide for explaining the present invention,
2 is a plan view of the chlorine dioxide water production apparatus of the present invention,
3 and 4 is a cross-sectional view of the operating state of the chlorine dioxide water production apparatus of the present invention,
5 is an exploded view of the main components of the chlorine dioxide water production apparatus of the present invention,
Figure 6 is a perspective view of the installation state of the sodium chlorite solution pumping diagram pump and hydrochloric acid solution pumping diagram pump of the present invention.
7 and 8 are the prior art

Detailed embodiments of the chlorine dioxide water production apparatus according to the present invention will be described in detail with reference to the accompanying drawings.

Reference numeral 1 denotes a case main body. A mixed liquid storage container 2 in which the sodium chlorite solution and the hydrochloric acid solution are mixed and stored in the same ratio at the lower side of the case main body 1, and the sodium chlorite solution are stored. The aqueous sodium chloride solution storage container (3) and the aqueous hydrochloric acid solution storage container (4) in which the aqueous hydrochloric acid solution is stored are respectively installed and stored.

In addition, the shelf 5 formed on the upper side of the case main body 1 has a printed circuit board 50 having various electrical and electronic parts and the like installed therein to control the chlorine dioxide production apparatus electrically and electronically. The shelf (5) is provided with a sodium chlorite solution pumping diagram (6) and a hydrochloric acid solution pumping diagram pump (7) for intermittently pumping the sodium chlorite solution.

In addition, the front surface of the case main body 1 is provided with an operation time measurement display unit 11, a current measurement display unit 12, a lighting display unit 13, etc. for measuring the operation time, one side of the case body 1 On the upper right side of the drawing, a blower fan 14 is formed, and on the other side (left side of the drawing), a one-touch switch 15 is provided for turning on and off the power supply.

In addition, one side of the case body 1 is connected to an external water pipe (not shown) so that the drinking water supply pipe (8a) receiving drinking water and the sterilization water discharging pipe (8b) for discharging chlorine dioxide are protruded. Each of the drinking water supply pipes 8a and the sterilized water discharging pipes 8b is inserted into the case body 1 and connected to each other by a U-shaped connection part 8c.

In addition, the U-shaped connection portion (8c) is formed with a venturi tube (9a) connecting the drinking water supply pipe (8a) and sterilization disinfection water discharge pipe (8b), the drinking water supply pipe (8a) in the U-shaped connection portion (8c) ), A solenoid valve 9b for opening and closing is provided.

In addition, a portion of the venturi tube 9a connecting the drinking water supply pipe 8a and the sterilization water discharging pipe 8b is installed with the injector 9 wrapped therein, and the injector 9 has a gas discharge hose 90. The discharge end 92 is connected, the suction end 91 of the gas discharge hose 90 is configured to be connected to the upper portion of the mixed liquid storage container (2).

Features of the present invention, the sodium chlorite solution pumping diagram pump (6) and hydrochloric acid solution pumping diagram pump (7) each of the intermittent pumping operation for a certain time and then stop the pumping operation again for a certain time By repeating the operation, the sodium chlorite solution and the hydrochloric acid solution stored in the sodium chlorite solution storage container (3) and the hydrochloric acid solution storage container (4) are each pumped by a predetermined amount and stored in the mixed solution storage container (2). And the chlorine dioxide gas generated in the mixed liquid storage container 2 by the suction force generated in the venturi tube 9a is mixed with the drinking water flowing through the venturi tube 9a to the sterilizing water discharging tube 8b. It is configured to be able to produce chlorine dioxide water as a means to discharge.

To this end, the suction end 62a of the suction hose 62 connected to the suction port 61 of the sodium chlorite aqueous solution pumping pump 6 is stored in the sodium chlorite aqueous solution storage container 3. The discharge end 64a of the discharge hose 64 connected to the outlet 63 of the diagram for pumping the sodium chlorite solution 6 is connected to be immersed in the sodium chlorate solution, and the mixed liquid storage container ( It is connected to discharge sodium chlorite solution from the inner upper part of 2).

In addition, the suction end 72a of the suction hose 72 connected to the suction port 71 of the hydrochloric acid aqueous solution pump pump 7 is immersed in the hydrochloric acid aqueous solution stored in the aqueous hydrochloric acid storage container 4. The discharge end 74a of the discharge hose 74 connected to the discharge port 73 is connected to discharge the hydrochloric acid aqueous solution from the inner upper portion of the mixed liquid storage container 2.

And the shelf (5) is equipped with a compressor 20 for injecting external air into the mixed liquid storage container (2), the compressor (20) is connected to the supply hose 21 for supplying compressed air The suction end 21a of the supply hose 21 is connected to the compressor 20, and the discharge end 21b of the supply hose 21 is inserted into the mixed liquid storage container 2 to store the mixed liquid storage container. It is connected to the two-way air outlet 21c inserted in the recessed part 22 formed in the inner bottom of (2).

The compressor 20 is configured to interlock with the solenoid valve 9b.

For example, when the solenoid valve 9b is opened, the compressor 20 is operated on to supply suction air to the supply hose 21 by inhaling and compressing external air, and the solenoid valve 9b is operated. When the closing operation the compressor 20 is configured to be off (off) operation.

Therefore, when the compressed air sucked and compressed by the ON operation of the compressor 20 is supplied to the suction end 21a of the supply hose 21 and discharged to the discharge end 21b, it is formed at the two-way outlet 21c. Air bubbles are generated by the compressed air discharged to the two outlets (not shown), and the air bubbles are stirred in the sodium chlorite solution and the hydrochloric acid solution stored in the mixed solution storage container 2. Accordingly, the sodium chlorite component and the hydrochloric acid component react with each other to generate chlorine dioxide gas, and the generated chlorine dioxide gas is stored in the state of being collected in the upper portion of the mixed liquid storage container 2. .

The chlorine dioxide gas stored in the upper portion of the mixed liquid storage container (2) is the mixed liquid storage container (2) by the air pressure that the air bubble discharged through the two-way outlet (21c) is collected in the upper portion of the mixed liquid storage container (2) ) Is pressurized into one end 91 of the gas discharge hose 90 inserted into the upper portion of the inner side, and the chlorine dioxide gas pressurized into the one end 91 is venturi tube 9a through the other end 92. Inhaled and mixed in the drinking water passing through at a high flow rate is configured to be discharged to the sterilization disinfection water discharge pipe (8b) with the drinking water.

Each of the sodium chlorite solution pumping diagram pump 6 and the hydrochloric acid solution pumping diagram pump 7 was pumped for 5 to 10 seconds, stopped for 30 to 60 seconds, and then pumped again. It is configured to repeat the stopping operation afterwards.

The reason for limiting the pumping operation time and the pumping stop time of each of the sodium chlorite aqueous pump pumping diagram 6 and the hydrochloric acid aqueous pumping diagram pump 7 as described above is that the pumping operation time is 10 seconds or more or If the stop time is 30 seconds or less, there is a concern that the chlorine dioxide component level defined by chlorine dioxide as sterilized water will be higher than the specified value.In addition, if the pumping operation time is 5 seconds or less or the pumping stop time is 60 seconds or more, It is preferable to limit the pumping operation time to 5 to 10 seconds and the pumping stop time to 30 to 60 seconds because the chlorine component value may fall short of the prescribed value of the sterilizing water, resulting in problems such as poor sterilization effect.

On the other hand, a cap stopper (a) (b) (c) on the upper portion of each of the mixed solution storage container (2), sodium chlorite aqueous solution storage container (3), the aqueous solution of hydrochloric acid solution (4) is screwed, The cap cap (a) (b) (c) can be drained by a method of opening and closing the screw type or it can be supplied by a predetermined amount.

In addition, a main power switch 16 is installed inside the case body 1 to supply and cut off power to the chlorine dioxide production device. The one-touch switch 15 drives and operates the chlorine dioxide production device. It is configured to act to stop.

The operation of the present invention configured as described above will be described.

First, the sodium chlorite solution stored in the sodium chlorite solution storage container 4 is mixed in a mixing ratio of 92 to 94% (weight) of water and 6 to 8% (weight) of sodium chlorite, and the sodium chlorite solution storage container. Filled with (4), the aqueous hydrochloric acid solution stored in the aqueous hydrochloric acid storage container (4) is mixed in a mixing ratio of water 90 to 92% (weight), hydrochloric acid 8 to 10% (weight) and the aqueous hydrochloric acid storage container (4 ), The mixed liquid storage container (2) is mixed with a mixing ratio of water 97-99% (weight), sodium chlorite 0.5-1.5% (weight), hydrochloric acid 0.5-1.5% (weight) The concave portion 22 formed at the bottom of (2) is to be filled in a small amount that can be filled.

As described above, when the solenoid valve 9b is opened while the aqueous solution is stored in each of the storage containers 2, 3, and 4, the compressor 20 is turned on at the same time, and the sodium chlorite The aqueous solution pumping diagram pump 6 and the hydrochloric acid solution pumping diagram pump 7 are operated intermittently, so that the mixed solution storage container 2 is stored in the sodium chlorite aqueous solution storage container 3. The aqueous hydrochloric acid solution stored in the aqueous solution and the aqueous hydrochloric acid storage container 4 is stored in a state in which a predetermined amount is injected into the mixed liquid storage container 2.

Subsequently, when the solenoid valve 9b is opened, drinking water is supplied to the drinking water supply pipe 8a connected to the water supply pipe, and at the same time, the compressor 20 is turned on so that the compressor 20 is turned on. The air bubble generated when the compressed air is discharged through the supply hose 21 to the two-way air outlet 21c provided in the recess 22 formed at the bottom of the mixed liquid storage container 2 is mixed with the mixed liquid. Since the sodium chlorite solution and the hydrochloric acid solution stored in the storage container 2 are stirred, the chlorine dioxide gas is generated by the reaction between the sodium chlorite component of the sodium chlorite solution and the hydrochloric acid component of the aqueous hydrochloric acid solution. The state is stored in the storage container (2).

As described above, the chlorine dioxide gas stored in the mixed liquid storage container 2 is applied to the air pressure generated inside the mixed liquid storage container 2 by the air bubble generated by the compressed air discharged from the two-way air outlet 21c. Is pressurized into one end 91 of the gas discharge hose 90 inserted into the mixed liquid storage container 2, and the chlorine dioxide gas pressurized into the one end 91 of the gas discharge hose 90. While being sucked into the drinking water flowing at a high flow rate from the venturi tube 9a through the other end 92, it is discharged together with the drinking water to the sterilizing water discharging pipe 8b.

The chlorine dioxide component is discharged into the drinking water discharged to the disinfectant disinfectant water discharge pipe 8b so as to discharge chlorine dioxide to 30 ppm or less, which is an allowable standard prescribed by the Ministry of Food and Drug Safety.

In addition, the present invention is to open the solenoid valve (9b) and supply drinking water to the drinking water supply pipe (8a) connected to the water supply pipe to discharge the chlorine dioxide water to the disinfectant disinfection water discharge pipe (8b). Each of the chlorate nitrate solution pumping diagram pump 6 and the hydrochloric acid solution pumping diagram pump 7 is configured to repeat the operation of pumping for 5 to 10 seconds and stopping for 30 to 60 seconds at the same time. The chlorine dioxide water in which the chlorine dioxide component is mixed to 30 ppm or less (specifically, about 10 to 15 ppm) can be prepared into the disinfectant sterilization water discharge pipe 8b. At this time, the chlorine dioxide gas is reacted with hydrochloric acid and sodium chlorite The reaction scheme to generate is as follows.

5NaCLO ₂ + 4HCL → 4CLO ₂ + 5NaCL + 2H ₂ O

Therefore, each of the sodium chlorite solution pumping diagram pump 6 and the hydrochloric acid solution pumping diagram pump 7 of the present invention intermittently operates simultaneously to store the sodium chlorite solution stored in the sodium chlorite solution storage container 3. The aqueous hydrochloric acid solution stored in the aqueous solution and the aqueous hydrochloric acid storage container 4 is supplied to the mixed liquid storage container 2 in small amounts, respectively, while the drinking water is supplied to the drinking water supply pipe 8a to the venturi tube 9a. The chlorine dioxide gas generated in the mixed liquor storage container 2 is discharged while being mixed with the drinking water passing through the venturi tube 9a by the pressure reduction phenomenon generated by the flow rate rapidly passing through the sterilization water discharging pipe 8b. Chlorine dioxide water mixed with chlorine is discharged.

That is, the sodium chlorite solution pumping diagram pump (6) and hydrochloric acid solution pumping diagram pump (7) because the pumping operation for 5 to 10 seconds and then repeats the operation to stop for 30 to 60 seconds In the mixed liquid storage container (2), not only the sodium chlorite solution and the aqueous hydrochloric acid solution are stored in small amounts, but also in the mixed liquid storage container (2) due to the reduced pressure caused by the flow rate of the drinking water passing through the venturi tube 9a quickly. The produced chlorine dioxide gas is press-fitted into one end 91 of the gas discharge hose 90 and suction-mixed into drinking water flowing rapidly through the venturi tube 9a through the other end 92 and discharged into the sterilization disinfection water discharge tube 8b. .

Therefore, the chlorine dioxide water in which chlorine dioxide gas is mixed with drinking water is discharged into the sterilization disinfection water discharge pipe 8b.

As described above, the present invention is an intermittent pumping operation of the sodium chlorite solution pumping diagram pump 6 and the hydrochloric acid solution pumping diagram pump 7 to store the sodium chlorite solution storage container 3 and the aqueous solution of hydrochloric acid. The sodium chlorite solution and the hydrochloric acid solution stored in each of the containers 4 are pumped and supplied to the mixed solution storage container 2 in small amounts. In the mixed solution storage container 2, the sodium chlorite component and the chlorine component react. The generated chlorine dioxide gas is pressurized into one end 91 of the gas discharge hose 90 and discharged to the other end 92. At this time, the drinking water supplied to the drinking water supply pipe 8a passes through the venturi tube 9a at a high flow rate. The chlorine dioxide gas discharged to the other end 92 of the gas discharge hose 90 is sucked into the drinking water passing quickly through the venturi tube 9a by the decompression occurring when the gas is discharged. Since chlorine dioxide is discharged into the sterilizing water discharging pipe 8b, chlorine dioxide water is discharged into the disinfecting sterilizing water discharge pipe 8b. It is excellent, so it is effective to sanitize and disinfect when washing vegetables at school restaurants, etc., and can be used to sanitize various plants grown on farms growing plants, or to sterilize lawns on golf courses. There are some useful effects, such as using them by accident.

1: Case body 11: Operation time measurement display
12: current measurement display unit 13: lighting display unit
14: blower fan 15: one-touch switch
16: power switch 2: mixed liquid storage container
20: compressor 21: supply hose
20a, 20b: Inlet and outlet 20c: 2-way air outlet
22 recessed portion 3: sodium chlorite aqueous solution storage container
4: aqueous hydrochloric acid storage container 5: shelf
50: printed circuit board
6: Diagram pump for pumping sodium chlorite aqueous solution
7: Diagram pump for aqueous hydrochloric acid solution
61,71: suction port 62,72: suction hose
63,73 outlet 64,74 outlet hose
62a, 72a: suction end 64a, 74a: discharge end
8a: drinking water supply pipe 8b: sterilization water discharge pipe
9: injector 9a: venturi tube
9b: Solenoid Valve 90: Gas Discharge Hose
91: first 92: the other end

Claims (5)

In a chlorine dioxide production apparatus consisting of a sodium chlorite solution storage container for storing sodium chlorite solution, a hydrochloric acid solution storage container for storing the hydrochloric acid solution, and a mixed solution storage container for the mixed solution of the sodium chlorite solution and aqueous hydrochloric acid solution In
The chlorine dioxide water production apparatus,
The sodium chlorite solution storage container, the hydrochloric acid solution storage container, and the mixed solution storage container are respectively installed and stored in a lower state inside the case body.
Sodium chlorite aqueous solution pumping diagram pump configured to intermittently pump a predetermined amount of sodium chlorite solution stored in the sodium chlorite aqueous solution storage container to the mixed liquid storage container on the inner upper portion of the case body, and the hydrochloric acid. The hydrochloric acid solution pumping diagram pump for intermittently pumping a certain amount of hydrochloric acid solution stored in the aqueous solution storage container to the mixed solution storage container is installed in a state separated from each other.
The case body is formed in a structure in which a drinking water supply pipe installed to receive drinking water from the outside and a sterilization water discharging pipe installed to discharge chlorine dioxide to the outside are connected in a U shape.
The mixed liquid storage container is connected to a compressor for sucking and compressing external air, and is provided with a supply hose for supplying compressed air, and compressed air supplied from a supply hose at an end of the supply hose installed to be inserted into the bottom of the mixed liquid storage container. Is connected to the two-way air outlet for discharging in two directions,
The drinking water supply pipe and the sterilization water discharge pipe installed to be formed inside the case body are connected to a venturi tube, and the venturi tube sucks chlorine dioxide gas generated from the mixed liquid storage container and flows at a high flow rate through the venturi tube. An apparatus for producing chlorine dioxide, characterized in that the injector is connected to the gas discharge hose for mixing the chlorine dioxide gas in the water is formed.
The method of claim 1,
Each of the sodium chlorite solution pumping diagram pump and the hydrochloric acid solution pumping diagram pump are operated intermittently, but the pumping operation is configured to repeat the operation of stopping for 30 to 60 seconds after operating for 5 to 10 seconds. Chlorinated dihydrogen water production apparatus, characterized in that.
The method of claim 1,
The suction end of the suction hose connected to the suction port of the sodium chlorite solution pumping diagram pump is connected to a state of being immersed in the sodium chlorite solution stored in the sodium chlorite solution storage container and connected to the discharge port. The discharging end of the chlorine dioxide water production apparatus, characterized in that connected to the upper portion of the mixed solution storage container so as to discharge the sodium chlorite solution from the inner top of the mixed solution storage container.
The method of claim 1,
The suction end of the suction hose connected to the suction port of the hydrochloric acid solution pumping diagram pump is connected to a state of being immersed in the hydrochloric acid solution stored in the hydrochloric acid solution storage container, and the discharge end of the discharge hose connected to the discharge port is a mixed solution. Apparatus for producing chlorine dioxide, characterized in that the insertion is connected to the inner upper portion of the mixed liquid storage container to discharge the hydrochloric acid solution from the inner upper portion of the storage container.
The method of claim 1,
A U-shaped connection portion connecting the drinking water supply pipe and the sterilization water discharging pipe is formed with a solenoid valve for opening and closing the drinking water supply pipe for supplying drinking water, and a compressor for supplying compressed air to the solenoid valve and the mixed liquid storage container. Chlorine dioxide water production apparatus, characterized in that configured to work in conjunction with each other.

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