KR19990073708A - Hypochlorous acid production system - Google Patents

Abstract

An electrode device in which an electrode rod and a hollow cylindrical electrode cylinder surrounding the electrode rod are welded to an electrode rod is provided in the longitudinal direction of the electrolytic cell in a hollow electrolytic chamber not provided with a diaphragm, A plurality of electrolyte inflow and distribution holes are formed in the inlet block, and usually one to two inlet inflow holes are formed in the outlet block, and salt (NaCl) water and a small amount Of HCl is introduced into the electrolytic bath to be next electrolyzed and then sent to a first dilution tank for diluting with water, and then a second dilution for bending and discharging the effluent discharged from the first dilution tank After the second dilution tank, the PH sensor protection device and the PH sensor are installed to detect the PH of the effluent water, (HOCl) solution in a pH range of PH 5 to 7.5 and a target PH range selected in accordance with the intended use, and subjected to a drain treatment when the pH is outside the target pH range. The hypochlorous acid (HOCl ) ≪ / RTI &

Description

Hypochlorous acid production system

The present invention relates to a hypochlorous acid generation system for effectively sterilizing an object hygienically from a drinking water such as a water supply to foods and medicines.

In particular, the present invention relates to a system for producing hypochlorous acid (HOCl), which is non-toxic but remarkably improved in bactericidal effect using an electrolytic cell having no diaphragm.

That is, according to the present invention, there is provided an electrode device in a hollow electrolytic cell in which a diaphragm is not provided, and an electrode block is provided in the longitudinal direction of the electrolytic bath. Upper and lower portions of the electrode rod are provided with an inlet block and an outlet block, In the block, a plurality of electrolyte inflow holes are formed, and one or two outlets are usually formed in the outlet block. The electrolytic solution is composed of NaCl and a small amount of HCl through the inlet of the electrolytic cell and is introduced into the electrolytic cell and then sent out to the diluting bath after the electrolysis. A first dilution tank for introducing water into the next step of the electrolytic cell is provided and a second dilution tank for treating the effluent discharged from the first dilution tank is provided, Next, the PH sensor protection device and the PH sensor are installed to detect the PH of the effluent. If the effluent basically reaches the target PH range within the range of PH 5 to 7.5, it is sent to the hypochlorous acid (HOCl) (HOCl) production system. The present invention also relates to a system for producing hypochlorous acid (HOCl).

In the case of the prior art, the generated chlorine primarily electrolysis of salt for the disinfection of the various water, including tap water, drinking water, food (Cl ₂₎ in addition to hypochlorite (NaOCl), sodium hypochlorite, calcium (CaCOCl · 2H ₂ O) Has been chlorinated in the form of. In addition, hypochlorous acid (HOCl) has high sterilization effect, but it has never been used for mass production and production, and there has been no proposal of a method and apparatus for efficiently using the method and apparatus.

In addition, the chlorine (Cl ₂ ) gas is inconvenient to store, and since it is obtained and used in the gas phase, it is very dangerous to handle and has a disadvantage that the sterilizing effect is also remarkably low.

Accordingly, the present inventors have found that hypochlorous acid (HOCl) has already been used as an acute toxicity test, an eye irritation test, a skin primary irritation test, a skin cumulative irritation test, a sensory test , Cytotoxicity test, and mutagenicity test. Therefore, hypochlorous acid has been reported to be an effective, economical and safe manufacturing method and apparatus for industrial use.

Generally, chlorine gas (Cl ₂ ) is produced by electrolysis of sodium chloride (NaCl), which is a main component such as salt. When brine is electrolyzed in an electrolytic cell,

2NaCl + H ₂ O 2NaOH + Cl ₂ ↑ + H ₂ ↑, where the chlorine gas produced reacts with water to produce Cl ₂ , HOCl, OCl ^­ Depending on the hydrogen ion concentration index (PH), Cl ₂ , HOCl, OCl ^­ The rate of existence of the That is, usually PH is Cl ₂ in acid, HOCl in neutral, and OCl ^­ In the form of. Among them, in the case of hypochlorous acid (HOCl), OCl ^­ As well as sterilizing power.

Cl ₂ + H ₂ O + H ⁺ + Cl ^­

HOCl H ⁺ +

Ca (OCl) ₂ .2H ₂ O? Ca ⁺ + 2OCl ^-

The change in concentration of HOCl according to the above pH is shown in FIG.

From this graph, it can be seen that the most effective chlorine (HOCl) existing ratio is high when PH is 5 to 7. Especially, at PH = 6, almost 100% HOCl is present. For example, at PH = 9, the HOCl form is 4%, OCl ^­ Since the form exists at about 96%, it is most effective to adjust the pH to about 6.0 in order to make it exist in the form of HOCl close to 100%. Since the chlorine gas is toxic and easily volatilizes into the air, the pH of the solution is adjusted to be within the range of 5 to 7.5, in consideration of the presence of HOCl close to 100% in order to increase the sterilizing effect while being nontoxic. And it is possible to produce a stable HOCl form by adjusting the appropriate PH range according to the use purpose.

On the other hand, HOCl in the water inhibits the metabolism reaction of microorganisms by the oxidation reaction and the chlorination reaction, resulting in a sterilizing effect.

That is, R-H + HOCl → R-OH + HCl (oxidation reaction)

RH + HOCl → R-Cl + H ₂ O (chlorination reaction)

Furthermore, this hypochlorous acid (HOCl) is less toxic and more safe than glutaral, popidon, ethanol, cresol, and phenol, which are currently used as fungicides.

On the other hand, Cl ₂ gas, which must be manufactured and stored in the previous stage for producing HOCl, is very dangerous because it is very inconvenient to handle and store and is in the form of gas. In addition, CaCl ₂ · Ca (OCl) _{2 ·} 2H ₂ O (commercially available product at a concentration of 33 to 38%) is obtained by adding Ca (OCl ₂ ) → ₂ Ca ^{+ ­} NaOCl is also reduced in water to Na → Na ⁺ + OCl ^­ OCl ^­ The sterilization power is reduced to about 1/80 compared with the HOCl form. Therefore, in order to increase the sterilizing effect, ^­ The concentration is more than 4000ppm, which leads to toxicity.

1 is a schematic flow chart of a hypochlorous acid generation system according to the present invention

Fig. 2 is a detailed explanatory view of the electrolytic bath of Fig. 1

3 is a schematic cross-sectional explanatory view of the second dilution bath structure

Fig. 4 is an internal explanatory diagram of the PH sensor protection device according to the present invention

5 is a graph showing a correlation between the hydrogen ion concentration index (PH) and the effective chlorine presence rate

Description of the Related Art [0002]

1: electrolytic cell 2: first dilution tank

3: Second dilution tank 4: PH sensor protection device

4 ': PH sensor 5: Solenoid valve

6: electrolyte inflow conduit 7: dilution water (water) supply conduit

8: effluent supply conduit 9: hypochlorous acid discharge conduit

9 ': drain pipe 15: electrode device

The present invention provides a method and apparatus for producing HOCl having a high sterilizing power at a low concentration. In order to produce Cl ₂ gas by electrolyzing NaCl, the pH of the NaCl electrolysis apparatus effluent is adjusted to 5.0 to 7.5 And the reaction product of the anode and the cathode is mixed and diluted by providing an electrolytic cell having no diaphragm in order to achieve this, so that the HCl produced in the anode in the electrolytic cell and the NaOH generated in the cathode are neutralized by neutralization , And the pH of the electrolyzed effluent by adding HCl to the influent water is adjusted to 5.0 to 7.5, particularly preferably to 7, so that Cl ₂ produced in the cathode of the electrolyzer exists in the form of highly sterilizing HOCl .

In the structure of the electrolytic cell, as shown in FIGS. 1 and 2, an electrolytic cell having no diaphragm at the center in the vertical direction is provided. In this electrolytic cell, both side portions corresponding to the outer wall of the electrolytic cell are positive (+), (-) and the NaCl-dissolved sodium liquid is injected into the electrolytic bath or the electrolytic cell through the metering pump as shown in FIG. 1, when the NaCl is dissolved in the water, Na ^{+ +} Cl ^- is dissociated into, Na ⁺ is moved toward the negative electrode, Cl ^­ Moves to the anode. Na ⁺ ions move toward the negative electrode is the one emitting ion (e ^-) Cl ^_ the anode side take Na ⁺ ions to fill the outermost electron 1 is a Na (sodium metal). That is, Na ⁺ + e → Na (reduced). The Na produced here reacts with water (H ₂ O) in a dilution tank to produce H ₂ gas and NaOH. That is, Na + H ₂ O → 1/2 H ₂ ↑ + (Na ⁺ + OH ^- )

On the other hand, Cl ^- shifted to the anode side is the outermost electron e ^­ ) To one side and Cl (chlorine radical). This chlorine radical (Cl) reacts to become chlorine gas Cl ₂ . In other words,

Cl ^- → Cl + e ^­ (Moving to the anode)

Cl ^­ + · Cl → Cl: Cl ( Cl 2)

The chlorine gas Cl ₂ produced at this time reacts with water in a mixed dilution tank to form hypochlorous acid HOCl and hydrochloric acid HCl.

Cl ₂ + H ₂ O (water) → HOCl + H ⁺ + Cl ^­

This picture shows that Cl: Cl + From O

And HOCl is generated.

As one embodiment, a system according to the present invention will be described in more detail with reference to the accompanying drawings.

1 is a device for producing hypochlorous acid (HOCl) according to the present invention. Reference numeral 4 denotes a PH sensor protection device. Reference numeral 4 denotes a PH sensor. Reference numeral 5 denotes a solenoid valve. Reference numeral 5 denotes a solenoid valve. Lt; / RTI >

As shown in detail in FIG. 2, the electrolytic cell 1 shown in FIG. 1 has an electrode rod 15 at the center in the upper and lower longitudinal direction in the middle thereof, and a hollow cylindrical cylindrical electrode An elongated electrode device 15 is provided in the form of a metal enclosing the electrode rod while being welded to the electrode rod in a concentric manner. The electrode device is made of metal, and its surface 15, 15 ' Thereby forming a large surface area. The lower part of the electrode device is supported by a fixed block 17 and is supported by blocks 11, 12, 19 and the like at the inlet or outlet so as to close the electrolyzer 1 around the electrode device 15 and its upper part is also supported by blocks 11 ' .

When the bactericidal agent enters the food, the pH of the food is changed to 6.5 or 7.5, so that it is most ideal to neutralize the pH of the food when the PH is alkaline or acidic. The pH is adjusted to 6.5 to 7.5. That is, the target PH is set and adjusted according to the purpose.

When the electrolytic solution introduced through the inlet 18 passes through the plurality of inlet / outlet holes 13 to supply the electrolytic solution to the outer spaces of the electrode devices 15 and 15 ', the electrolytic solution flows into the electrolytic cell evenly by the plurality of distributor holes 13, . When electrolytic solution mainly composed of salt water and a small amount of HCl is electrolyzed in the electrolytic cell 1, the electrolytic solution and gas are discharged to the outflow distribution hole 14 formed in the outlet block 11 'of the upper part of the electrolytic cell 1 of FIG. 14 is usually made of one or two holes. This is to suppress the sudden leakage of the electrolytic solution having a high concentration in the electrolytic cell.

The brine entering upward through the lower inlet 18 of the electrolytic cell 1 is electrolyzed and the Na ⁺ ions and the Cl ^­ Ions, and they are combined with water in the electrolytic cell 1 to react with water to produce NaOH and HCl, and are diluted with water (H ₂ O) supplied from the conduit 7 to the dilution chamber or the first dilution tank And PH is detected in the PH sensor 4 'through the PH sensor protection device 4.

When the effluent enters from the first dilution tank 2 into the second dilution tank 3, the internal structure as shown in FIG. 3 is bent in the direction of the arrow by the partitioning of the pipe 33, the bar 34, So that the evenly electrolyzed effluent is mixed and diluted before entering the next PH sensor protection device 4. That is, in the second dilution tank, a plurality of bars (not shown) are formed in a plurality of bars 35 that support bars in a plurality of longitudinal directions and are spaced apart at regular intervals, Thereby allowing the space between the pipe 33 and the bar 34 to pass through the liquid hole of the partition 35 and the space between the pipes 33 and 34 in the direction of the arrow as shown in Fig. At this time, the passage positions of the partition liquid passages are formed such that the positions of the liquid passages between the adjacent partition walls are not parallel to each other but in a zigzag position, so that the effluent water L is allowed to flow while being bending motion.

The PH sensor protection device 4 may damage the PH sensor 4 'next to the next due to the outlet pressure of the effluent in the PH sensor protection device 4 or may induce the PH sensor measurement result inaccurately, As shown in the figure, the partition wall 46 is provided, and at least one other outlet 45 'is provided at the upper part of the PH sensor protecting device to bypass the partition wall 46, thereby relieving the excessive impact on the PH sensor 4' Thereby protecting the PH sensor 4 '.

Next, the PH sensor 4 'measures the pH of the effluent.

When the PH detected by the PH sensor 4 'reaches the target PH range within the range of 5 to 7.5, the effluent that has passed through the second dilution tank 3 and the PH sensor 4' is normally sent to the hypochlorous acid (HOCl) solution When the effluent detected by the PH sensor is out of a certain range of pH, it flows out to the drain 9 'and is usually disposed of. The selection of such outflow water treatment in accordance with the PH range is usually made by three-way operation of the PH sensor 4 'and the solenoid valve 5 and the like. Of course, the PH sensor 4 'and the central control unit PCC (not shown) are connected to each other and connected to the central control unit and the electrolyte solution tank 10 (NaCl and a small amount of HCl: omitted) for adjusting the PH of the effluent detected by the PH sensor The amount of NaCl and HCl supplied is controlled by pH. Of course, the range of the target PH varies depending on whether the object to be treated is a food, a disinfectant, or a medicine.

The hypochlorous acid generation system according to the present invention can produce a new hypochlorous acid (HOCl) that is accurate and very convenient to work, and can provide hypochlorous acid such as safe food and medicine for a sterilizing effect, I have come to.

Claims (2)

An electrode device 15 formed by welding an electrode 15 and a hollow cylindrical electrode barrel 15 'surrounding the electrode bar 15 to the electrode bar 15 in a hollow electrolytic cell 1 without a diaphragm is provided in the longitudinal direction of the electrolyzer, 11 ', 12, 17, 19, and the like for supporting and sealing the electrode device 15, respectively. In addition, a plurality of electrolyte inflow and distribution holes 13 are formed in the inlet block 11, An electrolytic solution composed mainly of salt (NaCl) and a small amount of HCl is introduced into the electrolytic cell 1 through electrolytic solution inlet 18 and then electrolyzed to form electrolytic solution 1, which is then diluted with water. And a second dilution tank 3 for bending and discharging the electrolytically treated effluent discharged from the first dilution tank 2. The second dilution tank 3 is provided with PH Sensor Protection Device 4 And the PH sensor 4 'to detect the pH of the effluent water. When the effluent water basically reaches the target PH range selected in accordance with the intended use within the range of PH 5 to 7.5, it is subjected to the collection treatment with hypochlorous acid (HOCl) (HOCl) < / RTI > production system < RTI ID = 0.0 > [5] The apparatus according to claim 1, wherein the second dilution tank is provided with a plurality of bars in the longitudinal direction thereof, and a plurality of liquid chambers are formed in the plurality of compartments, The liquid hypochlorous acid production system in which the position of the liquid pores among the liquids is formed in a zigzag position instead of a parallel position to allow the effluent to flow out while being bent to be diluted uniformly