KR102328706B1 - A generator for chlorine dioxide - Google Patents

Abstract

The present invention relates to an apparatus for producing aqueous chlorine dioxide, which allows production of aqueous chlorine dioxide only when aqueous chlorine dioxide is required, and thus improves the user's convenience. The apparatus for producing aqueous chlorine dioxide includes: an introduction unit to which purified water is introduced; a sodium chlorite-storing unit in which sodium chlorite is stored; a hydrochloric acid-storing unit in which hydrochloric acid is stored; a reaction unit configured to receive the purified water from the introduction unit, to receive the sodium chlorite from the sodium chlorite-storing unit and to receive the hydrochloric acid from the hydrochloric acid-storing unit, and to carry out reaction of the sodium chlorite with the hydrochloric acid to produce chlorine dioxide, which, in turn, is dissolved in the purified water to produce the first aqueous chlorine dioxide; and a mixing unit configured to receive the purified water from the introduction unit and to receive the first aqueous chlorine dioxide from the reaction unit, and to mix the purified water with the first aqueous chlorine dioxide to produce the second aqueous chlorine dioxide.

Description

A generator for chlorine dioxide

The present invention relates to a chlorine dioxide water generator.

Conventionally, chlorine-based disinfectants such as sodium hypochlorite have been most widely used as disinfectants. However, chlorine-based disinfectants generate disinfection by-products (carcinogenic substances such as THMs, HAAs, and HANs), which are harmful to the human body and cause environmental pollution by flowing into sewage after secondary use.

In addition, when the pH of the chlorine-based disinfectant is increased, the sterilization effect is rapidly reduced, and during disinfection, it reacts with an organic compound to cause a substitution reaction, an addition reaction, etc. in addition to the oxidation reaction.

On the other hand, after disinfection with a chlorine-based disinfectant, a phenomenon of re-reproduction of bacteria occurred, and the effect was insignificant in inactivation of protozoa and removal of heavy metals. had a ham

In addition, ozone has been used as a disinfectant in addition to chlorine-based disinfectants, but ozone has been proven to be harmful to the human body and the environment, such as generating a strong, disgusting odor and potentially carcinogenic substances such as bromate.

Therefore, interest in chlorine dioxide has increased to replace disinfectants having the above problems. Chlorine dioxide (ClO2) is a greenish-yellow gas with a unique odor. When cooled, it turns into a yellow-red liquid and is chemically unstable. As it changes into ClO2, ClO3, and Cl, strong oxidizing power appears as a sterilizing effect.

In addition, due to its environmentally friendly properties that are easily decomposed by light, it is in the spotlight as an alternative to chlorine-based disinfectants.

In addition, according to the notification of the Ministry of Environment of Korea (No. 1999-173), chlorine dioxide can be used as a disinfectant when used below 1 ppm under the Drinking Water Management Act. According to the report, the chlorine dioxide production device and the electrolysis 　 chlorine dioxide water can be used as a disinfectant for vegetables and fruits when used below 30ppm.

The reaction equation for generating chlorine dioxide by reacting hydrochloric acid with sodium chlorite is as follows.

As such a conventional chlorine dioxide generator, there is a Korean Patent Registration No. 10-1742544 'Chlorine dioxide production apparatus'.

However, chlorine dioxide has a problem of severe change over time, a difficult process, and difficult storage.

It was devised based on the technical background as described above, and an embodiment of the present invention is to provide a chlorine dioxide water generating device that can generate and use chlorine dioxide water only when it is needed, thereby improving user convenience. do.

In order to achieve the above object, an apparatus for generating chlorine dioxide according to an embodiment of the present invention includes an inlet through which purified water is introduced; Sodium chlorite storage unit in which sodium chlorite is stored; Hydrochloric acid storage unit in which hydrochloric acid is stored; The purified water is supplied from the inlet, the sodium chlorite is supplied from the sodium chlorite storage unit, the hydrochloric acid is supplied from the hydrochloric acid storage unit, the sodium chlorite and hydrochloric acid are reacted to generate chlorine dioxide, and in the purified water a reaction unit for dissolving the chlorine dioxide to generate a first chlorine dioxide water; It may include a mixing unit that receives the purified water from the inlet and receives the first chlorine dioxide water from the reaction unit and mixes the purified water and the first chlorine dioxide water to generate a second chlorine dioxide water.

In addition, a first solenoid valve, a first pressure gauge, and a first pressure reducing valve are disposed between the inlet and the reaction unit, and a second solenoid valve, a second pressure gauge and a second pressure reducing valve are disposed between the inlet and the mixing unit. can be placed.

In addition, a first metering pump, a first back pressure valve, and a first damper are disposed between the sodium chlorite storage unit and the reaction unit, and a second metering pump and a second back pressure valve are disposed between the hydrochloric acid storage unit and the reaction unit. and a second damper, wherein the first back pressure valve lowers the pressure of the sodium chlorite to keep it constant, the second back pressure valve lowers the pressure of the hydrochloric acid to keep it constant, and the first damper and The second damper may prevent damage to the pipe due to pulsation.

In addition, the reaction unit, a reaction space is formed therein, a through hole is formed at the bottom, a fine filter is disposed at the lower end of the reaction space, a plurality of ceramic balls are filled in the reaction space, the inlet, sodium chlorite storage The part and the hydrochloric acid storage part are connected at the top, respectively, to receive the purified water, sodium chlorite and hydrochloric acid, react the sodium chlorite and hydrochloric acid in the reaction space to generate chlorine dioxide, and add the chlorine dioxide to the purified water flowing through the ceramic ball a reaction tank for dissolving the first chlorine dioxide water and discharging it downward through the through hole; and a storage tank connected to the lower portion of the reaction tank and having a storage space communicating with the through hole therein, and receiving and storing the first chlorine dioxide water generated from the reaction tank.

The chlorine dioxide water generating apparatus according to an embodiment of the present invention can generate and use the chlorine dioxide water whose concentration is adjusted only when the chlorine dioxide water is needed through the mixing unit, thereby improving the user's convenience.

1 shows an apparatus for generating chlorine dioxide according to an embodiment of the present invention.
Figure 2 shows the reaction part of the chlorine dioxide water generating apparatus according to an embodiment of the present invention.

Hereinafter, with reference to the accompanying drawings, the embodiments of the present invention will be described in detail so that those of ordinary skill in the art to which the present invention pertains can easily implement them. The present invention may be embodied in many different forms and is not limited to the embodiments described herein. In order to clearly explain the present invention in the drawings, parts irrelevant to the description are omitted, and the same reference numerals are assigned to the same or similar components throughout the specification.

In the present specification, terms such as “comprise” or “have” are intended to designate that a feature, number, step, operation, component, part, or combination thereof described in the specification exists, but one or more other features It is to be understood that it does not preclude the possibility of the presence or addition of numbers, steps, operations, components, parts, or combinations thereof.

1 to 2 , the chlorine dioxide water generating device 10 according to an embodiment of the present invention includes an inlet 100 , a sodium chlorite storage 200 , a hydrochloric acid storage 300 , and a reaction unit. 400 and a mixing unit 500 may be included.

Purified water may be introduced into the inlet 100 . In addition, the inlet 100 may be provided as a filter.

Sodium chlorite storage unit 200 may be stored in sodium chlorite.

Hydrochloric acid may be stored in the hydrochloric acid storage unit 300 .

The reaction unit 400 may receive purified water from the inlet unit 100 , receive sodium chlorite from the sodium chlorite storage unit 200 , and receive hydrochloric acid from the hydrochloric acid storage unit 300 . And, the reaction unit 400 may generate chlorine dioxide by reacting sodium chlorite and hydrochloric acid. In addition, the reaction unit 400 may generate the first chlorine dioxide water by dissolving chlorine dioxide in purified water.

In more detail, the reaction unit 400 may include a reaction tank 410 and a storage tank 420 .

The reaction tank 410 may have a reaction space 410s formed therein, and a through hole 410h formed at a lower end thereof. In addition, the reaction tank 410 may have a fine filter 411 disposed at the lower end of the reaction space 410s, and a plurality of ceramic balls 412 may be filled in the reaction space 410s. In addition, the reaction tank 410 may be supplied with purified water, sodium chlorite and hydrochloric acid by connecting the inlet part 100, the sodium chlorite storage part 200 and the hydrochloric acid storage part 300 to the upper portions, respectively.

And, the reaction tank 410 may generate chlorine dioxide by reacting sodium chlorite and hydrochloric acid in the reaction space (410s). In addition, the reaction tank 410 may dissolve chlorine dioxide in purified water flowing through the ceramic ball 412 and the fine filter 411 to generate a first chlorine dioxide water and discharge it downward through the through hole 410h. Here, the ceramic ball 412 and the fine filter 411 can expand the area of the purified water so that chlorine dioxide can be well dissolved in the purified water.

The storage tank 420 may have a storage space 420s connected to the lower portion of the reaction tank 410 and communicating with the through hole 410h therein. In addition, the storage tank 420 may receive and store the first chlorine dioxide water generated from the reaction tank 410 .

The mixing unit 500 receives purified water from the inlet 100 and receives the first chlorine dioxide water from the reaction unit 400 and mixes the purified water and the first chlorine dioxide water to generate the second chlorine dioxide water. .

In more detail, since the first chlorine dioxide water is provided with a high concentration of chlorine dioxide water, the mixing unit 500 mixes the first chlorine dioxide water with purified water to generate a second chlorine dioxide water that is a low concentration of chlorine dioxide water. can

And, the mixing unit 500 may be provided with a venturi tube or a liquid fertilizer mixer.

Additionally, a first solenoid valve SV1, a first pressure gauge AR1, and a first pressure reducing valve GA1 are disposed between the inlet 100 and the reaction unit 400, and the inlet 100 and the mixing unit ( 500 , the second solenoid valve SV2 , the second pressure gauge AR2 , and the second pressure reducing valve GA2 may be disposed.

Here, the first solenoid valve SV1 may open and close the valve to supply purified water from the inlet 100 to the reaction unit 400 .

In addition, the first pressure gauge AR1 may indicate the pressure of purified water supplied from the inlet 100 to the reaction unit 400 .

Also, when the pressure of the purified water supplied from the inlet 100 to the reaction unit 400 is high, the first pressure reducing valve GA1 may decrease the pressure of the purified water.

Here, the second solenoid valve SV2 may open and close the valve to supply purified water from the inlet 100 to the mixing unit 500 .

In addition, the second pressure gauge AR2 may indicate the pressure of purified water supplied from the inlet 100 to the mixing unit 500 .

In addition, when the pressure of the purified water supplied from the inlet 100 to the mixing unit 500 is high, the second pressure reducing valve GA2 may decrease the pressure of the purified water.

Additionally, a first metering pump JR1, a first back pressure valve BV1, and a first damper DP1 are disposed between the sodium chlorite storage unit 200 and the reaction unit 400, and the hydrochloric acid storage unit 300 ) and the reaction unit 400 , a second metering pump JR2 , a second back pressure valve BV2 , and a second damper DP2 may be disposed.

Also, the first metering pump JR1 may quantitatively transfer sodium chlorite from the sodium chlorite storage unit 200 to the first back pressure valve BV1 and the first damper DP1.

In addition, the first back pressure valve BV1 may lower the pressure of sodium chlorite to keep it constant.

Also, the first damper DP1 may prevent damage to the pipe due to pulsation.

In addition, the second metering pump JR2 may quantitatively transfer hydrochloric acid from the hydrochloric acid storage unit 300 to the second back pressure valve BV2 and the second damper DP2.

In addition, the second back pressure valve BV2 may lower the pressure of hydrochloric acid and maintain it constant.

In addition, the second damper DP2 may prevent damage to the pipe due to pulsation.

As a result, the chlorine dioxide water generating device 10 according to an embodiment of the present invention can be used by the user to generate and use the second chlorine dioxide water whose concentration is adjusted only when the chlorine dioxide water is needed.

Although the present invention has been described through preferred embodiments as described above, the present invention is not limited thereto, and various modifications and variations are possible without departing from the concept and scope of the following claims. Those in the technical field to which it belongs will readily understand.

10: chlorine dioxide water generator
100: inlet 200: sodium chlorite storage unit
300: hydrochloric acid storage unit 400: reaction unit
410: reaction tank 411: fine filter
412: ceramic ball 410h: through hole
410s: reaction space 420: storage tank
420s: storage space 500: mixing part
SV1: 1st solenoid valve AR1: 1st pressure gauge
GA1: first pressure reducing valve JR1: first metering pump
BV1: first back pressure valve DP1: first damper
SV2: 2nd solenoid valve AR2: 2nd pressure gauge
GA2: 2nd pressure reducing valve JR2: 2nd metering pump
BV2: 2nd back pressure valve DP2: 2nd damper

Claims (4)

an inlet through which purified water is introduced;
Sodium chlorite storage unit in which sodium chlorite is stored;
Hydrochloric acid storage unit in which hydrochloric acid is stored;
The purified water is supplied from the inlet, the sodium chlorite is supplied from the sodium chlorite storage unit, the hydrochloric acid is supplied from the hydrochloric acid storage unit, the sodium chlorite and hydrochloric acid are reacted to generate chlorine dioxide, and in the purified water a reaction unit for dissolving the chlorine dioxide to generate a first chlorine dioxide water;
A mixing unit receiving the purified water from the inlet and receiving the first chlorine dioxide water from the reaction unit to mix the purified water and the first chlorine dioxide water to generate a second chlorine dioxide water,
A first solenoid valve, a first pressure gauge, and a first pressure reducing valve are disposed between the inlet and the reaction unit,
A second solenoid valve, a second pressure gauge and a second pressure reducing valve are disposed between the inlet and the mixing unit. an inlet through which purified water is introduced;
Sodium chlorite storage unit in which sodium chlorite is stored;
Hydrochloric acid storage unit in which hydrochloric acid is stored;
The purified water is supplied from the inlet, the sodium chlorite is supplied from the sodium chlorite storage unit, the hydrochloric acid is supplied from the hydrochloric acid storage unit, the sodium chlorite and hydrochloric acid are reacted to generate chlorine dioxide, and in the purified water a reaction unit for dissolving the chlorine dioxide to generate a first chlorine dioxide water;
A mixing unit receiving the purified water from the inlet and receiving the first chlorine dioxide water from the reaction unit to mix the purified water and the first chlorine dioxide water to generate a second chlorine dioxide water,
A first metering pump, a first back pressure valve, and a first damper are disposed between the sodium chlorite storage unit and the reaction unit,
A second metering pump, a second back pressure valve, and a second damper are disposed between the hydrochloric acid storage unit and the reaction unit,
The first back pressure valve lowers the pressure of the sodium chlorite to keep it constant,
The second back pressure valve lowers the pressure of the hydrochloric acid to keep it constant,
The first damper and the second damper are chlorine dioxide water generator to prevent damage to the pipe due to pulsation. an inlet through which purified water is introduced;
Sodium chlorite storage unit in which sodium chlorite is stored;
Hydrochloric acid storage unit in which hydrochloric acid is stored;
The purified water is supplied from the inlet, the sodium chlorite is supplied from the sodium chlorite storage unit, the hydrochloric acid is supplied from the hydrochloric acid storage unit, the sodium chlorite and hydrochloric acid are reacted to generate chlorine dioxide, and in the purified water a reaction unit for dissolving the chlorine dioxide to generate a first chlorine dioxide water;
A mixing unit receiving the purified water from the inlet and receiving the first chlorine dioxide water from the reaction unit to mix the purified water and the first chlorine dioxide water to generate a second chlorine dioxide water,
The reaction unit,
A reaction space is formed inside, a through hole is formed at the bottom, a fine filter is disposed at the lower end of the reaction space, a plurality of ceramic balls are filled in the reaction space, and the inlet part, sodium chlorite storage part and hydrochloric acid storage part are each It is connected to the upper part to receive the purified water, sodium chlorite and hydrochloric acid, react the sodium chlorite and hydrochloric acid in the reaction space to generate chlorine dioxide, and dissolve the chlorine dioxide in purified water flowing through the ceramic ball to dissolve the first dioxide a reactor for generating chlorine water and discharging it downward through the through hole; and
Chlorine dioxide water generating apparatus including a storage tank connected to the lower portion of the reaction tank and having a storage space communicating with the through hole therein, and receiving and storing the first chlorine dioxide water generated from the reaction tank. delete

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