KR20030065060A - The essence system which uses the chlorine dioxide and that control method - Google Patents

Abstract

The present invention sterilizes harmful bacteria, viruses and impurities dissolved in water using water-soluble chlorine dioxide (ClO₂) to be used as water used in fisheries, drinking water supplied to each household, and cooling water for thermal power plants and nuclear power plants. The present invention relates to a raw water purification system using chlorine dioxide and a method thereof, comprising: first, second and third tanks in which hydrochloric acid (HCl), sodium hypochlorite (NaOCl) and sodium chlorite (NaClO₂) are stored; Hydrochloric acid (HCl) from the first, second and third tanks to remove bacteria, microorganisms and other toxic substances (heavy metals, iron, manganese, etc.) contained in the water supplied through the water (raw water) supply pipe. A mixer for mixing chlorine dioxide by mixing sodium hypochlorite (NaOCl) and sodium chlorite (NaClO₂) with water (raw water); A flow meter for checking the current flow rate value while identifying a state where water and chlorine dioxide are mixed in the mixer; PI which checks the amount of chemicals contained in the first, second and third tanks, changes the checked amount of data into a digital signal and checks the amount of chlorine dioxide currently mixed with water in real time. Seed (PLC); The amount of chlorine dioxide in which the hydrochloric acid (HCl), sodium hypochlorite (NaOCl) and sodium chlorite (NaClO₂) medicines stored in the first, second and third tanks are mixed, and the chlorine dioxide is mixed with water A central computer that receives the digital signal data calculated by PLC and displays it on a monitor so that an administrator can check it; And detecting means for re-detecting whether or not the concentration of the chemical contained in the purified water controlled by the flow meter is appropriate, and adjusting the concentration of the chemical (ppm) based on the detected data. , Water (raw water) and drinking water purified by chlorine dioxide improves the reliability of water, and completely sterilizes and disinfects the bacteria contained in the water to further protect the health of the drinker. It can bring an effect.

Description

The essence system which uses the chlorine dioxide and that control method}

The present invention relates to a system for purifying raw water, and more particularly, using water-soluble chlorine dioxide (ClO₂) to disinfect and disinfect harmful bacteria, viruses, and impurities contained in water to be used in fish farms, and spread to households. The present invention relates to a raw water sterilization and disinfection system using chlorine dioxide, which can be used as drinking water, cooling water of a thermal power plant, and a nuclear power plant.

In general, water (raw water) is disinfected to purify and sterilize water. There are three types of treatments: chlorine disinfection, ozone disinfection, and ultraviolet disinfection. In Korea, chlorine disinfection is used for cost reasons.

Purifying water (raw water) roughly involves the steps of water intake, chemical treatment, coagulation and flocculation, sedimentation, filtration, disinfection and storage.

The withdrawal step is to draw water through the source of water, at this time to take the water while filtering the various contaminants and the like with the water.

In the chemical treatment step, chemicals such as aluminum sulfate and chlorine are introduced into the water (raw water) supplied through the water intake step, and the bacteria contained in the water are killed by the injected chemical and the suspended solids in the water are precipitated.

The flocculation step is a flocculation step in which a drug such as aluminum sulfate is flocculated in response to suspended solids and suspended matter in water, and in the process of flocculation, the flocculation process is entangled with other suspended particles to form a larger floc. Is done.

In the precipitation step, the aggregated solid material and water flow into the settling basin to precipitate the aggregated solid material.

In the filtration step, water and solids are separated from the sedimentation basin, and the water passes through a filtration tank composed of sand and gravel layers to remove residual suspension in water.

The filtered water is again sterilized, disinfected or disinfected, with the addition of some chlorine or other chemicals, which sterilize the bacteria remaining in the water and make it safe while transported to people. . In addition, in the case of using groundwater as raw water, only the above disinfection step may be performed.

The purified water through the disinfection step is stored in a reservoir called a tank or a purified water, and chlorine is spread throughout the water to be completely disinfected during the storage time, and the stored water is returned to each household or through a water supply pipe. It is supplied to offices and the like.

The use of chlorine in the process of purifying the water is to continuously maintain the safety of the purified water due to the rapid filtration, and to reduce the time and cost of purifying the water.

However, when water is purified using chlorine as described above, there is a disadvantage in that the smell of strong chlorine odor from the water.

In addition, the purified water is supplied to each home or business office through a supply pipe, and in the process, chlorine disinfection is inevitably caused by trihalomethanes (THMs) and other chlorine compounds in order to ensure the safety of the water. Among the THMs, ChCl3 (Chlorofrom) is known to have strong carcinogenicity in animal experiments, and therefore has the disadvantage of being carcinogenic to humans.

In addition, the haloacetic acid (HAAS) produced as a by-product of the chlorine is a highly toxic substance. The US Environmental Protection Agency (EPA) regulated 60ppbs in 2001 and 30ppb in 2002 (2 stage). There is a situation.

In addition, the water disinfected using chlorine as described above is a case where most common bacteria and pathogenic bacteria are alive, there is also a problem such as water-borne infection occurs when a person drink.

In addition, the current water used as cooling water, such as power plants are used to purified water or river water, the problem caused by this is that the water used as cooling water discharges the water from the cooling, discharged water As a result, water and a slightly high temperature are used as it is, so animal and phytoplankton inhabit the side of the suction pipe that sucks the coolant, and small fish and shellfish gather to eat it. There is a problem that these fish and shellfish are sucked together through a suction pipe to suck the water, which damages the cooling system of the power plant.

In addition, a manpower for removing shellfish and the like inhabiting the suction pipe is quite necessary, and the labor cost by the manpower has also been considerably spent.

In order to solve the above problems, the present invention sterilizes various bacteria that are not completely sterilized by chlorine in a waterworks office so that users who use tap water can use clean water, and also purify water through the present invention. An object of the present invention is to provide a water purification system using chlorine dioxide and a control method thereof, which can be used and trusted by a user.

The present invention for achieving the above object is the first, second, third and fourth tanks are stored in hydrochloric acid (HCl) and sodium hypochlorite (NaOCl) and sodium chlorite (NaClO₂) and chlorine dioxide (ClO₂); Hydrochloric acid, sodium hypochlorite and sodium chlorite are supplied to electricity from the first, second and third tanks to remove bacteria, heavy metals and other toxic substances contained in the water supplied through the water (raw water) supply pipe. A mixer to generate chlorine dioxide by automatic mixing; A flow meter which checks the current flow rate while identifying a state in which water, hydrochloric acid, sodium hypochlorite and sodium chlorite are mixed in the mixer; PI which checks the amount of chemicals contained in the first, second and third tanks, changes the checked amount of data into a digital signal and checks the amount of chlorine dioxide currently mixed with water in real time. Seed (PLC); The amount of chlorine dioxide mixed with the chemicals stored in the first, second, and third tanks, and the ratio state in which chlorine dioxide is mixed with water are applied with digital data calculated by the PLC, and displayed on the monitor. A central computer that allows administrators to verify this; And detecting means for re-detecting whether or not the concentration of the chemical contained in the purified water controlled by the flow meter is appropriate and adjusting the concentration of the chemical to the appropriate concentration (ppm) based on the detected data. Provides a water purification system using chlorine dioxide.

In addition, the first, second, third, fourth tank according to the invention is characterized in that the ultrasonic counter for measuring the amount of the stored medicine (hydrochloric acid, sodium hypochlorite, sodium chlorite, chlorine dioxide) is further installed. .

In addition, the flow meter according to the present invention includes a power lamp that is turned on so that the user can check the power-on state; A first flow control meter for adjusting the input amount of hydrochloric acid (HCl); A second flow control meter for adjusting the input amount of sodium hypochlorite (NaOCl); A third flow control meter for adjusting the input amount of sodium chlorite (NaClO 2); A flow controller for adjusting the flow rate of chlorine dioxide (ClO₂) formed by mixing the hydrogen chloride, sodium hypochlorite and sodium chlorite; A speed controller controlling an emission amount by adjusting a rotation speed of the inverter; On / off means consisting of a power switch for turning on / off power, a switching switch for manually and automatically switching, and a control switch (on / off switch) for manually using a solenoid valve, a water pump, and a metering pump; And an emergency stop switch for stopping all operations by cutting off all output power.

In addition, the detection means according to the present invention receives a data applied from the PLC (PLC) to measure the concentration of water and chlorine dioxide is mixed to adjust the appropriate concentration PPM (ppm); When the concentration of chlorine dioxide mixed in order to adjust to the appropriate concentration PPM (ppm) in response to the signal of the controller is low, the chlorine dioxide is further added to adjust to the appropriate concentration PPM (ppm), the chlorine dioxide mixed with the water Inverter for controlling the chlorine dioxide when the concentration of the high; And an analyzer for determining whether the concentration of chlorine dioxide dissolved in water finally discharged through the supply pipe through the inverter is an appropriate concentration.

In addition, step S1 of determining whether the current water purification system according to the present invention is automatic mode; Step S2 of determining whether the system is in the manual mode if the current mode is not in the automatic mode; Measure the level of the 1st, 2nd, 3rd and 4th tanks, the concentration of the ideal chlorine mixed through the mixer, and the concentration of the chlorine dioxide contained in the water, and transmit the data to the central computer through the PLC. Step S3 to allow the user to grasp the current state; Step S4 of determining whether the preset data has been changed in the central computer by the data; S5 step of introducing a chlorine dioxide in the appropriate concentration in the water by the preset data when there is no change of data through the step S4; S6 step of injecting chlorine dioxide into the water by the existing data when there is no change in the preset data through the step S4; S7 step of detecting whether the concentration of chlorine dioxide introduced into the water through the step S6 is an appropriate concentration through the analyzer; S8 step of discharging if the concentration detected through the analyzer through the step S7 is an appropriate concentration; Step S9 of calculating data if the concentration of chlorine dioxide added to the water in step S7 is not a proper concentration and applying data to the central gum computer through PL (PLC); S10 step of discharging water after further inputting the medicine through the metering pump in order to adjust the concentration of chlorine dioxide introduced into the water to the appropriate concentration after applying the data through the step S9; In step S1, if the manual mode, in step S10 to determine whether the automatic mode is off in the system; S11 step of turning on the solenoid valve so that the water for making chlorine dioxide flows when the automatic mode is turned off through the step S10; Step S13 of inputting a target value of chlorine phosphate input through the inverter when the solenoid valve is turned on through step S11; Step S14 of determining whether the level of the fourth tank in which the chlorine dioxide applied through the step S13 is stored is high or high; S15 step of stopping the production of chlorine dioxide by turning off the water pump when the water level is high or high to stop the introduction of water; Step S16 of continuously turning on the water pump so as to continuously create chlorine dioxide when the water level is high or below high in step S14; Step S17 of determining whether the fourth tank level in which the chlorine dioxide generated through the step S16 is stored is low or low; Step S18 of turning off the purified water by turning off the metering pump when the water level is low or low in step S17; And controlling quantitative pumps to produce chlorine dioxide only to an appropriate level when the water stored in the fourth tank through the step S17 is at a low or low level. The water purification system using chlorine dioxide is controlled. Provide a method.

In addition, the PLC according to the present invention converts an electrical signal applied through the analyzer into data, interfaces the converted data to the central computer, and simultaneously applies data to a controller to turn on the inverter and the metering pump. It is characterized in that the chlorine dioxide is introduced into the water at an appropriate concentration by intermittent / off.

In addition, the PLC according to the present invention is to determine whether the water level is high, high, low, low to the controller to maintain the amount of chlorine dioxide stored in the fourth tank to the controller It is characterized in that the data is applied to the central computer and the status can be continuously determined by applying the data.

In addition, the monitor of the central computer according to the present invention, the amount of chemicals stored in the first, second, and third tanks so that the user can receive the data received from the PLC and can be confirmed by the user, the current operating state (automatic, manual ), The on / off state of the valve of the floor meter, the control value of the inverter, the concentration controlled in real time, and the final flow rate discharged are characterized by displaying the graph and number.

In addition, the central computer according to the present invention is the input of the maximum value for each drug, the current flow value input, the target value input of the inverter in the manual mode, automatic, manual mode conversion, flow meter valve on / off operation, manual solenoid valve, The on / off of the water pump and the metering pump is input from a long distance to modify the set value, and through this control the purified water system is characterized in that the concentration of dioxide to be discharged to the appropriate concentration.

1 is a configuration of the water purification system using chlorine dioxide according to the present invention.

2 is a front view showing a flow meter according to the present invention.

Figure 3 is a flow chart showing a process of purifying through the water purification system using chlorine dioxide according to the present invention.

* Code Description for Main Drawing *

10a: 1st tank 10b: 2nd tank

10c: 3rd tank 10d: 4th tank

11a, 11b, 11c, 11d: ultrasonic counter

20: mixer 30: flow meter

31: power lamp 32: the first flow control meter

33: second flow rate meter 34: third flow rate meter

35 display 36 speed controller

37: on / off means 37a: power switch

37b: changeover switch 37c: control switch

40: PLC 50: Central Computer

60 detection means 61 controller

62: Inverter 63: Analyzer

64: metering pump 70: water pump

80: solenoid valve

Hereinafter, a water purification system using chlorine dioxide according to the present invention and a control method thereof will be described in detail with reference to the accompanying drawings.

1 is a block diagram of a water purification system using chlorine dioxide according to the present invention, Figure 2 is a front view showing a flow meter according to the present invention.

As shown in FIG. 1, the present invention mainly includes first, second and third tanks and fourth tanks 10a, 10b, 10c, and 10d, a mixer 20, a flow meter 30, and a PLC. (PLC) 40, central computer 50, and detection means 60.

The first, second, third and fourth tanks 10a, 10b, 10c, and 10d store different chemicals, respectively, wherein the first tank 11a is hydrochloric acid and the second tank 11b is sodium hypochlorite. The third tank 11c stores sodium chlorite and the fourth tank 11d stores chlorine dioxide.

And, the upper portion of the first, second, third tank, fourth tank (10a, 10b, 10c, 10d) of the drug (hydrochloric acid, sodium hypochlorite, sodium chlorite, chlorine dioxide) stored therein Ultrasonic counters 11a, 11b, 11c, and 11d for measuring the quantity are further installed.

The mixer 20 is water, sea water, or raw water (natural water) and the first, second, third tank, fourth tank 10a, 10b, 10c, Mix the chemical stored in 10d) and mix chlorine dioxide with the water.

The flow meter 30 checks in real time when water and chemicals are mixed by the mixer 20 and checks the current flow rate.

The flow meter 30 is provided with a case 30a, and a power lamp 31 which is turned on so that a user can check a state in which power is applied and a state in which the power is not applied is installed in the upper part of the case 30a. .

A first flow control meter 32, a second flow control meter 33, and a third flow control meter 34 are installed at predetermined positions of the front surface of the case 30a, which are hydrochloric acid, sodium hypochlorite, and sodium chlorite. This is to adjust the dosage.

The flow controller 35 and the speed controller 36 are installed in the downward direction of the first, second, third, and flow control meters 32, 33, and 34 installed on the front of the case 30a. The controller 35 is for controlling the flow rate of hydrochloric acid, sodium hypochlorite, sodium chlorite, and the speed controller 36 adjusts the rotational speed of the inverter 62 to be described later to release the drug (chlorine dioxide) Adjust

In addition, the display 35 displays the concentration of the chemicals (chlorine dioxide) contained in the finally discharged water so that the user can check the bottom of the first, second, and third flow control meters 32, 33, and 34. Direction is installed.

On / off means 37 and emergency stop button 38 are provided in the downward direction of the first, second and third flow controllers 32, 33, 34 and the speed controller 36.

The on / off switch 37 includes a power switch 37a for interrupting power, a switching switch 37b for automatically and manually converting a system drive in a downward direction of the power switch 37a, and the power switch ( 37a) and a control switch 37c for controlling the water pump, the solenoid valve 80, and the metering pump 64 during manual driving are provided on one side of the changeover switch 37b.

The emergency switch 38 is installed in the downward direction of the control switch 37 to stop when an emergency occurs.

The PLC 40 checks the amount of each medicine contained in the first, second, third, and fourth tanks 11a, 11b, 11c, and 11d, and checks the checked amount of data. At the same time, it converts to digital signal and checks the amount of chlorine dioxide currently mixed with water in real time.

The central computer 50 is the amount of each medicine stored in the first, second, third tank, fourth tank (11a, 11b, 11c, 11d), the first, second, third tank , The amount of chlorine dioxide stored and mixed in (11a, 11b, 11c), the fourth tank (11d), monitors the rate of mixing the chlorine dioxide with water and receives digital data calculated by the PLC (40). (51) so that the administrator can check it.

In addition, the detection means 60 is re-detected whether or not the concentration of the drug contained in the purified water controlled by the flow meter 30 is appropriate, and the concentration of the drug at the appropriate concentration PPM (ppm) based on the detected data. Adjust

The detecting means includes a controller 61, an inverter 62, an analyzer 63, a metering pump 64, and the controller 61 is data applied from the PLC 40. Received by measuring the concentration of water and chlorine dioxide is mixed to adjust the appropriate concentration PPM (ppm), the inverter 62 is the PPM of the chlorine dioxide contained in the water (ppm) through the controller 61 is the appropriate concentration When the PPM is lower than or equal to ppm, chlorine dioxide is added by controlling the metering pump 64 to adjust to an appropriate PPM.

The analyzer 63 measures whether the concentration of chlorine dioxide dissolved in water finally discharged through the supply pipe P through the metering pump 64 through the inverter 62 is an appropriate concentration.

3 is a flowchart illustrating a process of purifying water through a water purification system using chlorine dioxide according to the present invention. As shown in FIG. 3, the present invention is a step S1 for determining whether the current water purification system is in an automatic mode, and the present step. In step S2 of determining whether the current system is in the manual mode or the automatic mode through the water level of the first, second, third, and fourth tanks 10a, 10b, 10c, and 10d, the mixer 20 S3 step of measuring the concentration of the ideal chlorine mixed through, the concentration of chlorine dioxide contained in the water by sending data to the central computer 50 through the PLC 40 (PLC) so that the user can determine the current state In step S4 of determining whether the preset data has been changed in the central computer 50 by the data, and when there is no change of the data through the step S4, the chlorine dioxide in the appropriate concentration of the chemical is set in the water by the preset data. When there is no change of the preset data through the step S5 and the step S4, S6 step of introducing chlorine dioxide into the water by the existing data, and the concentration of chlorine dioxide introduced into the water through the S6 step is appropriate S7 step of detecting whether the concentration through the analyzer (63), and S8 step of discharging if the concentration detected through the analyzer (63) through the step S7 and the concentration of the chlorine dioxide introduced into the water in step S7 If the concentration is not appropriate, the data is calculated by applying the data to the central computer 50 through the PLC (PLC) 40, and the concentration of chlorine dioxide added to the water after applying the data through the S9 step In order to adjust the concentration to the appropriate concentration through the dosing pump (64) and further performs the step S10 to discharge the water.

The steps are to automatically produce chlorine dioxide to sterilize the tap water. In this step, it can be linked to a manual or semi-automatic state (operation state using a central computer), which is as follows.

If the manual mode in the step S1, the step S10 to check whether the automatic mode is off in the current system, and if the automatic mode is turned off through the step S10, the solenoid valve 80 so that water for making chlorine dioxide flows in When the solenoid valve 80 is turned on through the step S11 and the step S11, the step S13 of inputting a target value of chlorine phosphate input through the inverter 62 and the step S13 are applied. In step S14 of determining whether the level of the fourth tank 10d in which chlorine dioxide is stored is high or high, and stopping the water input by turning off the water pump 70 when the level is high or high. In step S15 to stop the production of chlorine dioxide, and in the step S14, if the water level is high or high or below the high water pump 70 to continuously create chlorine dioxide Step S16 to turn on, and step S17 to determine whether the level of the fourth tank (10d) in which the chlorine dioxide produced by the step S16 is stored low or low, and if the water level is low or low in step S17 If the water stored in the fourth tank through step S18 to turn off the fixed water pump 64 by turning off the fixed water pump 64 and the step S17, if the water level is low or more than the low-low control the metering pump 64 to only the appropriate level S18 step of producing chlorine dioxide is performed.

As described above, the operation of the water purification system using chlorine dioxide according to the present invention is as follows.

First, when power is applied to the system, the power lamp 31 installed on the front of the flow meter 30 is turned on so that the user can determine whether power is applied to the system.

The water is supplied to the mixer 20 through the supply pipe (P) while power is supplied to the system, and is stored in the first, second, and third tanks (10a, 10b, 10c) at the same time the water is supplied. The medicine is supplied to the mixer 20 to mix the medicine first.

In the mixer 20, when the chemicals supplied from the first and second third tanks 10a, 10b, and 10c are added to the supplied water and mixed, chlorine dioxide (ClO₂) is generated.

Then, when the water and the respective medicines are mixed through the mixer 20, the flow meter 30 controls the current flow rate while controlling based on the set data of each medicine.

In addition, the first, second, third, and fourth tanks are provided by the ultrasonic level gauges 11a, 11b, 11c, and 11d installed above the fourth tanks 10a, 10b, 10c, and 10d. The amount of chemicals stored in the three tanks and the fourth tanks 10a, 10b, 10c, and 10d is checked in real time, and the checked electrical signal is applied to the PLC 40.

The electrical signal applied to the PLC 40 is converted into data to be applied to the central computer 50 so that the user can check the current state, and each drug mixed with water in the mixer 20 The electrical signal applied from the flow meter 30 for controlling the amount of injected is applied to the PLC 40 as described above.

The PLC 40 does not apply only the data values of the ultrasonic level gauges 11a, 11b, 11c to the central computer 50 as described above, but controls the mixer 20 in real time in the flow meter 30. Data to be displayed on the monitor 51 of the central computer 50.

Then, the water supplied through the flow meter 30 is applied to the controller 61 of the detection means 60, and the controller 61 measures the chlorine dioxide contained in the water to be applied to determine whether or not the concentration state is high. If it is low to determine whether the low, the control the metering pump (63) through the inverter 62 is further injected into the discharged water at this time using the data of the analyzer (63) to finally measure the concentration.

In addition, the water supplied through the metering pump 63 is again measured by the analyzer 63, the concentration of chlorine dioxide, and if the measured value is less than the appropriate concentration PPM (ppm) electrical signal to the controller 61 Since the concentration of chlorine dioxide contained in the water discharged by the current is low, a signal to add more medicine is applied.

In the controller 61, chlorine dioxide is further introduced to drive the metering pump through the inverter 62 by an electrical signal to obtain an appropriate concentration PPM, and at the same time, an electrical signal applied by the analyzer 63. Is applied to the PLC 40, and the PLC 40 converts the applied electrical signal into data and applies the data to the central computer 50 so that the numerical value is displayed on the monitor 51 so that the user can finally Make sure you know the concentration of chlorine dioxide in your water.

In addition to measuring the concentration of chlorine dioxide contained in the above and finally discharged water, the monitor 51 indicates whether it is automatically driven or manually driven, and the current solenoid valve 80, water pump 70, Displays whether the metering pump 64 is on or off, and also displays the current flow rate, that is, how much the amount of chemicals mixed with the water is currently being introduced, and simultaneously displays the maximum flow rate and the proper flow rate. Check if the chemical is injected at the proper flow rate.

In addition, the cycle of the inverter 62 is identified to determine whether the chemical is currently injected through the metering pump 64, and the appropriate concentration of chlorine dioxide contained in the finally discharged water as described above is analyzed by the analyzer (ppm). Through 63, the value of the appropriate concentration PPM (ppm) is measured in real time and displayed on the monitor 51 of the central computer 50.

As described above, by killing the bacteria contained in the raw water, purified tap water, etc., there is an advantage in drinking water with confidence to those who finally drink it.

By using the purified water system using chlorine dioxide according to the present invention, water (raw water), people who drink water purified by chlorine dioxide can give faith in water, and sterilize even pathogenic bacteria contained in water Therefore, the health of the drinker brings further effects.

In the system of the present invention, it is also possible to purify the seawater, which purifies the water used as the cooling water of the power plant, such as nuclear power plants, so that the plankton, etc. do not live in the water, thereby preventing the secondary food chain that may occur secondary Cooling water has the effect of solving problems such as destruction of the equipment of the power plant.

Claims (9)

First, second, third, and fourth tanks of hydrochloric acid (HCl), sodium hypochlorite (NaOCl), sodium chlorite (NaClO₂), and chlorine dioxide (ClO₂); Hydrochloric acid, sodium hypochlorite and sodium chlorite are supplied to electricity from the first, second and third tanks to remove bacteria, heavy metals and other toxic substances contained in the water supplied through the water (raw water) supply pipe. A mixer to generate chlorine dioxide by automatic mixing; A flow meter which checks the current flow rate while identifying a state in which water, hydrochloric acid, sodium hypochlorite and sodium chlorite are mixed in the mixer; PI which checks the amount of chemicals contained in the first, second and third tanks, changes the checked amount of data into a digital signal and checks the amount of chlorine dioxide currently mixed with water in real time. Seed (PLC); The amount of chlorine dioxide mixed with the chemicals stored in the first, second, and third tanks, and the ratio state in which chlorine dioxide is mixed with water are applied with digital data calculated by the PLC, and displayed on the monitor. A central computer that allows administrators to verify this; And detecting means for re-detecting whether or not the concentration of the chemical contained in the purified water controlled by the flow meter is appropriate and adjusting the concentration of the chemical to the appropriate concentration (ppm) based on the detected data. Automation device. The method of claim 1, Electrical automation device, characterized in that the first, second, third, fourth tank is further provided with an ultrasonic counter for measuring the amount of stored drugs (hydrochloric acid, sodium hypochlorite, sodium chlorite, chlorine dioxide); The method of claim 1, The flow meter is a power lamp that is turned on so that the user can check the power-on state; First flow control meter to control the amount of hydrochloric acid (HCl) A second flow control meter for adjusting the input amount of sodium hypochlorite (NaOCl); A third flow control meter for adjusting the input amount of sodium chlorite (NaClO 2); A flow controller for adjusting the flow rate of chlorine dioxide (ClO₂) formed by mixing the hydrogen chloride, sodium hypochlorite and sodium chlorite; A speed controller controlling an emission amount by adjusting a rotation speed of the inverter; Power switch to turn on / off the power, manual and automatic change over switch, An on / off means composed of a solenoid valve, a control switch (on / off switch) for manually using the water pump and the metering pump; And Chlorine dioxide purification system comprising an emergency stop switch to stop all the operation of all output power. The method of claim 1, The detecting means includes a controller for receiving the data applied from the PLC (PLC) to measure the concentration of water and chlorine dioxide is mixed to the appropriate concentration PPM (ppm); When the concentration of chlorine dioxide mixed in order to adjust to the appropriate concentration PPM (ppm) in response to the signal of the controller is low, the chlorine dioxide is further added to adjust to the appropriate concentration PPM (ppm), the chlorine dioxide mixed with the water Inverter for controlling the chlorine dioxide when the concentration of the high; And And an analyzer for determining whether the concentration of chlorine dioxide dissolved in water finally discharged through the supply pipe through the inverter is an appropriate concentration. In the method of purifying water, Step S1 of determining whether the current water purification system is in an automatic mode; Step S2 of determining whether the system is in the manual mode if the current mode is not in the automatic mode; Measure the level of the 1st, 2nd, 3rd and 4th tanks, the concentration of the ideal chlorine mixed through the mixer, and the concentration of the chlorine dioxide contained in the water, and transmit the data to the central computer through the PLC. Step S3 to allow the user to grasp the current state; Step S4 of determining whether the preset data has been changed in the central computer by the data; S5 step of introducing a chlorine dioxide in the appropriate concentration in the water by the preset data when there is no change of data through the step S4; S6 step of injecting chlorine dioxide into the water by the existing data when there is no change in the preset data through the step S4; S7 step of detecting whether the concentration of chlorine dioxide introduced into the water through the step S6 is an appropriate concentration through the analyzer; S8 step of discharging if the concentration detected through the analyzer through the step S7 is an appropriate concentration; Step S9 of calculating data if the concentration of chlorine dioxide added to the water in step S7 is not a proper concentration and applying data to the central gum computer through PL (PLC); S10 step of discharging water after further inputting the medicine through the metering pump in order to adjust the concentration of chlorine dioxide introduced into the water to the appropriate concentration after applying the data through the step S9; In step S1, if the manual mode, in step S10 to determine whether the automatic mode is off in the system; S11 step of turning on the solenoid valve so that the water for making chlorine dioxide flows when the automatic mode is turned off through the step S10; Step S13 of inputting a target value of chlorine phosphate input through the inverter when the solenoid valve is turned on through step S11; Step S14 of determining whether the level of the fourth tank in which the chlorine dioxide applied through the step S13 is stored is high or high; S15 step of stopping the production of chlorine dioxide by turning off the water pump when the water level is high or high to stop the introduction of water; Step S16 of continuously turning on the water pump so as to continuously create chlorine dioxide when the water level is high or below high in step S14; Step S17 of determining whether the fourth tank level in which the chlorine dioxide generated through the step S16 is stored is low or low; Step S18 of turning off the purified water by turning off the metering pump when the water level is low or low in step S17; And If the water stored in the fourth tank through the step S17 is low or more than the low level control the quantitative pump to control the water purification system using chlorine dioxide, characterized in that it comprises a step S18 to produce only chlorine dioxide up to the appropriate level Way. The method of claim 5, The PLC converts an electrical signal applied through the analyzer into data, interfaces the converted data to the central computer, and simultaneously applies data to a controller to interrupt the on / off of the inverter and the metering pump. A method for controlling a water purification system using chlorine dioxide, wherein chlorine dioxide is introduced into water at an appropriate concentration. The method of claim 5, In order to keep the amount of chlorine dioxide stored in the fourth tank appropriately, the PLC determines whether the water level is high, high, low or low, and applies data to the controller. Apparatus for controlling the water purification system using chlorine dioxide, characterized in that by applying the data to the central computer to determine the status continuously. The method of claim 5, The central computer monitor has the amount of chemicals stored in the first, second, and third tanks, the current operating state (automatic, manual), and the valve of the floor meter so that the user can receive the data received from the PC and confirm the data. The on / off state of the control, the control value of the inverter, the concentration controlled in real time, the final flow rate discharged by using a graph and a number, characterized in that the control method using a chlorine dioxide. The method according to claim 5 or 8, The central computer inputs the maximum value of each chemical, input the current flow value, input the target value of the inverter in manual mode, automatic, manual mode conversion, flow meter valve on / off operation, manual solenoid valve, water pump, metering pump A method for controlling a water purification system using chlorine dioxide, characterized in that to modify the set value by inputting the data on / off at a long distance, and to control the water purification system to discharge the concentration of the dioxide into the appropriate concentration.