KR102011108B1 - Sodium hypochlorite feeding systerm - Google Patents

Abstract

The present invention relates to a sodium hypochlorite injection system, comprising: a sodium hypochlorite storage tank for storing sodium hypochlorite; a liquid input amount control device for receiving sodium hypochlorite from the sodium hypochlorite storage tank and diluting the same with water to form sodium hypochlorite dilution water; and a dilution water distribution device for distributing the sodium hypochlorite dilution water formed in the liquid input amount control device to a plurality of input points at a uniform concentration and a desired distribution ratio, and supplying the same. The liquid input amount control device comprises: an image flow rate measurement unit connected to the sodium hypochlorite storage tank by a sodium hypochlorite transfer pipe and transmitting a flow rate of the sodium hypochlorite moving along the sodium hypochlorite transfer pipe at a long distance through an image; a water supply pipe for supplying water; a vacuum control type ejector for mixing sodium hypochlorite supplied via the image flow rate measurement unit and the water supplied via the water supply pipe by vacuum pressure and moving sodium hypochlorite dilution water at a long distance by vacuum pressure; and a liquid chemical injection unit coupled between the sodium hypochlorite transfer pipe and the vacuum control type ejector and controlling an input amount of sodium hypochlorite with respect to the water.

Description

Precise control of injection amount and easy injection of dilution water {SODIUM HYPOCHLORITE FEEDING SYSTERM}

The present invention relates to a sodium hypochlorite injection system, and more particularly to a sodium hypochlorite injection system having a high-efficiency automatic liquid dosing device that is easy to control the injection amount and equal distribution of dilution water.

 In general, the disinfection method applied to the water and sewage disinfection process uses a method of disinfecting chlorine to vaporize liquefied chlorine with a vaporizer and supplying it to the raw water to be treated through an ejector. However, chlorine disinfection is treated as a high pressure gas, and chlorine is classified as a toxic substance, which always poses a high risk in safety management.

Recently, the disinfection process using sodium hypochlorite, which has the same sterilization mechanism as chlorine, has been replaced.In advanced countries such as the United States and Japan, more than 90% of the hydrochloric acid is considered in consideration of natural disasters such as earthquakes and dangers against terrorism. It has been replaced by sodium, and gradually replaced by sodium hypochlorite in Korea.

Sodium hypochlorite is produced in the form of sodium hypochlorite directly in the field through electrolysis of brine, stored in sodium hypochlorite storage tank and injected into the place of use, and stored in a storage tank for use in the form of chemicals manufactured in the chemical process. In a way that makes sense.

However, such sodium hypochlorite is a chemically unstable substance and the concentration decreases with time. In particular, sodium hypochlorite is significantly affected by the temperature, the concentration is significantly reduced when the temperature increases.

When the concentration of sodium hypochlorite is thus reduced, there is a problem in that the concentration of carcinogenic by-products such as chlorate is relatively increased.

In addition, when the sodium hypochlorite having an irregular concentration is supplied to the contaminated water at the input place, there is a problem that the residual chlorine concentration remaining in the purified water sterilized by the sodium hypochlorite becomes uneven by time.

Accordingly, there is a need for a method of maintaining a constant concentration of sodium hypochlorite in a sodium hypochlorite storage tank that is stored for a long time, and a new system of sodium hypochlorite injecting system capable of maintaining a residual chlorine concentration at an input point below a target value. do.

When using a vacuum ejector for the injection of conventional sodium hypochlorite, there was a problem that hose compression and pulsation in the pump caused by the vacuum pressure of the ejector.

In addition, when injecting the dilution water into the multi-point, there was a problem that the input amount is pulled by distance.

In addition, in the input of sodium hypochlorite, if a sudden change in water quality occurs due to the occurrence of high turbidity and influx of abnormal substances, a problem occurs in which the standard concentration cannot be met even if sodium hypochlorite is supplied at a predetermined concentration.

SUMMARY OF THE INVENTION An object of the present invention is to solve the above-described problem, and to provide a sodium hypochlorite injection system capable of dispensing dilute hypochlorite dilution water of a uniform concentration into a plurality of input sites and reducing the occurrence of input amount by distance. It is.

Another object of the present invention is to provide a sodium hypochlorite injection system capable of emergency response even if a sudden change in the water quality due to the occurrence of high turbidity and influx of abnormal substances.

The above objects and various advantages of the present invention will become more apparent from the preferred embodiments of the present invention by those skilled in the art.

An object of the present invention can be achieved by a sodium hypochlorite injection system for injecting dilution water formed by diluting sodium hypochlorite with water. Sodium hypochlorite injection system of the present invention, the salt storage tank in which sodium hypochlorite is stored; A liquid input amount adjusting device for receiving sodium hypochlorite from the flame storage tank and diluting with water to form the diluted salt water; And a dilution water dispensing device for distributing the diluted liquid dilution water formed in the liquid input amount control device to a plurality of input sites at an equal concentration and a desired distribution ratio, wherein the liquid input amount control device includes the flame storage tank and the flame transfer pipe. It is connected by, and the image flow rate measuring unit for transmitting the flow rate of sodium hypochlorite which is moved along the flame transfer pipe in the distance to the image; A water supply pipe for supplying water; A vacuum controlled ejector for mixing sodium hypochlorite supplied through the image flow rate measuring unit with water supplied through the water supply pipe by vacuum pressure, and then moving the diluted salt distilled water to a distance by vacuum pressure; It is characterized in that it comprises a liquid chemical injector coupled between the vehicle and the vacuum-controlled ejector, the input amount of the sodium hypochlorite to the water.

According to one embodiment, the liquid chemical injection unit, the liquid injection amount control valve for increasing or decreasing the input amount of the sodium hypochlorite according to the increase or decrease of the negative pressure applied from the vacuum-controlled ejector; A manual control unit for manually adjusting the input amount of the sodium hypochlorite when power is not supplied; It may include an automatic control unit for adding or subtracting the input amount of the sodium hypochlorite according to the input signal of the control unit.

According to one embodiment, the manual control unit, the handle used to manually adjust the sodium hypochlorite dose; Diaphragm for preventing the leakage of sodium hypochlorite by adjusting the amount of sodium hypochlorite; It includes a flow regulator for adjusting the input amount of sodium hypochlorite according to the V groove and the angle, The automatic control unit, Connection pin for connecting the input adjustment port and the shaft; A shaft connected to the connection pin; A precision potentiometer for confirming the current position by measuring the potential through forward / reverse rotation according to an external instruction; A potentiometer gear for driving the precision potentiometer; A motor for driving the precision potentiometer; An input amount adjusting tool for forming a V-groove at a constant angle, length, and ratio, and changing the input amount of sodium hypochlorite according to rotation; A shaft gear for adjusting a length of the dose adjusting device when the dose adjusting device is rotated; It may include a position measuring sensor for confirming the first and last position of the dose adjustment.

According to an embodiment, the dilution water distribution device includes a plurality of dilution water distributors which are provided as many as the number of input sites, and distribute the discharged dilution water at a desired input ratio at the same concentration. Each of the dilution water distributors includes: a dilution water flow rate control valve configured to control an inflow amount corresponding to an input ratio of the dilution water; It may include a dilution water flow meter for measuring the flow rate of the incoming dilution water.

 In the sodium hypochlorite injection system according to the present invention, the flames of the flame retardant storage tank are diluted with the flame and water in the vacuum-controlled ejector through the liquid injection amount control valve and the automatic control part of the liquid injection amount control device, and the dilution water is formed in the vacuum. The vacuum dilution of the ejector transports the diluted dilution water over a long distance. As a result, the chemical dosage can be automatically adjusted through the liquid dosage control device rather than the conventional metering pump.

In addition, the sodium hypochlorite injection system according to the present invention is distributed according to the required input amount for each injection point through the area flow meter and dilution water flow control valve positioned in the middle of the injection point of the flame dilution water supplied by the vacuum control ejector The amount can be adjusted.

Figure 1 is a schematic diagram showing the overall configuration of the sodium hypochlorite injection system according to the present invention,
Figure 2 is a schematic diagram showing the configuration of the liquid dosing device of the sodium hypochlorite injection system according to the present invention,
Figure 3 is a schematic diagram showing the configuration of the liquid chemical injection unit of the sodium hypochlorite injection system of the present invention,
Figure 4 is a cross-sectional view showing the configuration of the manual adjustment portion of the liquid chemical injection unit,
Figure 5 is a cross-sectional view showing the configuration of the automatic control of the liquid chemical injection unit,
6 is a cross-sectional view showing the configuration of a liquid injection amount control valve of the liquid chemical injection unit;
Figure 7 is a schematic diagram showing the configuration of the dilution water distribution device of the sodium hypochlorite injection system of the present invention.

In order to fully understand the present invention, preferred embodiments of the present invention will be described with reference to the accompanying drawings. Embodiment of the present invention may be modified in various forms, the scope of the invention should not be construed as limited to the embodiments described in detail below. This embodiment is provided to more completely explain the present invention to those skilled in the art. Therefore, the shape of the elements in the drawings and the like may be exaggerated to emphasize a more clear description. It should be noted that the same members in each drawing are sometimes shown with the same reference numerals. Detailed descriptions of well-known functions and configurations that are determined to unnecessarily obscure the subject matter of the present invention are omitted.

1 is a schematic diagram schematically showing the overall configuration of a sodium hypochlorite injection system 1 according to the present invention.

Sodium hypochlorite injection system 1 according to the present invention stores sodium hypochlorite (hereinafter referred to as tea salt) commercially available as a drug at a constant concentration set in the flame retardant storage tank (100). The sodium hypochlorite injection system 1 according to the present invention stores the flame A in a non-contact manner with the atmosphere, and can secure quantitativeness by automatically adjusting the chemical dose according to the opening degree control of the liquid dosage controller.

In addition, when diluting the dilution water to multiple points, the dilution amount of the chemical dilution water can be dispensed and injected as necessary according to the desired ratio.

The sodium hypochlorite injection system 1 of the present invention supplies the flame retardant storage tank 100 for storing the flame retardant A so that the concentration of the flame retardant A does not change, and the flame retardant A of the flame retardant storage tank 100. And dilution with water (W) to form the dilution dilution water (C) and the liquid input amount control device 200, and dilution dilution water (C) at a desired concentration at a uniform concentration corresponding to the number of the injection sites (20) Dilution water distribution device 300 for dispensing and injecting.

The flame moving pipe 180 supplies the flame A of the tank body 110 to the liquid input amount adjusting device 200.

2 is a schematic view showing the configuration of the liquid dosing control device 200. As shown, the liquid input amount adjusting device 200 mixes the flame A moved along the flame transfer pipe 180 with water W while maintaining the concentration to form the flame dilution water C. The liquid input amount adjusting device 200 includes an image flow rate measuring unit 230 indicating a flow rate of the flame A moving through the flame moving pipe 180, a water supply pipe 240 for supplying water W, and a flame shield ( A) and the water (W) by mixing the vacuum dilution dilution water (C) to the dilution water distribution device 300 by the vacuum pressure, the vacuum controlled ejector 250, flame transfer pipe 180 and the water supply pipe 240 ) Is provided between the liquid chemical injection portion 270 for adjusting the amount of the flame (A) to the water.

The pressure gauge 210 and the vacuum gauge 220 are respectively provided at the ends of the flame moving pipe 180.

The liquid chemical injection unit 270 is equipped with a flame retardant injection capacity control function when the injection requirement of the flame retardant exceeding the input of the flame retardant that is normally injected due to the rapid change of the water quality occurs due to the occurrence of high turbidity and abnormal substances. It is possible to respond to emergency operation in excess of facility capacity such as abnormal water quality operation as well as proper injection range operation.

The flame A moved through the flame moving tube 180 is moved to the image flow rate measuring unit 230. The image flow rate measuring unit 230 includes an hour meter unit 231 which can visually check the flow rate of the flame at a short distance.

The hour meter 231 is a device for visually confirming an input amount of the flame A moved through the flame moving tube 180. The hour meter unit 231 is installed integrally with the flow meter and is equipped with a diaphragm type air discharge pipe for preventing hunting of the hour meter ball due to air that may occur in the hydrochloric acid flow meter. In addition, the hour meter 231 is provided when the failure of the flame retardant pump or the imaginary value occurs, the hour meter ball is lowered to the CCTV and the naked eye to monitor.

By the configuration of the image flow rate measuring unit 230, not only can visually confirm the flow rate of the flame in the field, but also can accurately check the real-time flow rate of the flame (A) through the image output from the remote control room 30. .

The water supply pipe 240 supplies water (W). The water (W) supplied through the water supply pipe 240 is diluted with the flame salt (A) in the vacuum control ejector 250. The vacuum-controlled ejector 250 allows the flame A to be uniformly and quickly spread when the flame A is introduced into the contaminated water of the feed point 20. To this end, the vacuum-controlled ejector 250 supplies the dilution dilution water (C) diluted with the water (W) to the input (20) to the input place in a vacuum pressure.

Dilution water (C) is transferred from the vacuum control ejector 250 is supplied to the dilution water distribution device 300 through the dilution water supply pipe 260.

Meanwhile, the liquid chemical injection unit 270 is provided between the flame retardant pipe 180 and the vacuum control ejector 250.

The liquid chemical injection unit 270 operates the diaphragm of the vacuum controller at the vacuum pressure generated by the vacuum control ejector 250 through the automatic control unit 273 to introduce the flame A into the flame A, and the introduced flame A ) Opens and closes the opening amount of the automatic valve, injects the flame A, and transmits the opened opening amount to the controller (not shown). In addition, during the power outage, it is possible to manually adjust the amount of hydrochloric acid through the manual control unit 271.

3 is a schematic diagram schematically showing a configuration of the liquid chemical injection unit 270. As shown, the liquid chemical injection unit 270 operates the diaphragm of the vacuum controller at the vacuum pressure generated by the vacuum control ejector 250 through the automatic control unit 273 to introduce the flame (A), and the inflow. The open flame A opens and closes the open amount of the automatic valve, injects the open flame A, and transmits the open amount to the control unit (not shown). In addition, during the power outage, it is possible to manually adjust the amount of hydrochloric acid through the manual control unit 271.

4 is a cross-sectional view showing the internal configuration of the manual adjustment unit 271. The manual control unit 271 manually adjusts the amount of hydrochloric acid when power is not supplied to the site due to a power failure. In addition, when the maintenance, such as the inspection of the automatic control unit 273 is transferred to the spare unit.

In addition, the manual control unit 271 has a capacity increase function to the structure that can be injected additional drugs when the injection range of the automatic control unit 273 is exceeded. That is, it has a variable structure capable of adjusting the injection dose range. As a result, in response to rapid changes in water quality such as algae, it is possible to freely operate facilities without introducing additional facilities at peak loads.

As illustrated in FIG. 4, the manual control unit 271 is formed of a controller handle 271a used to manually adjust the amount of hydrochloric acid, and C-PVC, which is a strong corrosion resistant material resistant to pressure and sufficient strength to withstand pressure. The first body (271b) is made of, Teflon is a corrosion-resistant strong corrosion resistant material, and the double-sealed diaphragm (271c) to prevent leakage of flames by adjusting the amount of hydrochloric acid, and according to the V groove and angle It includes a flow controller and a flow control bolt (271d) for adjusting the amount of hypochlorite input.

5 is a diagram showing the configuration of the automatic adjustment unit 273. Automatic control unit (273) functions to add or reduce the amount of chemical input according to the chemical input signal in the field or remote. The automatic adjustment unit 273 operates according to the opening degree indicated by the field control panel PLC and a control unit (not shown).

The automatic adjusting unit 273 measures the potential through the second body 273a, the connecting pin 273b for connecting the input amount adjusting port 273g and the shaft 273c, and the forward / backward rotation according to an external instruction. Precision potentiometer 273d for confirming the current position, potentiometer gear 273e for driving precision potentiometer 273d, motor 273f for driving precision potentiometer 273d, and at a constant angle, length and ratio An input amount adjusting opening (273g) which forms a V-groove and changes the flame input amount according to rotation, a shaft gear (273h) for adjusting the length of the input adjusting opening (273g) during rotation of the input adjusting opening (273g), and an input adjusting amount It includes a position measuring sensor (273i) to check the first and last position of the sphere (273g) and automatically stops when the dose adjustment (273g) is in contact.

The automatic control unit 273 implements quantitative control by controlling the opening degree in the form of a control valve of the V groove for injecting liquid medicine using the vacuum pressure of the pressure pump.

The automatic adjustment unit 273 may improve the precision and control ability in the low flow rate section by changing the angle and length of the input amount adjustment port 273g.

FIG. 6 is a diagram showing the configuration of the liquid input amount adjusting valve 275. The liquid input amount control valve 275 converts the flame dilution liquid present in the pressure state into the negative pressure (vacuum) state generated by the vacuum control ejector 250 to operate the internal diaphragm 275c to allow the flame dilution liquid to flow therein. And, the introduced drug can be supplied to the automatic control unit (273).

Liquid input volume control valve 275 is operated only by the negative pressure (vacuum), and includes a function that automatically closes when the negative pressure is destroyed, the inside is composed of titanium and teflon, such as steel corrosion-resistant materials that do not corrode the chemicals. As a result, secondary accidents can be prevented from being vaporized in the atmosphere of harmful chemicals.

The liquid input flow control valve 275 is made of a third body 275a, a corrosion resistant steel corrosion resistant material titanium, a spring 275b having a tension to operate when it is introduced at a predetermined pressure or higher, and a corrosion resistant material resistant to corrosion. It is made of in teflon and includes a diaphragm (275c) to increase and decrease the flow rate according to the increase and decrease of the sound pressure (vacuum).

The dilution water distribution device 300 is for preventing the variation of residual salt concentration between the input sites due to the drift and deflection of the cold dilution water (C) when the dilution water (C) is introduced into a plurality of input sites. Device. Dilution water distribution device 300 is an automatic control valve or a manual control valve is attached to the transparent area flow meter evenly distributes the input amount of the dilution dilution water (C).

7 is a schematic diagram schematically showing the configuration of the dilution water distribution device 300.

Here, the sodium hypochlorite injection system (1) of the present invention illustrates the addition of the dilution dilution water (C) to the two input sites, the dilution water distribution device 300 also the two dilution dilution water distributor (310, 320) It is illustrated as having. However, this is only an example, and the dilution water distribution device 300 may include the flame-dilution water distributors 310 and 320 corresponding to or greater than the number of input sites.

Each flame dilution water distributor (310, 320) includes a dilution water flow rate control valve (311, 321), and dilution water flow meter (330, 330a) for measuring the flow rate of the flame-dilution water (C). The plurality of tea dilution water distributors 310 and 320 injects the tea dilution water C to each input site through the dilution water discharge nozzles 340 and 340a.

Diluted dilution water (C) discharged by the dilution water discharge nozzles (340, 340a) is rapidly diffused into the contaminated water of the input site and disinfects the contaminated water.

Here, each dilution water flow rate control valve (311, 321) allows the user to adjust the amount of the dilution dilution water (C) for each injection point by a remote control of the control unit (not shown) at a desired ratio. For example, the two diluents may be divided into 5: 5 ratios or 7: 3 ratios.

As a result, when the conventional dilution dilution water is injected into the multi-point, it is possible to prevent the dilution of the dilution dilution water from occurring near the injection point.

At this time, it is possible to identify the input amount of the dilution dilution water (C) through each dilution flow rate meter (330, 330a), it may be possible to check and check the real-time drug injection through CCTV.

As described above, in the sodium hypochlorite injection system according to the present invention, the flames of the flame storage tank are diluted with flame and water in the vacuum-controlled ejector through the liquid injection amount control valve and the automatic control part of the liquid injection amount control device. The dilution water is transferred to the far distance by the vacuum pressure of the vacuum-controlled ejector. As a result, the chemical dosage can be automatically adjusted through the liquid dosage control device rather than the conventional metering pump.

In addition, the sodium hypochlorite injection system according to the present invention is distributed according to the required input amount for each injection point through the area flow meter and dilution water flow control valve positioned in the middle of the injection point of the flame dilution water supplied by the vacuum control ejector The amount can be adjusted.

Embodiment of the sodium hypochlorite injection system of the present invention described above is merely exemplary, and those skilled in the art to which the present invention pertains that various modifications and equivalent other embodiments are possible. You can see well. Therefore, it will be understood that the present invention is not limited to the forms mentioned in the above detailed description. Therefore, the true technical protection scope of the present invention will be defined by the technical spirit of the appended claims. It is also to be understood that the present invention includes all modifications, equivalents, and substitutes within the spirit and scope of the invention as defined by the appended claims.

1: sodium hypochlorite injection system 100: flame retardant storage tank
180: chemical supply pipe 200: liquid input volume control device
210: pressure gauge 220: vacuum gauge
230: flow meter 231: hour meter
240: water supply pipe 241: water supply pump
250: vacuum control ejector 251: pressure reducing valve
260: dilution water supply pipe 270: liquid chemical injection unit
271: manual control unit 271a: adjuster handle
271b: first body 271c: first diaphragm
271d: flow regulator and flow adjusting bolt 273: automatic control unit
273a: second body 273b: connecting pin
273c: shaft 273d: precision potentiometer
273e: Potentiometer gear 273f: Motor
273g: Dosage adjustment port 273h: Shaft gear
273i: Position Measuring Sensor 275: Liquid Input Control Valve
275a: third body 275b: spring
275c: diaphragm 300: dilution water distribution device
310: first dilution water distributor 311: first dilution water flow control valve
320: secondary dilution water distributor 321: second dilution water flow control valve
330: first dilution water flow meter 330a: second dilution water flow meter
340,340a: Dilution water discharge nozzle
A: flame retardant
C: Cha Yeon Hee Seok Soo
W: water

Claims (4)

In the sodium hypochlorite injection system for injecting the dilution water formed by diluting sodium hypochlorite with water,
A flame storage tank in which sodium hypochlorite is stored;
A liquid input amount adjusting device for receiving sodium hypochlorite from the flame storage tank and diluting with water to form the diluted salt water;
It includes a dilution water distribution device for distributing the diluted liquid dilution water formed in the liquid input amount control device to a plurality of input sites at equal concentrations and desired distribution ratio,
The liquid input amount control device,
An image flow rate measuring unit connected to the flame storage tank and the flame moving tube and transmitting a flow rate of sodium hypochlorite moved along the flame moving tube to an image at a distance;
A water supply pipe for supplying water;
A vacuum controlled ejector for mixing sodium hypochlorite supplied through the image flow rate measuring unit with water supplied through the water supply pipe by vacuum pressure, and then moving the diluted salt distilled water to a distance by vacuum pressure;
It is coupled between the flame transfer pipe and the vacuum-controlled ejector, and includes a liquid chemical injecting unit for adjusting the input amount of the sodium hypochlorite to water,
The liquid chemical injection unit,
A liquid input amount control valve for increasing or decreasing the input amount of sodium hypochlorite according to the increase or decrease of the negative pressure applied from the vacuum-controlled ejector;
A manual control unit for manually adjusting the input amount of the sodium hypochlorite when power is not supplied;
Including an automatic control unit for adding or subtracting the input amount of the sodium hypochlorite in accordance with the input signal of the control unit,
The manual adjustment unit,
A controller handle used to manually adjust the sodium hypochlorite dosage;
Diaphragm for preventing the leakage of sodium hypochlorite by adjusting the amount of sodium hypochlorite;
It includes a flow controller for adjusting the input amount of sodium hypochlorite according to the V groove and angle,
The automatic adjustment unit,
A connection pin connecting the dose adjustment port and the shaft;
A shaft connected to the connection pin;
A precision potentiometer for confirming the current position by measuring the potential through forward / reverse rotation according to an external instruction;
A potentiometer gear for driving the precision potentiometer;
A motor for driving the precision potentiometer;
An input amount adjusting tool for forming a V-groove at a constant angle, length, and ratio, and changing the input amount of sodium hypochlorite according to rotation;
A shaft gear for adjusting a length of the dose adjusting device when the dose adjusting device is rotated;
Sodium hypochlorite injection system, characterized in that it comprises a position measuring sensor for confirming the first and last position of the dose control.
delete delete The method of claim 1,
The dilution water distribution device,
It includes a plurality of dilution distributors are provided as the number of input sites, distributing the dilution water supplied to the desired concentration at the same concentration and discharged,
Each of the plurality of dilution dividers,
A dilution water flow rate control valve configured to control an inflow rate corresponding to an input ratio of the flame-diluted water;
Sodium hypochlorite injection system comprising a dilution water flow meter for measuring the flow rate of the dilution water introduced.

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