KR101990544B1 - Automatic Chlorine Dioxide Dispenser Combined with Drinking Water and Disinfection Water - Google Patents

Abstract

The present invention relates to an automatic chlorine dioxide injection device for both drinking water and disinfection water, which separates raw water supplied from a water supply source into drinking water and disinfection water, adjusts the drinking water and the disinfection water to uniform chlorine dioxide concentration suitable for a use to supply the same to a consumer, and prevents corrosion of a supply pipe due to residual disinfection water by replacing the disinfection water remaining in the supply pipe after use, with raw water. According to the present invention, the concentration of chlorine dioxide introduced into first and second injection lances are separately controlled by an integrated controller in accordance with the amount of water measured by first and second flowmeters, such that each concentration of the chlorine dioxide is uniformly maintained while being different from each other in accordance with use of water discharged from first and second discharge pipes, thereby supplying the disinfection water to a consumer of a pen and the like, and supplying drinking water to a consumer of a farm and the like.

Description

Automatic Chlorine Dioxide Dispenser Combined with Drinking Water and Disinfection Water}

The present invention relates to an automatic chlorine dioxide injector for both drinking and sterilizing water, and more specifically, to separate the raw water supplied from the water supply source for drinking and disinfecting water, and to adjust the drinking and disinfecting water to the required chlorine dioxide concentration according to the purpose. It is supplied to the place of use so that it can be used as drinking water and disinfectant water, and chlorine dioxide, which is used as a disinfectant for drinking water, is used as a disinfectant for disinfectant water. The present invention relates to an automatic chlorine dioxide injector for both drinking water and sterilizing water, which has a double disinfection effect of disinfecting germs in the air by volatilizing the disinfecting water sprayed on the floor.

Because livestock are raised in groups in a defined space, they are vulnerable to infectious diseases such as foot-and-mouth disease and bird flu, and once they are easily transmitted to the surrounding area, they cause enormous damage to livestock farms. Therefore, the farmers who run the barn must prevent such infectious diseases through periodic prevention by themselves, and they must also have disinfection facilities for moving vehicles, but the construction and operation of these facilities is difficult due to the enormous cost and difficulty of operation. to be.

In addition, hog farms and poultry farms are known to have the biggest complaints due to the odor generated from livestock manure. Many formulations are commercially available to reduce odors, but they are reluctant in farms due to ongoing costs. In addition, a method of liquefying livestock manure using the Bacillus strain has been proposed, but such a fermentation method has a problem that the bad smell occurs during the housing process and the disadvantage that the housing time is progressed for a long time.

Livestock farmers are dependent on local defense organizations because of their difficulty in providing protection facilities and the lack of defense personnel. In response to the epidemic disease occurring irregularly in local governments, it is difficult to respond suddenly, and once it occurs for a long time, it is difficult to properly respond to the demand for protection.

In addition, when a strong toxic disinfectant such as insecticide is used for strong sterilization, the livestock can be eaten and remain in the feed and drinking water, and may remain in the air and inhale and accumulate in the livestock body during respiration. Milk, eggs and meat produced from these livestock also remain a problem because of pesticides.

Korean Patent Publication No. 10-0867427 (2008.11.06.) Discloses a device for disinfecting livestock and generating livestock drinking water.

The barn inside and outside disinfection and livestock drinking water generating device is a sodium hypochlorite generator that continuously generates and hypothesized sodium hypochlorite in real time and collect in the storage, livestock disinfection system, car disinfection system and drinking water supply By installing the device, pumping sodium hypochlorite generated in real time and continuously diluting it to the incoming water such as groundwater and spraying it inside the barn that collectively breeds various livestock (cow, pig, chicken, etc.) In addition to disinfecting the inside of the house, the odor can be removed, and if necessary, it can spray and sterilize people and vehicles entering and leaving the house, preventing the movement of various viruses and infectious diseases through people and vehicles. And sodium hypochlorite in a fixed ratio By providing the seats with disinfection and sterilization of drinking water livestock it is effective to prevent a variety of bacterial diseases that can occur due to drinking water contaminated by water.

On the other hand, water supplied through a simple water supply facility, a well or a water supply source is disinfecting drugs such as sodium hypochlorite to prevent contamination and inactivate waterborne pathogens that may cause illness to the human body. . Such water supply facilities are already supplied to rural areas, thereby preventing pollution of drinking water and improving health.

Republic of Korea Patent Publication No. 10-1543299 (2015.08.11.) Discloses a drug injection device and a waterworks integrated management control system including the same.

The drug injection device is decomposed with the sodium hypochlorite solution in the chemical tank according to time or temperature to reduce the concentration of the effective chlorine in the sodium hypochlorite solution, so that more sodium hypochlorite solution is added, the desired amount of the desired amount There is an effect that chlorine can be put in the water, and the integrated water management control system has the advantage that the desired amount of chlorine can remain in the water even after a certain period of time after injecting sodium hypochlorite solution into the chemical tank .

However, the automatic chlorine dioxide injector for both drinking and disinfecting water that can be supplied to each application by adjusting the drinking water and disinfecting water to the required chlorine concentration for each use has not yet been disclosed.

KR 10-0867427 B1 2008.11.06. KR 10-1543299 B1 2015.08.11.

An object of the present invention is to separate the raw water supplied from the wells and water supplies for drinking water and disinfection water, automatic drinking water and disinfection water combined automatic chlorine dioxide injector that can supply drinking water and disinfection water to the respective chlorine dioxide concentration for each purpose To provide.

It is another object of the present invention to provide an automatic chlorine dioxide injector for both drinking water and disinfecting water that can supply disinfecting water and drinking water that is safe and excellent in sterilization and can also be used as drinking water for livestock.

Still another object of the present invention is to provide an automatic chlorine dioxide injector for both drinking water and disinfectant water that can be used as human drinking water, livestock drinking water and livestock barn disinfection water using one chlorine dioxide generator.

Still another object of the present invention is suitable as a harmless, non-toxic, non-irritating, drinking water in livestock, safe and safe even when discharged to minimize the contamination of the source disinfecting water and drinking water can be installed as a single chlorine dioxide generator combined automatic drinking water and disinfection water It is to provide a chlorine injector.

Still another object of the present invention is to provide an automatic chlorine dioxide injector combined with drinking water and disinfectant water that can be produced in large quantities and actively cope with environmental changes in livestock farms.

In addition, another object of the present invention is to prevent the corrosion of the supply pipe due to residual disinfecting water by replacing the disinfecting water remaining in the supply pipe after use of the disinfecting water to prevent the chlorine dioxide component, when the raw water is added to the supply pipe again It is to provide automatic chlorine dioxide injector for both drinking and disinfection water to prevent the disinfection effect from being deteriorated due to unnecessary spraying of water by informing the user when the disinfection water is discharged.

In order to achieve the above object, the present invention provides the following means.

The present invention relates to a chlorine dioxide injector for providing different chlorine dioxide concentrations in one chlorine dioxide generator, comprising a sodium chlorite (NaClO ₂ ) solution tank, a hydrochloric acid (HCl) solution tank, a reactor and a chemical control controller. Chlorine (ClO ₂ ) generator; A built-in main body having a plurality of metering pumps for receiving a chlorine dioxide solution from the reactor and having an integrated controller; An input pipe receiving water from a water supply source, a first discharge pipe branching the water introduced into the input pipe in two directions, and a branch pipe formed with a second discharge pipe; A dual flow meter installed in each of the first discharge pipe and the second discharge pipe, the first flow meter measuring the amount of water passing through the first discharge pipe and the second discharge pipe, and the second flow meter being provided; And a first injection lance and a second injection lance respectively inserted into the first discharge pipe and the second discharge pipe to receive the chlorine dioxide solution from the metering pump, and to introduce the chlorine dioxide solution into the first discharge pipe and the second discharge pipe, respectively. It includes an injection lance is provided with an injection lancer, including, the chlorine dioxide concentration in the first discharge pipe and the second discharge pipe is different from each other, provides both automatic drinking water and disinfection water chlorine dioxide injector.

The chlorine dioxide (ClO ₂ ) generator is supplied by mixing the sodium chlorite (NaClO ₂ ) solution and hydrochloric acid (HCl) solution from each of the sodium chlorite (NaClO ₂ ) solution tank, hydrochloric acid (HCl) solution tank, each solution tank Reactor, a pump for inputting each stored solution in each solution tank to the reactor by a predetermined amount, a sensor for sensing the flow rate of each solution introduced into the reactor from each solution tank and the solution stored in the solution tank Including a chemical control controller for controlling the amount to be introduced into the reactor, the temperature of the sodium chlorite (NaClO ₂ ) solution and hydrochloric acid (HCl) solution in the reactor is 10 ~ 40 ℃, the sodium chlorite in the reactor The (NaClO ₂ ) solution and the hydrochloric acid (HCl) solution are combined in a weight ratio of 1: 1.

The chlorine dioxide solution introduced through the first injection lance in the first discharge pipe and the water supplied through the input pipe are used as disinfectant to disinfect the livestock house, and the second injection lance in the second discharge pipe. The chlorine dioxide solution and the water supplied through the input tube is mixed and used as drinking water, the disinfecting water is chlorine dioxide concentration of 10 to 300 PPM, the drinking water is chlorine dioxide concentration of 0.2 to 2 PPM.

A mixing tank is additionally provided to uniformize the chlorine dioxide concentration of the disinfectant water, and the rear end of the first discharge pipe and the inlet of the mixing tank are connected to the disinfection water discharge pipe, and the outlet and the livestock of the mixing tank are connected to the disinfection water supply pipe. do.

After the use of the sterilizing water is finished after the end of the use of the disinfecting water supply pipe to replace the disinfection water with general water, the bypass pipe is connected between the first injection lance and the input pipe, The rear end of the bypass pipe is connected to the disinfection water supply pipe.

After disinfection water passes through the disinfection water supply pipe and the supply of the chlorine dioxide solution from the first injection lance is finished, water passing through the first discharge pipe is introduced into the disinfection water supply pipe through the bypass pipe.

A discharge valve serving to open and close the injection of the disinfectant water supplied from the disinfectant water supply pipe is further provided at the end of the disinfectant water supply pipe, wherein the discharge valve includes an LED, an LCD, and a switch, and the discharge valve is connected to the integrated controller. Connected by wire or wirelessly, the disinfecting water or the general product remaining in the disinfecting water supply pipe calculated by the integrated controller is received and displayed on the LCD.

A check valve is further provided between the disinfecting water supply pipe and the mixing tank.

In the present invention, the raw water supplied from the water supply source 1 such as a well or a water supply source is introduced through the input pipe 310 of the branch pipe 300, and the raw water introduced into the input pipe 310 for drinking water and livestock disinfection. The chlorine dioxide is supplied to the discharge pipe, and the concentration of chlorine dioxide injected into each injection lance is controlled according to the amount of water provided in each discharge pipe, and each necessary chlorine dioxide is different depending on the use of the water discharged from each discharge pipe. By providing the concentration, it is possible to supply disinfectant water to a place of use such as a livestock house and drinking water to a place of use such as a farmhouse.

The present invention can supply disinfecting water and drinking water that is harmless to livestock and is safe and excellent in sterilization and can also be used as drinking water for livestock.

The present invention can be used as human drinking water, livestock drinking water and livestock barn disinfection water using one chlorine dioxide generator.

The present invention is suitable as a harmless, non-toxic, non-irritating, drinking water in livestock, and can be installed as a chlorine dioxide generator to disinfect water and drinking water to be safe even when discharged to minimize contamination of the water source.

The present invention can produce a large amount of disinfectant water is able to actively cope with the environmental changes of the livestock stalls.

Further, the present invention after sterilizing the use of the barn, etc. through the disinfection water supply pipe 610, the water to the disinfection water supply pipe 610 past the mixing tank 600 through the bypass pipe 700 connected to the first discharge pipe 320. Since the disinfecting water remaining in the disinfecting water supply pipe 610 may be discharged by supplying raw water of the supply source 1, there is an effect of preventing corrosion and damage of the disinfecting water supply pipe 610 due to the remaining disinfecting water.

In addition, the present invention informs the user when the disinfection water remaining in the disinfection water supply pipe 610 is completely escaped or when the raw water located in the disinfection water supply pipe 610 is completely escaped to remove the residual disinfection water in the disinfection water supply pipe 610 When preventing the waste of raw water, and when removing the raw water in the disinfecting water supply pipe 610, while preventing the waste of sterilization water, there is an effect of preventing the degradation of the sterilization effect due to the spraying of raw water.

On the other hand, according to the present invention, the disinfectant water sprayed to the place of use of the livestock by the disinfectant water supply pipe 610 has the effect of volatilizing performance of chlorine dioxide, so that the space sterilization inside the livestock is possible even without spraying the disinfectant separately in the air.

1 is a schematic diagram schematically showing the configuration of the automatic chlorine dioxide injector for both drinking and sanitizing water according to an embodiment of the present invention.
Figure 2 is a block diagram schematically showing the configuration of the automatic chlorine dioxide injector combined with drinking water and disinfecting water according to an embodiment of the present invention.
Figure 3 is an enlarged view of the display 212 in the automatic chlorine dioxide injector combined with drinking water and disinfection water according to an embodiment of the present invention.
Figure 4 is a schematic diagram showing an enlarged discharge valve 800 in the automatic chlorine dioxide injector for both drinking and disinfecting water according to an embodiment of the present invention.

Hereinafter, with reference to the accompanying drawings, preferred embodiments of the present invention will be described to be easily carried out by those of ordinary skill in the art.

1 is a schematic view showing the configuration of the automatic chlorine dioxide injector for both drinking and disinfectant water according to an embodiment of the present invention, Figure 2 is a schematic view of the configuration of the automatic chlorine dioxide injector combined with drinking water and sanitizing water according to an embodiment of the present invention The block diagram shown.

With reference to Figures 1 and 2 will be described automatic chlorine dioxide injector combined with drinking water and sterilizing water according to the present invention.

Automatic chlorine dioxide injector combined drinking water and sterilizing water of the present invention,

A chlorine dioxide (ClO ₂ ) generator 100 including a sodium chlorite (NaClO ₂ ) solution tank 110, a hydrochloric acid (HCl) solution tank 120, a reactor 130, and a chemical control controller 140;

A built-in main body 200 in which a plurality of metering pumps 220 receiving the chlorine dioxide solution 150 from the reactor 130 are built in and the integrated controller 210 is provided;

Inlet tube 310 to receive water from the water supply (1), the first discharge pipe 320 and the second discharge pipe 330 for branching and discharging the water introduced into the input pipe 310 in two directions, respectively The formed branch pipe 300;

A first flow meter 410 installed in the first discharge pipe 320 and the second discharge pipe 330, respectively, for measuring the amount of the water passing through the first discharge pipe 320 and the second discharge pipe 330; A dual flow meter 400 provided with a second flow meter 420; And

Inserted into the first discharge pipe 320 and the second discharge pipe 330, respectively, the chlorine dioxide solution 150 is supplied from the metering pump 220, the first discharge pipe 320 and the second discharge pipe 330 An injection lance 500 provided with a first injection lance 510 and a second injection lance 520 for respectively injecting the chlorine dioxide solution 150 into

Include.

In the present invention, the concentrations of the chlorine dioxide solution 150 in the first discharge pipe 320 and the second discharge pipe 330 are different from each other.

The chlorine dioxide (ClO ₂ ) generator 100 includes sodium chlorite (NaClO ₂ ) solution tank 110, hydrochloric acid (HCl) solution tank 120, and sodium chlorite (NaClO) from each of the solution tanks 110 and 120. ₂ ) Reactor 130 for receiving and mixing a solution and hydrochloric acid (HCl) solution, pumps for injecting the solution stored in each of the solution tank (110, 120) to the reactor (130) by a predetermined amount ), The sensors 115 and 125 for detecting the flow rate of each solution introduced into the reactor 130 from the respective solution tanks 110 and 120 and the solution stored in the solution tanks 110 and 120 are stored in the reactor ( 130 includes a drug control controller 140 for controlling the amount of input.

The supply of the solution from the sodium chlorite (NaClO ₂ ) solution tank 110 and hydrochloric acid (HCl) solution tank 120 to the reactor 130 is made by pumps 111 and 121 and valves 113 and 123. .

The temperature of the sodium chlorite (NaClO ₂ ) solution and hydrochloric acid (HCl) solution in the reactor 130 is preferably 10 ~ 40 ℃.

The mixing ratio of the sodium chlorite (NaClO ₂ ) solution and hydrochloric acid (HCl) solution in the reactor 130 is preferably 1: 1 by weight. In order to accelerate the generation of chlorine dioxide in the reactor, an ion exchange tank (not shown) may be further installed at the rear of the reactor to convert the unreacted sodium chlorite into chlorine dioxide to increase the reaction efficiency.

The level sensor 160 is disposed inside the reactor 130, and the level sensor 160 may measure the amount of the chlorine dioxide solution 150 embedded in the reactor 130. At this time, the level sensor 160 may use a resistance level sensor for the convenience of remote control and monitoring for use other than the barn.

The level sensor 160 is electrically connected to the integrated controller 210 to be described later. The level sensor 160 measures the amount of chlorine dioxide solution 150 contained in the reactor 130 and transmits it to the integrated controller 210.

Chlorine dioxide (ClO ₂ ) is used for sterilization, disinfection and deodorization because of its high oxidizing power. Chlorine dioxide (ClO ₂ ) has the strongest bactericidal power following ozone and has the advantage of not producing carcinogens. In the present invention, chlorine dioxide (ClO ₂ ) is used instead of sodium hypochlorite for the same reason as described above.

The injection base body 200 is disposed adjacent or spaced apart from the branch pipe 300, it is firmly installed on the foundation concrete (10). Two metering pumps 220 are installed in the main body 200 and the level sensor 160 and the injection lances disposed in the metering pump 220 and the reactor 130 above the main body 200. In electrical connection with the 500, an integrated controller 210 for controlling them is installed.

In addition, a display 212 and an operation button 214 for operating the integrated controller 210 are installed at the upper outer side of the input base 200. The display 212 displays the integrated flow rate, the instantaneous flow rate, the set concentration, and the remaining amount of the chlorine dioxide solution 150 in the reactor 130. The operation button 214 may set the concentration (PPM) of the chlorine dioxide solution 150.

At this time, the display 212 and the operation button 214 is made in two places in pairs. Each of the display 212 and the operation button 214 may set the concentration of the chlorine dioxide solution 150 of the disinfecting water and drinking water differently.

On the other hand, at the upper end of the input base 200 is provided with a warning light 230 to alert the remaining operation of the chlorine dioxide solution 150 and the abnormal operation of the device inside the reactor 130.

For example, the beacon 230 may notify a user by sound or light when the remaining amount of the chlorine dioxide solution 150 in the reactor 130 is less than 10%. In addition, even when an error occurs in the level sensor 160, the dual flowmeter 400, the injection lancer 500, and the like electrically connected to the integrated controller 210 can be notified to the user by sound or light.

Furthermore, a door 240 that can be opened and closed is installed at the front of the input base 200. The door 240 is provided with a lock device, and only an administrator having a key can open the door 240 to open the door 240 and maintain the metering pump 220 installed therein.

The metering pump 220 pumps the chlorine dioxide solution 150 inside the reactor 130 and serves to supply it to the branch pipe 300. The metering pump 220 adjusts and discharges the amount of chlorine dioxide solution 150 to a predetermined concentration toward the branch pipe 300. The metering pump 220 is provided with two, each is connected to the first discharge pipe 320 and the second discharge pipe 330 of the branch pipe 300 by the injection lancer 500, respectively.

On the other hand, the metering pump 220 and the inside of the reactor 130 is connected to the first drug supply pipe 250, the metering pump 220 and the injection lancer 500 is connected to the second drug supply pipe (260). The chlorine dioxide solution 150 located inside the reactor 130 by the first drug supply pipe 250 moves to the metering pump 220, and the chlorine dioxide solution moved to the metering pump 220 ( 150 is moved to the injection lancer 500 through the second chemical supply pipe 260.

In this case, the first drug supply pipe 250 and the second drug supply pipe 260 are hollow tubes, and the inner circumference is made of Teflon or coated with Teflon to prevent corrosion or damage by the chlorine dioxide solution 150. . Since Teflon has characteristics such as chemical inertness and heat resistance, non-adhesiveness, excellent insulation stability, low friction coefficient, and the like, the first chemical supply pipe 250 and the second chemical supply pipe 260 are protected from the chlorine dioxide solution 150. Do it.

The metering pump 220 pumps the chlorine dioxide solution 150 inside the reactor 130 according to the flow rate measured by the dual flowmeter 400 to be described later and supplies it to the injection lancer 500. At this time, the pumping amount and the cycle of the metering pump 220 depends on the concentration of the chlorine dioxide solution 150 is set.

Furthermore, the pump valve 222 is installed on the upper portion of the metering pump 220. The chlorine dioxide solution 150 discharged from the metering pump 220 passes through the pump valve 222. The pump valve 222 may open or close the passage of the chlorine dioxide solution 150 discharged to the branch pipe 300 as a multifunctional valve.

On the other hand, the integrated controller 210 is electrically connected to the level sensor 160 by a first signal line 270, the amount of chlorine dioxide solution 150 in the reactor 130 measured from the level sensor 160 To receive a signal.

In addition, the integrated controller 210 is electrically connected to the dual flowmeter 400 by the second signal line 280, the first drug supply pipe 250 and the second drug supply pipe 260 through the metering pump 220 It controls the input to the chlorine dioxide solution 150 is supplied to each. Furthermore, the integrated controller 210 is electrically connected to the dual flowmeter 400, and according to the amount of water measured by the first flowmeter 410 and the second flowmeter 420, respectively, the first injection lancer 510 and the first flowmeter. The amount of chlorine dioxide solution 150 injected from the two injection lance 520 is controlled.

The integrated controller 210 is connected to the power supply means by the power line 290, and receives power.

The branch pipe 300 serves to branch in two directions the water supplied from the groundwater well or the water supply source, which is the water supply source 1, and is installed at a position adjacent to the input base 200. The branch pipe 300 is connected to the ground water wells or water supply in the upper portion is formed in the inlet pipe 310 is supplied with water, branched in two directions from the inlet tube 310 in the lower portion to the inlet pipe 310 The first discharge pipe 320 and the second discharge pipe 330 for discharging the water passing through are integrally formed.

The upper side of the first discharge pipe 320 controls the water to flow in only one direction so that the water introduced into the first discharge pipe 320 does not flow back to the input pipe 310 or the second discharge pipe 330 again. The non-return valve 340 is installed. Depending on the design, the non-return valve 340 may be installed on the second discharge pipe 330 side.

The first discharge pipe 320 is formed with a first insertion hole 322 for insertion of the first injection lancer 510 in the injection lancer 500 to be described later. In addition, a second insertion hole 332 is formed in the second discharge pipe 330 to insert the second injection lancer 520 which will be described later.

The dual flowmeter 400 is installed in the bypass form on the side of the first discharge pipe 320 and the second discharge pipe 330, respectively, the amount of water passing through the first discharge pipe 320 and the second discharge pipe 330. Measure The dual flowmeter 400 is divided into a first flowmeter 410 installed on the side of the first discharge pipe 320 and a second flowmeter 420 installed on the side of the second discharge pipe 330.

The first flow meter 410 and the second flow meter 420 are electrically connected to the integrated controller 210 of the input main body 200 and transmit the measured flow rate information.

As described above, the first flowmeter 410 and the second flowmeter 420 may use a precise flowmeter having a minimum 1 L / pulse output for precise operation of the metering pump 220.

The injection lancer 500 is connected to the metering pump 220 to receive the chlorine dioxide solution 150, and the chlorine dioxide solution 150 into the first discharge pipe 320 and the second discharge pipe 330. Play a role of inputting In this case, the input amount of the chlorine dioxide solution 150 depends on the concentration of the chlorine dioxide solution 150 set by the user in the integrated controller 210.

The injection lancer 500 has a first injection lance 510 inserted into the first insertion hole 322 formed in the first discharge pipe 320 and a second insertion hole 332 formed in the second discharge pipe 330. It is divided into a second injection lance 520 inserted into the. At this time, the concentration of the chlorine dioxide solution 150 introduced from the first injection lancer 510 and the second injection lancer 520 varies depending on the intended use. That is, the disinfecting water or drinking water discharged after the chlorine dioxide solution 150 is mixed in the first discharge pipe 320 and the second discharge pipe 330 may be used in different concentrations according to the intended use.

The chlorine dioxide solution 150 introduced through the first injection lancer 510 and the water supplied through the input pipe 310 may be mixed into the first discharge pipe 320 to be used as disinfectant to disinfect the livestock barn. . The disinfectant water has a chlorine dioxide concentration of 10 to 300 PPM, but during normal livestock disinfection, the chlorine dioxide concentration of the disinfectant water is set to 10 to 150 PPM, and if an infectious disease such as foot-and-mouth disease or bird flu occurs in another region, the concentration of chlorine dioxide is 150 It is possible to strongly disinfect the livestock house at 300 PPM.

The chlorine dioxide solution 150 introduced through the second injection lancer 520 and the water supplied through the input pipe 310 are mixed in the second discharge pipe 330 to be adjacent to a farmhouse or barn operating a barn. Can be used as drinking water for other farms. The drinking water is made to have a chlorine dioxide concentration of 0.2 to 2 PPM.

On the other hand, in the case of disinfectant water after passing through the first discharge pipe 320 is moved to the barn through which disinfection water is used through the disinfection water discharge pipe 350. At this time, the disinfection water discharge pipe 350 is formed with a short distance, the mixing tank 600 is located at the end. The disinfectant water discharge pipe 350 connects the first discharge pipe 320 and the mixing tank 600 to a hollow tube.

The disinfectant water moved through the disinfecting water discharge pipe 350 enters the mixing tank 600 and is stirred in the mixing tank 600, thereby making it possible to uniformize the chlorine dioxide concentration of the disinfecting water.

The mixing tank 600 is the inlet side is connected to the disinfection water discharge pipe 350, the outlet side is connected to the disinfection water supply pipe 610. The disinfectant water uniformly mixed in the mixing tank 600 is supplied to the barn side through the disinfectant water supply pipe 610. The disinfecting water supplied through the disinfecting water supply pipe 610 is used to disinfect the barn.

On the other hand, in the case of drinking water is discharged through the drinking water discharge pipe 360 connected to the second discharge pipe (330). A drinking water tank 30 is positioned at the end of the drinking water discharge pipe 360, and the drinking water collected in the drinking water tank 30 is supplied to each consumer 40. At this time, the customer 40 is a farmhouse that operates the barn or another farmhouse adjacent to the barn, and is used as a drinking water source in the place of use.

The automatic chlorine injector for both drinking and sterilizing water of the present invention further includes a bypass pipe 700.

The bypass pipe 700 is a hollow tube connected to the first discharge pipe 320 and the water passing through the first discharge pipe 320 without passing through the disinfection water discharge pipe 350, the mixing tank 600 Skip and serves to supply directly to the disinfection water supply pipe (610). The bypass pipe 700 includes a valve on one side so as not to be used when chlorine dioxide is added and used as disinfecting water, and a tip thereof is disposed between the input pipe 310 of the branch pipe 300 and the first discharge pipe 320. In the upper portion than the first injection lancer 510, the rear end is preferably connected to the disinfection water supply pipe 610, it is preferably connected to the disinfection water supply pipe 610 adjacent to the mixing tank 600.

In addition, a check valve (not shown) is further added between the bypass pipe 700 connected to the disinfecting water supply pipe 610 and the mixing tank 600 to prevent backflow into the mixing tank 600. The water supplied from the bypass pipe 700 is not supplied to the mixing tank 600.

The bypass pipe 700 is used to replace the disinfecting water remaining in the disinfecting water supply pipe 610 with general water after the use of the disinfecting water. That is, after the use of the disinfectant water, the water passing through the first discharge pipe 320 in the state in which the supply of the chlorine dioxide solution 150 to the first injection lancer 510 is stopped by the integrated controller 210 is Through the bypass pipe 700 is introduced into the disinfection water supply pipe 610, the disinfection water is pushed into the disinfection water supply pipe 610. This prevents the corrosion and damage of the discharge valve 800 to be described later due to the remaining of the disinfecting water in the disinfecting water supply pipe 610. It is common to disinfect the house not every day, but at regular intervals or at a different chlorine dioxide concentration when certain circumstances occur. If chlorine dioxide is not sealed because of high volatility, chlorine dioxide volatilizes from the end of the pipe, and the chlorine dioxide concentration in the disinfecting water supply pipe 610 is different for each position. Can be lowered. In particular, when an infectious disease occurs and a strong disinfection occurs, even if the disinfection water concentration determined by the farm has already been used and disinfection, the chlorine dioxide concentration in the actual disinfection water supply pipe 610 is lower than the actual concentration due to volatilized chlorine dioxide. Can be generated. Therefore, in order to disinfect the livestock house with a concentration of chlorine dioxide determined according to the surrounding conditions, the livestock breeding farmer must empty the inside of the disinfected water supply pipe 610. The bypass pipe 700 is to solve this problem.

The automatic chlorine injector for both drinking and sterilizing water of the present invention further includes a discharge valve 800.

The discharge valve 800 is installed at the end of the disinfection water supply pipe 610, and serves to open and close the injection of the disinfection water supplied from the disinfection water supply pipe 610. The discharge valve 800 is a manual or electronic valve is provided with an LED 810, an LCD 820 and a switch 830 on the outside.

The LED 810 is red or green to indicate whether the water passing through the discharge valve 800 is disinfecting water or general water. For example, if it's red, it's normal, and if it's green, it's disinfected. Here, the general means pure water that does not contain the chlorine dioxide solution 150 in raw water.

The LCD 820 displays, in a message form that a user can recognize, how many seconds after disinfecting water is sprayed, when general water is contained in the disinfecting water supply pipe 610. For example, the message 'Sterile water is sprayed after 5 seconds' is displayed, and 'Sterile water is being sprayed' after the count is completed in seconds.

When the length of the disinfection water supply pipe 610 (more accurately, the length of the disinfection water supply pipe 610 from where the check valve is provided) is input on the integrated controller 210 through the operation button 214, the Depending on the length of the disinfection water supply pipe 610, the time taken to discharge all the water or disinfection water remaining in the disinfection water supply pipe 610 (more precisely the water remaining in the disinfecting water supply pipe 610 or disinfection water from the check valve) It is possible to calculate, and thus display the message on the LCD 820. In addition, when the countdown displayed on the LCD 820 is completed, the color of the LED 810 may be differently displayed according to the type of water supplied from the disinfectant water supply pipe 610.

The changeover switch 830 sends a control signal to the integrated controller 210 to control whether or not the chlorine dioxide solution 150 is introduced into the first discharge pipe 320 from the first injection lancer 510. The changeover switch 830 may control whether or not the chlorine dioxide solution 150 is input in a toggle manner, or may have a plurality of buttons.

When the changeover switch 830 is a toggle type, disinfecting water is supplied to the disinfecting water supply pipe 610 while the button is pressed. After the use of the disinfectant water is pressed once more the conversion switch 830 the general water that does not contain the chlorine dioxide solution 150 is introduced into the disinfectant water supply pipe 610, accordingly the LCD 820 and LED Information is displayed at 810. In this case, as described above, the LCD 820 and the LED 810 change after a time corresponding to the length of the disinfecting water supply pipe 610 passes.

When the disinfectant is left in the disinfectant water supply pipe 610 after the disinfectant water supply operation through this, the user can be supplied to the disinfectant water supply pipe 610 by the conversion switch 830 to the disinfectant water supply pipe 610 By discharging all remaining disinfectant water, it is possible to prevent corrosion of the disinfectant water supply pipe 610 and damage of the discharge valve 800 due to disinfectant water.

On the contrary, when disinfecting water is supplied to the disinfecting water supply pipe 610 by the changeover switch 830 in a state in which the general water is filled in the disinfecting water supply pipe 610, the discharge valve through the LCD 820 and the LED 810. By accurately indicating the time when the disinfectant comes out, the disinfectant water having a low chlorine dioxide concentration is sprayed on the barn or the barn article so that the disinfecting effect of the determined chlorine dioxide concentration is diluted even if it is sprayed later. This prevents you from failing.

The discharge valve 800 is connected to the integrated controller 210 in a wired or wireless manner, the time that the disinfecting water or the general product remaining in the disinfecting water supply pipe 610 calculated by the integrated controller 210 is completely discharged The value may be received and displayed on the LCD 820.

The automatic chlorine feeder for both drinking and disinfecting water of the present invention further includes a residual water storage tank 900.

The residual water storage tank 900 is installed adjacent to the discharge valve 800, and is a tank for storing the residual disinfecting water or the residual general discharged from the disinfecting water supply pipe 610.

The residual water storage tank 900 is connected when discharging the residual disinfecting water or the general residue in the disinfection water supply pipe 610, so that they can be stored. The water stored in the residual water storage tank 900 may be used for the cleaning of the barn. The discharge valve 800 is installed at the end of the disinfection water supply pipe 610, it can be selected whether to supply to the residual water storage tank 900 or directly to the disinfection station according to the state of the water or sterilized water stored therein It can be a three-way valve.

1 is a schematic view showing the configuration of the automatic chlorine dioxide injector for both drinking and disinfecting water according to an embodiment of the present invention, Figure 3 is a display 212 in the automatic chlorine dioxide injector for both drinking and sanitizing water according to an embodiment of the present invention ) Is an enlarged view.

The display 212 and the operation button 214 are divided into two parts (a) and (b). (a) shows the accumulated flow rate and the instantaneous flow rate of the water passing through the first discharge pipe 320 through the display 212, and shows the chlorine dioxide concentration of the disinfectant water set by the user in units of PPM. In addition, the remaining amount of the chlorine dioxide solution 150 remaining in the reactor 130 is displayed.

When the chlorine dioxide concentration is set through the operation button 214, the first injection lancer 510 is adapted to the amount of water measured by the first flowmeter 410 by the integrated controller 210 according to a set value. The chlorine dioxide solution 140 is introduced into the first discharge pipe 320 to mix the water and the chlorine dioxide solution. Accordingly, the sterilizing water is generated according to the chlorine dioxide concentration set by the operation button 214. Although the chlorine dioxide set concentration is shown as 10 PPM in the drawing as an example, the chlorine dioxide concentration can be changed as necessary with the operation button 214.

(b) displays the integrated flow rate and the instantaneous flow rate of the water passing through the second discharge pipe 330 through the display 212. In addition, the chlorine dioxide concentration of the drinking water set by the user is displayed in units of PPM. In addition, the remaining amount of the chlorine dioxide solution 150 remaining in the reactor 130 is also displayed.

When the chlorine dioxide concentration is set through the operation button 214, the second injection lancer 520 is adapted to the amount of water measured by the second flowmeter 420 by the integrated controller 210 according to a set value. The chlorine dioxide solution 150 is introduced into the second discharge pipe 330 to mix the water and the chlorine dioxide solution. Accordingly, the drinking water is generated according to the chlorine dioxide concentration set by the operation button 214. Although the chlorine dioxide set concentration is represented as 0.2 PPM in the drawing as an example, the chlorine dioxide concentration can be changed by the operation button 214.

Figure 1 is a schematic diagram showing the configuration of the automatic chlorine dioxide injector for both drinking and sterilizing water according to an embodiment of the present invention, Figure 4 is a discharge valve ( 800 is an enlarged schematic diagram.

When disinfecting water is sprayed directly on the inside or outside of the barn or the article used in the barn, the disinfection water is opened and closed at the end of the disinfection water supply pipe 610. Then, the disinfecting water is injected through the discharge valve 800, and the barn is disinfected by the disinfecting water.

In this case, the chlorine dioxide solution 150 introduced from the first injection lance 510 is mixed with water in the first discharge pipe 320 firstly, and passes through the disinfecting water discharge pipe 350 and then, in the mixing tank 600. Because the tea is mixed evenly, the concentration of disinfectant water is discharged uniformly.

Since chlorine dioxide contained in the disinfectant water has a property of volatilizing in the air, volatilization of chlorine dioxide occurs inside the barn, and the air is also sterilized.

On the other hand, the distance from the branch pipe 300 to the barn is at least 50 meters to 200 meters apart, after the end of the disinfection water spraying operation disinfecting water in the disinfection water supply pipe 610 connected to the mixing tank 600 Will remain. The disinfecting water supply pipe 610 may cause corrosion or damage to a connection portion with the discharge valve 800 due to the remaining disinfecting water.

In order to prevent this, in the present invention, the LED 810 and the LCD 820 are placed on the discharge valve 800, and the integrated controller 210 is connected in a wired or wireless manner. And to the integrated controller 210 to input the length of the disinfection water supply pipe 610.

After the user finishes spraying the disinfecting water through the discharge valve 800, the residual water storage tank 900 and the discharge valve 800 is connected before withdrawing the residual disinfecting water of the discharge valve 800.

 When the changeover switch 830 is disposed on the discharge valve 800, the supply of the chlorine dioxide solution 150 is stopped by the first injection lancer 510, and the dioxide is passed through the bypass pipe 700. Water without chlorine is introduced into the disinfecting water supply pipe 610. At this time, the LCD 820 displays a message '5 seconds before the discharge of raw water'. When the second countdown of the message displayed on the LCD 820 is completed, the LED 810 changes from 'green' to 'red'. Through this, the user can know that the general water is injected through the discharge valve 800. This locks the discharge valve 800.

This prevents corrosion of the disinfecting water supply pipe 610 and damage of the discharge valve 800 due to residual disinfection water of the disinfecting water supply pipe 610 after disinfecting water is discharged.

On the contrary, when the disinfecting water is to be injected through the discharge valve 800, the discharge valve 800 is pressed once more in the state in which the discharge valve 800 is connected to the residual water storage tank 900, and the discharge valve Open (800). Then, the chlorine dioxide solution 150 is introduced into the first discharge pipe 320 by the first injection lancer, and the first disinfecting water mixed with the chlorine dioxide solution 150 is firstly discharged into the first discharge pipe 320. ) And the disinfection water discharge pipe 350 connected to the mixing tank 600, the disinfecting water mixed in a second uniform concentration in the mixing tank 600 passes through the mixing tank 600 to the disinfection water supply pipe It is moved to the discharge valve 800 through 610.

At this time, water without chlorine dioxide remains in the disinfecting water supply pipe 610, and this water is replaced with disinfecting water. At this time, the LCD 820 is displayed a message '5 seconds before the disinfection water discharge'. When the second countdown of the message displayed on the LCD 820 is completed, the LED 810 changes from 'green' to 'red'. Through this, the user can know that the disinfecting water is sprayed through the discharge valve 800. Then, after the discharge valve 800 is locked, the discharge valve 800 is separated from the residual water storage tank 900 and opened again. In the discharge valve 800, a disinfecting unit having a uniform concentration is discharged.

Through this, when spraying the disinfection water in the barn, the water without the chlorine dioxide component remaining in the disinfection water supply pipe 610 is sprinkled first, thereby diluting the chlorine dioxide concentration of the disinfection water to prevent the disinfection effect is lowered.

The water stored in the residual water storage tank 900 may be utilized for cleaning the barn, washing the articles used in the barn, or drinking livestock. The present invention can be used in places or articles that require disinfection or sterilization in addition to the barn.

In the present invention, the raw water supplied from the water supply source 1 such as a well or a water supply source is introduced through the input pipe 310 of the branch pipe 300, and the raw water introduced into the input pipe 310 for drinking water and livestock disinfection. The chlorine dioxide is supplied to the discharge pipe, and the concentration of chlorine dioxide injected into each injection lance is controlled according to the amount of water provided in each discharge pipe, and each necessary chlorine dioxide is different depending on the use of the water discharged from each discharge pipe. By providing the concentration, it is possible to supply disinfectant water to a place of use such as a livestock house and drinking water to a place of use such as a farmhouse.

The present invention can supply disinfecting water and drinking water that is harmless to livestock and is safe and excellent in sterilization and can also be used as drinking water for livestock.

The present invention can be used as human drinking water, livestock drinking water and livestock barn disinfection water using one chlorine dioxide generator.

The present invention is suitable as a harmless, non-toxic, non-irritating, drinking water in livestock, and can be installed as a chlorine dioxide generator to disinfect water and drinking water to be safe even when discharged to minimize contamination of the water source.

The present invention can produce a large amount of disinfectant water is able to actively cope with the environmental changes of the livestock stalls.

Further, the present invention after sterilizing the use of the barn, etc. through the disinfection water supply pipe 610, the water to the disinfection water supply pipe 610 past the mixing tank 600 through the bypass pipe 700 connected to the first discharge pipe 320. Since the disinfecting water remaining in the disinfecting water supply pipe 610 may be discharged by supplying raw water of the supply source 1, there is an effect of preventing corrosion and damage of the disinfecting water supply pipe 610 due to the remaining disinfecting water.

In addition, the present invention informs the user when the disinfection water remaining in the disinfection water supply pipe 610 is completely escaped or when the raw water located in the disinfection water supply pipe 610 is completely escaped to remove the residual disinfection water in the disinfection water supply pipe 610 When preventing the waste of raw water, and when removing the raw water in the disinfection water supply pipe 610, while preventing the waste of sterilization water, there is an effect of preventing the degradation of the sterilization effect due to the spraying of raw water.

On the other hand, according to the present invention, the disinfectant water sprayed to the place of use of the livestock by the disinfectant water supply pipe 610 has the effect of volatilizing performance of chlorine dioxide, so that the space sterilization inside the livestock is possible even without spraying the disinfectant separately in the air.

1: water supply
10: basic concrete 30: drinking water tank 40: customer
100: chlorine dioxide generator
110: sodium chlorite solution tank 111: pump 113: valve 115: sensor
120: hydrochloric acid solution tank 121: pump 123: valve 125: sensor
130: reactor
140: chemical control controller
150: chlorine dioxide solution
160: level sensor
200: input base
210: integrated controller 212: display 214: operation buttons
220: metering pump 222: pump valve
230: warning light 240: door
250: first drug supply pipe 260: second drug supply pipe
270: first signal line 280: second signal line
290 power line
300: branch pipe
310: input pipe
320: first discharge pipe 322: first insertion hole
330: second discharge pipe 332: second insertion hole
340: non-return valve
350: disinfection water discharge pipe 360: drinking water discharge pipe
400: dual flow meter
410: first flow meter 420: second flow meter
500: injection lance
510: first injection lance 520: second injection lance
600: Mixing Tank
610: disinfection water supply pipe
700: bypass tube
800: discharge valve
810: LED 820: LCD 830: Switch
900: residual water storage tank

Claims (8)

In a chlorine dioxide injector providing different chlorine dioxide concentrations in one chlorine dioxide generator,
Dioxide including sodium chlorite (NaClO ₂ ) solution tank, hydrochloric acid (HCl) solution tank, reactor and medicine control controller for receiving and mixing sodium chlorite (NaClO ₂ ) solution and hydrochloric acid (HCl) solution from each solution tank Chlorine (ClO ₂ ) generator;
A built-in main body having a plurality of metering pumps for receiving a chlorine dioxide solution from the reactor and having an integrated controller;
An input pipe receiving water from a water supply source, a first discharge pipe branching the water introduced into the input pipe in two directions, and a branch pipe formed with a second discharge pipe;
A dual flow meter installed in each of the first discharge pipe and the second discharge pipe, the first flow meter measuring the amount of water passing through the first discharge pipe and the second discharge pipe, and the second flow meter being provided; And
A first injection lance and a second injection respectively inserted into the first discharge pipe and the second discharge pipe to receive the chlorine dioxide solution from the metering pump, and to inject the chlorine dioxide solution into the first discharge pipe and the second discharge pipe, respectively. Including; injection lancer is provided with a lancer,
Chlorine dioxide concentrations in the first discharge pipe and the second discharge pipe are different from each other;
The chlorine dioxide solution introduced through the first injection lance in the first discharge pipe and the water supplied through the input pipe are used as disinfectant to disinfect the livestock house, and the second injection lance in the second discharge pipe. While using the chlorine dioxide solution and the water supplied through the inlet tube mixed with drinking water,
A mixing tank is additionally provided to uniformize the chlorine dioxide concentration of the disinfectant water, and the rear end of the first discharge pipe and the inlet of the mixing tank are connected to the disinfection water discharge pipe, and the outlet of the mixing tank is connected to the disinfection water supply pipe.
Automatic chlorine dioxide dispenser for drinking and sanitizing water.
The method of claim 1,
The chlorine dioxide (ClO ₂ ) generator is a pump for inputting each stored solution in each solution tank to the reactor by a predetermined amount, a sensor for sensing the flow rate of each solution introduced into the reactor from each solution tank and the solution Chemical control controller for controlling the amount of the solution stored in the tank to the reactor
Automatic chlorine dioxide dispenser for drinking and sanitizing water.
delete delete The method of claim 1,
After the use of the disinfectant water, the bypass pipe is additionally provided to replace the disinfectant water remaining in the disinfectant water supply pipe with general water,
A tip of the bypass pipe is connected between the first injection lance and the injection pipe,
The rear end of the bypass pipe is connected to the disinfection water supply pipe,
Automatic chlorine dioxide dispenser for drinking and sanitizing water.
The method of claim 5,
After disinfecting water passes through the disinfecting water supply pipe and the supply of the chlorine dioxide solution from the first injection lance is finished, water passing through the first discharge pipe is introduced into the disinfecting water supply pipe through the bypass pipe.
Automatic chlorine dioxide dispenser for drinking and sanitizing water.
The method according to claim 1 or 6,
A discharge valve serving to open and close the injection of the disinfectant water supplied from the disinfectant water supply pipe is further provided at the end of the disinfectant water supply pipe,
The discharge valve includes an LED, an LCD and a changeover switch,
The discharge valve is connected to the integrated controller in a wired or wireless manner, and receives the time value for completely discharging the disinfecting water or general water remaining in the disinfecting water supply pipe calculated by the integrated controller to display on the LCD,
Automatic chlorine dioxide dispenser for drinking and sanitizing water.
The method of claim 6,
A check valve is further provided between the disinfecting water supply pipe and the mixing tank.
Automatic chlorine dioxide dispenser for drinking and sanitizing water.

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