KR20150141400A - Wastewater disinfection and dissolved oxygen device - Google Patents

Abstract

A UV sterilizing device of the present invention having functions of dissolving oxygen and injecting medicine for a water treatment may include: a discharging water purification process unit which has a dissolution unit pulverizing and dissolving the discharging water and purificatory gas by supplying the purificatory gas to the processed discharging water; a UV sterilizing unit which is connected to a discharging hole of the dissolution unit through a third pipeline; a final discharging tank which stores the discharging water ejected from a discharging hole of the UV sterilizing unit; a final discharging purifying unit which maintains a set water quality state of the discharging water; a purification detecting sensor which detects the purification state of the water in the final discharging tank by being installed in the final discharging tank; and a control unit which controls the operation of the discharging water purification process unit, the UV sterilizing unit, and the final discharging purifying unit. The UV sterilizing device of the present invention having functions of dissolving oxygen and injecting medicine can selectively supply at least one purificatory gas such as oxygen, ozone, and chlorine depending on the water quality state of the discharging water, increase the purification rate of the discharging water by dissolving the purificatory gas in the discharging water by pulverizing the purificatory gas particles in the state that the discharging water and the purificatory gas are mixed, and efficiently improve the purification rate of the discharging water by maintaining the discharging water stored in the final discharging tank in the initial purification state.

Description

{Wastewater disinfection and dissolved oxygen device}

More particularly, the present invention relates to an ultraviolet sterilizer having a function of injecting water for treatment and dissolving oxygen, and more particularly, to an ultraviolet sterilizer having a function of dissolving gas oxygen and oxygen in the atmosphere directly or indirectly into discharged water having no dissolved oxygen content, The present invention relates to an ultraviolet sterilizer having a function of injecting water for treatment and dissolving oxygen which effectively releases a large amount of dissolved water rich in dissolved oxygen concentration and effectively improves ecosystem composition and water quality.

A dissolving apparatus that dissolves a gas is typically used to treat wastewater to increase the dissolved oxygen content in the water. It is necessary not only to preserve the life of fish or other aquatic organisms, but also to keep the amount of dissolved oxygen above a predetermined value for the purpose of suppressing odor and inhibiting the production of organic substances. Biochemical oxygen demand is determined by the amount of oxygen required for biological processes that destroy organic matter in the water. The higher the biochemical oxygen demand, the greater the amount of organic matter in the water and the greater the amount of dissolved oxygen needed to destroy it it means. The gas dissolving apparatus is very useful for increasing the amount of dissolved oxygen, and is particularly useful when the biochemical oxygen demand is high.

Korean Patent No. 10-0784509 discloses a photocatalytic water treatment unit and a gas-mixing type water treatment unit having the same.

The disclosed water treatment apparatus includes a unit tube coated with a photocatalyst and having an ultraviolet lamp inserted therein, and at least one unit tube, and the space between the processing water inlet and the outlet is blocked, so that the residence time of the treated water flowing through the unit tube And a unit tube support configured to keep the flow rate constant.

However, this prior art has a disadvantage in that the purified state is weakened over time after being stored until the purified effluent is discharged, and is discharged without maintaining the initial purification state.

Disclosure of the Invention The present invention has been made to solve the above-mentioned problems, and it is an object of the present invention to provide an ultraviolet sterilizer having a function of introducing a chemical for water treatment and oxygen dissolving function for selectively supplying oxygen, chlorine or ozone, do.

In order to accomplish the above object, the present invention provides an ultraviolet sterilizer having a water treatment chemical loading function and an oxygen dissolution function, comprising: a supply unit that supplies a purifying gas to the water treatment water to finely pulverize the discharged water and the purifying gas, An outlet water purification unit having an inlet and an outlet; An ultraviolet sterilizing unit connected to an outlet of the dissolving unit through a third duct; A final discharge purification unit including a final discharge tank for storing discharged water discharged from an outlet of the ultraviolet sterilizing unit and capable of maintaining a water quality of the discharged water; And a control unit for controlling the operation of the discharged water purification unit, the ultraviolet sterilizing unit, and the final discharge purification unit, wherein the purification sensor is installed in the final discharge tank and detects a state of purification of water in the final discharge tank .

The purifying gas may be any one or more of oxygen, chlorine, and ozone.

Wherein the dissolving unit comprises: a cylindrical rotor mounting portion formed with a plurality of main mixing chambers partitioned by an inner circumferential surface; a housing having an outlet communicating with the rotor mounting portion at one side; and a premixing chamber coupled to the other side of the housing, A main body having a cover member having an inlet port through which the purified water and the purifying gas are introduced, and a rotor unit installed on a rotating shaft rotatably supported by the housing, wherein the rotor unit has first blades formed on an outer circumferential surface thereof, A first rotor formed coaxially with the first rotor and having a plurality of second blades formed on an outer circumferential surface thereof and a second auxiliary mixing chamber formed corresponding to the main mixing chamber; A second rotor and partition dividing plates provided between the first and second rotors and partitioning the first and second auxiliary mixing chambers, Characterized in that a plurality of projections formed on the outer circumferential surface the first and second blade of the emitter.

The final discharge purification unit includes a mixing pump installed in the final discharge tank, a discharge pipe connected to the mixing pump, and a crusher connected to the other end of the discharge pipe to crush discharged water conveyed from the final discharge tank Wherein the crushing unit includes a connection pipe connected to the discharge pipe so that the discharge water can flow into the crusher, and a plurality of crushers installed inside the connection pipe to collide with the discharge water, And at least two impingement plates spaced from each other along the longitudinal direction of the connection pipe.

The ultraviolet sterilizer having the function of introducing water treatment chemicals and dissolving oxygen according to the present invention can selectively supply one or more purifying gases such as oxygen, ozone, and chlorine according to the water quality of the discharged water. In the state where the discharged water and the purifying gas are mixed The purifying rate of the discharged water is increased by dissolving the purifying gas in the discharged water by finely pulverizing the purifying gas particles in the discharged water, and the discharged water stored in the final discharge tank before discharging can be maintained at the initial purification state at all times, Can be improved.

FIG. 1 is a configuration diagram showing the overall configuration of an ultraviolet sterilizer having a water treatment chemical input and oxygen dissolving function according to the present invention,
Fig. 2 is a cross-sectional view schematically showing a dissolution part applied to Fig. 1,
FIG. 3 is an exploded perspective view of the rotor unit of FIG. 2,
FIG. 4 is an exploded perspective view showing the structure of the final discharge purification unit applied to FIG. 1; FIG.

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an ultraviolet sterilizer having a water treatment chemical introduction function and an oxygen dissolving function, and one embodiment thereof is shown in Fig. 1 to Fig.

Referring to FIG. 1, the ultraviolet sterilizer having a function of introducing a chemical for water treatment and dissolving oxygen according to the present invention comprises a dissolving unit 300 having a dissolving unit 300 for selectively supplying a purifying gas to water- An ultraviolet sterilizing unit 40 connected to the unit 10 through the dissolving unit 300 and the third duct 18 and a final discharging tank 550 storing the discharged water discharged from the ultraviolet sterilizing unit 40 And a control unit 70 including a purification sensor 72 installed in the final discharge tank 550. The control unit 70 includes a control unit 70,

The discharged water purification unit 10 includes an effluent water supply tank 11 for storing treated water to be treated, a purifying gas unit 20, a dissolving unit 20 for crushing the water- 300).

The supply port 12 of the discharge water supply tank 11 and the injection port 327 of the dissolution part 300 are connected to the first pipe 14, Respectively.

A dissolving pump 15 is provided on the first conduit 14 for transferring the discharged water from the discharged water supply tank 11 to the dissolving unit 300. A first valve 16 is provided in the first conduit 14 between the supply port 12 of the discharge water supply tank 11 and the dissolution pump 15. The first valve 16 may be a solenoid valve.

The purifying gas unit 20 is provided for selectively supplying oxygen, chlorine and ozone, which are purifying gas, to the dissolving unit 300. The purifying gas unit 20 includes a second channel 17 branched at one end from the first channel 14, A second branch passage 22 and a third branch passage 23 branched from the other end of the second conduit 17 and connected to the first branch passage 21 A chlorine tank 212 connected to the second branch passage 22 and an ozone tank 213 connected to the third branch passage 23. A second valve (24) is provided on the second conduit (17), and a solenoid valve may be applied to the second valve (24). Preferably, the oxygen tank 211, the chlorine tank 212, and the ozone tank 213 may be installed in only one of the branch pipes regardless of the order. The first, second and third branch conduits 21, 22 and 23 are provided with first, second and third branch valves 25, 26 and 27, respectively, So that it can be supplied to the dissection 300.

Referring to FIG. 2, the dissolving unit 300 includes a main body 320 having an outlet 321 formed at one side thereof and having a rotor mounting portion 322, A rotor unit 330 installed on the rotor mounting portion 322 and mounted on the rotary shaft 324 rotatably installed on the housing 323 and a rotary shaft 324 coupled to the housing 323, And a motor 340 for rotating the motor.

A plurality of main mixing chambers 325 are formed in the inner circumferential surface of the rotor mounting portion 322 formed in the housing 323 of the main body 320. The main mixing chambers 325 are formed from the inner circumferential surface of the rotor mounting portion 322 Ribs 325a are formed at the boundary of the main mixing chamber 325. [ The main mixing chambers 325 may be arranged in the circumferential direction of the rotor mounting portion 320, and are preferably installed at positions corresponding to the blades of the rotor unit 320 described later.

The housing 323 is coupled to the other side of the housing 323 corresponding to the side on which the outlet 321 is formed to form a premixing chamber 326 and a cover member 328 having an injection port 327 formed therein. The inlet 327 of the cover member 328 is provided with a check valve 329 for preventing mixed water of the discharged water and the purifying gas flowing into the rotor mounting portion 322 or the premixing chamber 326 through the injection port 327 Is installed.

Referring to FIG. 3, the rotor unit 330 is rotatably installed in the rotor mounting portion 322 of the housing 323 to dissolve the purifying gas in the discharged water. The rotor unit 330 includes first blades 331 and first A first rotor 332 formed coaxially with the first rotor 332 and having a plurality of second blades 333 formed on the outer circumferential surface thereof and a plurality of second blades 333 corresponding to the main mixing chamber 325, And a second rotor 335 forming a second auxiliary mixing chamber 334b. A partition plate 336 for partitioning the first and second auxiliary mixing chambers 334a and 334b in the circumferential direction is provided between the first and second rotors 332 and 335. A through hole (not shown) may be formed in the partition plate 336 to allow the first and second auxiliary mixing chambers 334a and 334b to communicate with each other.

On the outer circumferential surface of the first and second rotors 332 and 335, a plurality of grooves are formed in the longitudinal direction, thereby forming protrusions 337. The protrusions 337 are preferably formed in the axial direction of the first and second rotors 332 and 335. The first and second auxiliary mixing chambers 334a and 334b are formed with partition walls 47 which are not shown in the figure but which have communication holes so that they can be discharged from the first and second auxiliary mixing chambers 334a and 334b, So that the mixed purifying gas can be refluxed.

The ultraviolet sterilizing unit 40 is for sterilizing ultraviolet rays supplied from the dissolving unit 300. The ultraviolet sterilizing unit 40 includes a case 41 and a plurality of And a partition 47 formed between the ultraviolet lamp 44 and the ultraviolet lamp 44.

A sterilizing inlet 42 is formed in the upper portion of the case 41 so as to communicate with the inside of the case 41 and is connected to the outlet 321 of the dissolving unit 300 by a third duct 18. A discharge port 43 is formed in the lower part of the case 41 so that the fourth pipe 19 is connected to the final discharge tank 550 so that the discharged water flowing into the case 41 can be transferred to the final discharge tank 550.

The ultraviolet lamps 44 are arranged in parallel to the bottom surface of the case 41 in the horizontal direction and are spaced apart from each other in the height direction. A partition wall 47 is formed in a direction parallel to the ultraviolet lamp 44 between the ultraviolet lamps 44 positioned in the up and down direction so that the effluent water can be brought into contact with the outer surface of the respective ultraviolet lamps 44. One end of the partition wall 47 is formed at a predetermined distance from the inner wall of the case 41 and the other end of the partition wall 47 located above or below the partition wall 47 is spaced apart from the inner wall of the case 41 by a predetermined distance. The discharge water flowing from the upper surface of the case 41 is moved toward the discharge port 43 formed in the lower portion of the case 41 in a zigzag manner along the partition wall 47 and comes into contact with the respective ultraviolet lamps 44. The ultraviolet sterilizer 40 allows the organic matter in the discharged water to be removed through the ultraviolet rays irradiated from the ultraviolet lamp 44 when the discharged water contacts the respective ultraviolet lamps 44.

The structure of the ultraviolet sterilizing unit 40 is not limited to this, and any structure capable of removing organic matter in the discharged water through ultraviolet rays is applicable.

The final discharge purification unit 500 is applied to the oxygen dissolution aeration apparatus of Patent No. 10-1333298 filed by the present applicant.

4, the final discharge purification unit 500 stores the discharge water discharged from the ultraviolet sterilizing unit 40, and the water quality of the stored discharge water can be maintained at a predetermined value. The final discharge purification unit 500, A mixing pump 510 installed in the final outlet tank 550 and a discharge pipe 520 connected to the mixing pump 510. The discharge pipe 520 is connected to the other end of the discharge pipe 520, And a crushing unit 530 for crushing the discharged water conveyed from within the final effluent tank 550.

The mixing pump 510 is installed in the final discharge tank 550 and is controlled to be driven when the dissolved oxygen amount of the discharged water detected by the DO sensor included in the purification sensor 72 described below is less than the set dissolved oxygen amount, .

The discharge pipe 520 allows the discharge water stored in the final discharge tank 550 to be transferred to the crushing unit 530 by the mixing pump 510. One end and the other end of the discharge pump 520 are connected to the mixing pump 510, (530). The first flange portion 521 may be formed at the other end connected to the crushing portion 530.

The crushing unit 530 includes a connection pipe 531 connected to the other end of the discharge pipe 520 and a first pipe 531 installed inside the connection pipe 531 to collide with the discharge water flowing into the connection pipe 531. [ 533, and 536, respectively.

The connection pipe 531 is formed in a pipe shape extending in the vertical direction and provided with a flow path through which the discharge water flows. The upper end of the connection pipe 531 is connected to the first flange member 521 of the discharge pipe 520, (538) are formed. The second flange member 538 extends along the circumferential direction on the upper peripheral surface of the upper end of the connecting pipe 531. The second flange member 538 fastens the first nut to the end of the first fixing bolt to connect the discharge pipe 520 and the connection pipe 531 in a mutually communicable manner.

The first impingement plate 532 is formed in a disk shape having an outer diameter corresponding to the inner diameter of the connection pipe 531 and a plurality of first through holes 533 having a first inner diameter are formed so that the discharge water can pass therethrough .

The second impingement plate 534 is provided on the connection pipe 531 behind the first impingement plate 532 with respect to the flow of the discharged water and is formed in a disk shape having an outer diameter corresponding to the inner diameter of the connection pipe 531, A plurality of second through holes 535 are formed so that the discharged water can pass through. At this time, the second through hole 535 has a second inner diameter different from the first inner diameter of the first through hole 533. The second impingement plate 534 may have a total area of the second through holes 535 in the range of 0.95 to 1.05 with respect to the sum of the areas of the first through holes 533 so as to reduce the resistance to the flow of the discharged water. The sum of the areas of the first through holes 533 and the sum of the areas of the second through holes 535 are formed to be equal to each other.

The third impingement plate 536 is provided on the connection pipe 531 behind the second impingement plate 534 with respect to the flow of the discharged water and is formed into a disc shape having an outer diameter corresponding to the inner diameter of the connection pipe 531, A plurality of third through holes 537 are formed so that the through holes 537 can pass through. At this time, the third through-hole 537 is formed to have a third inner diameter that is different from the second inner diameter of the second through-hole 535.

In the illustrated example, the crushing unit 530 has three collision plates. However, the number of the collision plates is not limited to the illustrated example, but may be two or three or more.

The discharge water injected into the connection pipe 531 collides with and collapses due to the collision plates. The size of the through holes differs depending on the impingement plate, and the generation of vortices is increased or dispersed in the space between the impingement plates, Can be increased.

The transfer pipe 541 is connected to the lower end of the connection pipe 531 so as to extend in the vertical direction and to transfer the discharged water passing through the connection pipe 531 to the final discharge tank 550, The lower end portion of the final discharge vessel 550 is formed so as to be drawn into the final discharge vessel 550 so as to be adjacent to the bottom surface of the final discharge vessel 550.

A fourth flange member 542 is formed at the upper end of the transfer pipe 541 so that the transfer pipe 541 can be easily installed in the connection pipe 531. The fourth flange member 542 extends along the circumferential direction on the outer circumferential surface of the upper end of the transfer pipe 541, and a plurality of through holes are formed at positions spaced apart from each other along the edge so that the second fixing bolt can be inserted therethrough. do. Therefore, the third flange member 539 and the fourth flange member 542 are engaged by the second fixing bolt and the second nut fastened to the end of the second fixing bolt.

A guide member 544 for guiding the discharged water discharged from the transfer pipe 541 to the bottom surface of the final discharge tank 550 is provided at the lower end of the transfer pipe 541. The guide member 544 is provided on the outer circumferential surface of the conveyance pipe 541 at a position spaced upward from the ejection port 543 of the conveyance pipe 541 and extends in a hemispherical shape so as to move away from the conveyance pipe 541 toward the downside. The discharged water that rises upward or rises from the discharge port 543 to the final discharge tank 550 or collides with the bottom surface collides with the guide member 544 and is guided to the bottom surface of the final discharge tank 550.

The final effluent tank 550 is for ultimately storing the discharged water conveyed from the discharge port 43 of the ultraviolet sterilizing unit 40 by the fourth pipeline 19 and discharging the discharged water to a river or the like. And a discharge hole for discharging is formed on the lower side and connected to the discharge pipe 560. A fourth valve 570 is provided in the discharge pipe 560 to regulate the discharge of the discharge water.

In addition, a plurality of carriers 548 are filled in the final outlet tank 550. The carrier 548 is provided with a habitat space so that microorganisms capable of decomposing contaminants in discharged water can be inhabited. 3, the carrier 548 is formed in a cylindrical shape having a hollow to provide a habitat. However, the shape of the carrier 548 is not limited thereto, and any structure capable of living microorganisms may be used Do.

A guide cylinder 546 for guiding the discharged water discharged from the transfer pipe 541 to the bottom surface of the final discharge tank 550 is provided in the final discharge tank 550. The guide tube 546 is formed in a drum shape having an internal space for inserting the transfer tube 541 therein. A discharge hole 547 is formed in the outer peripheral surface of the lower end of the guide tube 546 so that the discharge water discharged from the transfer tube 541 into the guide tube 546 can be discharged into the final discharge tank 550. A plurality of discharge holes 547 are formed at positions spaced apart from each other along the circumferential direction on the outer circumferential surface of the guide cylinder 546.

In addition, the guide cylinder 546 is formed so that the upper surface thereof is opened so that the discharged water in the mixing tank 550 can be introduced through the upper surface. As described above, the guide cylinder 546 discharges the discharged water to the lower side of the final outlet tank 550 through the discharge hole 547 formed at the lower end, and the discharged water flows into the inside through the opened upper surface, Thereby guiding the discharged water to be agitated.

The control unit 70 is provided for controlling the operation of the discharged water purification processing unit 10 and discharging the discharged water stored in the final discharge tank 550 to the set purified state. The control unit 70 is installed in the final discharge tank 550, And a purifying sensor 72 for detecting the purge state of the discharged water stored in the tank 550.

The purification sensor 72 is provided for measuring the quality of the discharged water stored in the final outlet tank 550. Although not shown in the drawing, the DO sensor for measuring the amount of dissolved oxygen, the chlorine concentration A sensor, an ozone sensor for measuring the concentration of ozone, and a water quality sensor for measuring the degree of contamination of the discharged water. The PH sensor can be applied to the water quality measurement sensor.

When the water quality information of the discharged water measured by the purification sensor 72 is transmitted to the control unit 70, the control unit 70 drives the discharged water purification processing unit 10 when the water quality information of the discharged water is worse than the set water quality information So that the required purifying gas is supplied to the dissolving unit 300. When the amount of dissolved oxygen is insufficient, the mixed pump 510 is driven to transfer the discharged water stored in the final discharge tank 550 to the crushing unit 530 to increase the amount of dissolved oxygen. The control unit 70 preferably controls the operation of the dissolving unit 300 or the mixing pump 510 when the water quality information of the discharged water in the final discharge tank 550 detected by the purification sensor 72 matches the set water quality information .

The operation of the ultraviolet sterilizer having the oxygen dissolution function and the introduction of the water treatment agent of the present invention will be described in detail.

First, the motor 340, the ultraviolet lamp 44 and the dissolving pump 15 of the dissolving unit 300 are operated through the control unit 70, the first valve 16 is opened to be water-treated, 11 to be supplied to the dissolving unit 300 through the dissolving pump 15. Next, the second valve 24 is opened to select at least one of oxygen, chlorine, and ozone in the purifying gas 20, and the branch valve connected to the selected purifying gas tank is opened to the dissolving unit 300 . The discharged water and the purifying gas are introduced into the premixing chamber 326 through the injection port 327 of the dissolving unit 300 and transferred to the rotor unit 330 side. The discharged effluent and purifying gas are introduced between the first rotor 332, the second rotor 335 and the inner circumferential surface of the housing 323 and are pulverized. In this process, the first and second blades 331, 333, And further finely pulverized by the projections 337.

The purified water in which the purifying gas is dissolved is transferred to the ultraviolet sterilizing unit 40 through the third conduit 18 connected to the outlet 321 of the dissolving unit 300. The discharged water is transported in contact with the respective ultraviolet lamps 44 along the partition walls 47 in the case 41 of the ultraviolet sterilizing unit 40 and the organic substances in the discharged water are removed by ultraviolet rays. The discharged water that has passed through the ultraviolet sterilizing unit 40 flows into the final discharge tank 550 along the fourth duct 19 and is stored until discharged. The purification sensor 72 provided in the final discharge tank 550 measures the quality of the discharged water stored in the final discharge tank 550 and drives the mixing pump 510 when the dissolved oxygen content of the discharged water is lower than the set value And the discharged water is transferred to the crushing unit 530. The discharged water transferred through the discharge pipe 520 flows into the crushing unit 530 of the final discharge purification unit 500 and is crushed by the first, second and third collision plates 532, 534 and 536. Discharged water mixed with each other through the crushing unit 530 is decomposed by the microorganisms in the carrier 548 filled in the receiving space of the final discharge tank 550 along the transfer pipe 541. When the set dissolved oxygen amount becomes abnormal, the control unit controls to stop the driving of the mixing pump. Thereafter, the discharged water is discharged into a stream or the like through the discharge pipe 560 in the final discharge tank 550.

On the other hand, the purification sensor 72 provided in the final discharge tank 550 compares the chlorine concentration and the ozone amount set in addition to the set dissolved oxygen rate with the discharged water to transmit the water quality information of the discharged water to the control unit 70, ) Drives the discharged water purification unit 10 again according to the water quality of the discharged water to supply the necessary purifying gas to the set water quality condition and repeats the above process.

The ultraviolet sterilizer having the function of introducing water treatment chemicals and dissolving oxygen according to the present invention can selectively supply one or more purifying gases such as oxygen, ozone, and chlorine according to the water quality of the discharged water. In the state where the discharged water and the purifying gas are mixed The purifying rate of the discharged water can be increased by dissolving the purifying gas in the discharged water by finely pulverizing the purifying gas particles in the discharged water tank 550. The discharged water stored in the final discharge tank 550 before discharge can be maintained in the purified state for the first time, The purification rate can be effectively improved.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, the present invention is not limited to the above-described exemplary embodiments. Various modifications may be made by those skilled in the art without departing from the scope of the present invention.

10: discharged water purification processing unit
11: Outlet water supply tank
15: Dissolving pump
20: purifying gas
300: dissolution part
40: ultraviolet sterilizer
500: Final discharge purification unit
510: Mixed pump
520: discharge pipe
550: Final discharge tank

Claims (4)

And a dissolving unit for supplying a purifying gas to the water-treated discharged water to finely crush the discharged water and the purifying gas so that they can be mutually dissolved;
An ultraviolet sterilizing unit connected to an outlet of the dissolving unit through a third duct;
A final discharge purification unit including a final discharge tank for storing discharged water discharged from an outlet of the ultraviolet sterilizing unit and capable of maintaining a water quality of the discharged water;
And a control unit for controlling the operation of the discharged water purification unit, the ultraviolet sterilizing unit, and the final discharge purification unit, wherein the purification sensor is installed in the final discharge tank and detects a state of purification of water in the final discharge tank Wherein the ultraviolet ray sterilizer has a function of injecting a water treatment agent and dissolving oxygen. The method according to claim 1,
Wherein the purifying gas is any one or more of oxygen, chlorine, and ozone, and has a function of charging water for treatment and oxygen dissolving function. The method according to claim 1,
Wherein the dissolving unit comprises: a cylindrical rotor mounting portion formed with a plurality of main mixing chambers partitioned by an inner circumferential surface; a housing having an outlet communicating with the rotor mounting portion at one side; and a premixing chamber coupled to the other side of the housing, A main body having a cover member formed with an inlet through which the discharged water and the purifying gas are introduced, and a rotor unit mounted on a rotating shaft rotatably supported by the housing,
The rotor unit includes a first rotor having first blades formed on an outer circumferential surface thereof and having a first auxiliary mixing chamber corresponding to the main mixing chamber, a first rotor coaxially installed with the first rotor, and a plurality of second blades formed on an outer circumferential surface thereof A second rotor provided with a second auxiliary mixing chamber corresponding to the main mixing chamber, and a partition diaphragm provided between the first and second rotors and partitioning the first and second auxiliary mixing chambers, Characterized in that a plurality of projections are formed on the outer circumferential surface of the first and second blades of the rotor. The method according to claim 1,
The final discharge purification unit includes a mixing pump installed in the final discharge tank, a discharge pipe connected to the mixing pump, and a crusher connected to the other end of the discharge pipe to crush discharged water conveyed from the final discharge tank And,
The crushing unit may include a connection pipe connected to the discharge pipe so that the discharge water may flow into the crusher, and a plurality of through holes may be formed in the connection pipe so that the discharge water may collide with the discharge pipe. And at least two impingement plates spaced apart from each other along the longitudinal direction of the connection pipe.

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