KR101896964B1 - Water treatment apparatus using air bubbles ultrasonic waves and system using the same - Google Patents

Abstract

The present invention relates to a water treatment apparatus using an air bubble ultrasonic wave to sterilize a nutrient solution reservoir used in facility horticulture by applying a direct disinfection system to the nutrient solution reservoir, . A water treatment apparatus using an air bubble ultrasonic wave according to the present invention includes an inflow water recovery unit for recovering inflow water, an inflow water cistern for receiving inflow water from the inflow water recovery unit, an inflow water sterilization unit for sterilizing inflow water through an ultrasonic wave and an air bubble, And a treated water discharging portion for receiving and discharging sterilized treated water from the inflow cistern.

Description

TECHNICAL FIELD The present invention relates to a water treatment apparatus using air bubble ultrasonic waves and a sterilizing system using the same.

The present invention relates to a water treatment apparatus, and more particularly, to a water treatment apparatus for sterilizing a nutrient solution reservoir used in facility horticulture by directly applying a sterilizing system to the nutrient solution reservoir, And a sterilizing system using the same.

Facility horticulture is a form of agriculture that intensively cultivates horticultural crops such as vegetables, flowers, and fruit trees in facilities such as vinyl houses, glass greenhouses and plastic houses. This kind of facility horticulture provides environmental conditions suitable for crops through environmental control, unlike the non-production method, so that it can produce stable production with high yield and quality of existing horticultural crops.

On the other hand, the domestic government designates and manages pollutant emission standards (Article 8, Paragraph 1 of the Water Quality Preservation Act - 60 ppm of total nitrogen, 8 ppm of total phosphorus).

However, the nutrient solution used in facility horticulture is rich in nutrients, so that microorganisms tend to propagate in the process of transportation, use, and storage, and are likely to be contaminated by bacteria.

Accordingly, if the waste liquid used in the horticulture is discharged to the sewer through the pump, there is a possibility of exceeding the pollutant discharge allowance standard. Inorganic organic components contained in the discharged waste liquid may cause water pollution and eutrophication of the river It can cause.

In recent years, there have been proposed methods for circulating a spent nutrient solution to solve these problems.

Here, in order to recycle the pulp nutrient solution, it is preferable to suppress the excessive propagation of microorganisms, which can be accomplished through pulmonary fluid sterilization. However, existing disinfection systems using chemicals such as chlorine sterilization are causing problems that can cause obstacles to the growth of plants.

In order to solve such a problem, sterilization using ultraviolet rays has been studied, but a waste liquid sterilization apparatus using ultraviolet rays has a disadvantage in that a separate sterilization apparatus must be provided.

Accordingly, an object of the present invention is to provide a water treatment apparatus using an air bubble ultrasonic wave and a sterilizing system using the same, which enables sterilizing and reusing the waste nutrient solution discharged from facility horticulture with minimum construction and cost.

A water treatment apparatus using an air bubble ultrasonic wave according to the present invention comprises an inflow water recovery unit for recovering inflow water, an inflow water cistern for receiving and storing the inflow water from the inflow water recovery unit, an inflow water cistern provided in the inflow cistern, And a treatment water discharging portion for receiving and discharging sterilized treated water from the inflow water cistern.

In the water treatment apparatus using the air bubble ultrasonic wave according to the present invention, the inflow water sterilizing unit is formed on one surface of the inflow water tube and is formed on one surface of the inflow water tube for sterilizing the inflow water by applying ultrasonic waves to the inflow water, And an air bubbler for supplying an air bubble to the inflow water to support the sterilizing action of the ultrasonic generator.

In the water treatment apparatus using the air bubble ultrasonic waves according to the present invention, the ultrasonic wave generator and the air bubbler are provided in plural in the inflow water cistern.

In the water treatment apparatus using the air bubble ultrasonic wave according to the present invention, the ultrasonic generator includes a first ultrasonic generator for generating ultrasonic waves of 100 kHz or less, a second ultrasonic generator for generating ultrasonic waves in excess of 100 kHz together with the first ultrasonic generator, And an ultrasonic wave generator.

In the water treatment apparatus using the air bubble ultrasonic wave according to the present invention, the inflow water includes waste liquid used in the horticulture, and the inflow water recovery unit recovers the waste liquid from the plant horticulture.

In the water treatment apparatus using the air bubble ultrasonic waves according to the present invention, the inflow water cistern is a nutrient solution reservoir for storing the waste nutrient solution.

The disinfection system according to the present invention comprises a facility gardening for growing a plant, an inflow water recovery unit for recovering inflow water from the plant horticulture, an inflow water reservoir for receiving and storing the inflow water from the inflow water recovery unit, an ultrasonic wave and an air bubble A sterilizing unit for sterilizing the inflow water through the sterilizing unit, and a treatment water discharging unit for receiving and discharging sterilized treatment water from the inflow cistern.

In the disinfection system according to the present invention, the treated water, which is disposed between the facility horticulture and the water treatment apparatus using the air bubble ultrasonic waves and discharged from the water treatment apparatus using the air bubble ultrasonic waves, is mixed with fresh nutrient solution, And a mixing tank for mixing the water and the water.

The water treatment apparatus using the air bubble ultrasonic wave and the disinfection system using the air bubble ultrasonic wave according to the present invention are characterized in that an ultrasonic generator is disposed in an inflow water cistern for recovering inflow water from facility horticulture and storing the inflow water to sterilize inflow water, It can be made sterilizable and reusable.

In the water treatment apparatus using the air bubble ultrasonic wave and the sterilizing system using the air bubble ultrasonic wave according to the present invention, an air injector is disposed in addition to the ultrasonic wave generator in the inflow water cistern to supply air bubbles, thereby circulating inflow water in the inflow water cistern, Can be maximized.

1 is a schematic diagram showing a sterilization system according to an embodiment of the present invention.
2 is a view illustrating a water treatment apparatus using air bubble ultrasonic waves according to an embodiment of the present invention.
3 is a view for explaining an ultraviolet sterilizing unit according to an embodiment of the present invention.
4 is an enlarged view of the area A in Fig.
5 is a view for explaining a sterilizing method of a sterilizing system using an ultraviolet sterilizing unit according to an embodiment of the present invention.
6 is a view for explaining an ultraviolet sterilizing unit according to another embodiment of the present invention.
Fig. 7 is an enlarged view of the area A in Fig. 6; Fig.
8 is a view for explaining a sterilizing method of a sterilizing system using an ultraviolet sterilizing unit according to another embodiment of the present invention.

In the following description, only parts necessary for understanding the embodiments of the present invention will be described, and the description of other parts will be omitted so as not to obscure the gist of the present invention.

The terms and words used in the present specification and claims should not be construed as limited to ordinary or dictionary meanings and the inventor is not limited to the meaning of the terms in order to describe his invention in the best way. It should be interpreted as meaning and concept consistent with the technical idea of the present invention. Therefore, the embodiments described in the present specification and the configurations shown in the drawings are merely preferred embodiments of the present invention, and are not intended to represent all of the technical ideas of the present invention, so that various equivalents And variations are possible.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a schematic diagram showing a sterilization system according to an embodiment of the present invention.

Referring to FIG. 1, a sterilization system 500 according to an embodiment of the present invention includes a facility horticulture 200 and a water treatment apparatus 400 using air bubble ultrasonic waves.

The facility horticulture (200) refers to agriculture that intensively cultivates horticultural crops such as vegetables, flowers, and fruit trees in a facility such as a vinyl house, a glasshouse or a plastic house.

The facility horticulture 200 includes an artificial lighting apparatus that supplies light to plants for cultivating plants as needed, an air conditioning apparatus for cooling and heating and ventilation, and a gas control apparatus for controlling the supply amount of carbon dioxide gas, Lt; / RTI >

The facility horticulture 200 according to an embodiment of the present invention may include a plurality of nutrient supply pipes 210 for supplying nutrients to plants and a waste nutrient solution receptacle 220 for receiving the used nutrient solutions.

The nutrient solution supply pipe 210 is connected to the water treatment device 400 using the air bubble ultrasonic waves and can receive sterilized nutrient solution from the water treatment device 400 using the air bubble ultrasonic waves and supply the nutrient solutions to the plants. Here, the nutrient solution supply pipe 210 may be connected to the water treatment device 400 using the air bubble ultrasonic wave through the first pipe 240, and may be separated from the first pipe 240 to be in contact with the crop tray 230 .

The crop tray 230 can house plants therein. The culture plant accommodated in the crop tray 230 is grown through the nutrient solution supplied from the nutrient solution supply pipe 210. The pulp nutrient solution used from the crop tray 230 is transferred to the pulp nutrient solution receptacle 220.

The waste nutrient solution receptacle 220 may be positioned below the crop tray 230 and may be connected to the water treatment apparatus 400 using the air bubble ultrasonic wave through the second pipe 250. The used pulp nutrient solution collected in the pulp nutrient solution receptacle 220 can be recovered to the water treatment apparatus 400 using the air bubble ultrasonic waves through the second pipe 250.

The sterilization system 500 may further include a suspending agent remover 180 disposed between the waste nourishment receptacle 220 and the water treatment apparatus 400 using air bubble ultrasonic waves. The scum removing unit 180 may transmit the scum to the water treatment apparatus 400 using the air bubble ultrasonic wave with the scum primarily removed from the waste nutrient solution recovered from the waste nutrient solution receiving unit 220.

The water treatment apparatus 400 using the air bubble ultrasonic wave can recover the inflow water through the inflow water collection unit 130 connected to the second pipe 250 from the waste nutrient solution receptacle 220 and sterilize the inflow water. Herein, the inflow water may be pulp nutrient solution used from facility horticulture 200.

The water treatment apparatus 400 using the air bubble ultrasonic wave according to the embodiment of the present invention may include an inflow cistern 120 for storing inflow water and an inflow cistern 120 may be disposed at the bottom of the facility horticulture 200, But it is not limited thereto and may be separately provided outside the facility horticulture 200. That is, the inflow tube 120 may be a waste liquid tank for storing waste liquid used from the facility horticulture 200.

In other words, the water treatment apparatus 400 using the air bubble ultrasonic wave according to the embodiment of the present invention can sterilize the inflow water through the inflow water cistern 120 storing the inflow water, 120 to sterilize the inflow water recovered from the plant horticulture 200.

The water treatment apparatus 400 using the air bubble ultrasonic wave can supply the sterilized treated water to the nutrient solution supply pipe 210 through the treated water discharge unit 110 connected to the first pipe 240.

The treatment water discharge unit 110 or the inflow water recovery unit 130 according to the embodiment of the present invention may further include an ultraviolet sterilizer 100.

The ultraviolet sterilizer 100 may further sterilize the treated water through ultraviolet rays in the process of supplying sterilized treated water from the inflow tube 120 to the horticultural apparatus 200. [

The ultraviolet sterilizing unit 100 may be provided when the number of microorganisms is large in the inflow water in the inflow tube 120 or when the processing capacity is large.

Details of the configuration of the ultraviolet sterilizer 100 will be described later.

The disinfection system 500 according to the embodiment of the present invention is disposed between the facility horticulture 200 and the water treatment apparatus 400 using the air bubble ultrasonic waves and is disposed between the disinfection apparatus 400 using the air bubble ultrasonic wave And a mixing tank 170 for mixing the treated water with the new nutrient solution and supplying the treated nutrient to the facility horticulture 200.

Hereinafter, the configuration of the water treatment apparatus 400 using the air bubble ultrasonic waves according to the embodiment of the present invention will be described in more detail.

Meanwhile, the water treatment apparatus 400 using the air bubble ultrasonic waves according to the embodiment of the present invention can be applied to a system for sterilizing various wastewater such as facility horticulture, wastewater treatment plant, and the like. However, in the embodiment of the present invention, the facility horticulture will be described as an example.

2 is a view illustrating a water treatment apparatus using air bubble ultrasonic waves according to an embodiment of the present invention.

1 and 2, a water treatment apparatus 400 using air bubble ultrasonic waves according to an embodiment of the present invention includes an inflow water recovery unit 130, an inflow water bottle 120, an inflow water sterilizing unit 160, (110).

The inflow water recovery unit 130 is connected to the facility horticulture 200 to recover the infused water that has been used from the facility horticulture 200 to the inflow water cistern 120. The inflow water recovery unit 130 may be formed of a pipe and connected to the second pipe 250 of the facility horticulture 200.

The inflow tube 120 can receive inflow water from the facility horticulture 200 through the inflow water collection unit 130 and store the inflow water. Here, the inflow tube 120 may be stored in the bottom of the facility horticulture 200, that is, in the ground, but not limited thereto, and may be separately provided outside the facility horticulture 200.

On the other hand, the inflow cistern 120 is one of the constituent elements which is essentially constituted to store inflow water in the institutional gardening 200. That is, the inflow tube 120 may be a waste liquid tank for storing waste liquid discharged from the facility horticulture 200.

The inflow tube 120 according to the embodiment of the present invention may be provided with an ultrasonic generator 140 and an air bubble generator 150 to sterilize influent water without constructing a separate sterilization system.

The influent sterilizing unit 160 is installed in the inflow tube 120 to regenerate the inflow water through the ultrasonic waves and the air bubbles with sterilized treated water. The inflow sterilization part 160 includes an ultrasonic generator 140 and an air bubbler 150.

The ultrasonic generator 140 may be formed on one surface of the inflow tube 120 to inflow and sterilize inflow water. Preferably, the ultrasonic generator 140 may be uniformly formed in a zigzag manner on the lower surface of the inflow tube 120. The ultrasonic generator 140 according to the embodiment of the present invention is formed on the lower surface of the inflow tube 120, but it is not limited thereto and may be formed on the side surface or the upper surface.

The ultrasonic generator 140 may include an integrated type ultrasonic generator 140a having a plurality of holes 140b formed on the upper surface of the inflow tube 120 and inserted into the plurality of holes 140b. Accordingly, the number of the direct type ultrasonic generators 140a can be adjusted according to the application.

The ultrasonic generator 140 vibrates the inflow water collected in the inflow tube 120 to generate strong cavitation and acceleration to physically clean the foreign matter. More specifically, the ultrasound generator 140 may sterilize influent water through cavitation, acceleration, and chemical action.

That is, the ultrasonic generator 140 can wash the influent water through the micro jet generated when the steam cavitation breaks at the ultrasonic wave of 100 kHz or less. Also, the ultrasonic generator 140 generates vibration in the contaminants present in the inflow water, and can clean the inflow water by the acceleration. In addition, the ultrasonic generator 140 generates vibration and promotes oxidation and reduction reaction by radicalization of water molecules or hydrogen atom production, thereby washing inflow water.

The ultrasonic generator 140 may include a first ultrasonic generator 141 and a second ultrasonic generator 142.

The first ultrasonic wave generator 141 can generate ultrasonic waves of 100 kHz or less. That is, the first ultrasonic wave generator 141 may generate cavitation energy.

The second ultrasonic wave generator 142 may generate ultrasound waves in excess of 100 kHz together with the first ultrasonic wave generator 141. That is, the second ultrasonic wave generator 142 generates a chemical reaction with the acceleration through vibration, thereby performing cleaning, removing particle contamination, metal contamination, or inorganic contamination.

The ultrasonic generator 140 according to the embodiment of the present invention can maximize the sterilizing action through the ultrasonic waves by generating frequencies in two bands.

The air bubbler 150 is formed on one surface of the inflow tube 120 to supply an air bubble to the inflow water to support the sterilizing action of the ultrasonic generator 140. Preferably, the air bubbler 150 can be uniformly disposed between the zigzag arranged ultrasonic generators 140.

The air bubbler 150 circulates inflow water in the sterilization system bottle 120 and maximizes the effect of ultrasonic disinfection by the ultrasonic generator 140.

The treated water discharging portion 110 can supply the sterilized treated water from the inflow tube 120 to the facility horticulture 200.

Although not shown, the water treatment apparatus 400 using the air bubble ultrasonic waves according to the embodiment of the present invention may include a control unit for controlling the water treatment apparatus 400 using the air bubble ultrasonic waves as a whole.

The control unit controls the inflow water from the facility horticulture 200 to be recovered and stops the collection of inflow water when the inflow water is filled in the inflow tube 120 and operates the ultrasonic wave generator 140 and the air bubbler 150 So as to sterilize the inflow water recovered in the inflow tube 120. When the sterilization of the inflow water is completed, the control unit can control the inflow water discharge unit 110 to supply the regenerated treated water of the inflow tube 120 to the facility horticulture 200.

As described above, the water treatment apparatus 400 using the air bubble ultrasonic waves according to the embodiment of the present invention disposes the ultrasonic wave generator 140 in the inflow tube 120 that recovers and stores inflow water from the facility horticulture, The infusion water can be sterilized and reusable without the need to add a sterilization line.

The water treatment apparatus 400 using the air bubble ultrasonic wave according to the present invention is characterized in that the ultrasonic wave generator 140 and the air injector 150 are disposed in the inflow tube 120 to supply air bubbles to the inflow tube 120 The sterilizing effect of the ultrasonic generator can be maximized by circulating the inflow water.

Hereinafter, the ultraviolet sterilizing unit 100 according to an embodiment of the present invention will be described in more detail.

FIG. 3 is a view for explaining an ultraviolet sterilizing unit according to an embodiment of the present invention, and FIG. 4 is an enlarged view of a region A in FIG.

Referring to FIGS. 3 and 4, the ultraviolet sterilizing unit 100 secures the time required for ultraviolet sterilization by increasing the residence time of the inflow water. The ultraviolet sterilizing unit 100 can simplify the structure and facilitate maintenance and cost reduction. Here, the inflow water may be waste liquid used in hydroponic cultivation farms. The ultraviolet sterilizing unit 100 includes an influent moving tube 10 and an ultraviolet ray irradiating unit 20.

The inflow passageway 10 is formed so as to block exposure of ultraviolet rays from the inside to the outside, and the inflow water moves inside. The inflow passageway 10 is divided into an inflow section 11, a reaction section 12 and an outflow section 13.

The inflow section 11 is a section through which inflow water flows from the outside. The reaction section 12 is a section through which inflow water is sterilized by irradiation of ultraviolet rays. The outflow section 13 is a section through which inflow water flows out to the outside. At this time, the reaction part 12 is formed in a spiral shape between the inflow part 11 and the outflow part 13. In this way, the reaction part 12 increases the time for the inflow water to travel between the inflow part 11 and the outflow part 13.

That is, the conventional inflow passageway formed in a straight line can not secure the time required for ultraviolet sterilization as the inflow water flows in and flows out quickly. However, in the reaction part 12 of the present invention, the inflow water flowing into the inflow part 11 flows out to the outflow part 13 while being rotated along the spiral-shaped pipe, so that the inflow water travel time becomes long. By this means, the inflow water can increase the residence time in the reaction part 12, which means that it is possible to secure more time for performing ultraviolet sterilization.

The reaction part (12) includes a fixing part (14) and a through hole (15). The fixing portion 14 is formed at a portion adjacent to the inflow portion 11 and is fixed to one end of the flexible substrate 23 of the ultraviolet irradiating portion 20 to be described later. At this time, the fixing portion 14 can form a hook-shaped protrusion for fixing to one end of the flexible substrate 23. Preferably, the fixing portion 14 may be in the form of a hook, but is not limited thereto. The through-hole 15 is formed in a portion adjacent to the outflow portion 13, and the other end of the flexible substrate 23 is penetrated to be connected to an external power source. That is, the through hole 19 is a hole through which the flexible substrate 23 can be connected to the outside. At this time, the through-hole 19 may have an O-ring on its inner circumferential surface to prevent a gap from the flexible substrate 23.

The inflow passageway 10 is provided with an inflow valve 16 and an outflow valve 17 between the inflow section 11 and the reaction section 12 and between the outflow section 13 and the reaction section 12 respectively. The inlet valve 16 and the outlet valve 17 can control the movement of the influent water.

For example, the inflow valve 16 may block the inflow water flowing into the inflow section 11 by closing the valve, or may open the valve to move inflow water flowing into the inflow section 11. [ In addition, the outlet valve 17 may close the valve to prevent the influent water regenerated by the ultraviolet rays from flowing out to the outside in the reaction part 12, or may open the valve to drain the inflow water regenerated by the ultraviolet rays from the reaction part 12 to the outside.

The inlet valve 16 and the outlet valve 19 serve as an intermediary for allowing the reaction section 12 to attach and detach from the inlet section 11 and the outlet section 13. In other words, the influent moving tube 10 can separate and wash and replace the reaction part 12 formed between the inlet valve 16 and the outlet valve 17 by using the inlet valve 16 and the outlet valve 17 .

The ultraviolet ray irradiating unit 20 is inserted into the influent moving tube 10, and ultraviolet rays are sterilized by irradiating the inflow water with ultraviolet rays. Specifically, the ultraviolet ray irradiating portion 20 is inserted into the reaction portion 12 of the influent moving tube 10. Therefore, the ultraviolet ray irradiating unit 20 may be coated to prevent physical contact with inflow water. The ultraviolet ray irradiating unit 20 includes a plurality of ultraviolet LEDs 21, a flexible substrate 23 and a coating film 25.

A plurality of ultraviolet LEDs (21) emit ultraviolet rays to the inflow water. The plurality of ultraviolet LEDs 21 emit UV-C having a wavelength range of 100 to 280 nm. At this time, when the wavelength of the ultraviolet LEDs 21 is 200 nm or less, ozone (O ₃ ) can be generated spontaneously and the sterilization efficiency can be increased by using the generated ozone. Preferably, the plurality of ultraviolet LEDs 21 can obtain an optimum sterilization and deodorizing effect at a wavelength of 184.9 nm (Ozone Forming Range).

The flexible substrate 23 is connected to a plurality of ultraviolet LEDs 21 to supply power. At this time, the flexible substrate 23 can be connected to a plurality of ultraviolet LEDs 21 attached to one side or to both sides thereof. Preferably, the flexible substrate 23 is provided with a plurality of ultraviolet LEDs 21 on both sides so that the ultraviolet ray irradiation direction can be irradiated in all directions. The flexible substrate 23 can be thin and flexible so as to be inserted along the inside of the reaction part 13. [ One end of the flexible substrate 23 is formed in an annular shape 27 and fixedly engaged with the fixed portion 17 of the inflow port 10 and the other end is passed through the through hole 15 of the inflow port 10, It is connected to the power source.

The coating film 25 is formed on the outside of the plurality of ultraviolet LEDs 21 and the flexible substrate 23 to block contact with inflow water. That is, the coating film 25 prevents a phenomenon in which a plurality of ultraviolet LEDs 21 and the flexible substrate 23 are in contact with the inflow water to cause a short circuit. The coating film 25 may be formed of a flexible material.

As described above, the ultraviolet sterilizing unit 100 can directly sterilize the inflow water with ultraviolet rays irradiated from a plurality of ultraviolet LEDs 21. That is, the ultraviolet sterilizer 100 can irradiate the ultraviolet rays directly to the inflow water by inserting the plurality of ultraviolet LEDs 21 into the reaction part 12. Accordingly, the ultraviolet sterilizing unit 100 can quickly and strongly irradiate ultraviolet rays, thereby maximizing sterilizing efficiency.

In addition, since the ultraviolet sterilizing unit 100 has a simple structure in which the ultraviolet ray irradiating unit 20 is inserted into the inflow passageway 10, the size of the ultraviolet sterilizer 100 can be minimized, and the amount of parts used can be minimized, have.

5 is a view for explaining a method of influent sterilization using an ultraviolet sterilizing unit according to an embodiment of the present invention.

3 to 5, the infectious water sterilization method can maximize sterilization efficiency within a short time by performing ultraviolet sterilization of inflow water by direct ultraviolet irradiation.

In step S41, the influent sterilizing apparatus 100 inflows influent water through the inlet 11 of the influent moving tube 10. In this case, the inflow water may be an influent used in hydroponic cultivation farms. Here, the inflow passageway 10 is formed in a spiral shape, and blocks the exposure of ultraviolet rays from the inside to the outside.

In step S43, the influent sterilizing apparatus 100 sterilizes the inflow water. The influent sterilizing apparatus 100 sterilizes the inflow water moving through the reaction section 13 of the influent moving tube 10 with ultraviolet rays irradiated from a plurality of ultraviolet LEDs 21 included in the ultraviolet ray irradiating section 20. The influent sterilizing apparatus 100 directly irradiates ultraviolet rays to the inflow water by inserting a plurality of ultraviolet LEDs 21 into the inside of the reaction unit 13.

In step S45, the influent sterilizing apparatus 100 drains inflow water regenerated by ultraviolet rays. The inflow sterilization apparatus 100 allows the ultraviolet ray-regenerated inflow water to flow out to the outside through the outflow portion 15 of the inflow / outflow pipe 10. At this time, the influent water flowing out may be supplied to the hydroponic cultivation farm again and reused or discharged to the external environment.

Hereinafter, an ultraviolet sterilizing unit according to another embodiment of the present invention will be described.

FIG. 6 is a view for explaining an ultraviolet sterilizing unit according to another embodiment of the present invention, and FIG. 7 is an enlarged view of a region A in FIG.

Referring to FIGS. 6 and 7, the ultraviolet sterilizer 300 secures the time required for ultraviolet sterilization by increasing the residence time of the inflow water. The ultraviolet sterilizer 300 can use the reflection of ultraviolet light to increase sterilization efficiency in a short time, thereby reducing the cost of additional energy consumption and influent recirculation. Here, the inflow water may be an influent used in hydroponic cultivation farms. The ultraviolet sterilizer 300 includes an inflow passageway 310, an ultraviolet irradiator 320, and an ultraviolet reflector 330.

The inflow passageway 310 is formed in a spiral shape, has ultraviolet transmittance, and the inflow water moves inside. Preferably, the influent moving pipe 310 may be formed of quartz. The inflow passageway 310 is divided into an inflow section 311, a reaction section 313 and an outflow section 315.

The inflow section 311 is a section through which inflow water is introduced from the outside, the reaction section 313 is a section through which inflow water is sterilized by irradiation of ultraviolet rays, and the outflow section 315 is a section through which inflow water flows out. At this time, the reaction part 313 is formed in a spiral shape between the inflow part 311 and the outflow part 315. Thus, the reaction part 313 increases the time for the inflow water to move between the inflow part 311 and the outflow part 315.

That is, the conventional inflow passageway formed in a straight line can not secure the time required for ultraviolet sterilization as the inflow water flows in and flows out quickly. However, in the reaction part 313 of the present invention, the inflow water flowing into the inflow part 311 flows out to the outflow part 315 while being rotated along the spiral-shaped pipe, so that the moving time of the inflow water becomes long. By this means, the inflow water can have an increased residence time in the reaction part 313, which means that it is possible to secure more time for performing ultraviolet sterilization.

The inflow passageway 310 is provided with an inflow valve 317 and an inflow valve 319 between the inflow section 311 and the reaction section 313 and between the inflow section 315 and the reaction section 313. The inlet valve 317 and the outlet valve 319 can control the movement of the influent water.

For example, the inflow valve 317 may block the inflow water flowing into the inflow section 311 by closing the valve, or may open the valve to move inflow water flowing into the inflow section 311. In addition, the outlet valve 317 may close the valve to prevent the influent water regenerated by the ultraviolet rays from flowing out to the outside through the reaction part 313, or may open the valve to drain the inflow water regenerated by the ultraviolet rays to the outside.

The inlet valve 317 and the outlet valve 319 serve as an intermediary for allowing the reacting section 313 to attach and detach from the inlet section 311 and the outlet section 315. That is, the inflow passageway 310 can separate and clean and replace the reaction part 313 formed between the inflow valve 317 and the outflow valve 319 by using the inflow valve 317 and the outflow valve 319 .

The ultraviolet ray irradiating unit 320 irradiates ultraviolet rays to the inflow water moving in the inflow passaging pipe 310. The ultraviolet ray irradiating unit 320 is installed on the outer peripheral surface of the reaction unit 313 of the influent moving tube 310. The ultraviolet ray irradiating unit 320 includes a plurality of ultraviolet LEDs 321 and a flexible substrate 323.

The plurality of ultraviolet LEDs 321 emit ultraviolet rays to the inflow water. The plurality of ultraviolet LEDs 321 emit UV-C having a wavelength range of 100 to 280 nm. At this time, when the wavelength of the ultraviolet LEDs 321 is 200 nm or less, ozone (O ₃ ) can be generated spontaneously and the sterilizing efficiency can be increased by using the generated ozone. Preferably, the plurality of ultraviolet LEDs 321 can obtain an optimum sterilization and deodorizing effect at a wavelength of 184.9 nm (Ozone Forming Range).

The flexible substrate 323 is connected to a plurality of ultraviolet LEDs 321 to supply power. At this time, the flexible substrate 323 may be attached to one surface of a plurality of ultraviolet LEDs 321, or may be attached to both surfaces of the flexible substrate 323. The flexible substrate 323 is wound spirally along the outer circumferential surface of the reaction part 313. Therefore, the flexible substrate 323 can be made thin and flexible so as to be wound around the outer peripheral surface of the reaction part 313. Further, a transparent bonding material may be applied or taped to fix the flexible substrate 323 to the outer peripheral surface of the reaction part 313 on one side.

The ultraviolet reflector 330 is formed to surround the reaction part 313 of the influent moving tube 310 and reflects the ultraviolet rays irradiated from the ultraviolet ray irradiating part 320 toward the influent moving tube 310, Lt; / RTI > The ultraviolet reflector 330 includes a reflector body 331, a first lid 333, a second lid 335, and a reflector 337.

The reflector body 331 is formed in a pipe shape so that the reaction part 313 of the influent moving tube 310 is surrounded. Accordingly, the reflector body 331 is formed larger than the size of the reaction part 313.

The first lid 333 and the second lid 335 are respectively coupled to both ends of the reflector body 331. Accordingly, when the first cover 333 and the second cover 335 are combined with the reflector body 331, the interior of the reflector body 331 is made a sealed space. At this time, the first lid 333 and the second lid 335 are formed with through-holes (not shown) through which the inflow portions 311 and the outflow portions 315 pass.

The reflector 337 is formed on the inner circumferential surface of the reflector body 331 and reflects ultraviolet rays toward the reflector 313 of the influent moving tube 310. At this time, the reflector 337 can irregularly reflect ultraviolet rays. The reflector 337 includes a material that reflects ultraviolet light, such as a white plaster, a white water-based paint, or a polished stainless steel. At this time, the reflector 337 may be formed on at least one of an inner surface of the reflector body 331, a coating, a coating, and an attachment.

As described above, the ultraviolet sterilizing unit 300 can sterilize the inflow water in a short time in a dual structure, thereby increasing the sterilizing efficiency. That is, the ultraviolet sterilizer 300 can sterilize the inflow water using the first ultraviolet sterilization and the second ultraviolet sterilization.

The ultraviolet sterilizing unit 300 sterilizes the first ultraviolet rays by the ultraviolet rays emitted from the plurality of ultraviolet LEDs 321. The first ultraviolet sterilization is sterilization by ultraviolet rays directly irradiated from a plurality of ultraviolet LEDs 321. Accordingly, the ultraviolet sterilizing unit 300 can sterilize the inflow water primarily through the first ultraviolet sterilization.

The ultraviolet sterilizer 300 sterilizes the second ultraviolet rays by using the ultraviolet rays reflected by the reflector. The second ultraviolet sterilization is sterilization by the ultraviolet ray reflected on the reflector 337. Therefore, the second ultraviolet sterilization is sterilized by indirectly irradiated ultraviolet light, and the inflow water can be sterilized secondarily. Here, the ultraviolet sterilizer 300 has a reflector 337 formed in a pipe shape so that ultraviolet rays are reflected in all directions. That is, the ultraviolet sterilizer 300 can effectively increase the sterilizing efficiency for the second ultraviolet sterilization.

8 is a view for explaining a method of influent sterilization using an ultraviolet sterilizing unit according to another embodiment of the present invention.

Referring to FIGS. 6 to 8, the infectious water sterilization method can maximize sterilization efficiency within a short time by performing the ultraviolet sterilization of inflow water with a dual structure.

In step S341, the ultraviolet sterilizer 300 inflows influent water through the inlet 311 of the influent moving tube 310. In this case, the inflow water may be an influent used in hydroponic cultivation farms. Here, the influent moving pipe 310 is formed in a spiral shape.

In step S343, the ultraviolet sterilizer 300 ultraviolet sterilizes the inflow water. At this time, the ultraviolet sterilization may be the first ultraviolet sterilization and the second ultraviolet sterilization. The ultraviolet sterilizer 300 sterilizes the inflow water flowing through the reaction part 313 of the influent moving tube 310 with ultraviolet rays emitted from a plurality of ultraviolet LEDs 321 included in the ultraviolet ray irradiating part 320. At this time, the ultraviolet sterilizing unit 300 can improve the sterilization efficiency by increasing the reflectance of ultraviolet rays by forming the reflector 337 in a pipe shape. Here, the ultraviolet light reflected by the reflector 337 may be ultraviolet light directly irradiated by the plurality of ultraviolet LEDs 321, or ultraviolet light transmitted after irradiating inflow water which is moved into the inflow passaging pipe 310.

In step S345, the ultraviolet sterilizer 300 emits ultraviolet-regenerated inflow water. The ultraviolet sterilizing unit 300 allows the ultraviolet ray-regenerated inflow water to flow out to the outside through the outflow portion 315 of the influent moving tube 310. At this time, the inflowed influent water may be supplied to the hydroponic cultivation farm again and reused or discharged to the external environment.

It should be noted that the embodiments disclosed in the drawings are merely examples of specific examples for the purpose of understanding, and are not intended to limit the scope of the present invention. It will be apparent to those skilled in the art that other modifications based on the technical idea of the present invention are possible in addition to the embodiments disclosed herein.

10, 310: Influent moving tube 11, 311:
12, 313: Reactor 13, 315:
14: fixed portion 15: penetration hole
16, 317: inlet valve 17, 319: outlet valve
20, 320: ultraviolet ray irradiating unit 21, 321: ultraviolet LED
23, 323: flexible substrate 25: coating film
27: annular shape 100, 300: ultraviolet sterilizing part
110: treated water discharging portion 120: inflow cistern
130: Inflow water recovery unit 140: Ultrasonic wave generator
150: Airbubbler 160: Influent sterilizer
170: mixing tank 180:
200: facility horticulture 210: nutrient supply pipe
220: Lung sucker 230: Crop tray
240: first pipe 250: second pipe
330: ultraviolet reflector 331: reflector body
333: first cover 335: second cover
337: reflector 400: water treatment device using air bubble ultrasonic wave
500: Sterilization System

Claims (8)

An influent recovery unit for recovering inflow water;
An inflow water reservoir for receiving and storing the inflow water from the inflow water recovery unit and having a plurality of holes formed on an upper surface thereof;
An inflow water sterilizer installed in the inflow tube and sterilizing the inflow water through an ultrasonic wave and an air bubble;
A treated water discharging portion for receiving and discharging sterilized treated water from the inflow cistern;
An ultraviolet sterilizing unit for sterilizing the treated water discharged from the treated water discharging unit through ultraviolet rays; Lt; / RTI >
Wherein the influent sterilizing portion comprises:
An ultrasonic generator disposed on one surface of the inflow tube and selectively inserted in the plurality of holes of the inflow tube to sterilize the inflow water by applying ultrasonic waves to the inflow water;
An air bubbler formed on one surface of the inflow tube and supplying air bubbles to the inflow water to support sterilizing action of the ultrasonic generator; Lt; / RTI >
The ultrasonic generator includes:
A first ultrasonic generator for generating ultrasonic waves of 100 kHz or less;
A second ultrasonic generator for generating ultrasonic waves in excess of 100 kHz together with the first ultrasonic generator; Lt; / RTI >
The ultraviolet-
An inflow passageway formed in a spiral shape and having ultraviolet transmittance and in which the process water moves into the inside;
An ultraviolet irradiating unit installed so as to be spirally wound around the outer circumferential surface of the influent moving tube and irradiating ultraviolet rays to the treated water in the influent moving tube for first sterilization; And
An ultraviolet reflector formed to surround the inflow passageway and reflecting the ultraviolet rays irradiated from the ultraviolet irradiator in the direction of the inflow passageway to sterilize the treated water in the inflow passageway;
Wherein the air bubble ultrasonic wave is generated by the air bubble ultrasonic wave. delete delete delete The method according to claim 1,
Wherein the influent water comprises waste nutrients used in institutional gardening,
And the inflow water recovery unit recovers the waste nutrient solution from the facility horticulture. 6. The method of claim 5,
Wherein the inflow water cistern is a nutrient solution reservoir for storing the waste nutrient solution. Plant horticulture;
An inflow water returning portion for receiving the inflow water from the inflow water returning portion and storing the inflow water from the inflow water returning portion, a plurality of holes formed in the upper surface of the inflow water returning portion, an inflow water introducing portion for introducing the inflow water through an ultrasonic wave and an air bubble, And an ultraviolet sterilizing unit for sterilizing the treated water discharged from the treated water discharging unit through ultraviolet rays, wherein the sterilizing unit includes a sterilizing unit for sterilizing the sterilized water, a treatment water discharging unit for receiving and discharging sterilized treated water from the inflow tube, Water treatment equipment; Lt; / RTI >
Wherein the influent sterilizing portion comprises:
An ultrasonic generator disposed on one surface of the inflow tube and selectively inserted in the plurality of holes of the inflow tube to sterilize the inflow water by applying ultrasonic waves to the inflow water;
An air bubbler formed on one surface of the inflow tube and supplying air bubbles to the inflow water to support sterilizing action of the ultrasonic generator; Lt; / RTI >
The ultrasonic generator includes:
A first ultrasonic generator for generating ultrasonic waves of 100 kHz or less;
A second ultrasonic generator for generating ultrasonic waves in excess of 100 kHz together with the first ultrasonic generator; Lt; / RTI >
The ultraviolet-
An inflow passageway formed in a spiral shape and having ultraviolet transmittance and in which the process water moves into the inside;
An ultraviolet irradiating unit installed so as to be spirally wound around an outer circumferential surface of the influent moving tube, the ultraviolet irradiating unit irradiating the treated water in the influent moving tube with ultraviolet rays for first sterilization; And
An ultraviolet reflector formed to surround the inflow passageway and reflecting the ultraviolet rays emitted from the ultraviolet irradiator toward the inflow passageway to sterilize the treated water in the inflow passageway;
The sterilization system comprising: delete

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