KR100419828B1 - Water-cleaning apparatus having a plurality of uv lamps - Google Patents

Abstract

The present invention is equipped with a plurality of ultraviolet lamps, a new advanced oxidation process (AOP) that maximizes the efficiency of water treatment by maximizing the ozone gas generated by the ultraviolet rays as well as sterilization of water by ultraviolet rays generated therefrom. It relates to a water treatment apparatus by. In more detail, the water treatment apparatus includes a first pipe for supplying water to be treated into the water treatment apparatus, a plurality of ultraviolet lamps composed of double quartz tubes, a second pipe for supplying air to the ultraviolet lamps, and the ultraviolet lamps. A third pipe which collects the generated ozone gas and supplies it to the first pipe, a fourth pipe vertically extending from the water treatment device to the bottom of the water tank to discharge the treated water through the plurality of ultraviolet lamps; A first wall having a passage for partitioning between the space in which the first pipe is installed and the space in which the plurality of ultraviolet lamps are installed, and allowing water introduced through the first pipe to move to the space in which the ultraviolet lamp is installed; and The ultraviolet ray lamp is partitioned between the space in which the fourth pipe is installed and the ultraviolet ray The water which has passed through the loop characterized in that it comprises a second wall having a passage to be supplied to the fourth pipe.

Description

WATER-CLEANING APPARATUS HAVING A PLURALITY OF UV LAMPS}

The present invention relates to a new water treatment apparatus having a plurality of ultraviolet lamps, and maximizing water treatment efficiency by maximizing the ozone gas generated by the ultraviolet rays as well as sterilizing water by ultraviolet rays generated therefrom. More specifically, the present invention is a water treatment apparatus having a plurality of ultraviolet lamps, the plurality of ultraviolet lamps are composed of a double quartz tube from which it is possible to efficiently convert oxygen in the air to ozone gas, and further generated ozone The gas can be collected and used efficiently, and the ozone treated water passes through the plurality of ultraviolet lamps so that it can be treated with ultraviolet rays at the same time. The water can be sterilized and purified more efficiently than the conventional water treatment apparatus. It relates to a device that allows.

Ultraviolet lamps are widely used for the sterilization and purification of microorganisms in the air and water, and for the decomposition of organic substances that cause odors. Ultraviolet rays are light with a wavelength in the range of approximately 0.1 nm to 400 nm and have a relatively high energy. When irradiated directly to the cell membrane of a microorganism, the ultraviolet ray destroys the cell wall or cell membrane of the microorganism and destroys its DNA or inhibits its proliferation. Has the effect of sterilizing. On the other hand, ultraviolet rays are known to cause no harm to humans except to irritate the eyes or skin, and require sanitary facilities, such as restaurants and livestock barns, storage warehouses, food factories, aquariums, purification plants or hospitals. UV lamps are installed and used.

On the other hand, ozone (O ₃ ) is harmful to the human body when present in the air more than 0.1ppm, but also known to have the effect of sterilization and deodorization and organic matter removal, it is widely used in deodorization devices such as septic tank, water treatment device, and barn.

Recently, various devices have been developed for using microorganisms to simultaneously sterilize, purify, decompose and deodorize organic matter. As described above, by using ultraviolet and ozone, ozone and hydrogen peroxide or iron salt and hydrogen peroxide in combination, it is possible to obtain microbial sterilization, organic decomposition and deodorization effect by using advanced or advanced oxidation process (AOP). This is called.

Conventionally, there is a patent No. 149049 (the above-mentioned) regarding "high-purity water treatment apparatus and its method" as an invention regarding the purified water treatment apparatus by the advanced oxidation method using ultraviolet-ray and ozone. The patent is a first water purification unit for sterilizing contaminated water by generating an organic substance decomposition material of OH radicals using ozone provided from an ozone generator and ultraviolet rays from an ultraviolet lamp installed therein, the first water purification unit The second purified water treatment unit for adsorbing the remaining pollutants by adsorbing the untreated pollutants by the adsorption means made of granular activated carbon, and performs a reverse washing action between the first purified water treatment unit and the second purified water treatment unit Disclosed is a high water purification apparatus including a backwashing unit and a third water purification unit subjected to sterilization treatment again using ozone, and a high water purification treatment method using the same.

In the above patent, the ultraviolet lamp is located in the primary water treatment unit, and the ozone generator is configured to be supplied to the primary water treatment unit through an air injector in the primary water treatment unit separately installed outside. Therefore, the purified water treatment is performed by the advanced oxidation method by ozone and ultraviolet rays in the first purified water treatment unit, and the purified water is once again purified by ozone supplied by the ozone generator in the third purified water treatment unit. do.

Of course, by using an ultraviolet lamp sterilization effect by the ultraviolet rays generated therefrom, and by supplying air to pass through the ultraviolet lamp, the air is converted into ozone to sterilize the water to have the effect of sterilization and organic matter decomposition by ozone and Ultraviolet and ozone generators for purifying treatment have also been disclosed (see Utility Model Registration No. 216078). However, the amount of ozone that can be generated from the ultraviolet and ozone generators disclosed in the registration utility model is suitable for sterilizing and purifying water inside a small aquarium, and installed in a large-scale water tank or a septic tank. It was not enough to efficiently purify a large amount of water.

It is a first object of the present invention to provide a water treatment apparatus capable of efficiently sterilizing and purifying water stored in a large-scale water tank or a septic tank by an advanced oxidation method using ultraviolet rays and ozone. It is an object of the present invention to provide a water treatment apparatus capable of efficiently utilizing ozone gas generated from a plurality of ultraviolet lamps without installing a.

It is a second object of the present invention to provide a water treatment apparatus using ultraviolet and ozone which can maintain a constant treatment efficiency by using a pump of a constant capacity irrespective of the flow rate of water to be treated.

It is also a third object of the present invention to provide a water treatment apparatus having a plurality of ultraviolet lamps that are easy to clean and maintain.

1 is a view schematically showing the structure of a water treatment device having a plurality of ultraviolet lamps according to an embodiment of the present invention,

FIG. 2 is a plan view with the lid of the water treatment apparatus shown in FIG. 1 removed.

3 is a cross-sectional view taken along the line A-A of FIG. 2 and viewed from the arrow direction.

4 is a schematic view showing an assembly of a plurality of ultraviolet lamps installed in the water treatment apparatus.

* Explanation of symbols for the main parts of the drawings

10: first pipe 20: UV lamp

30: second pipe 40: third pipe

50: fourth pipe 60: first wall

70: second wall 80: third wall

90: fourth wall

In order to achieve the above object, according to the first aspect of the present invention, a first pipe extending in the water treatment device to supply the water to be treated into the water treatment device, and the water pipe installed in the water treatment device and introduced from the first pipe A plurality of ultraviolet lamps comprising a double quartz tube positioned in the water to be treated, a second pipe connected to the ultraviolet lamp to supply air, and collecting ozone gas generated from the ultraviolet lamp connected to the ultraviolet lamp A third pipe to supply the first pipe to the first pipe, a fourth pipe installed in the water treatment device and extending outside the water treatment device to discharge the treated water through the plurality of ultraviolet lamps, and the first pipe. A space between the space provided with the plurality of ultraviolet lamps and the space provided with the first pipe; By introducing the water which the ultraviolet lamp is provided with a passage so as to be movable in the installed space, the first wall, and

Provided is a water treatment apparatus having a second wall having a passage for partitioning between the space in which the ultraviolet lamp is installed and the space in which the fourth pipe is installed, so that water passing through the ultraviolet lamp can be supplied to the fourth pipe. do.

According to a second aspect of the invention,

In the water treatment device according to the first aspect of the present invention,

The plurality of ultraviolet lamps are arranged in parallel with each other, vertically arranged on both sides of the second pipe and the third pipe disposed horizontally in contact with each other in the upper space of the water treatment device, and beneath the second pipe and the third pipe. The water treatment apparatus is further provided with a third wall having a passageway for dividing the space between the ultraviolet lamps arranged in parallel on both sides and allowing the water to move through the portion.

Furthermore, according to the third aspect of the present invention,

In addition to the configuration of the water treatment device according to the first aspect of the present invention,

In the upper part of the second wall, a water treatment device is provided, characterized in that a tube for discharging ozone present in the upper part of the space in which the ultraviolet lamp is installed and supplied into the fourth pipe.

According to the fourth aspect of the invention,

In the water treatment apparatuses according to the present invention as described above, the plurality of ultraviolet lamps are installed on a separate bottom that can be separated from the water treatment apparatus and form an assembly in connection with the second and third pipes. Thereby, a water treatment apparatus is provided, which is configured to be collectively separated or mounted from a water treatment apparatus.

As can be realized in the above various aspects, the water treatment device according to the present invention is a portion for supplying water to be treated, a portion for generating ultraviolet and ozone gas to treat the water supplied, ozone generated by the lamp And a portion for discharging water treated by ultraviolet rays into a water tank, wherein each of the portions is separated into respective spaces by a plurality of walls in the water treatment apparatus, and water to be treated is formed on the plurality of walls. The water treatment efficiency can be remarkably improved by moving between the spaces in which the respective portions are located through passages.

The process of sterilization and purification by ozone and ultraviolet rays generated by the plurality of ultraviolet lamps while the water requiring treatment in the water treatment apparatus of the present invention according to the above configuration is as follows.

As described in the above configuration, when water to be treated through the first pipe is supplied into the water treatment apparatus, the water first contacts the ozone gas supplied to the first pipe through the third pipe and causes an oxidation reaction. The ozone gas is generated by converting oxygen in air supplied to the plurality of ultraviolet lamps through a second pipe into ozone by ultraviolet rays in the lamp. The ozone gas thus generated is collected from the lamp into the third pipe, and the third pipe supplies the ozone gas to the first pipe.

As described above, the water first contacting the ozone gas in the water treatment apparatus according to the present invention moves to a space in which the plurality of ultraviolet lamps are installed through a passage formed in the first wall. Here, the water is subjected to ultraviolet treatment irradiated from the lamp while moving along the lamp outside the ultraviolet lamp. Water thus treated with both ozone and ultraviolet light moves to the next space through the second wall. In the space, a fourth pipe for discharging the treated water to the water tank is provided. The treated water enters the space and is discharged into the water tank through the fourth pipe.

On the other hand, as will be described in detail with reference to the drawings showing a preferred embodiment of the invention attached hereafter, the plurality of ultraviolet lamps are supplied with air through a second pipe, and also generated from the ultraviolet lamps Since ozone gas has to be collected in a third pipe, for efficient placement of a plurality of lamps taking into account the movement of air and the collection of ozone, and the relationship with the pipes, the pipes are arranged horizontally in the upper space in the water treatment apparatus. Preferably, the plurality of ultraviolet lamps are arranged in a erected form in the device in a structure perpendicular to the pipes.

More preferably, as in the second aspect of the present invention, the plurality of ultraviolet lamps not only have a structure perpendicular to the two pipes as described above, but also the plurality of ultraviolet lamps between the pipes. It is better if the lamps are arranged side by side on both sides of the pipes.

On the other hand, as shown in the above configuration, the plurality of ultraviolet lamps used in the apparatus of the present invention are all composed of a double quartz tube, preferably inside the inner tube is filled with a gas capable of generating ultraviolet rays, The space between the quartz tube and the outer quartz tube is composed of a vacuum so that air is supplied from the second pipe described above. When air is supplied, oxygen in the air is converted into ozone by ultraviolet light emitted from the ultraviolet lamp, and the generated ozone is discharged from the ultraviolet lamp and collected in the above-mentioned third pipe. The collected ozone gas is sent to the first pipe and supplied to the water treatment apparatus to be mixed with water.

Referring to the third aspect of the present invention in more detail, the water treatment apparatus according to the present invention further comprises a tube for discharging ozone present in the upper part of the space in which the plurality of ultraviolet lamps are installed on the upper part of the second wall. do.

As described above, the water treatment apparatus according to the present invention has its interior divided into individual spaces by a plurality of walls, and the divided spaces are sterilized and purified step by step in each space through the passages formed in the walls. The water is moved to receive. According to such a structure, during operation of the apparatus, each space in the apparatus is always filled with water above a certain level. In this case, when the tube connected to the fourth pipe is inserted in the upper part of the second wall as in the third aspect of the present invention, the other space in contact with the wall, that is, the space in which the plurality of ultraviolet lamps are installed The water level is adjusted to be below the position of the tube fitted on top of the second wall. That is, when the water level is about to be higher than the tube position, water is drawn through the tube into the space where the fourth pipe is located and the water level in the space where the plurality of ultraviolet lamps are installed is kept below the position of the tube.

However, a substantially important function of the tube is to supply ozone gas, which is located above the space in which the plurality of ultraviolet lamps are installed, into the fourth pipe, as described above. This is because the water mixed with the ozone gas generated by the plurality of ultraviolet lamps is first moved through the first pipe into the space where the plurality of ultraviolet lamps are installed, and some of the ozone gas dissolved in the water is released into the air. In this case, the ozone gas is collected and used again to increase the water treatment effect. The tube preferably extends into the fourth pipe, so that the ozone gas supplied through the tube is sent into the tank to oxidize the water in the tank.

On the other hand, the water supplied to the water treatment apparatus according to the present invention is preferably water in the water tank in which the water treatment apparatus is installed. Therefore, according to the water treatment apparatus of the present invention, preferably, the water treated by the water treatment apparatus is discharged into the water tank, and the water thus discharged takes a repetitive circulation structure which is supplied to the water treatment apparatus, thereby providing Similarly, the water treatment capacity does not depend on the flow rate. That is, the water treatment apparatus according to the present invention can maintain a high water treatment efficiency by using a pump having a constant capacity regardless of the flow rate of water to be treated.

Hereinafter, with reference to the accompanying drawings, a water treatment apparatus according to a preferred embodiment of the present invention will be described in detail.

1 is a view schematically showing the structure of a water treatment device having a plurality of ultraviolet lamps according to an embodiment of the present invention.

As shown in the drawing, the water treatment device 100 according to the present invention can be installed and used on the water tank 200 in which the water to be treated is stored. Preferably, the pipes 50 extending vertically from the water treatment apparatus 100 to the lower portion of the water tank may be configured to supply water treated by the water treatment apparatus 100 to the water tank 200 as described in detail with reference to the accompanying drawings. It is for discharging). More preferably, by supplying the ozone gas generated in the water treatment device 100 through the pipe 50 together with the treated water deeply below the water tank 200, sterilization and organic substance decomposition effects in the water tank can be caused. . In addition, when the pipe 50 extends deeply below the water tank, there is no fear that ozone gas odor is generated in the water tank. At this time, however, a small amount of surplus ozone gas is located on the surface of the water, thereby preventing water pollution by air pollution.

In the figure, the pump 11 supplies water in the water tank 200 to the water treatment device 100 through the first pipe 10. The first pipe 10 extends horizontally to the top of the water treatment device 100 and branches therefrom into two pipes 10a extending vertically down towards the interior of the water treatment device 100. The pump 32 supplies air into the water treatment device 100 through the pipe 33.

FIG. 2 is a plan view with the lid of the water treatment apparatus shown in FIG. 1 removed.

As shown in the figure, the water treatment apparatus 100 is a space in which two branched pipes 10a extending vertically downward from the first pipe 10, respectively, a plurality of ultraviolet lamps 20 The space in which it is located and the space in which the fourth pipes 50 are arranged to allow the treated water to be discharged from the device are divided. The first wall 60 divides a space between two pipes branched from the first pipe path 10 and a space where the plurality of ultraviolet lamps 20 are located, and the plurality of ultraviolet lamps 20 The second wall 70 divides between the space in which they are located and the space in which the fourth pipes 50 are located.

As shown in the figure, it can be seen that the plurality of ultraviolet lamps 20 are arranged side by side parallel to both sides of the third pipe 40 which collects and supplies the ozone gas generated in the lamps to the first pipe. . At this time, there is also a third wall 80 dividing each space between the two rows of ultraviolet lamps 20.

Meanwhile, as shown in FIG. 1, there is also a fourth wall 90 that divides between the spaces in which the two pipes 10a branched from the first pipe 10 are located.

The walls 60, 70, 80, and 90 divide the space in the water treatment apparatus 100 of the present invention vertically, thereby increasing the water treatment efficiency of the parts of the water treatment apparatus located in each space. Therefore, the water treatment apparatus according to the present invention can exhibit a high water treatment effect even with a relatively small capacity.

As shown in the figure, each of the ultraviolet lamps 20 has a tube 41 for supplying the ozone gas generated in the ultraviolet lamp to the third pipe 40, and although not shown in the figure, the ozone gas Tubes 31 extending from the second pipe 30 for supplying external air to the respective ultraviolet lamps 20 are connected for the generation of.

A tube 42 for the delivery of ozone gas is connected between the first pipe 10 and the third pipe 40, in particular, the two pipes 10a described above are connected to the first pipe ( Each connected to a position branched from 10). Since the water to be treated is transported through the first pipe 10 and supplied into the water treatment apparatus 100 through the two branched pipes 10a, a vacuum is introduced into the branched pipe 10a. Is formed. Thus, ozone gas supplied through the tubes 42 connected to the branched pipes 10a is sucked into the branched pipes 10a under the influence of the vacuum. Thus, ozone gas is quickly mixed with water to sterilize and oxidize the water.

3 is a cross-sectional view taken along the line A-A of FIG. 2 and viewed from the arrow direction.

As shown in the figure, in the water treatment apparatus according to the preferred embodiment of the present invention, a plurality of ultraviolet lamps 20 are erected vertically in the apparatus so as to sandwich the second pipe 30 and the third pipe 40 between them. Placed in parallel.

Air is supplied from the second pipe 30 into the ultraviolet lamp 20 through the tube 31, and the air supplied is in the direction of the arrow through the outer space of the double quartz tube of the ultraviolet lamp as described above. Moving downward along the lamp, the oxygen in the air is converted to ozone by the ultraviolet light from the lamp. The air containing the ozone gas thus converted is collected into the third pipe 40 through the tube 41 connected to the lower end of the ultraviolet lamp, as indicated by the arrow at the bottom of the ultraviolet lamp. In this manner, ozone gas generated in each of the plurality of ultraviolet lamps 20 is collected in the third pipe 40, and the collected ozone gas is supplied to the first pipe 10 through the tube 42. It is mixed with the treated water. Preferably, the tube 42 extends down along the branched pipe 10a in the first pipe 10 to allow ozone gas to mix well with the feed water in the pipe 10a. As such, the water supplied into the water treatment device 100 is sterilized and purified by ozone gas generated by the plurality of ultraviolet lamps 20 at first.

As described above, the water mixed with the ozone gas through the first pipe 10 moves to the space in which the plurality of ultraviolet lamps 20 are installed through the passage 61 provided under the first wall 60. The moved water rises along the lamp outside the ultraviolet lamp in the direction of the arrow and is subjected to treatment by the ultraviolet light emitted from the lamp. The water which has risen under UV treatment is also the next space in which a plurality of UV lamps 20 are arranged through a passage 81 formed in the upper part of the third wall 80 intersecting between two rows of UV lamps arranged in parallel. Will be moved to. In the space, the water moves downward along the ultraviolet lamp 20 in the direction of the arrow, and again undergoes sterilization and purification treatment by ultraviolet light emitted from the lamps 20.

The water thus moved passes through a passage 71 formed in the lower portion of the second wall 70 that divides the space where the ultraviolet lamps 20 are installed and the space where the fourth pipe 50 for discharging the treated water is installed. Through this, the fourth pipe 50 is moved to the installed space. The moved water rises again in the direction of the arrow, and is discharged to the outside of the water treatment device 100 through the fourth pipe 50.

On the other hand, at the upper end of the second wall 70, a tube 51 for discharging ozone gases collected in the upper portion of the space where the plurality of ultraviolet lamps 20 are installed is fitted. The tube 51 extends into the fourth pipe 50.

The water level is adjusted by the tube 51 according to the position of the tube 51 in the space in which the plurality of ultraviolet lamps 20 are installed. That is, water is filled only up to the bottom of the tube 51. At this time, ozone gases dissolved in water may be collected in the upper space in which the water is not filled. The ozone gas is ozone gas emitted into the air due to the movement and rise of water, in which ozone gas supplied through the first pipe 10 is dissolved in water supplied into the apparatus. The tube 51 supplies the ozone gas thus collected into the fourth pipe 50, and injects the ozone gas into the water discharged through the ultraviolet treatment or into the water tank into which the water is discharged, thereby oxidizing the ozone gas. The process happens once again. Accordingly, the ozone gas generated in the water treatment device 100 can be utilized to the maximum.

Meanwhile, as shown in FIG. 1, since the fourth pipe 50 extends vertically downward from the water treatment device 100 to the depth of the bottom of the water tank 200, the ozone gas supplied into the pipe 50 is supplied to the water tank 200. ) Can be fully melted into. Therefore, the oxidation treatment of water in the water tank 200 by the ozone gas can be improved, and an unpleasant ozone odor is not released into the air around the water tank. At this time, however, a small amount of surplus ozone gas is located on the surface of the water to prevent water pollution by air pollution.

Moreover, as shown in the said figure, the said 4th pipe 50 has the narrow lower end compared with the inlet. According to such a configuration, as the inner diameter of the pipe is narrowed, the pressure increases and the flow velocity of the fluid passing therethrough is increased. Therefore, the discharged water and ozone gas may have an effect of falling into the water tank 200 while being quickly mixed in the pipe 50. Accordingly, the water treatment efficiency by ozone may also be increased.

Preferably, the plurality of ultraviolet lamps are connected to the above-described second pipe 30 and the third pipe 40 and a lower portion of the second pipe 30 to divide a space between the ultraviolet lamps arranged in parallel. It forms one assembly with a wall 80 and a separate bottom 85 that is vertically connected to the third wall 80 and detachable from the water treatment device that supports the ultraviolet lamps. By such an assembly structure, the plurality of ultraviolet lamps may be integrally mounted in or separated from the water treatment apparatus 100, thereby simplifying cleaning and maintenance of the ultraviolet lamps.

FIG. 4 is a schematic side view of the assembly of the plurality of ultraviolet lamps shown in FIG. 3.

As shown in the figure, a plurality of ultraviolet lamps have the same UV lamp on the other side, with the third wall 80 and the second pipe 30 and the third pipe 40 disposed therebetween. It can be seen that it is configured integrally with the arrangement of. Therefore, when cleaning, maintaining or repairing the ultraviolet lamps, the assembly can be collectively removed or mounted from the water treatment apparatus. To this end, the water treatment device 100 is formed with a rail portion so that the front end and the rear end of the third wall 80 can be fitted.

Referring back to FIG. 2, the rail unit may be configured with two rows of guide protrusions 82 each approximately near the center on the front and rear walls of the space in which the assembly of the plurality of ultraviolet lamps is to be installed in the water treatment apparatus. Front and rear cross-sections of the third wall 80 may fit snugly in grooves partitioned by the protrusions 82. Therefore, the administrator can easily clean, maintain and manage the assembly of the ultraviolet lamp by inserting the assembly of the ultraviolet lamp into the groove easily from the top of the water treatment apparatus. Therefore, the water treatment apparatus according to the present invention is very convenient also in its maintenance and management.

The preferred embodiments described above are not intended to limit the present invention, and those skilled in the art will be able to easily change and modify the present invention disclosed in the above embodiments. For example, the above preferred embodiment has been described in that the water treatment apparatus according to the present invention includes a plurality of ultraviolet lamps, and the ultraviolet lamp is composed of a double quartz tube so that ozone gas generated therefrom can be used in the water treatment apparatus. The present invention is not limited thereto. That is, the ultraviolet lamp is not necessarily configured as a double quartz tube, at this time, ozone gas for advanced oxidation treatment may be supplied from a separate ozone supply device installed outside the water treatment apparatus of the present invention. It will be understood by those skilled in the art that such changes and modifications fall within the scope of the present invention.

As described above, the water treatment apparatus according to the present invention can efficiently sterilize and purify a large amount of water by an advanced oxidation method using ultraviolet rays and ozone gas irradiated from a plurality of ultraviolet lamps. In particular, according to a preferred embodiment of the present invention, the water treatment device of the present invention is energy-efficient because it is configured to effectively use ozone generated only in a plurality of ultraviolet lamps without a separate ozone generator.

In addition, the water treatment apparatus according to the present invention can be installed in a large water tank or the like to exhibit an excellent water treatment effect, regardless of the flow rate of water to be treated even with a relatively small pump capacity by the repetitive circulation treatment structure.

In the water treatment apparatus according to the present invention, since the plurality of ultraviolet lamps constitute one assembly, it is easy to clean, maintain and manage.

Claims (12)

A first pipe extending into the water treatment device and supplying water to be treated into the water treatment device; A plurality of ultraviolet lamps made of double quartz tubes, installed in the water treatment apparatus and located in the water to be treated introduced from the first pipe; A second pipe connected to the ultraviolet lamp to supply air; A third pipe connected to the ultraviolet lamp and collecting ozone gas generated from the ultraviolet lamp and supplied to the first pipe; A fourth pipe installed in the water treatment device and extending out of the water treatment device to discharge the treated water through the plurality of ultraviolet lamps; A first wall having a passage for partitioning between the space in which the first pipe is installed and the space in which the plurality of ultraviolet lamps are installed, and allowing water introduced through the first pipe to move to the space in which the ultraviolet lamp is installed; And a second wall having a passage for partitioning between the space where the ultraviolet lamp is installed and the space where the fourth pipe is installed, so that water passing through the ultraviolet lamp can be supplied to the fourth pipe. The water treatment apparatus as claimed in claim 1, wherein the plurality of ultraviolet lamps are arranged vertically in the water treatment apparatus and are connected to the second pipe and the third pipe through separate tubes, respectively. According to claim 1 or 2, wherein the plurality of ultraviolet lamps are arranged in parallel to the vertical space on both sides of the second pipe and the third pipe disposed horizontally in contact with each other in the upper space in the water treatment device, Underneath the second pipe and the third pipe, a third wall is further provided with a passage for dividing the space between the ultraviolet lamps arranged in parallel on both sides, and allowing the water to move through a part thereof. A water treatment device. The water treatment apparatus of claim 1, And a tube for discharging ozone present in the upper part of the space in which the ultraviolet lamp is installed and feeding it into the fourth pipe at the upper part of the second wall. The water treatment apparatus according to claim 1 or 2, wherein the plurality of ultraviolet lamps are installed on a separate bottom which can be separated from the water treatment apparatus and form an assembly in connection with the second and third pipes. A water treatment device, characterized in that configured to be separated or mounted in a batch. The apparatus of claim 3, wherein the plurality of ultraviolet lamps are detachable from the water treatment device and are installed on a bottom portion connected vertically to the third wall to form an assembly in connection with the second and third pipes. The front and rear cross-sections of the third wall are interposed between the protrusions formed on the front and back wall surfaces of the water treatment apparatus, so that the assembly can be collectively separated or mounted from the water treatment apparatus. The water treatment apparatus according to claim 1, wherein the fourth pipe extends vertically to a lower portion of the water tank for discharging water from the water treatment apparatus. The water treatment apparatus of claim 1, wherein the fourth pipe has a smaller inner diameter at the bottom of the pipe than the inlet. The water treatment apparatus according to claim 1, wherein the water to be treated is circulated and supplied from a water tank through which the water treated by the water treatment apparatus is discharged. A water supply unit having a water supply pipe extending vertically therein and having a water outlet at the bottom thereof; At least one reactor connected to the water outlet of the water supply unit and having at least one UV lamp; Is provided with a treated water discharge portion having a water discharge pipe for discharging the water passed through the reaction tank, The plurality of ultraviolet lamps are connected to an air supply having an air supply pipe for supplying air, and the water supply pipe is connected to an ozone supply device connected to the plurality of ultraviolet lamps. The water discharge pipe extends vertically from the inside of the treated water discharge portion to the lower portion of the reservoir for storing the treated water, And between the one or more reactors and between the reactor and the treated water outlet is partitioned by walls formed with passages through which water can move. The water treatment apparatus as claimed in claim 10, wherein the plurality of ultraviolet lamps are erected vertically in the reactor. According to claim 10 or 11, wherein the plurality of ultraviolet lamps are made of a double quartz tube, the ozone supply device is connected to the plurality of ultraviolet lamps to collect the ozone gas generated from the plurality of ultraviolet lamps Water treatment device characterized in that the supply to the water supply pipe.