KR102356648B1 - Cleaning apparatus for water treatment - Google Patents

Abstract

The present invention relates to a purification device for water treatment used for purifying water used in fountains and water play facilities, irrigation water, wastewater treatment plants, non-point pollution reduction water treatment, recycled water treatment, lakes, detention ponds, reservoirs, agricultural waters, industrial water, etc. More specifically, the present invention relates to a purification device for water treatment using an artificial control method applying a semi-permanent filtration screen, which can improve purification performance of polluted water and simultaneously perform a backwash operation of each filtration screen by forming a backwash nozzle inside each filtration screen.

Description

Artificial intelligence-controlled water purification and disinfection system with semi-permanent filtration screen {CLEANING APPARATUS FOR WATER TREATMENT}

The present invention relates to a purification system for water treatment used for purifying water or irrigation used in fountains and water play facilities, wastewater treatment plants, non-point pollution reduction water treatment, recycling water treatment, lakes, reservoirs, reservoirs, agricultural water, industrial water, etc. More specifically, it is possible to improve the purification performance of contaminated water by forming filtering screens in the spaces on both sides of the body so that the contaminated water is filtered twice while passing through each filtering screen, It relates to a purification system for water treatment of an artificial intelligence control method using a semi-permanent filtering screen that can simultaneously perform backwashing of each filter screen by forming a backwash nozzle inside.

In general, in playgrounds, such as playgrounds, parks, and school grounds, where children run and play, various play facilities are installed so as to bring the development of physical strength and perceptual ability of children.

Recently, by transforming these play facilities, play facilities are being developed that allow children to develop physical strength and intellectual abilities in a variety of ways while having more curiosity. In order to achieve this, many fountains and water play facilities are being developed and installed in parallel with the combination play area and other water play facilities and fountain facilities inside the pool so that they can play with more interest in summer, etc.

Fountains and water play facilities as described above are generally provided with a purification system for water treatment. Such a water treatment purification system is a device that filters organic floats flowing in and generated from various facility systems, and in addition to fountains and water play facilities, agricultural and industrial water. It is widely used for water purification purposes.

In addition, in factories, etc., a water treatment purification system that filters contaminated cooling water, etc., is installed to filter a large amount of contaminated water, and the filtered water is used to cool products such as steel.

A key component for filtering contaminated water in a water purification system is a screen manufactured in the form of a mesh wire or wedge wire. That is, when contaminated water mixed with foreign substances passes through the screen, the foreign substances are filtered out of the screen and only the filtered water passes through and is discharged. In this case, if the filtration is continuously performed, a lot of foreign substances are caught in the screen, which may decrease the filtration efficiency.

However, in the conventional purification system for water treatment, backwash water did not flow uniformly over the entire area of the filtering screen during the backwashing process, so foreign substances trapped in the filtering screen were not effectively achieved. The backwashing process of the filtration screen was impossible, and as a result, periodic cleaning or replacement of the filtration screen, which was unable to perform the backwashing process, was required. There was a problem that this greatly deteriorated.

On the other hand, the prior art of the purification system for water treatment is the Republic of Korea Utility Model Registration No. 20-0110358 and the like.

The present invention has been devised to solve the problems of the prior art as described above, and by forming filtering screens in the spaces on both sides of the body, the contaminated water is filtered twice while passing through each of the filtering screens, thereby purifying contaminated water An object of the present invention is to provide a purification system for water treatment capable of improving performance and capable of simultaneously performing backwashing of each of the filter screens by forming a backwashing nozzle inside each of the filtering screens.

The problems to be solved by the present invention are not limited to the above problems, and other technical problems not mentioned will be clearly understood by those of ordinary skill in the art to which the present invention belongs from the following description.

A purification system for water treatment according to the present invention for achieving the above object includes: a main body in which an inner space is separated into a first filtration chamber and a second filtration chamber by a diaphragm; a first filtration screen fixedly installed in the first filtration chamber of the main body; a second filtration screen fixedly installed in the second filtration chamber of the main body; a contaminated water inlet pipe for supplying contaminated water to the first filtration chamber of the main body; a filtered water discharge pipe through which the filtered water is discharged through the first and second filtering screens; a backwash water inlet pipe for supplying backwash water to the inside of the first and second filtration screens; and a backwash water discharge pipe for discharging backwash water to the outside.

At this time, one end of the first filtration screen having a closed structure is installed to flow into the second filtration chamber through the through hole of the diaphragm, so that the filtered water introduced into the first filtration screen enters the second filtration chamber. It is characterized in that a movable flow path is formed.

In addition, it is characterized in that a plurality of porous media is formed on the inside of the second filtration screen.

In addition, the backwash water inlet pipe may include: a first connection pipe connected to the first filtration screen; and a second connection pipe connected to the second filtration screen.

In addition, the purification system for water treatment may include: a first backwash nozzle formed inside the first filtration screen to communicate with the first connection pipe and spraying backwash water to the first filtration screen; and a second backwash nozzle formed inside the second filtering screen to communicate with the second connection pipe and spraying backwashing water to the second filtering screen.

In addition, it is characterized in that a plurality of injection holes are formed in the longitudinal direction and the front portion of the first and second backwashing nozzles.

In addition, the first and second backwash nozzles include a lower body and an upper body rotatable 360 degrees with respect to the lower body, and a semi-circular injection hole is formed in the upper body.

In addition, the first and second backwash nozzles include a body portion and a polygonal head portion rotatable 360 degrees with respect to the body portion, and a plurality of injection holes are formed in the head portion.

In addition, the backwash water discharge pipe may include: a first backwash water discharge pipe connected to the first filtration chamber to discharge backwash water subjected to the backwashing process of the first filtration screen; and a second backwashing water discharge pipe connected to the second filtration chamber and discharging the backwashing water subjected to the backwashing process of the second filtration screen.

In addition, the purification system for water treatment is controlled by the IOT control panel to purify and disinfect the water sucked in through the inlet and discharge it to the inside of the water tank through the outlet. It is characterized in that it is applied to the floor fountain that sprays the used water to the outside.

In addition, the purification system for water treatment is controlled by the IOT control panel to purify and disinfect the water sucked in through the inlet, and discharge it into the water tank through the outlet. It is characterized in that it is applied to a water playground that sprays water to the outside.

In addition, the purification system for water treatment is controlled by the IOT control panel to purify and disinfect the water sucked in through the inlet and discharge it to the inside of the water tank through the outlet. It is characterized in that it is applied to a wall cloth that sprays purified and disinfected water to flow along the wall in the direction of the ground.

In addition, the purification system for water treatment is controlled by the IOT control panel to purify the water sucked into the inlet, and spray the purified water through a plurality of spray nozzles formed in a shape inclined in one direction to the supply pipe to keep the water constant. It is characterized in that it is applied to a purified water disinfection system that agitates purified water and ozone and chlorine supplied from the ozone and purification chemical supply unit by rotating it while flowing in the direction.

In addition, it is characterized in that the microbubble generator is formed inside the injection nozzle of the purified water disinfection system.

The present invention relates to a purification system for water treatment used for purifying water used in fountains and water play facilities, irrigation, wastewater treatment plants, non-point pollution reduction water treatment, recycling water treatment, lakes, reservoirs, reservoirs, agricultural water, industrial water, etc. In this regard, it is possible to improve the purification performance of contaminated water by forming filtering screens in the spaces on both sides of the body so that the contaminated water is filtered twice while passing through each of the filtering screens.

In addition, by forming backwash nozzles on the inside of each filter screen, it is possible to simultaneously perform backwashing of each filter screen. It can effectively remove foreign substances.

In addition, it is possible to improve the purification performance of the contaminated water by forming a plurality of porous media for removing fine impurities contained in the contaminated water inside the filtration screen.

In addition, it is possible to further improve the purification performance of contaminated water by forming a second purification device equipped with an activated carbon filter and an LED sterilizer.

In addition, the purification system for water treatment of the present invention can be applied to various facilities such as a floor fountain, a fountain, a music fountain, a water playground, a swimming pool, a running water pool, a byeokcheon, and a running water pool.

Effects of the present invention are not limited to the effects mentioned above, and other effects not mentioned will be clearly understood by those skilled in the art from the description of the claims.

1 is a view showing the overall configuration of a water treatment purification system of an artificial intelligence control method to which a semi-permanent filtering screen is applied according to an embodiment of the present invention.
FIG. 2 is a view showing a water purification system for water treatment of an artificial intelligence control method to which a semi-permanent filtering screen is applied according to an embodiment of the present invention as viewed from the direction A of FIG. 1 .
FIG. 3 is a view showing a water purification system for water treatment of an artificial intelligence control method to which a semi-permanent filtering screen is applied according to an embodiment of the present invention as viewed from the direction B of FIG. 1 .
4 is a view showing the flow direction of contaminated water in the purification process of the water treatment purification system of an artificial intelligence control method to which a semi-permanent filtering screen is applied according to an embodiment of the present invention.
5 is a view showing the flow direction of backwash water in the backwashing process of the filter screen of the water treatment purification system of an artificial intelligence control method to which a semi-permanent filtering screen is applied according to an embodiment of the present invention.
6 is an enlarged cross-sectional view of a filtration screen in an artificial intelligence-controlled water treatment purification system to which a semi-permanent filtration screen according to an embodiment of the present invention is applied.
7 is an enlarged cross-sectional view of the backwash nozzle formed inside the filtering screen in the artificial intelligence-controlled water treatment purification system to which the semi-permanent filtering screen is applied according to an embodiment of the present invention.
8 is a schematic diagram showing one end of the second filtration screen in the artificial intelligence-controlled water treatment purification system to which the semi-permanent filtration screen is applied according to an embodiment of the present invention.
9 to 11 are views showing various embodiments of backwash nozzles formed inside the filtering screen in the artificial intelligence-controlled water treatment purification system to which the semi-permanent filtering screen is applied according to an embodiment of the present invention.
12 is a view showing various specifications of a purification system for water treatment of an artificial intelligence control method to which a semi-permanent filtering screen is applied according to an embodiment of the present invention.
13 is a view showing a state in which a second purification device is added to the purification system for water treatment of an artificial intelligence control method to which a semi-permanent filtering screen is applied according to an embodiment of the present invention.
14 is a view showing the internal structure of a water treatment purification system of an artificial intelligence control method to which a semi-permanent filtering screen is applied according to another embodiment of the present invention.
15 is a view showing a state in which the artificial intelligence-controlled water purification system to which the semi-permanent filtering screen is applied according to an embodiment of the present invention is applied to a floor fountain (fountain, music fountain).
16 is a view showing a state in which the artificial intelligence-controlled water purification system to which the semi-permanent filtering screen is applied according to an embodiment of the present invention is applied to a water playground (pool, lazy river).
17 is a view showing a state in which a water treatment purification system of an artificial intelligence control method to which a semi-permanent filtering screen is applied according to an embodiment of the present invention is applied to a wall cloth.
18 is a view showing a state in which the artificial intelligence-controlled water purification system to which the semi-permanent filtering screen is applied according to an embodiment of the present invention is applied to the purified water disinfection system.

Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings. However, some components irrelevant to the gist of the present invention will be omitted or compressed, but the omitted configuration is not necessarily a configuration that is not necessary in the present invention, and will be used in combination by those of ordinary skill in the art to which the present invention belongs. can

1 is a view showing the overall configuration of a water treatment purification system of an artificial intelligence control method to which a semi-permanent filtering screen is applied according to an embodiment of the present invention, and FIG. 2 is an artificial intelligence to which a semi-permanent filtering screen according to an embodiment of the present invention is applied. It is a view showing the control system for water treatment as viewed from the direction A in FIG. 1, and FIG. 3 is an artificial intelligence control system for water treatment to which a semi-permanent filtration screen according to an embodiment of the present invention is applied. It is a view showing the view from the direction B, and FIG. 4 is a view showing the flow direction of contaminated water in the purification process of the artificial intelligence-controlled water purification system to which the semi-permanent filtering screen is applied according to an embodiment of the present invention, 5 is a view showing the flow direction of backwashing water in the filter screen backwashing process of the artificial intelligence-controlled water treatment purification system to which the semi-permanent filtering screen is applied according to an embodiment of the present invention, and FIG. 6 is an embodiment of the present invention. A cross-sectional enlarged view of a filtration screen in a water treatment purification system of an artificial intelligence control method to which a semi-permanent filtering screen is applied according to the present invention, and FIG. It is an enlarged cross-sectional view of the backwashing nozzle formed inside the screen, and FIG. 8 is a schematic view showing one end of the second filtration screen in the artificial intelligence-controlled water treatment purification system to which the semi-permanent filtration screen according to the embodiment of the present invention is applied. 9 to 11 are views showing various embodiments of backwash nozzles formed inside the filtering screen in the artificial intelligence-controlled water treatment purification system to which the semi-permanent filtering screen is applied according to an embodiment of the present invention; 12 is a view showing various specifications of a purification system for water treatment of an artificial intelligence control method to which a semi-permanent filtering screen is applied according to an embodiment of the present invention, and FIG. 13 is an artificial intelligence control using a semi-permanent filtering screen according to an embodiment of the present invention It is a view showing a state in which a second purification device is added to the purification system for water treatment, and FIG. 14 is a semi-permanent filtering screen according to another embodiment of the present invention. It is a diagram showing the internal structure of a purification system for water treatment of an artificial intelligence control method, and FIG. 15 is a floor fountain (fountain, music It is a view showing a state applied to the fountain), and FIG. 16 is a view showing a state in which the artificial intelligence-controlled water purification system to which a semi-permanent filtering screen is applied according to an embodiment of the present invention is applied to a water park (pool, running water) 17 is a view showing a state in which the artificial intelligence-controlled water treatment purification system to which a semi-permanent filtering screen is applied according to an embodiment of the present invention is applied to a wall cloth, and FIG. 18 is a semi-permanent filtering screen according to an embodiment of the present invention. It is a diagram showing the state in which the purification system for water treatment of the artificial intelligence control method applied to the purified water disinfection system is applied.

<Configuration of purification system for water treatment>

1 to 14, the artificial intelligence-controlled water purification system (hereinafter referred to as 'water treatment purification system') to which a semi-permanent filtration screen is applied according to an embodiment of the present invention (hereinafter referred to as 'purification system for water treatment') is at the bottom of the support ( 160) formed on the main body 110, the cover 120, the first and second filtration screens 130 and 140, and the backwash nozzles 131 and 141 formed inside the first and second filtration screens 130 and 140 ), and as shown in FIGS. 15 to 18 , an IOT control panel 10 for controlling each configuration of the purification system 100 for water treatment is separately provided on the outside of the main body 110 . A detailed description of the IOT control panel 10 will be described later.

A diaphragm 118 having a through hole 115a formed therein is installed in the body 110 .

Here, the main body 110 is filtered primarily through the first filtration chamber 110a, in which the first filtration screen 130 is formed, and the first filtration screen 130, into which the contaminated water is first introduced with the diaphragm 118 as the center. The filtered water is introduced and the second filtration chamber 110b in which the second filtration screen 140 is formed is formed.

In addition, the main body has a contaminated water inlet pipe 111 connected to the first filtration chamber 110a for supplying contaminated water to the first filtration chamber 110a, and a second filtration screen 140 of the second filtration chamber 110b. ) connected to a filtrate discharge pipe 112 for discharging secondarily filtered filtrate through the second filtration screen 140 , and a backwash water inlet pipe for supplying backwash water to the first and second screens 130 and 140 . 113 and first and second backwashing water discharge pipes 117 and 117 for discharging backwashing water containing foreign substances that have been subjected to the backwashing process in the first and second screens 130 and 140 are formed. At this time, the backwash water inlet pipe 113 is branched by the first connection pipe 114 and the second connection pipe 115 , and the first connection pipe 114 is the first connection pipe 114 formed inside the first filtration screen 130 . It communicates with the first backwash nozzle 131 to supply backwash water to the first backwash nozzle 131 , and the second connection pipe 115 is connected to the second backwash nozzle 141 formed inside the second filtration screen 140 and It communicates to supply backwashing water to the second backwashing nozzle 141 . The filtered water discharge pipe 112, the second connection pipe 115, and the first and second backwash water discharge pipes 116 and 117 have solenoid valves 112a, 113a, 115a, 116a, 117a that can open and close the inside, respectively. ) is formed, and a check valve (not shown) is formed inside the contaminated water inlet pipe 111 and the backwash water inlet pipe 113 . In addition, the cover 120 is formed on both sides of the body 110, and if necessary, the cover 120 may be opened to perform operations such as replacement of the first and second filtration screens 130 and 140. In this case, the shape of the body 110 and the cover 120 can be formed in various shapes as needed, including a circular shape or a square shape, as shown in FIGS. 2 and 3 .

On the other hand, the first and second filtering screens 130 and 140, as shown in Figure 1, one end is blocked and the other end has a through hole for installing the first and second backwash nozzles 131 and 141 are formed in a tubular shape. and the first and second backwash nozzles 131 and 141 of the first and second filtration screens 130 and 140 are connected to the first and second connecting pipes 114 and 115 through the through-holes. In addition, as shown in FIG. 8 , a circular outlet 140c for discharging filtered water is separated from the through hole 140b on the outer periphery of the through hole 140b formed at the other end of the second filtering screen 140 . It is formed in a multiplicity of forms.

The first filtration screen 130 has a central portion fixed to the diaphragm 118, and the right end in the drawing, in which a through hole is formed, passes through the through hole 118a of the diaphragm 118 to enter the second filtration chamber 110b. installed to flow in. Accordingly, as the right part of the first filtration screen 130 flows into the second filtration chamber 110b, the contaminated water introduced into the first filtration screen 130 and filtered primarily moves to the second filtration chamber 110b. A flow path 132 is formed. In addition, the second filtration screen 140 is fixedly installed to the right end of the second filtration chamber (110b) side cover 120 in the drawing.

Here, the first and second filtration screens 130 and 140 may have a tubular shape in which wires are spirally stacked. And, as shown in FIG. 6 , the wire may have a triangular cross-section, and a base of the triangular shape may be formed to face outward. In this case, the cross-sectional shape of the first and second filtering screens 130 and 140 is not limited to a triangular shape, and various types of filterable shapes are applicable as needed. In addition, the second filtration screen 140 is more densely stacked wires than the first filtration screen 130 , so that finer filtration is possible. Therefore, the filtration process is sequentially performed in such a way that, after a relatively large foreign material is filtered by the first filtering screen 130 , a fine foreign material is filtered by the second filtering screen 140 .

In addition, a plurality of porous media 140a for removing fine impurities contained in the contaminated water are formed inside the second filtration screen 140, and these porous media 140a adsorb the fine impurities contained in the contaminated water. A variety of known porous materials such as activated carbon and sponge can be used. At this time, in the present invention, since the first and second filtration screens 130 and 140 are separated into separate spaces, filling in only one of the first and second filtration screens 130 and 140 with the porous filter medium 140a is It is possible.

Although the drawing shows that the porous filter medium 140a is formed only on the inside of the second filtering screen 140, it is not limited thereto, and only one of the first and second filtering screens 130 and 140 is selectively porous if necessary. It is also possible to form the filter media 140a or to form the porous filter media 140a both inside the first and second filter screens 130 and 140 .

Accordingly, the contaminated water introduced from the contaminated water inlet pipe 111 as shown in FIG. By passing through the spiral gap at the end of 130), foreign substances mixed with the contaminated water are primarily filtered, and the primary filtered water introduced into the first filtration screen 130 passes through the flow path 132 of the first filtration screen 130. After being introduced into the second filtration chamber 110b through the second filtration screen 140, the foreign substances mixed in the primary filtrate water are secondarily filtered by passing through the spiral gap at the end of the second filtration screen 140 from the outside.

Meanwhile, as shown in FIG. 7 , the first and second backwash nozzles 131 and 141 formed inside the first and second filtration screens 130 and 140 have a plurality of injection holes spaced apart from each other at regular intervals in the longitudinal direction. A 131a is formed, and accordingly, the backwash water supplied through the backwash water inlet pipe 113 and the first and second connection pipes 114 and 115 is supplied through the first and second injection holes 131a through the plurality of injection holes 131a. By uniformly spraying the entire area of the filtering screens (130, 140), it is possible to effectively remove foreign substances stuck in the first and second filtering screens (130, 140). At this time, in the present invention, since the first and second backwashing nozzles 131 and 141 are long, backwashing is possible uniformly from the front to the rear of the first and second filtering screens 130 and 140 . That is, if the first and second backwash nozzles 131 and 141 are not long, in the rear part of the first and second filtration screens 130 and 140 located far from the first and second backwash nozzles 131 and 141, The water pressure of backwash water may be lowered, and the backwashing function may be reduced. In the present invention, the first and second backwash nozzles 131 and 141 are formed to be elongated from the front of the first and second filtration screens 130 and 140 . Backwashing is possible uniformly to the rear.

At this time, in the present invention, the first and second backwash nozzles 131 and 141 formed inside the first and second filtration screens 130 and 140 may be formed in various shapes.

That is, as shown in FIG. 9 , a backwash nozzle 170 having a plurality of injection holes 171 formed in the longitudinal direction and the front portion is formed inside the first and second filtration screens 130 and 140 , Backwashing water can be uniformly sprayed over the entire area of the first and second filtration screens 130 and 140 by spraying backwashing water through the injection hole 171 .

In addition, as shown in FIG. 10, it is composed of a lower body 181 and an upper body 182, and the upper body 182 is formed to be able to rotate 360 degrees with respect to the lower body 181, and the upper body 182 is A backwash nozzle 180 having a semi-circular injection hole 183 formed on the front part is formed inside the first and second filtration screens 130 and 140, and the upper body 182 rotates 360 degrees to remove the injection hole 183. By spraying backwashing water through the backwashing water, it is possible to uniformly spray backwashing water over the entire area of the first and second filtration screens 130 and 140 .

In addition, as shown in FIG. 11 , a polygonal head 192 rotatably formed by 360 degrees is provided on the upper end of the body 191 and the body 191 , and a plurality of injection holes is provided in the head 192 . A backwash nozzle 190 having a shape of 193 is formed inside the first and second filtration screens 130 and 140, and the head part 192 rotates 360 degrees to spray backwashing water through the injection hole 193. By doing so, backwashing water can be uniformly sprayed over the entire area of the first and second filtration screens 130 and 140 .

Although it has been described above that the same type of backwash nozzles are formed on the first and second filtration screens 130 and 140, the various types of backwash nozzles described above are applied to the first and second filtration screens 130 and 140. It is also possible to use it by mixing.

On the other hand, although not shown in the drawing, a pressure sensor (not shown) that measures the pressure of the contaminated water flowing into the contaminated water inlet pipe 111 of the body 110 and the pressure of the filtered water discharged through the filtered water discharge pipe 112 is contaminated. One each may be installed in the water inlet pipe 111 and the filtered water outlet pipe 112 .

In general, in the process of filtering water, foreign substances are caught in the gaps of the filtering screens 130 and 140, so that the pressure in the contaminated water inlet pipe 111 is increased or the pressure in the filtered water outlet pipe 112 is lowered. When a pressure sensor (not shown) is installed in each of the water inlet pipe 111 and the filtered water outlet pipe 112, the control unit (not shown) controls the pressure in the contaminated water inlet pipe 111 or the pressure in the filtered water outlet pipe 112. After reading from a sensor (not shown) and comparing it with a pre-entered reference pressure value, when the pressure in the contaminated water inlet pipe 111 or the pressure in the backwash water outlet pipe 112 deviates from the pre-entered reference pressure value, the control unit (not shown) City) can be controlled so that the backwashing process is performed.

The purification system for water treatment of the present invention configured as described above can be formed in various standards as shown in FIG. 12 . That is, as shown in Fig. 12(a), a purification system for water treatment of 50A standard with an hourly treatment capacity of 17 to 20 tons, and a purification system for water treatment of 80A standard with a treatment capacity of 29 to 32 tons per hour as shown in Fig. 12(b) system, it is possible to form a purification system for water treatment of various standards, such as a purification system for water treatment of 100A standard having a treatment capacity of 37 to 40 tons per hour, as shown in FIG. 12( c ).

On the other hand, as shown in FIG. 13 , the sterilization device 200 may be additionally configured in the purification system for water treatment according to an embodiment of the present invention.

Specifically, when the inlet 230 of the sterilizer 200 is connected to the filtered water discharge pipe 112 through the pipe, the filtered water passes through the first and second filtering screens 130 and 140, and the filtered water flows in, it is arranged in the vertical direction. The activated carbon filter 210 and the ultraviolet lamp (LED lamp, 220) may be sequentially purified and then discharged through the outlet 240. Accordingly, the filtered water filtered through the first and second filtration screens 130 and 140 passes through the activated carbon filter 210, fine impurities are adsorbed and removed, and after being sterilized and disinfected through the ultraviolet lamp (LED lamp, 220) Since it is discharged, the purification performance of polluted water is greatly improved.

Meanwhile, FIG. 14 is a view showing the internal structure of a purification system for water treatment according to another embodiment of the present invention.

Hereinafter, a detailed description of the purification system for water treatment according to another embodiment of the present invention will be given, but the description of the same configuration as the embodiment described above will be omitted.

As shown in FIG. 14 , the purification system 300 for water treatment according to another embodiment of the present invention has a high-pressure washing backwash nozzle 320 connected to the filtered water inlet pipe 310 inside the first filtration screen 330 . This is formed and inside the second filtration screen 340, a number of carbon particles 341, ceramic balls 342 and hydro filter 343, Volcanic ash, which can sequentially adsorb contaminants from the left in the drawing, are formed. do. At this time, the order in which the carbon grains 341, the ceramic ball 342 and the hydro filter 343, Volcanic ash are formed on the inside of the second filtration screen 340 can be variously changed as needed, and the carbon grains (341), ceramic ball (342), and hydro filter (343, Volcanic ash) can be variously changed in various ways or by using only a single material. In addition, the first filtering screen 330 is formed to filter foreign substances having a particle size of 50 to 100 μm, and the second filtering screen 340 is formed to filter foreign substances having a particle size of 1 to 50 μm. In addition, the high-pressure washing backwashing nozzle 320 formed inside the first filtration screen 330 is a polygonal head part that is formed rotatably 360 degrees on the upper end of the body 321 and the body 321 ( 322) and a plurality of injection holes 323 are provided on the head portion 322, and the head portion 322 rotates 360 degrees and sprays backwashing water through the injection hole 323 to the first filtration screen ( 330), backwashing water can be uniformly sprayed over the entire area.

The purification system 300 for water treatment according to another embodiment of the present invention configured as described above filters foreign substances having a particle size of 50 to 100 μm included in the contaminated water through the first filtration screen 130 and a second filtration screen ( 140), after filtering foreign substances having a particle size of 1 to 50 μm, a plurality of carbon particles 341, ceramic balls 342, and hydro filters 343, Volcanic ash, formed on the inside of the second filtration screen 140 It can be purified by adsorbing the pollutants contained in the polluted water. In addition, the shape of the outer case of the purification system 300 for water treatment according to another embodiment of the present invention can be formed in various shapes as needed, including a circular shape or a square shape.

<Operating process of purification system for water treatment>

Hereinafter, the operation of the purification system 100 for water treatment will be described.

First, as shown in FIG. 4, the backwash water inlet pipe 113 is closed by a check valve (not shown), and the first and second backwash water outlet pipes 116 and 117 are connected to the solenoid valves 113a, 116a, 117a. When the check valve (not shown) of the contaminated water inlet pipe 111 is opened while the contaminated water is introduced in the closed state by the The first filtering screen 130 is introduced into the inside, and while passing through the end of the first filtering screen 130, foreign substances are primarily filtered.

Thereafter, the filtered water from which foreign substances are primarily filtered moves to the second filtration chambers 110b on both sides of the second filtration screen 140 through the flow path 132 formed on the right side of the first filtration screen 130, and then the second filtration screen After entering the inside of the 140 and passing through the end of the second filtration screen 140, foreign substances are secondarily filtered and fine impurities are removed by the porous media 140a inside the second filtration screen 140 The filtered water is discharged to the discharge pipe (112).

As described above, in the present invention, filtering screens 130 and 140 are respectively formed in the spaces on both sides of the body 110 so that the contaminated water is filtered twice while passing through each of the filtering screens 130 and 140, thereby purifying contaminated water. performance can be improved.

At this time, if the filtration process is continued for a certain period of time, the amount of foreign substances caught in the first and second filtration screens 130 and 140 increases, and the filtration efficiency decreases.

Accordingly, the pressure in the contaminated water inlet pipe 111 is increased or the pressure in the filtered water outlet pipe 112 is lowered, and the pressure in the contaminated water inlet pipe 111 or the filtered water outlet pipe 112 in the control panel 10 is After reading the internal pressure from the pressure sensor (not shown) and comparing it with the preset reference pressure value, when the pressure in the contaminated water inlet pipe 111 or the pressure in the filtered water outlet pipe 112 deviates from the preset reference pressure value Controlling the backwashing process to be performed.

When the backwashing process starts, the inflow of contaminated water into the contaminated water inlet pipe 111 is stopped, the contaminated water inlet pipe 111 is closed by a check valve (not shown), and the filtered water outlet pipe 112 is closed with a solenoid valve 112a ), the second connection pipe 115 and the first and second backwashing water discharge pipes 116 and 117 are opened by the solenoid valves 113a, 115a, 116a, and 117a.

In this state, when backwash water flows in through the backwash water inlet pipe 113, the check valve (not shown) of the backwash water inlet pipe 113 is opened as shown in FIG. 114, 115, and then introduced into the first and second backwash nozzles 131 and 141 formed inside the first and second filtration screens 130 and 140, and then sprayed through the injection holes 131a and 141a. While passing through the ends of the first and second filtering screens (130, 140) sweep away foreign substances caught in the first and second filtering screens (130, 140).

Thereafter, the backwashing water passing through the ends of the first and second filtration screens 130 and 140 and moving to the first filtration chamber 110a and the second filtration chamber 110b is the first and second backwashing water together with foreign substances. It is discharged to the outside through the discharge pipe (116, 117).

As described above, in the present invention, by forming the backwash nozzles 131 and 141 inside each of the filtering screens 130 and 140, it is possible to simultaneously perform the backwashing of each of the filtering screens 130 and 140, and the backwashing nozzles Since the filtered water is uniformly sprayed over the entire area of each of the filtering screens 130 and 140 through the injection holes 131a and 141a of the 131 and 141, foreign substances trapped in each of the filtering screens 130 and 140 are effectively removed. can do.

After that, when the backwashing process is continuously performed and the foreign substances are sufficiently discharged, the filtration process is performed again.

Hereinafter, with reference to FIGS. 15 to 18, a floor fountain (fountain, music fountain, 400) to which the purification system 100 for water treatment according to an embodiment of the present invention is applied, a water playground (pool, lazy river, 500), a byeokcheon (600) ) and the configuration and operation of the purified water disinfection system 700 will be described in detail.

First, as shown in FIG. 15 , the bottom fountain (fountain, music fountain, 400) to which the purification system 100 for water treatment according to an embodiment of the present invention is applied is located at the bottom of the inner bottom of the water tank 410 and the water tank 410. The supply pump 440 is formed, the injection nozzle 442 is formed on the inner upper portion of the water tank 410 to discharge water to the outside to spray the water stream, and the supply pump 440 is spaced apart from the supply pump 440 at the inner bottom of the water tank 410 . The disinfection device 450 formed, the water tank 410 includes a drain pump 420 formed on one side of the lower inner side, and the floor fountain 400 and the purification system 100 for water treatment applied to the floor fountain 400 are IOT It is connected through the control panel 10 and a communication power cable (not shown) to control the operation of each component. At this time, the IOT control panel 10 may control the operation of the floor fountain 400 to which the purification system 100 for water treatment is applied according to weather and climate. That is, it is possible to control the floor fountain 400 not to operate on a rainy day, reduce the water injection amount on a day with a low temperature, and increase the water injection amount on a day with a high temperature. As described above, the IOT control panel 10 provided in the present invention is an artificial intelligent device and can control the operation of the floor fountain 400 to which the water purification system 100 is applied based on data such as weather and climate.

The water tank 410 is buried lower than the ground, and a space is formed in which water and each component are accommodated.

That is, the water tank 410 is prepared by excavating the ground and excavating the ground to be made of reinforced concrete, and after excavating the ground and compacting the excavated ground floor, a compaction layer of rubble thereon, a discarded concrete layer, a deformed reinforcing bar, a reinforced concrete layer, a waterproofing layer, It may be formed by stacking the protective mortar layers in the order, but is not limited thereto.

In addition, a support frame for supporting the flagstone installed in the ground is formed on the upper surface of the water tank 410 .

On one side of the inner side of the water tank 410, a water supply line 430 for supplying water to the inside of the water tank 410 is formed through the inner wall of the water tank 410, and a water supply line located inside the water tank 410 ( A water supply port 431 is formed at the end of the 430 . Although not shown in the drawings, a valve (not shown) for opening or closing the water supply line 430 may be provided in the water supply line 430 , and a water supply pump (not shown) for supplying water through the water supply line 430 . city) may be provided separately.

In addition, a drain pump 420 for discharging water and foreign substances inside the water tank 410 to the outside is formed on one side of the inner lower end of the water tank 410 , and the drain pump 420 penetrates the inner wall of the water tank 410 . It is connected to the formed drain line 421 to discharge water and foreign substances inside the water tank 410 to the outside through the drain line 421 . Although not shown in the drawings, a valve (not shown) for opening or closing the drain line 421 may be separately provided in the drain line 421 .

The disinfection device 450 is formed on one side of the lower end of the water tank 410 , and receives ozone and chemicals necessary for water purification through the ozone and purification agent supply unit 20 .

In addition, the purification system 100 for water treatment is formed to be connected to the disinfection device 450 on one side of the lower end of the water tank 410 .

Accordingly, after the contaminated water is sucked in through the inlet 451 , it is first purified in the disinfection device 450 , then passes through the purification system 100 for water treatment and is secondarily purified through the outlet 452 in the water tank 410 . ) so that the water inside the water tank 410 can be maintained in a clean state by being discharged to the inside.

The overflow pipe 422 is formed through the inner wall of the water tank 410 at the inner upper end of the water tank 410, and when the height of the water inside the water tank 410 exceeds the water level limit, the overflow tube 422 of the water tank (410) Water exceeding the water level limit is introduced into the overflow inlet 423 formed at the inner end and discharged to the outside through the overflow pipe 422, so that the height of the water inside the water tank 410 does not exceed the water level limit. adjusted so that

A plurality of injection nozzles 442 are formed on the upper portion of the water tank 410 .

The injection nozzle 442 discharges water coming in through the supply line 441 connected from the supply pump 440 to the outside to spray a stream of water.

In addition, a lighting (not shown) is attached to the spray nozzle 442 to illuminate the water sprayed through the spray nozzle 442 to produce an effect of coloring the water, and according to the control signal of the IOT control panel 10 . Color or brightness can be controlled, so it can be used to produce lights that are bright or dark depending on the volume or pitch of the music.

The supply pump 440 is connected to the injection nozzle 442 and the supply line 441 to supply water to the injection nozzle 442 .

The floor fountain 400 to which the purification system 100 for water treatment configured as described above is applied, based on various sound sources and water presentation pattern data stored in the IOT control panel 10, the water presentation is operated by a control signal applied to each device. It is controlled so as to be possible, and clean water purified through the purification system 100 for water treatment can be sprayed to the outside through the injection nozzle 442 .

Hereinafter, with reference to FIG. 16, the configuration and operation of a water play area (pool, lazy river, 500) to which the purification system 100 for water treatment according to an embodiment of the present invention is applied will be described in detail.

As shown in FIG. 16 , the water play area 500 to which the purification system 100 for water treatment according to an embodiment of the present invention is applied has a water tank 510 and a supply pump 540 formed at the inner lower end of the water tank 510 . , the sterilization device 550 formed to be spaced apart from the supply pump 540 at the inner lower end of the water tank 510, the drain pump 520 and the water tank 510 formed on one side of the inner lower end of the water tank 510 and spaced apart from each other by a certain distance It is formed on the ground where the sprayed water does not flow to the outside and is formed on the upper part of the amusement facility installed at a low place so that the sprayed water does not flow to the outside and is installed on the top of the playground equipment. , the water playground 500 and the water purification system 100 applied to the water playground 500 are connected through the IOT control panel 10 and a communication power cable (not shown) to control the operation of each component. At this time, the IOT control panel 10 may control the operation of the water park 500 to which the purification system 100 for water treatment is applied according to weather and climate. That is, it is possible to control the water playground 500 not to operate on a rainy day, reduce the water injection amount on a day with a low temperature, and control so that the water injection amount increases on a day with a high temperature. As described above, the IOT control panel 10 provided in the present invention is an artificial intelligent device and can control the operation of the water park 500 to which the water purification system 100 for water treatment is applied based on data such as weather and climate.

The water tank 510 is buried lower than the ground, and a space is formed in which water and each component are accommodated.

That is, the water tank 510 is prepared by excavating the ground to be made of reinforced concrete, and after excavating the ground and compacting the excavated ground floor, a compaction layer of rubble thereon, a discarded concrete layer, deformed reinforcing bars, a reinforced concrete layer, a waterproofing layer, It may be formed by stacking the protective mortar layers in the order, but is not limited thereto.

In addition, a support frame for supporting the flagstone installed in the ground is formed on the upper surface of the water tank 510 .

On one side of the inner side of the water tank 510, a water supply line 530 for supplying water to the inside of the water tank 510 is formed through the inner wall of the water tank 510, and a water supply line located inside the water tank 510 ( A water supply port 532 is formed at the end of the 530 . Although not shown in the drawings, a valve (not shown) for opening or closing the water supply line 530 may be provided in the water supply line 530 , and a water supply pump (not shown) for supplying water through the water supply line 530 . city) may be provided separately.

In addition, a drain pump 520 for discharging water and foreign substances inside the water tank 510 to the outside is formed on one side of the lower inner side of the water tank 510 , and the drain pump 520 penetrates the inner wall of the water tank 510 . It is connected to the formed drain line 521 to discharge water and foreign substances inside the water tank 510 to the outside through the drain line 521 . Although not shown in the drawings, a valve (not shown) for opening or closing the drain line 521 may be separately provided in the drain line 521 .

The disinfection device 550 is formed on one side of the lower end of the water tank 510 , and receives ozone and chemicals required for water purification through the ozone and purification agent supply unit 20 .

In addition, the purification system 100 for water treatment is formed to be connected to the disinfection device 550 on one side of the lower end of the water tank 510 .

Accordingly, after the contaminated water is sucked in through the inlet 551 , it is first purified in the disinfection device 550 , then passes through the purification system 100 for water treatment and is secondarily purified through the outlet 552 in the water tank 510 . ) so that the water inside the water tank 510 can be maintained in a clean state by being discharged to the inside.

The overflow pipe 522 is formed through the inner wall of the water tank 510 at the inner upper end of the water tank 510, and when the height of the water inside the water tank 510 exceeds the water level limit, the overflow pipe 522 of the water tank (510) Water exceeding the water level limit is introduced into the overflow inlet 523 formed at the inner end and discharged to the outside through the overflow pipe 522, so that the height of the water inside the water tank 510 does not exceed the water level limit. adjusted so that

A plurality of spray nozzles 542 formed on the upper part of the amusement facility are formed on the ground spaced apart from the water tank 510 by a certain distance, and are installed on the floor surface formed low by a certain height so that the sprayed water can be stagnant without flowing to the outside, On the bottom surface, the water sprayed from the spray nozzle 542 and stagnated on the floor is discharged from the recovery line 570 and the spray nozzle 542 to the inside of the water tank 510 to recover the water accumulated on the floor to the outside. A discharge pipe 580 for discharging is formed. At this time, the recovery line 570 and the discharge pipe 580 are formed at a position lower than the floor where the water is located, so that it is possible to recover or discharge the water accumulated on the floor without a separate device such as a pump.

On the other hand, a plurality of injection nozzles 542 formed on the upper part of the amusement facility discharge water coming through the supply line 541 connected from the supply pump 540 to the outside to spray a stream of water.

In addition, a lighting (not shown) is attached to the spray nozzle 542 to illuminate the water sprayed through the spray nozzle 542 to produce an effect of coloring the water, and according to the control signal of the IOT control panel 10 . Color or brightness can be controlled, so it can be used to produce lights that are bright or dark depending on the volume or pitch of the music.

The supply pump 540 is connected to the injection nozzle 542 and the supply line 541 to supply water to the injection nozzle 542 .

In the water park 500 to which the purification system 100 for water treatment configured as described above is applied, water presentation is operated by a control signal applied to each device based on various sound sources and water presentation pattern data stored in the IOT control panel 10 . It is controlled to be able to be, and clean water purified through the purification system 100 for water treatment can be sprayed to the outside through the injection nozzle 542 .

Hereinafter, the configuration and operation of the wall cloth 600 to which the purification system 100 for water treatment according to an embodiment of the present invention is applied will be described in detail with reference to FIG. 17 .

17, the wall cloth 600 to which the purification system 100 for water treatment according to an embodiment of the present invention is applied is a water tank 610, a supply pump 640 formed at the lower inner side of the water tank 610, The disinfection device 650 formed at the inner lower end of the water tank 610 to be spaced apart from the supply pump 640, the drain pump 620 and the water tank 610 formed on one side of the inner lower end of the water tank 610 and spaced apart from each other by a certain distance It is formed in the place and includes a spray nozzle 641 formed at a location spaced apart from the ground by a certain height so that the sprayed water can flow along the wall in the direction of the ground, and purification for water treatment applied to the wall cloth 600 and the wall cloth 600 The system 100 is connected through the IOT control panel 10 and a communication power cable (not shown) to control the operation of each component. At this time, the IOT control panel 10 may control the operation of the wall cloth 600 to which the purification system 100 for water treatment is applied according to weather and climate. That is, it is possible to control the wall cloth 600 not to operate on a rainy day, reduce the water injection amount on a low temperature day, and control it to increase the water injection amount on a high temperature day. As described above, the IOT control panel 10 provided in the present invention is an artificial intelligent device and can control the operation of the wall cloth 600 to which the water purification system 100 is applied based on data such as weather and climate.

The water tank 610 is buried lower than the ground, and a space is formed in which water and each component are accommodated.

That is, the water tank 610 is prepared by excavating the ground and excavating the ground and compacting the excavated ground floor. It may be formed by stacking the protective mortar layers in the order, but is not limited thereto.

In addition, a support frame for supporting the flagstone installed in the ground is formed on the upper surface of the water tank 610 .

On one side of the inner side of the water tank 610, a water supply line 630 for supplying water to the inside of the water tank 610 is formed through the inner wall of the water tank 610, and a water supply line located inside the water tank 610 ( A water supply port 632 is formed at the end of the 630 . Although not shown in the drawings, a valve (not shown) for opening or closing the water supply line 630 may be provided in the water supply line 630 , and a water supply pump (not shown) for supplying water through the water supply line 630 . city) may be provided separately.

In addition, a drain pump 620 for discharging the water and foreign substances inside the water tank 610 to the outside is formed on one side of the inner lower end of the water tank 610 , and the drain pump 620 penetrates the inner wall of the water tank 610 . It is connected to the formed drain line 621 to discharge water and foreign substances inside the water tank 610 to the outside through the drain line 621 . Although not shown in the drawings, a valve (not shown) for opening or closing the drain line 621 may be separately provided in the drain line 621 .

The disinfection device 650 is formed on one side of the lower end of the water tank 610 , and receives ozone and chemicals required for water purification through the ozone and purification agent supply unit 20 .

In addition, the purification system 100 for water treatment is formed to be connected to the disinfection device 650 on one side of the lower end of the water tank (610).

Accordingly, after the contaminated water is sucked in through the inlet 651, it is first purified in the disinfection device 650, then passes through the purification system 100 for water treatment and is secondarily purified through the outlet 652 in the water tank 610 ) so that the water inside the water tank 610 can be maintained in a clean state by being discharged to the inside.

The overflow pipe 622 is formed through the inner wall of the water tank 610 at the inner upper end of the water tank 610, and when the height of the water inside the water tank 610 exceeds the water level limit, the overflow pipe 622 of the water tank (610) Water exceeding the water level limit is introduced into the overflow inlet 623 formed at the inner end and discharged to the outside through the overflow pipe 622, so that the height of the water inside the water tank 610 does not exceed the water level limit. adjusted so that

The spray nozzle 641 formed at a location spaced apart from the water tank 610 by a certain distance and formed at a location spaced apart from the ground by a certain distance so that the sprayed water can flow along the wall in the direction of the ground is the supply pump 640. is discharged to the outside so that it flows along the wall toward the ground.

In addition, a light (not shown) is attached to the wall through which the water sprayed from the spray nozzle 641 flows to illuminate the water flowing along the wall to produce an effect of coloring the water, and the control signal of the IOT control panel 10 The color or brightness can be controlled according to the music, so it can be used to produce bright or dark lighting depending on the volume or pitch of the music.

The supply pump 640 is connected to the injection nozzle 641 and the supply line 641 to supply water to the injection nozzle 641 .

The wall cloth 600 to which the purification system 100 for water treatment configured as described above is applied, based on the various sound sources and water presentation pattern data stored in the IOT control panel 10, the water presentation will be operated by a control signal applied to each device. It is controlled so as to be able to, and clean water purified through the purification system 100 for water treatment can be sprayed to the outside through the spray nozzle 641 .

Hereinafter, the configuration and operation of the purified water disinfection system 700 to which the purification system 100 for water treatment according to an embodiment of the present invention is applied will be described in detail with reference to FIG. 18 .

18, the purified water disinfection system 700 to which the purification system 100 for water treatment according to an embodiment of the present invention is applied is a supply pump 740, a purification system 100 for water treatment, and a supply pipe 770. and a spray nozzle 780, and the purification system 100 for water treatment applied to the purified water disinfection system 700 and the purified water disinfection system 700 connects the IOT control panel 10 and the communication power cable (not shown). The operation of each component is controlled by being connected through it.

The purified water disinfection system 700 configured as described above purifies the water introduced into the inlet 751 by the supply pump 740 through the purification system 100 for water treatment, and then sprays a plurality of water through the supply pipe 770 . It is supplied to the nozzle 780 to be sprayed. At this time, the supply pipe 770 receives ozone and chemicals necessary for water purification through the ozone and purifying chemical supply unit 20, passes through the purification system 100 for water treatment, sterilizes the firstly purified water, and then the spray nozzle (780).

A plurality of spray nozzles 780 are formed in the purified water disinfection system 390 in a form inclined in one direction along the supply pipe 770 as shown in FIG. 18 .

The spray nozzle 780 sprays water entering through the supply pipe 770 connected from the supply pump 740 to the water stagnant in the purified water disinfection system 700, so that the stagnant water in the purified water disinfection system 700 is directed in a certain direction. By changing the direction of the injection nozzle 780 according to the control signal of the IOT control panel 10 by installing the injection nozzle 780 to be movable by a driving motor (not shown) in the present invention. It is possible to change the flow direction of the water accumulated in the purified water disinfection system 700 .

As described above, in the purified water disinfection system 700 of the present invention, the water treatment purification system 100 ), it is possible to effectively stir the purified water and ozone and chlorine supplied from the ozone and purifying chemical supply unit 20 .

On the other hand, a microbubble generator 781 is formed inside the injection nozzle 780, and the microbubble generator 781 mixes air with the water purified in the water purification system 100 for water treatment to create microbubbles with a diameter of 50 μm or less. creates

As microbubbles are generated in the purified water, the purified water particles become finer, and thus the area in which the purified water particles come into contact with ozone and chlorine supplied from the ozone and purifying agent supply unit 20 increases, so that the purified water is purified. It is possible to improve the disinfection efficiency of water. In addition, as microbubbles are generated in the purified water, when the particles of the purified water become finer, the buoyancy is lowered and the rate of ascent in the water is sharply lowered and stays in the water for a long time. The contact time with ozone and chlorine supplied from the supply unit 20 may be increased to improve disinfection efficiency.

As described above, in the present invention, the ozone supplied from the ozone and purifying agent supply unit 20 and It is possible to improve the disinfection efficiency by chlorine.

On the other hand, the IOT control panel 10 receives the pressure data on the inlet side of the water treatment purification system 100 from the pressure gauge 760 formed on the contaminated water inlet pipe side of the water treatment purification system 100 and automatically performs the backwashing process. can make it happen In general, in the process of filtration of water, foreign substances are caught in the gaps of the filtration screen, thereby increasing the pressure in the contaminated water inlet pipe. As described above, when the pressure gauge 760 is installed in the contaminated water inlet pipe of the water purification system 100 for water treatment, IOT control After reading the pressure data in the contaminated water inlet pipe of the water treatment purification system 100 from the panel 10 and comparing it with a reference pressure value input in advance, the pressure in the contaminated water inlet pipe of the water treatment purification system 100 is input in advance. When the standard pressure value is out of the standard pressure value, the IOT control panel 10 can control the backwashing process to be performed automatically. At this time, when the user inputs the reference pressure value in advance to the IOT control panel 10 or the user does not input the reference pressure value in advance, the inflow of contaminated water from the water treatment purification system 100 transmitted from the pressure gauge 760 It is possible to automatically set the reference pressure value by analyzing the pressure accumulation data on the pipe side in the IOT control panel (10). At this time, even when the user inputs the reference pressure value in the IOT control panel 10 in advance, the IOT control panel 10 analyzes the pressure accumulation data and, if necessary, may automatically change the reference pressure value input in advance.

As described above, the IOT control panel 10 formed in the purified water disinfection system 700 to which the water purification system 100 is applied is an artificial intelligent device that accumulates and analyzes the pressure data transmitted from the pressure gauge 760 to analyze the purified water disinfection system 700 ), it is possible to automatically control the purification and backwashing process of the purification system 100 for water treatment.

The purified water disinfection system 700 described above can be applied to various facilities such as a floor fountain, a fountain, a music fountain, a water play area, a swimming pool, a running water pool, a byeokcheon, and a running water pool shown in FIGS. 15 to 17 .

As described in detail above, the present invention is for purifying water or irrigation water used in fountains and water play facilities, wastewater treatment plants, non-point pollution reduction water treatment, recycling water treatment, lakes, reservoirs, reservoirs, agricultural water, industrial water, etc. It relates to a purification system for water treatment used, and by forming filtering screens in the spaces on both sides of the main body, so that the contaminated water is filtered twice while passing through each filtering screen, the purification performance of the contaminated water can be improved.

In addition, by forming backwash nozzles on the inside of each filter screen, it is possible to simultaneously perform backwashing of each filter screen. It can effectively remove foreign substances.

In addition, it is possible to improve the purification performance of the contaminated water by forming a plurality of porous media for removing fine impurities contained in the contaminated water inside the filtration screen.

In addition, it is possible to further improve the purification performance of contaminated water by forming a second purification device equipped with an activated carbon filter and an LED sterilizer.

In addition, the purification system for water treatment of the present invention can be applied to various facilities such as a floor fountain, a fountain, a music fountain, a water playground, a swimming pool, a running water pool, a byeokcheon, and a running water pool.

As described above, the detailed description of the present invention has been made by the embodiments with reference to the accompanying drawings, but since the above-described embodiments have only been described with preferred examples of the present invention, the present invention is limited only to the above embodiments It should not be understood as being, and the scope of the present invention should be understood as the following claims and their equivalent concepts.

100: purification system for water treatment
110: body
110a: first filtration chamber
110b: second filter room
111: contaminated water inlet pipe
112: filtered water discharge pipe
112a: solenoid valve
113: backwash water inlet pipe
113a: solenoid valve
114: first connection pipe
115: second connection pipe
115a: solenoid valve
116: first backwash water discharge pipe
116a: solenoid valve
117: second backwash water discharge pipe
117a: solenoid valve
118: diaphragm
118a: through hole
120: cover
130: first filtration screen
131: first backwash nozzle
131a: injection hole
132: Euro
140: second filtration screen
140a: porous media
141: second backwash nozzle
141a: jet hole
160: support
200: second purification device
210: activated carbon filter
220 : LED Sterilizer
230: inlet
240: outlet
<Another embodiment of the backwashing nozzle>
170: backwash nozzle
171: injection hole
180: backwash nozzle
181: lower body
182: upper body
183: nozzle
190: backwash nozzle
191: body
192: head
193 : Nozzle
<Another embodiment of a purification system for water treatment>
300: purification system for water treatment
320: backwash nozzle
321: body part
322: head
323: nozzle
330: first filtration screen
340: second filtration screen
341: carbon grains
342: ceramic ball
343: hydro filter (Volcanic ash)
<Fountain Fountain>
10: IOT control panel
20: ozone and purification chemical supply unit
100: purification system for water treatment
400: floor fountain
410: water tank
420: drain pump
421: drain line
422: overflow pipe
423: overflow entrance
430: water supply line
440: supply pump
441: supply line
442: injection nozzle
450: disinfection device
451: inlet
452: outlet
<Water Playground>
10: IOT control panel
20: ozone and purification chemical supply unit
100: purification system for water treatment
500 : water playground
510: water tank
520: drain pump
521: drain line
522: overflow pipe
523: overflow entrance
530: water supply line
540: supply pump
541: supply line
542: spray nozzle
550: disinfection device
551: inlet
552: outlet
570: recovery line
580: exhaust pipe
<Wall Cloth>
10: IOT control panel
20: ozone and purification chemical supply unit
100: purification system for water treatment
600: wall cloth
610: water tank
620: drain pump
621: drain line
623: overflow entrance
630: water supply line
640: supply pump
641: injection nozzle
650: disinfection device
651: inlet
652: outlet
<Lazy pool>
10: IOT control panel
20: ozone and purification chemical supply unit
100: purification system for water treatment
700: lazy river
740: supply pump
751: inlet
760: pressure gauge
770: supply pipe
780: spray nozzle

Claims (14)

a body in which an inner space is separated into a first filtration chamber and a second filtration chamber by a diaphragm;
a first filtration screen fixedly installed in the first filtration chamber of the main body;
a second filtration screen fixedly installed in the second filtration chamber of the main body;
a contaminated water inlet pipe for supplying contaminated water to the first filtration chamber of the main body;
a filtered water discharge pipe through which the filtered water is discharged through the first and second filtering screens;
a first connection pipe for supplying backwashing water to the inside of the first and second filtration screens and connected to the first filtration screen; and a second connection pipe connected to the second filtration screen;
a backwash water discharge pipe for discharging backwash water to the outside;
a first backwash nozzle formed inside the first filtering screen to communicate with the first connection pipe to spray backwashing water to the first filtering screen; and
a second backwash nozzle formed inside the second filtration screen to communicate with the second connection pipe to spray backwashing water to the second filtration screen; and
The first and second backwash nozzles are
lower body; and
Including; an upper body capable of 360 degree rotation with respect to the lower body;
A purification system for water treatment, characterized in that a semi-circular injection hole is formed in the upper body.
According to claim 1,
One end of the first filtration screen having a closed structure is installed to flow into the second filtration chamber through the through hole of the diaphragm, so that the filtered water introduced into the first filtration screen can move to the second filtration chamber. A purification system for water treatment, characterized in that a flow path is formed.
3. The method of claim 2,
A purification system for water treatment, characterized in that a plurality of porous media is formed inside the second filtration screen.
delete delete delete delete delete 4. The method according to any one of claims 1 to 3,
The backwash water discharge pipe is
a first backwashing water discharge pipe connected to the first filtration chamber to discharge backwashing water from which the backwashing process of the first filtration screen has been performed; and
and a second backwash water discharge pipe connected to the second filtration chamber to discharge backwash water that has been subjected to the backwashing process of the second filtration screen.
According to claim 1,
The purification system for water treatment,
A floor fountain that purifies and disinfects water sucked in through the inlet and discharges it to the inside of the water tank through the outlet, controlled by the IOT control panel, and then sprays purified and disinfected water to the outside through a plurality of spray nozzles formed at the top of the water tank Or a purification system for water treatment, characterized in that it is applied to a music fountain.
According to claim 1,
The purification system for water treatment,
It is controlled by the IOT control panel to purify and disinfect the water sucked in through the inlet and discharge it to the inside of the water tank through the outlet. A purification system for water treatment, characterized in that it is applied.
According to claim 1,
The purification system for water treatment,
It is controlled by the IOT control panel to purify and disinfect the water sucked in through the inlet and discharge it to the inside of the water tank through the outlet. Purification system for water treatment, characterized in that it is applied to the wall cloth to flow in the direction of the ground along the.
a body in which an inner space is separated into a first filtration chamber and a second filtration chamber by a diaphragm;
a first filtration screen fixedly installed in the first filtration chamber of the main body;
a second filtration screen fixedly installed in the second filtration chamber of the main body;
a contaminated water inlet pipe for supplying contaminated water to the first filtration chamber of the main body;
a filtered water discharge pipe through which the filtered water is discharged through the first and second filtering screens;
a backwash water inlet pipe for supplying backwash water to the inside of the first and second filtration screens; and
In the purification system for water treatment comprising; a backwash water discharge pipe for discharging backwash water to the outside,
The purification system for water treatment,
Purified water is controlled by the IOT control panel to purify the water sucked into the inlet and spray the purified water through a plurality of spray nozzles inclined in one direction to the supply pipe so that the water rotates while flowing in a certain direction. A purification system for water treatment, characterized in that it is applied to a purified water disinfection system that agitates ozone and chlorine supplied from the ozone and purification chemical supply unit.
14. The method of claim 13,
A purification system for water treatment, characterized in that a microbubble generator is formed inside the injection nozzle of the purified water disinfection system.

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