KR102146912B1 - Water quality management unit using water quality monitoring - Google Patents

Abstract

The present invention relates to an apparatus for purifying water quality using water quality monitoring, and more specifically, continuous water purification is achieved by selectively using two water purification modules, and the opening amount of the main valve in the main pipe is measured through a water quality sensor. By making the decision, water within the standard water quality can be supplied to the customer without significantly interfering with the flow of water, and backwashing can be performed with purified water when backwashing the water filter, and even when backwashing the water filter. Purified water can be continuously supplied to the main pipe, and the shape of the water filter is changed to a state where foreign matter is easily removed during backwashing, and water quality monitoring is used to more stably determine the backwashing timing of the water purification module. It is to provide a water purification device for tap water.

Description

Water quality management unit using water quality monitoring

The present invention relates to an apparatus for purifying water quality using water quality monitoring, and more specifically, continuous water purification is achieved by selectively using two water purification modules, and the opening amount of the main valve in the main pipe is measured through a water quality sensor. By making the decision, water within the standard water quality can be supplied to the customer without significantly interfering with the flow of water, and backwashing can be performed with purified water when backwashing the water filter, and even when backwashing the water filter. Purified water can be continuously supplied to the main pipe, and the shape of the water filter is changed to a state where foreign matter is easily removed during backwashing, and water quality monitoring is used to more stably determine the backwashing timing of the water purification module. It is to provide a water purification device for tap water.

Water flowing over the water supply pipe may cause contaminants to flow into the water due to construction, damage, vibration, water pressure, and direction of water flow. If such contaminated water reaches the customer, it becomes a big problem, so it is necessary to measure the contamination level of water flowing over the water supply pipe and take appropriate measures.

Conventionally, water with high pollution levels is supplied to customers by measuring the pollution level of water flowing over the tap water pipe, discharging all water at a specific point on the tap water pipe, and stopping the discharge when the water pollution level falls below a set value. Was prevented.

However, by discharging all the water until the degree of contamination of the water drops, there is a problem that a water shortage phenomenon occurs in which the customer cannot receive water during that period.

Accordingly, there is a need to develop a device capable of preventing a water shortage phenomenon while preventing water with a high degree of contamination from being supplied to customers.

KR10-1076179 (registration number) 2011.10.17.

In the present invention, continuous water purification is achieved by selectively using two water purification modules, and by determining the opening amount of the main valve in the main pipe through a water quality sensor, water within the water quality standard value without significantly disturbing the flow of water It is an object of the present invention to provide an apparatus for purifying tap water using water quality monitoring that can be supplied to customers.

In addition, the present invention enables backwashing with purified water during backwashing of the water filter, so that even if contaminated water flows through the water supply pipe, it is not washed with water flowing through the water supply pipe during backwashing to prevent contamination of the filter. The purpose of this is to provide a water quality purification device for tap water using possible water quality monitoring.

In addition, an object of the present invention is to provide an apparatus for purifying water quality using a water quality monitoring that minimizes water supply to a customer by allowing purified water to be continuously supplied into the main pipe even when backwashing the water filter.

In addition, an object of the present invention is to provide an apparatus for purifying water quality using water quality monitoring in which the shape of a water filter during backwashing is changed to a state in which foreign matter is easily removed.

In addition, an object of the present invention is to provide an apparatus for purifying water quality using water quality monitoring capable of installing a small scale because a separate pump facility is not required for backwashing a water purification module.

The present invention includes a front auxiliary pipe and a rear auxiliary pipe provided to communicate with the main pipe; A main valve disposed between a coupling portion of the front auxiliary pipe and a coupling portion of the rear auxiliary pipe inside the main pipe; A first water purification line having one end in communication with the front auxiliary pipe and the other end in communication with one end of the rear auxiliary pipe; A second water purification line provided in parallel to the first water purification line, one end connected in communication with the front auxiliary pipe, and the other end connected in communication with one end of the rear auxiliary pipe; First and second water purification modules provided on the first and second water purification lines to purify water flowing on the first and second water purification lines; A water quality sensor measuring the water quality inside the main pipe; A control unit receiving the measured value of the water quality sensor and controlling an opening amount of the main valve; The first and second water purification modules may include: first and second water purification housings having one side communicating with an inlet side of the first and second water purification lines and a lower end communicating with the outlet side; The upper end is sealed and the lower end is opened to be separated from the side surfaces of the first and second water purification housings and coupled to the bottom surfaces of the first and second water purification housings, and the inner hollow part communicates with the outlet side of the first and second water purification lines. First and second water filters; First and second drain lines communicating with one side of the first water purification housing; First and second drain valves provided inside the first drain line; Including, the first and second water purification lines are provided with first and second inlet valves on the inlet side, and first and second outlet valves on the outlet side Is provided; During the backwash operation, the opening and closing states of the inlet valves of the first and second water purification lines are opposite to each other, and the opening and closing states of the outlet valves are the same; The first and second water filters included in the first and second water purification modules have a smaller vertical height and a wider side surface during reciprocal water than during water purification; The first water purification housing and the second water purification housing each include a first water purification actuator and a second water purification actuator that pressurizes a first water filter and a second water filter provided therein, and the control unit is configured to perform backwashing. The first purified water actuator and the second purified water actuator are operated differently from each other.

The water that has passed through the first water purification module or the second water purification module of the present invention is transferred to the main pipe through the rear auxiliary pipe during water purification, and the purified water passes through the water purification module for back washing during back washing.

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In the present invention, the extension length of the actuator built in the water purification module to be backwashed is longer than the extension length of the actuator built in the water purification module.

In the present invention, continuous water purification is achieved by selectively using two water purification modules, and by determining the opening amount of the main valve in the main pipe through a water quality sensor, water within the standard water quality can be accommodated without significantly interfering with the flow of water. It has the effect of being able to supply to.

In addition, the present invention provides backwashing by supplying purified water to a water purification module requiring backwashing while performing a backwashing while one water purification module purifies the other water purification module at a time when backwashing is required. Even if water flows in the water supply line, the filter is contaminated by backwashing, so that backwashing can be performed with clean water during backwashing of the water filter.

In addition, in the present invention, while one water purification module purifies the other cleansing module at a time when backwashing is required, while supplying purified water to the water purification module requiring backwashing, a part of the purified water is returned to the main pipe. By consolidating into the main pipe, purified water can be continuously supplied to the main pipe, thereby minimizing the number of steps to the customer even in the backwashing process.

In addition, the present invention is provided with an actuator to pressurize the water filter from above during backwashing to change the shape of the hole in the mesh net of the water filter, so that the water filter is in a state in which foreign matter is easily removed during backwashing. have.

In addition, the present invention does not require a separate pump facility for backwashing of the water purification module, and thus, there is an advantage that a small scale can be installed.

1 is a cross-sectional view of an apparatus for purifying water quality using water quality monitoring according to an embodiment of the present invention.
Figure 2 is a cross-sectional view of the first and second water purification modules of the water purification apparatus using water quality monitoring according to an embodiment of the present invention.
3 is a state diagram of use of the first and second water filters when the first and second actuators of the water supply water purification apparatus using water quality monitoring according to an embodiment of the present invention are operated.
4 is a state diagram of use of a first water purification module of a water purification apparatus using water quality monitoring according to an embodiment of the present invention during water purification.
5 is a use state diagram of a first water purification module of a water purification apparatus using water quality monitoring during a backwash operation in accordance with an embodiment of the present invention.

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

The present invention provides a main pipe 100 for supplying water to a customer, a front auxiliary pipe 230 having one end in communication with the main pipe 100, and a rear side provided with the other end in communication with the main pipe 100 The auxiliary pipe 240 and the main valve 110 provided between the coupling portion of the front auxiliary pipe 230 and the coupling portion of the rear auxiliary pipe 240 on the inside of the main pipe 100, and the rear auxiliary pipe 240 ) From the inside of the backflow prevention valve 247 provided so that water flows only in the direction toward the main pipe 100, and one end is coupled in communication with the other end of the front auxiliary pipe 230, and the other end is the rear auxiliary pipe 240 It is provided in parallel with the first water purification line (A) and the first water purification line (A) connected to one end of the first water purification line (A), one end is connected in communication with the other end of the front auxiliary pipe 230, and the other end is the rear auxiliary pipe 240 A second water purification line (B) connected in communication with one end of the), a first water purification module 210 provided on the first water purification line (A) to purify water flowing on the first water purification line, and a second water purification The second water purification module 220 is provided on the line (b) to purify the water flowing on the second water purification line, and is provided in the front of the front auxiliary pipe 230 coupling portion inside the main pipe 100 and inside the pipe. A front water quality sensor 101 that measures the water quality of the main pipe 100, a rear water quality sensor 102 provided at the rear of the rear auxiliary pipe 240 coupling part to measure the water quality inside the pipe, and the front water quality It is configured to include a control unit that receives the measured values of the sensor 101 and the rear water quality sensor 102 and controls the opening amount of the main valve 110.

The main pipe 100 is provided between the source of water and the customer and serves to supply water to the customer, and is usually buried in the ground, but is not limited thereto.

At one side of the main pipe 100, the front auxiliary pipe 230 is connected in communication, and the rear auxiliary pipe 240 is connected in communication at a position spaced from the position where the front auxiliary pipe 230 is coupled to the rear. In addition, a main valve 110 is provided between the position where the front auxiliary pipe 230 is coupled to the inner side of the main pipe 100 and the position where the rear auxiliary pipe 240 is coupled to the main pipe 100 and the front auxiliary pipe. It is configured to adjust the ratio of water flowing through the pipe 230.

A front water quality sensor 101 is provided inside the front where the front auxiliary pipe 230 of the main pipe 100 is coupled, and the front water quality sensor 101 measures turbidity, PH, chlorine concentration, electrical conductivity, etc. It is configured so that water having high turbidity can be quickly introduced into the front auxiliary pipe 230. To this end, the front water quality sensor 101 is provided inside the main pipe 100 in front of the coupling portion 10 to 30 meters of the front auxiliary pipe 230. In addition, a rear water quality sensor 102 is provided on the rear inner side of the main pipe 100 to which the rear auxiliary pipe 240 is coupled, so that the water flowing through the main pipe 100 and the first water purification module 210 or the second purified water It is configured to measure turbidity in a state in which water introduced through the rear auxiliary pipe 240 through the module 220 is mixed. The rear water quality sensor 102 is installed 5 to 30 m rear from the coupling portion of the rear auxiliary pipe 240 and measures after being sufficiently mixed between the water passing through the water purification line and the May pipe.

The reason why the front water quality sensor 101 and the rear water quality sensor 102 are respectively provided is, when the opening amount of the main valve 110 is controlled only by the measured value of the front water quality sensor 101, the first water purification module 210 ) Or the water purified through the second water purification module 220 and water flowing through the main valve 110 in a mixed state, such as turbidity. In addition, when adjusting the opening amount of the main valve 110 only by the measured value of the rear water quality sensor 102, also, the opening amount of the main valve 110 only after the measured value of the rear water quality sensor 102 is greater than or equal to the set value. There is a concern that water with high turbidity will be supplied to customers as it can be adjusted.

Meanwhile, when the front water quality sensor 101 is used alone and the water quality is greater than or equal to a preset value, the opening amount of the main valve 110 may be set to 0%. In this case, the first water purification module 210 or the second There is a concern that it may cause an excessive burden on the water purification module 220 and shorten the life of the module.

Therefore, when the water (raw water) flowing through the main pipe 100 is greater than or equal to the value set by the front water quality sensor 101, the main valve 110 partially opens (adjusts the opening amount), and the first water purification module ( 210) or the second water purification module 220 by allowing a portion of the water to flow, and the water quality after the water that has passed through the water purification module and the water flowing through the main pipe are mixed by the rear water quality sensor 102, It checks whether it is within the set value, and if the water quality item measured by the rear water quality sensor 102 is within the set water quality, the current water condition is maintained, and if the measured value of the water quality sensor 102 is higher than the set value, the main The amount of water moving to the water purification module is increased by reducing the opening amount of the valve 110. At this time, if the pollution degree of water flowing through the main pipe 100 is very severe, the first and second water purification modules 210 and 220 are operated simultaneously to increase the amount of purified water, and the opening amount of the main valve 110 It is also possible to reduce the amount of water so that most or all of the water flowing toward the receiver becomes water that has passed through the water purification module.

Afterwards, when it is confirmed that the water quality of the water flowing into the main pipe 100 by the front water quality sensor 101 is improved, the control unit adjusts the opening amount of the main valve through the value measured by the rear water quality sensor 102 Adjust the amount of water flowing into the furnace.

The main valve 110 serves to adjust the ratio of water flowing through the main pipe 100 and the front auxiliary pipe 230, and for this purpose, the coupling portion of the front auxiliary pipe 230 and the inner side of the main pipe 100 It is provided between the coupling portion of the rear auxiliary pipe 240.

The main valve 110 is driven on the main pipe 100 to give resistance to water flowing on the main pipe 100, and is configured to adjust the amount of opening from 100% to 0%. The opening amount of the main valve 110 is determined by the control of the control unit, and when it is 100% open, the amount of water flowing to the front auxiliary pipe 230 is very little or no, and when it is 0%, all water is forward auxiliary. The first water purification module 210 or the second water purification module 220 is passed through the pipe 230. In the present invention, two water purification lines are provided, each water purification line includes a respective water purification module on the water purification line, and each water purification module also includes a respective water purification housing, a water filter, a drain line, and a drain valve. An inlet valve is provided on the inlet side of the line and an outlet valve is provided on the outlet side. In the present invention, when each of the water purification lines and the water purification modules on the water purification lines and their internal configurations are respectively described, they are separately described, and in this case, they are referred to as a first integer line and a second integer line.

On the other hand, when these are described at the same time, the first and second integer lines are used to simplify the notation. The rest of the components are the same. Accordingly, "the first and second drain lines communicating with one side of the first and second water purification housings" are "the first drain lines communicating with one side of the first water purification housing", and "the second drain line communicating with one side of the second water purification housing." “Drain line” is marked at once. In addition, "the first and second water purification housings in which one side communicates with the inlet side of the first and second water purification lines and the lower end is in communication with the outlet side" means "one side is in communication with the inlet side of the first water purification line, and the outflow The first water purification housing having a lower end in communication with the side and “a second water purification housing in which one side communicates with the inlet side of the second water purification line and the lower end communicate with the outlet side” are collectively indicated.

On the other hand, the water purifying device 200 that is coupled in communication with the main pipe 100 of the present invention to branch and purify water flowing in the main pipe 100 is a front auxiliary pipe 230, a rear auxiliary pipe 240, and reverse flow It consists of a prevention valve 247, the first water purification line (A), the second water purification line (B), the first water purification module 210, the second water purification module 220, etc. In order to do this, the components of each part will be mainly described.

The front auxiliary pipe 230 supplies water to the first water purification module 210 through the inlet 231 of the first water purification line (A), or the second water purification line (B) to the second water purification module 220 ) Serves to supply water through the inlet side 232, and for this purpose, one end is coupled to the main pipe 100 in communication.

Accordingly, the other end of the front auxiliary pipe 230 is connected in communication with one end of the inlet side 231 of the first water purification line (A) and the inlet side 232 of the second water purification line (B).

At this time, a plurality of front auxiliary pipes 230 may be provided to supply water to the first water purification module 210 and the second water purification module 220 as respective pipes, and the inlet side 231 of the first water purification line And one end of the inlet side 232 of the second water purification line extends forward and is coupled to the main pipe, and at this time, each of the extended inlet sides 231 and 232 becomes the front auxiliary pipe 230.

The rear auxiliary pipe 240 is water discharged through the outlet side 241 of the first purified water line through the first water purification module 210 or the outlet side of the second purified water line through the second water purification module 220 ( It serves to join the water flowing out through 242 to the main pipe 100, and for this purpose, the other end is coupled to the main pipe 100 in communication.

Accordingly, one end of the rear auxiliary pipe 240 is connected in communication with the outlet side 241 of the first water purification line (A) and the other end of the outlet side 242 of the second water purification line (B). A plurality of rear auxiliary pipes 240 may be provided to provide water purified by the first water purification module 210 and the second water purification module 220 to respective pipes. In this case, the outlet side of the first water purification line ( 241) and the other end of the outlet side 242 of the second water purification line is extended to be directly coupled to the main pipe 100, and the other end of each extended outlet side 241, 242 becomes the rear auxiliary pipe 240, The present invention encompasses this.

At this time, the water flowing on the main pipe 100 is high pressure, and the first water purification module 210 and the second water purification module 220 are inlet sides 231 and 232 and outlet sides 241 and 242 by a water filter. Since a pressure difference of is generated, there is a concern that water flowing on the main pipe 100 flows in the direction of the first water purification module 210 or the second water purification module 220 in reverse along the rear auxiliary pipe 240. Accordingly, a non-return valve 247 is provided inside the rear auxiliary pipe 240 in order to prevent such reverse flow.

The non-return valve 247 is provided inside the rear auxiliary pipe 240 so that water flowing on the rear auxiliary pipe 240 flows only in a direction toward the main pipe 100, and is in the form of a check valve in the forward direction. It is configured to pass only the flow and block the flow in the reverse direction.

The first water purification line (A) receives water from the main pipe 100 through the front auxiliary pipe 230, supplies water to the first water purification module 210, and supplies the purified water to the rear auxiliary pipe 240. It means the overall facility supplied by

The first water purification line (A) is not a name that refers to a single continuous pipe type. A series of lines for supplying or discharging water to the first water purification module 210 to proceed with water purification is referred to as a first water purification line (A), and looking at this in detail, the front auxiliary pipe 230 and the first water purification module ( Each of the portions communicating with 210) is the inlet side 231 of the first water purification line, and the portion communicating with the first water purification module 210 and the rear auxiliary pipe 240 is the outlet side 241 of the first water purification line. It is distinguished.

Therefore, the first purified water line (A) should be interpreted as a name that collectively refers from the inlet side 231 of the first purified water line to the outlet side 241 of the first purified water line.

A first inlet valve 233 is provided on the inlet side 231 of the first water purification line to determine whether to supply water flowing from the front auxiliary pipe 230 to the first water purification module 210, and at the same time, the first water purification module It is configured to prevent the water of the first water purification module 210 from flowing toward the front auxiliary pipe 230 during backwashing of 210.

In addition, a first outlet valve 243 is provided on the outlet side 241 of the first water purification line to allow water to flow to the rear auxiliary pipe 240 during the water purification operation of the first water purification module 210, and at the same time It is configured such that water provided from the outlet side 242 of the second water purification line can be supplied to the first water purification module 210 when backwashing the first water purification module 210. At this time, in a situation where the second water purification module 220 is performing a water purification operation, but the backwashing of the first water purification module 210 is not required, it is preferable that the opening amount of the first outlet valve 243 is set to 0%. .

In addition, a first inlet-side water pressure sensor 235 is provided on the inlet side 231 of the first water purification line, and a first outlet water pressure sensor 245 is provided on the outlet side 241 of the first water purification line. This is to determine the timing of backwashing of the first water purification module 210, and when the first water purification module 210 performs a water purification operation, the first water filter 212 is gradually clogged by foreign substances, and thus water purification efficiency If it falls below this level, backwash should be performed. At this time, the measured value of the first inlet water pressure sensor 235 gradually increases according to the degree of clogging of the first water filter 212, and the measured value of the first outlet water pressure sensor 245 gradually decreases. Accordingly, when the difference between the measured values of the first inlet-side water pressure sensor 235 and the first outlet-side water pressure sensor 245 is greater than or equal to the set value, it is determined as a time when backwashing of the first water purification module 210 is required.

The first water purification module 210 serves to purify water supplied through the first water purification line, and for this purpose, one side communicates with the other end of the inlet side 231 of the first water purification line, and the lower end is the first water purification line. The outlet side 241 is coupled to one end in communication.

The first water purification module 210 includes a first water purification housing 211 having one side in communication with the inlet side 231 of the first water purification line and a lower end in communication with the outlet side 241 of the first water purification line, and an upper end. The sealed and lower end is formed in a cylindrical shape, separated from the side surface of the first water purification housing 211 and coupled to the bottom surface of the first water purification housing 211, and the inner hollow part is connected to the outlet side 241 of the first water purification line. A first water filter 212 in communication, a first drain line 213 in communication with one side of the first water supply housing 211, and a first drain valve 214 provided inside the first drain line 213 ). In addition, the first water purification module 210 is configured to further include a first actuator 215 for pressing the first water filter 212 downward from the upper end of the first water filter 212.

In the present invention, the actuator is a generic name for a device that moves up and down linearly including a solenoid.

The first water purification housing 211 is a closed tubular shape having a hollow portion formed therein, the inlet side 231 of the first water purification line is connected in communication to one side, and the outlet side 241 of the first water purification line at the lower central portion This communication is combined. In addition, the drain line is coupled to the other side in communication, and the drain line is preferably coupled near the lower edge of the first water filter 212 to be discharged from the first water filter 212 during backwashing. In addition, it is preferable that the inlet side 231 of the first water purification line is also coupled to the upper end or near the side upper end of the first water purification housing 211 so that water can evenly flow into the first water filter 212.

It is preferable that the first actuator 215 is coupled to the upper end of the first water purification housing 211 so that only the drive shaft or cylinder (hereinafter referred to as'drive shaft') is inserted into the upper end of the first water purification housing 211 . This is to prevent water from flowing into the first actuator 215 and to allow the drive shaft to press the upper surface of the first water filter 212 downward when the first actuator 215 is operated. If the actuator 215 can be completely waterproof, it may be provided inside the first water purification housing 211.

The first water filter 212 serves to filter foreign substances of water flowing into the first housing. To this end, the first water filter 212 is formed in a form of overlapping each other so that a plurality of cylindrical mesh nets are concentric, and the upper end is sealed and the lower end is opened, so that the lower opening is the outlet side 241 of the first water purification line. It is coupled to the bottom surface of the first housing from the inside of the first housing to communicate with.

The first water filter 212 is formed by overlapping a plurality of cylindrical mesh nets to form a concentric shape, and the outermost mesh net has the largest hole size, and the hole is formed in a denser shape toward the inside. Therefore, the largest foreign matter is filtered out from the outermost mesh net, and gradually smaller foreign matters are filtered out toward the inside, so that the water reaching the inner hollow portion through all the mesh nets becomes clean. The water from which foreign matters are filtered is flown along the inner hollow portion of the first water filter 212 and the outlet side of the first water purification line coupled to the first water purification housing 211 to communicate with the inner hollow portion of the first water filter 212 Go through 241.

When the first water filter 212 is backwashed, that is, when water is supplied through the outlet side 241 of the first water purification line, water is passed from the inside to the outside of the first water filter 212, When the foreign matter stuck in the filter 212 is removed in the outward direction, the size of the hole in the outer mesh net is larger than the hole in the inner mesh net, so that the foreign material can easily move to the outside of the outermost mesh net. In addition, since the first water filter 212 is pressed from the first actuator 215 in a downward direction during backwashing, the shape of the hole in the mesh network is varied as shown in FIG. 3B. The hole of the mesh net is gradually increased and changed by the drive of the first actuator 215, and since water with a strong pressure is introduced from the inside and discharged to the outside of the water filter, the hole of the mesh net by the variable of the mesh net and the strong water pressure Foreign matters that were strongly stuck in the mesh net change the shape of the hole and fall out. That is, during backwashing, the first actuator is extended more than usual to pressurize the first water filter.

Optionally, when backwashing, the first actuator 215 provides not only a moving force from top to bottom, but also a moving force from bottom to top, so that the first water filter 212 moves up and down, and the size of the mesh network and You can have the shape change continuously.

When the first water filter 212 is backwashed, foreign substances that are removed from the first water filter 212 float inside the first water filter 211. In order to discharge such foreign substances to the outside, a first drain line 213 is connected to one side of the first water purification housing 211 in communication.

The first drain line 213 serves to discharge water inside the first water purification housing 211 to the outside, and is connected to one side of the first water purification housing 211 for this purpose, and is preferably The first water filter 212 is coupled to the bottom surface of the housing 211 and is provided in an outer direction. The first drain line 213 is opened only during backwashing because water should not be discharged to the outside except during backwashing, and the first drain valve 214 is opened so that water can flow to the first drain line 213. Is equipped.

The first drain valve 214 is provided inside the first drain line 213 and is 100% open during backwashing so that the water inside the first water purification housing 211 can be discharged to the outside. It is driven to open 0% or 100% under the control of.

The first actuator 215 serves to pressurize the first water filter 212 from an upper direction to a lower direction by being driven when the first water purification module 210 is backwashed, and for this purpose, the first water filter 212 ) Is provided above.

The first actuator 215 may have a structure that is provided outside the upper end of the first water purification housing 211 and only its driving shaft is inserted into the inside of the first water purification housing 211, but is not limited thereto, and waterproofing may be completely achieved. In the case of a product, it may be provided inside the upper end of the first water purification housing 211.

The state of use of the first actuator 215 is shown in FIG. 3. 3<a> is a state of the first actuator 215 and the first water filter 212 when the first water purification module 210 performs water purification or no operation, and FIG. 3<b> is a backwash. It is a diagram showing the state of the first actuator 215 and the first water filter 212 in the city. 3B, the first water filter 212 is pressed downward when the first actuator 215 is driven, so that the shape of the hole in the mesh net is changed, and thus, the trapped foreign matter is easily removed. Becomes. That is, compared to the case of water purification operation or no operation, the vertical interval of the first water filter 212 becomes smaller during backwashing, and the width of the side surface becomes wider. In addition, when backwashing is completed, the drive shaft of the first water purifying actuator 215 returns to an initial position, and the first water filter 212 is also returned in a form as shown in FIG. 3<a>.

The second water purification line serves to supply water to the second water purification module 220, and for this purpose, both ends are provided in communication with the other end of the front auxiliary pipe 230 and one end of the rear auxiliary pipe 240, respectively.

The second water purification line is not a name that refers to one continuous pipe type. A series of lines for supplying or discharging water to the second water purification module 220 is referred to as a second water purification line, and in detail, a portion communicating with the front auxiliary pipe 230 and the second water purification module 220 is A portion communicating with the inlet side 232 of the second water purification line, the second water purification module 220 and the rear auxiliary pipe 240 is divided into an outlet side 242 of the second water purification line. Therefore, the second purified water line should be interpreted as a name that refers to two parts of the inlet side 232 of the second purified water line and the outlet side 242 of the second purified water line.

A second inlet valve 234 is provided on the inlet side 232 of the second water purification line to determine whether to supply the water flowing from the front auxiliary pipe 230 to the second water purification module 220, or It is configured to prevent water from flowing in the direction of the front auxiliary pipe 230 when the module 220 is backwashed.

In addition, a second outlet valve 244 is provided on the outlet side 242 of the second water purification line to allow water to flow to the rear auxiliary pipe 240 during the water purification operation of the second water purification module 220, or , It is configured so that water provided from the outlet side 241 of the first water purification line can be supplied to the second water purification module 220 when backwashing the second water purification module 220. At this time, in a situation where the first water purification module 210 performs water purification, but the backwash of the second water purification module 220 is not required, it is preferable that the opening amount of the second outlet valve 244 is set to 0%. .

In addition, a second inlet-side water pressure sensor 236 is provided on the inlet side 232 of the second water purification line, and a second outlet side water pressure sensor 246 is provided on the outlet side 242 of the second water purification line. This is to determine the backwash timing of the second water purification module 220, and when the second water purification module 220 performs a water purification operation, the second water filter 222 is gradually clogged by foreign substances, and thus water purification efficiency If it falls below this level, backwash should be performed. At this time, according to the degree of clogging of the second water filter 222, the measured value of the second inlet side water pressure sensor 236 gradually increases, and the measured value of the second outlet side water pressure sensor 246 gradually decreases. Therefore, when the difference between the measured values of the second inlet-side water pressure sensor 236 and the second outlet-side water pressure sensor 246 is greater than or equal to the set value, it is possible to determine the time when backwashing of the second water purification module 220 is required. will be.

The second water purification line (B) is installed in parallel with the first water purification line (A) and receives water from the main pipe 100 through the front auxiliary pipe 230 to supply water to the second water purification module 220. It means an overall facility that supplies and supplies purified water to the rear auxiliary pipe 240.

The second water purification module 220 serves to purify water supplied from the second water purification line, and for this purpose, one side communicates with the other end of the inlet side 232 of the second water purification line, and the lower end is the second water purification line. It is coupled in communication with one end of the outlet side 242.

The second water purification module 220 includes a second water purification housing 221 having one side in communication with the inlet side 232 of the second water purification line and a lower end in communication with the outlet side 242 of the second water purification line, and an upper end. The sealed and lower end is formed in a cylindrical shape, separated from the side surface of the second water purification housing 221 and coupled to the bottom surface of the second water purification housing 221, and the inner hollow portion is connected to the outlet side 242 of the second water purification line. A second water filter 222 in communication, a first drain line 213 in communication with one side of the second water purification housing 221, and a first drain valve 214 provided inside the first drain line 213 ). In addition, the second water purification module 220 is configured to further include a second actuator 225 for pressing the second water filter 222 downward from the upper end of the second water filter 222.

The second water purification housing 221 is a closed tubular shape with a hollow portion formed therein, the inlet side 232 of the second water purification line is connected to one side, and the outlet side 242 of the second water purification line at the lower center portion This communication is combined. In addition, the drain line is coupled to the other side in communication, and the drain line is preferably coupled near the lower edge of the second water filter 222 to discharge foreign matters that are removed from the second water filter 222 during backwashing. In addition, the inlet side 232 of the second water purification line is also preferably coupled to the upper end of the second water purification housing 221 or near the upper side of the side so that water can evenly flow into the second water filter 222.

It is preferable that the second actuator 225 is coupled to the upper end of the second water purification housing 221 so that only the drive shaft thereof is inserted into the upper end of the second water purification housing 221. This is to prevent water from flowing into the second actuator 225 while allowing the drive shaft to press the upper surface of the second water filter 222 downward when the second actuator 225 is operated. If the actuator 225 can be completely waterproof, it may be provided inside the second water purification housing 221.

The second water filter 222 serves to filter foreign substances of water flowing into the first housing. To this end, the second water filter 222 is formed in a form of overlapping each other so that a plurality of cylindrical mesh nets are concentric, and the upper end is sealed and the lower end is opened so that the lower opening is the outlet side 242 of the second water purification line. It is coupled to the bottom surface of the first housing from the inside of the first housing to communicate with.

The second water filter 222 is formed by overlapping a plurality of cylindrical mesh nets to form a concentric shape, and the outermost mesh net has the largest hole size, and has a denser hole size toward the inside. Therefore, the largest foreign matter is filtered out from the outermost mesh net, and gradually smaller foreign matters are filtered out toward the inside, so that the water reaching the inner hollow portion through all the mesh nets becomes clean. The water from which foreign matters are filtered out is the outlet side of the second water purification line coupled to the second water purification housing 221 to communicate with the inner hollow part of the second water filter 222 along the inner hollow part of the second water filter 222. Go through 242.

When the second water filter 222 is backwashed, that is, when water is supplied through the outlet side 242 of the second water purification line, water is passed from the inside to the outside of the second water filter 222 and When the foreign matter stuck in the filter 222 is removed in the outward direction, the size of the hole in the outer mesh net is larger than the hole in the inner mesh net, so that the foreign material can easily move to the outside of the outermost mesh net. In addition, in the second water filter 222, since the second actuator 225 is stretched and pressurized from the top when backwashing, the shape of the hole in the mesh network is varied as shown in FIG. 3B. Therefore, foreign matters that were strongly caught in the hole of the mesh net are dropped out as the shape of the hole of the mesh net changes.

Optionally, when the second water filter is backwashed in the same way as the first actuator, the second actuator is based on pressure from top to bottom, and additionally provides pressure from the bottom to the top so that the second water filter is Can be moved to.

When the second water filter 222 is backwashed, foreign substances that are removed from the second water filter 222 float inside the second water filter 221. A second drain line 223 is connected to one side of the second water purification housing 221 in order to discharge such foreign substances to the outside.

The second drain line 223 serves to discharge water inside the second water purification housing 221 to the outside, and is connected to one side of the second water purification housing 221 for this purpose. The second water filter 222 is coupled to the bottom surface of the housing 221 and is provided in an outer direction. The second drain line 223 is opened only during backwashing because water should not be discharged to the outside except during backwashing, and the second drain valve 224 is opened so that water can flow to the second drain line 223. Is equipped.

The second drain valve 224 is provided inside the second drain line 223 and is 100% open during backwashing so that the water inside the second water purification housing 221 can be discharged to the outside. It is driven to open 0% or 100% under the control of.

The second actuator 225 serves to pressurize the second water filter 222 from an upper direction to a lower direction by being driven when the second water purification module 220 is backwashed. To this end, the second water filter 222 ) Is provided above.

The second actuator 225 may have a structure that is provided outside the upper end of the second water purification housing 221 and only its drive shaft is inserted into the inside of the second water purification housing 221, but is not limited thereto, and waterproofing may be completely achieved. In the case of a product, it may be provided inside the upper end of the second water purification housing 221.

The state of use of the second actuator 225 is shown in FIG. 3. 3<a> is a state of the second actuator 225 and the second water filter 222 when the second water purification module 220 performs water purification or no operation, and FIG. 3<b> is a backwash. It is a view showing the state of the second actuator 225 and the second water filter 222 in the city. Referring to FIG. 3<b>, the second water filter 222 is pressed downward when the second actuator 225 is driven to change the shape of the hole in the mesh net, and thus, the trapped foreign matter is easily removed. Becomes. That is, compared to the case of water-purifying operation or no operation, the upper and lower intervals of the second water-purifying filter 222 during backwashing are reduced, and the width of the side surfaces thereof is increased. In addition, when backwashing is completed, the drive shaft of the second water purifying actuator 225 returns to the initial position, and the second water filter 222 is also returned to the shape as shown in FIG. 3<a>.

In the present invention, since the backwash is performed with purified water, the first water purification module and the second water purification module cannot be backwashed at the same time, and only one water purification module should be performed for the backwash. Accordingly, when the first actuator 215 and the second actuator 225 are backwashed, one is elongated and the other is contracted to become different from each other.

The control unit includes a main valve 110, a first inlet valve 233, a first outlet valve 243, a first drain valve 214, a second inlet valve 234, a second outlet valve 244, and 2 It serves to control the driving of the drain valve 224, the first actuator 215, the second actuator 225, etc., and for this purpose, the front water quality for determining the driving amount of the above-described components including the above-described components Sensor 101, rear water quality sensor 102, first inlet side water pressure sensor 235, first outlet side water pressure sensor 245, second inlet side water pressure sensor 236, second outlet side water pressure sensor 246 ) And is electrically connected.

First, the control unit adjusts the opening amount of the main valve 110 so that water is supplied to the first water purification module 210 or the second water purification module 220 in order to maintain the water quality of water to be supplied to the customer within the standard value.

To this end, the control unit determines the opening amount of the main valve 110 using the measured values of the front water quality sensor 101 and the rear water quality sensor 102. For example, the control unit sets the main valve 110 to a 0% opening amount when the turbidity measurement value is suddenly changed to 0.5NTU (Nepthelometric Trubidity Unit) or more as a result of the measurement by the front water quality sensor 101. In this case, all water in the main pipe 100 passes through the front auxiliary pipe 230 through the first water purification module 210 or the second water purification module 220 to the main pipe 100 through the rear auxiliary pipe 240. Join. And the turbidity of the water joined to the main pipe 100 is measured from the rear water quality sensor 102 and compared with the measured value of the front water quality sensor 101. Thereafter, the control unit gradually increases the opening amount of the main valve 110 and stops the opening of the main valve 110 at a point where the measured value of the rear water quality sensor 102 does not exceed 0.5 NTU. The opening amount of the main valve 110 is gradually accumulated as the device of the present invention is driven, so that the measured value of the front water quality sensor 101, the measured value of the rear water quality sensor 102, and the front water quality sensor 101 It is possible to appropriately converge by parameters such as the difference between the measured value of and the measured value of the rear water quality sensor 102. For example, when the measured value of the front water quality sensor 101 is 0.7 NTU when the device is initially driven, the main valve 110 is completely closed to 0%, and then the rear water quality sensor 102 is gradually increased. If the measured value was 50% of the maximum opening amount that does not exceed 0.5 NTU, the opening amount of the main valve 110 is increased by 50% or 50 when the measured value of the front water quality sensor 101 increases to 0.7 NTU after the seal has passed. By conservatively operating the set ratio in% and directly changing it to about 40% to 45%, it is possible to reduce the load of the first water purification module 210 or the second water purification module 220. In addition, such data is preferably determined in conjunction with the water purification efficiency of the first water purification module 210 or the second water purification module 220 decreases over time, and the data used for this is the first flow The side water pressure sensor 235, the first outlet side water pressure sensor 245, the second inlet side water pressure sensor 236, the second outlet side water pressure sensor 246, and the like may be targets.

Accordingly, since the opening amount of the main valve 110 is actively varied under the control of the controller, it is possible to prevent accidents in which foreign substances generated in the front end of the apparatus of the present invention are supplied to the customer.

In addition, the control unit determines whether to use the first water purification module 210 or the second water purification module 220 at the same time or which water purification module, and when backwashing is required during use of one water purification module, another water purification module At the same time, it is controlled so that backwashing of the water purification module requiring backwashing can be performed.

To explain this in more detail, first, when the pollution degree of the main pipe is not very severe, the control unit selects a water purification module and performs a water purification operation. 4 illustrates a configuration in which the first water purification module 210 performs water purification. It is understood that during the water purification operation of the second water purification module 220, a water flow is formed along the inlet side 232 of the second water purification line through the second water purification module 220 to the outlet side 242 of the second water purification line. It is desirable to do.

Referring to FIG. 4, the control unit first adjusts the opening amount of the main valve 110 by 100% so that water flowing in the main pipe 100 can be moved to the front auxiliary pipe 230. And, since the first water purification module 210 is used, the controller sets the opening amount of the first inlet valve 233 and the first outlet valve 243 to 100%, and the second inlet valve 234 and the second The outlet valve 244 and the opening amount of the first drain valve 214 and the second drain valve 224 are controlled to be 0%. In the case of the non-return valve 247, since it is a one-way check valve, separate control is not performed. Accordingly, water flowing into the front auxiliary pipe 230 passes through the inlet side 231 of the first water purification line and flows into the first water purification housing 211, and passes through the first water filter 212 to the first water purification line. It passes through the outlet side 241 of and joins the main pipe 100 through the rear auxiliary pipe 240. If the second water purification module 220 is used, the opening amount of the second inlet valve 234 and the second outlet valve 244 is set to 100%, and the first inlet valve 233 and the first outlet valve ( 243), the opening amounts of the first drain valve 214 and the second drain valve 224 are controlled to 0%.

When foreign substances gradually accumulate in the first water filter 212 during the water purification operation of the first water purification module 210, the measured value of the first inlet water pressure sensor 235 increases, and the first outlet water pressure sensor ( The measured value of 245 is lowered so that the difference between the measured value of the first inlet-side water pressure sensor 235 and the measured value of the first outlet-side water pressure sensor 245 increases. When the measured value of the first inlet water pressure sensor 235 and the measured value of the first outlet water pressure sensor 245 are greater than or equal to the set value, the control unit requires the backwash operation of the first water purification module 210 Is judged as.

A configuration for performing the backwash operation of the first water purification module 210 is shown in FIG. 5. Referring to FIG. 5, water purified from the second water purification module 220 is supplied to the first water purification module 210 in the reverse direction so that the first water filter 212 is backwashed, and the main pipe 100 is The reason for backwashing the first water purification module 210 as water purified from the second water purification module 220 without backwashing the first water purification module 210 as flowing water is water flowing on the main pipe 100 Foreign matter is still present (contaminated water) in the first water filter 212, which may be rather contaminated by backwashing, and also, the innermost mesh network of the first water filter 212 through which water passes first during backwashing. This is because the silver hole has the smallest size, and there is a risk of clogging by foreign matter.

Therefore, when backwashing, purified water must be provided, and for this purpose, the control unit opens the second inlet valve 234 and the second outlet valve 244 by 100% so that the second water purification module 220 operates. And the opening amount of the first inlet valve 233 is set to 0%, and the opening amount of the first outlet valve 243 is set to 100%. Accordingly, the water purified by the second water purification module 220 is supplied from the outlet side 242 of the second water purification line to the inside of the first water filter 212 through the outlet side 241 of the first water purification line, The water supplied to the inside of the first water filter 212 passes through the first water filter 212 in reverse and is discharged to the first water filter housing 211. In this process, the control unit drives the first actuator 215 so that the first water filter 212 changes the shape of the hole as shown in FIG. 3B.

Meanwhile, when the first water purification module 210 is backwashed, foreign matters dropped from the first water filter 212 are mixed with water and floated inside the first water purification housing 211. In order to discharge this to the outside, the controller 100% of the first drain valve 214 is opened so that water and foreign substances in the first water purification housing 211 can be discharged to the outside. Optionally, during such a backwash operation, the controller may repeatedly drive the first actuator 215 so that the first water filter 212 repeats shape transformation and restoration, thereby increasing the dropout rate of foreign substances. In addition, when backwashing is performed at the set time, the control unit sets the opening amount of the first outlet valve and the first drain valve 214 to 0%, so that the first water purification module 210 does not perform a water purification operation and a backwash operation. To enter the standby state.

This backwashing operation is similarly applied to the case of backwashing the second water purification module 220. When backwashing the second water purification module 220, the control unit includes the first inlet valve 233 and the first outlet valve 243. ) Is opened to 100% so that the first water purification module 210 can perform the water purification operation, the opening amount of the second inlet valve 234 is 0%, and the opening amount of the second outlet valve 244 is 100%. %, the water purified by the first water purification module 210 is transferred from the outlet side 241 of the first water purification line to the inside of the second water filter 222 through the outlet side 242 of the second water purification line. Be supplied. In this case, the opening amount of the second drain valve 224 is similarly set to 100% so that foreign substances generated during backwashing of the second water filter 222 can be discharged to the outside.

As described above, in the present invention, during water purification, the first water purification module 210 and the second water purification module 220 operate separately or at the same time to purify water and do not affect other water purification modules installed in parallel. However, during backwashing, the water purification module to be backwashed and the water purification module to be purified affect each other, so that the purified water that has passed through the water purification module operating as purified water moves to the water purification module that is backwashed.

In addition, the pressure of the water is controlled only by the opening and closing operation of the valve during water purification and backwash, so that a separate pump for backwash is not required. That is, the first water purification module 210 is backwashed and the second water purification module 220 purifies, and the purified water that has passed through the second water purification module 220 moves to the first water purification module 210 and is When looking at the opening and closing of each valve in the case of backwashing the water purification module 210, the second inlet valve 234 and the second outlet valve 244 are opened, the first inlet valve 233 is closed, and the first When the outlet valve 243 is opened, the purified water passing through the second water purification module moves to the rear auxiliary pipe 240 and the first outlet valve 243 having a low pressure without the help of a separate pump. In addition, when the first drain valve 214 is opened, the water obtained by backwashing the first water filter is discharged to the first drain valve.

Next, the second water purification module 220 is backwashed and the first water purification module 210 purifies, and the purified water that has passed through the first water purification module 210 moves to the second water purification module 220 and When looking at the opening and closing of each valve in the case of backwashing the water purification module 220, the first inlet valve 233 and the first outlet valve 243 are opened, the second inlet valve 234 is closed, and the second When the outlet valve 243 is opened, the purified water that has passed through the first water purification module moves to the rear auxiliary pipe 240 and the second outlet valve 244 having a low pressure without the help of a separate pump. In addition, when the second drain valve 224 is opened, water obtained by backwashing the second water filter is discharged to the second drain valve.

In other words, in order for the water purification module to purify water, the inlet valve and the outlet valve of the water purification module must be opened, and in order to backwash the water purification module, the inlet valve must be closed and the outflow valve must be open. Conversely, the state of the outlet valve is the same.

On the other hand, during the water purification operation of the first water purification module 210 or the second water purification module 220, a situation where backwashing is not immediately required, but foreign matters are present in the first water filter 212 or the second water filter 222. There may be cases where the water purification efficiency decreases due to accumulation.

In this situation, if the opening amount of the main valve 110 is controlled only by the measured values of the front water quality sensor 101 and the rear water quality sensor 102, the water purification efficiency gradually decreases, and the purified water joins the main pipe 100. The amount of water is gradually reduced and the measured value of the rear water quality sensor 102 increases. In this situation, the opening amount of the main valve 110 is determined only with the measured value of the front water quality sensor 101 and the measured value of the rear water quality sensor 102, and the first inlet side water pressure sensor 235 and the first outflow Backwashing timing of the first water purification module 210 or the second water purification module 220 only with the measured values of the side water pressure sensor 245 or the second inlet water pressure sensor 236 and the second outlet water pressure sensor 246 In judging, as the amount to which the purified water merges decreases, the opening amount of the main valve 110 has to be set less than necessary. Therefore, it is applied to the first water purification module 210 or the second water purification module 220. The losing load will increase that much.

Therefore, the control unit, when compared to the difference between the measured value of the front water quality sensor 101 and the measured value of the rear water quality sensor 102, the opening degree of the main valve 110 is smaller than the set amount, that is, the front water quality sensor 101 If the opening amount of the main valve 110 is too small compared to the measured value of, it is determined that the amount of purified water joined through the rear auxiliary pipe 240 is reduced, and the backwashing time of the water purification module is advanced. In other words, the opening amount of the main valve 110 is determined on a line where the turbidity measured value of the rear water quality sensor 102 does not exceed 0.5 NTU, and the purified water joining through the rear auxiliary pipe 240 is reduced. Then, the ratio of water passing through the main valve 110 and entering the rear water quality sensor 102 along the main pipe 100 increases, and the measured value of the rear water quality sensor 102 increases. Then, the control unit should further reduce the opening amount of the main valve 110 so that more water passes through the first water purification module 210 or the second water purification module 220, which means that more water than necessary is added to the first water purification module. (210) or a result of passing through the second water purification module 220, the front auxiliary pipe 230, the inlet side 231 of the first water purification line, the inlet side 232 of the second water purification line, the first The pressure of the water purification housing 211 and the second water purification housing 221 may be increased, thereby reducing durability.

Accordingly, the control unit measures the rear water quality sensor 102 compared to the predicted opening amount of the main valve 110 derived as a result of comparing the measured value of the front water quality sensor 101 and the measured value of the rear water quality sensor 102 When the actual opening amount of the main valve 110, which is changed so that the value is less than the set value, is less than the set value, it is determined that the first water purification module 210 or the second water purification module 220 needs backwashing, and the first The water purification module 210 or the second water purification module 220 may be backwashed. This is a first integer calculated based on the measured values of the first inlet side water pressure sensor 235, the first outlet side water pressure sensor 245 or the second inlet side water pressure sensor 236, and the second outlet side water pressure sensor 246. This is a time earlier than the backwash time of the module 210 or the second water purification module 220. Further, in this case, as the time of backwashing is advanced, the flow of water supplied to the customer through the main valve 110 of the main pipe 100 becomes smooth, thereby preventing a water shortage phenomenon in the customer.

In the present invention having the above-described configuration, continuous water purification is achieved by selectively using two water purification modules, and by determining the opening amount of the main valve 110 in the main pipe 100 through a water quality sensor, the flow of water is controlled. It has the effect of allowing water within the standard level of turbidity to be supplied to customers without much interference.

In addition, the present invention provides backwashing by supplying purified water to a water purification module requiring backwashing while performing a backwashing while one water purification module purifies the other water purification module at a time when backwashing is required. Even if water flows in the water supply line, the filter is contaminated by backwashing, so that backwashing can be performed with clean water during backwashing of the water filter.

In addition, in the present invention, while one water purification module purifies the other cleansing module at a time when backwashing is required, while supplying purified water to the water purification module requiring backwashing, a part of the purified water is returned to the main pipe. By consolidating into the main pipe, purified water can be continuously supplied to the main pipe, thereby minimizing the number of steps to the customer even in the backwashing process.

In addition, the present invention is provided with an actuator to pressurize the water filter from above during backwashing to change the shape of the hole in the mesh net of the water filter, so that the water filter is in a state in which foreign matter is easily removed during backwashing. have.

In addition, the present invention does not require a separate pump facility for backwashing of the water purification module, and thus, there is an advantage that a small scale can be installed.

100: main pipe 101: front water quality sensor
102: rear water quality sensor 110: main valve
200: water purification device
210: first water purification module 211: first water purification housing
212: first water filter 213: first drain line
214: first drain valve 215: first actuator
220: second water purification module 221: second water purification housing
222: second water filter 223: second drain line
224: second drain valve 225: second actuator
230: front auxiliary pipe 231: inlet side of the first water purification line
232: inlet side of the second water purification line 233: first inlet valve
234: second inlet valve 235: first inlet side water pressure sensor
236: second inlet side water pressure sensor
240: rear auxiliary pipe 241: outflow side of the first water purification line
242: outlet side of the second water purification line 243: first outlet valve
244: second outlet valve 245: first outlet side water pressure sensor
246: second outlet side water pressure sensor 247: non-return valve

Claims (6)

The main pipe supplying water;
A front auxiliary pipe and a rear auxiliary pipe provided in communication with the main pipe;
A main valve disposed between a coupling portion of the front auxiliary pipe and a coupling portion of the rear auxiliary pipe inside the main pipe;
A first water purification line having one end in communication with the front auxiliary pipe and the other end in communication with one end of the rear auxiliary pipe;
A second water purification line provided in parallel to the first water purification line, one end connected in communication with the front auxiliary pipe, and the other end connected in communication with one end of the rear auxiliary pipe;
First and second water purification modules provided on the first and second water purification lines to purify water flowing on the first and second water purification lines;
A water quality sensor measuring the water quality inside the main pipe;
A control unit receiving the measured value of the water quality sensor and controlling an opening amount of the main valve;

The first and second water purification modules,
First and second water purification housings having one side communicating with the inlet side of the first and second water purification lines and the lower end communicating with the outlet side;
The upper end is sealed and the lower end is opened to be spaced apart from the side surfaces of the first and second water purification housings and coupled to the bottom surfaces of the first and second water purification housings, and the inner hollow part communicates with the outlet side of the first and second water purification lines. First and second water filters;
First and second drain lines communicating with one side of the first water purification housing;
Including; first and second drain valves provided inside the first drain line,

The first and second water purification lines are provided with first and second inlet valves on the inlet side, and first and second outlet valves on the outlet side; During the backwash operation, the opening and closing states of the inlet valves of the first and second water purification lines are opposite to each other, and the opening and closing states of the outlet valves are the same;
The first and second water filters included in the first and second water purification modules have a smaller vertical height and a wider side surface during reciprocal water than during water purification;
The first water purification housing and the second water purification housing each include a first actuator and a second actuator that pressurizes a first water filter and a second water filter provided therein, and the controller Integrated water quality management system that operates the 1 actuator and the second actuator differently.
The method of claim 1,
Water passing through the first water purification module or the second water purification module is transferred to the main pipe through the rear auxiliary pipe at the time of purification, and during backwashing, the purified water passes through the water purification module for backwashing. Water purification device.
delete delete delete The method of claim 1,
Water quality water purification device using water quality monitoring in which the extension length of the actuator built in the backwashing water purification module is longer than the extension length of the actuator built in the water purification module.

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