KR102658845B1 - Smart water quality measurement and microfiltration system - Google Patents

Abstract

The present invention provides a precision filter (15) for filtering tap water, a flow path (20) connected to the precision filter (15) and through which tap water is introduced or discharged, and provided on the flow path (20) to improve the quality of tap water. It includes a water quality measurement unit 30 that measures water quality in real time, and the flow path 20 is connected to an inflow line 21 through which tap water flows, the inflow line 21 and a precision filter 15, respectively, and the inflow line The tap water passing through (21) is connected to the supply line 22, which moves to the precision filter 15, the precision filter 15, and the inlet line 21, respectively, so that the tap water passing through the precision filter 15 is It includes a moving line 23 that moves to the inflow line 21 and a first drain line 24 that is connected to the precision filter 15 and drains the tap water that has passed through the precision filter 15 to the outside. , the water quality measuring unit 30 is provided on one side of the inflow line 21, and the first measuring unit 31 and the inflow line ( It is provided on the other side of 21) and includes a second measuring unit 32 that measures the quality of tap water discharged from the precision filter 15 in real time.

Description

Smart water quality measurement and microfiltration system}

The present invention relates to a smart water quality measurement and precision filtration system. More specifically, when the tap water measured by the water quality measurement unit exceeds the standard value, the path of the electromagnetic valve is changed to supply filtered tap water through a precision filter. It is about a smart water quality measurement and precision filtration system.

According to recent water supply statistics, Korea's water supply rate is 97%, and the majority of people are enjoying the benefits of tap water. However, an advanced country in water supply management is not defined solely by the water supply penetration rate. Qualitative growth along with quantitative growth must be achieved to be recognized as an advanced country in water management where tap water is trusted. However, our country still has deep distrust of tap water. The distrust of tap water is revealed by the drinking rate figures. According to a recent survey, the drinking rate of tap water was 43.5%, and only 7.2% responded that they drink it themselves.

Korea possesses many excellent technologies in the construction of water supply infrastructure. In particular, the development of innovative products such as digital sensors, networks, and AI along with the world's best communication network is continuously being developed, so there is high growth potential in the field of water supply management. Therefore, in the future, water supply management policy will change from a water leakage reduction policy focusing on replacing old pipes to a policy that simultaneously manages water quantity and quality through water supply network management using information and communication technology.

In general, when the pipe network of a water supply network deteriorates, it not only becomes a major cause of water leakage, but also causes various contaminants to flow in due to pipe rupture. In addition, rust occurs due to corrosion within the pipe, which can become a breeding ground for various microorganisms and bacteria. In particular, if you continuously drink tap water containing zinc and iron, it can cause serious problems to the human body.

Due to the above problems, the existing tap water supply system has a problem in that it is difficult to supply clean and safe tap water to the consumer.

However, the existing tap water supply system has a problem in that it is difficult to ensure the safety of tap water when supplying tap water, making it difficult to supply quality tap water to consumers.

KR 10-2023-0087246 A

The present invention was created to solve the above problems, and the purpose of the present invention is to change the path of the electromagnetic valve when the tap water measured by the water quality measurement unit exceeds the standard value, and to filter the water through a precision filter. The goal is to provide a smart water quality measurement and precision filtration system that can supply tap water.

In addition, the purpose of the present invention is to provide smart water quality measurement and precision filtration that enables efficient management and operation by replacing the filter of the precision filter according to the measured value of tap water, thereby reducing filter replacement costs by extending the filter replacement cycle. The goal is to provide a system.

In addition, the purpose of the present invention is to solve the problem of uncertainty in the supply of clean and safe tap water to the consumer due to the aging of the pipe network and the inflow and generation of contaminants in the pipe, and to provide a smart technology that can supply reliable, high-quality tap water to consumers. The goal is to provide water quality measurement and precision filtration systems.

In order to solve the above technical problems, the smart water quality measurement and precision filtration system according to the present invention is connected to a precision filter 15 that filters tap water and the precision filter 15, so that tap water flows in or out. It includes a flow path 20 and a water quality measuring unit 30 provided on the flow path 20 to measure the quality of tap water in real time, and the flow path 20 includes an inflow line 21 through which tap water flows, A supply line 22 connected to the inflow line 21 and the precision filter 15, respectively, through which tap water passing through the inflow line 21 moves to the precision filter 15, the precision filter 15, and They are each connected to the inflow line 21, and are connected to the movement line 23 and the precision filter 15 through which tap water passing through the precision filter 15 moves to the inflow line 21, and the precision filter 15 ) includes a first drain line 24 through which tap water that has passed through is drained to the outside, and the water quality measuring unit 30 is provided on one side of the inlet line 21 to measure the water flowing into the inlet line 21. A first measuring unit 31 that measures the quality of tap water in real time and a second measuring unit provided on the other side of the inlet line 21 to measure the quality of tap water discharged from the precision filter 15 in real time ( 32).

In addition, the precision filter 15 includes a filter 62 on the inside that filters foreign substances contained in tap water, and is provided at the center of the inlet line 21 and has a first valve V1 that can be opened and closed. ), a second valve (V2) provided at the center of the supply line 22 and configured to be opened and closed, a third valve (V3) provided at the center of the moving line 23 and configured to be opened and closed, A fourth valve (V4) provided at the center of the first drain line 24 and configured to be open and closed, a controller that controls the opening and closing of a plurality of valves according to the measurement value measured by the water quality measurement unit 30 ( 45) and a display unit 55 that displays the measured values measured by the water quality measuring unit 30 and whether or not there are abnormalities in the measured values, respectively.

In addition, the controller 45 includes an alarm unit 46 that displays an alarm sound according to the measurement value measured by the water quality measurement unit 30, and a plurality of valves according to the measurement value measured by the water quality measurement unit 30. A valve control unit 47 that controls, an alarm control unit 48 that controls the alarm unit 46 according to the measurement value measured by the water quality measurement unit 30, and a measurement value measured by the water quality measurement unit 30. A screen control unit 49 that controls the display unit 55, a storage unit 50 that stores the measurements measured by the water quality measurement unit 30, the water quality measurement unit 30, and a display unit 55. ) and a communication unit 51 for transmitting and receiving data between the controller 45, and the valve control unit 47 is configured to detect tap water when the measurement value measured by the first measurement unit 31 falls within a preset normal range. The first valve (V1) is opened to allow passage through the inflow line (21), and the second valve (V2), third valve (V3), and fourth valve (V4) are controlled to be closed, respectively, When the measurement value measured by the first measurement unit 31 falls within the normal section, the display unit 55 displays the message by voice or text message that the measurement value of the first measurement unit 31 is normal. and the valve control unit 47 controls the tap water to flow from the inflow line 21 to the precision filter 15 when the measurement value measured by the first measurement unit 31 does not fall within the normal section. The first valve (V1) and the second valve (V2) are controlled to be open and closed, respectively, to allow inflow, and the alarm control unit 48 determines that the measurement value measured by the first measurement unit 31 is in the normal section. If it does not belong to, the alarm unit 46 is controlled to emit the first alarm sound, and the screen control unit 49 controls the display unit 55 when the alarm unit 46 emits the first alarm sound. It is characterized by controlling the display by voice or text to indicate that the precision filter is in operation.

In addition, the valve control unit 47 controls the third valve V3 to allow tap water to flow into the moving line 23 when the measurement value measured by the second measuring unit 32 falls within the normal section. is opened, the first valve (V1), the second valve (V2), and the fourth valve (V4) are controlled to be closed, respectively, and the screen control unit 49 controls the measurement value measured by the second measurement unit 32. If it falls within the normal section, the display unit 55 is controlled to display in voice or text that the measurement value of the second measurement unit 32 is normal, and the valve control unit 47 controls the second measurement unit ( If the measured value in 32) does not fall within the preset normal range, the fourth valve (V4) and the third valve (V3) are controlled to open and close, respectively, so that tap water can be drained to the outside, and the alarm If the measurement value measured by the second measurement unit 32 does not fall within the normal section, the control unit 48 controls the alarm unit 46 to emit a second alarm sound, and the size of the second alarm sound. is set to 1.8 times or more and 2.3 times or less the size of the first alarm sound, and the screen control unit 49 determines that when the alarm unit 46 displays the second alarm sound, the display unit 55 uses a precision filter ( 15) It is characterized by controlling the message that the filter needs to be replaced by voice or text.

The smart water quality measurement and precision filtration system according to the present invention has the effect of supplying filtered tap water through a precision filter by changing the path of the electromagnetic valve when the tap water measured by the water quality measurement unit exceeds the standard value. .

In addition, the smart water quality measurement and precision filtration system according to the present invention can replace the filter of the precision filter according to the measured value of tap water, thereby reducing filter replacement costs by extending the filter replacement cycle, enabling efficient management and operation. There is a possible effect.

In addition, the smart water quality measurement and precision filtration system according to the present invention can solve the problem of uncertainty in the supply of clean and safe tap water to the consumer due to the aging of the pipe network and the inflow and generation of contaminants in the pipe, and provide reliable, high-quality water to consumers. It has the effect of supplying tap water.

Figure 1 is a configuration diagram of a smart water quality measurement and precision filtration system according to the present invention.
Figure 2 is a block diagram of a smart water quality measurement and micro-filtration system.
Figure 3 is a data flow diagram of a smart water quality measurement and microfiltration system.
Figure 4 is a data flow diagram of the controller.
Figure 5 is a data flow diagram according to measurement values measured by the first measurement unit.
Figure 6 is a data flow diagram according to measurement values measured by the second measurement unit.
Figure 7 is a configuration diagram of a smart water quality measurement and precision filtration system including this water tank.
Figure 8 is a data flow diagram according to measurement values measured by the third measurement unit.
Figure 9 is a front cross-sectional view of a precision filter.
Figure 10 is a front cross-sectional view of the precision filter when the filter is raised and lowered.
Figure 11 is a top view of a precision filter.

Hereinafter, in order to explain the present invention in detail so that a person skilled in the art can easily implement the technical idea of the present invention, embodiments of the present invention will be described with reference to the accompanying drawings.

However, the following example is only an example to aid understanding of the present invention, and the scope of the present invention is not reduced or limited thereby. Additionally, the present invention may be implemented in many different forms and is not limited to the embodiments described herein.

Figure 1 is a configuration diagram of a smart water quality measurement and precision filtration system according to the present invention.

Referring to FIG. 1, the smart water quality measurement and precision filtration system 5 according to the present invention includes a precision filter 15, a flow path 20, and a water quality measurement unit 30.

At this time, the smart water quality measurement and precision filtration system (5) according to the present invention is used in addition to the water tank (10) of the apartment, BEMS (Building Energy Management System), smart city, distributed water supply facilities, water pipe network, It can also be applied to mini water purification plants and small-scale water supply facilities.

First, the precision filter 15 filters tap water.

In addition, the flow paths 20 are respectively connected to the precision filters 15 and become passages through which tap water is introduced or discharged.

Additionally, the water quality measuring unit 30 is provided on the flow path 20 to measure the quality of tap water in real time.

At this time, the measured values of tap water measured by the water quality measurement unit 30 include residual chlorine, turbidity, temperature, electrical conductivity, pH, dissolved oxygen, ORP (Oxidation-reduction Potential), salinity, and TDS (Total Dissolved Solid). , total dissolved solids), MLSS (Mixed Liquer Suspended Solids), SS (Suspended Solids), heavy metals, nutrients, and water quality measurement items.

Meanwhile, the flow path 20 includes an inlet line 21, a supply line 22, a moving line 23, and a first drain line 24.

First, the inflow line 21 becomes a passage through which tap water flows.

In addition, the supply line 22 is connected to the inflow line 21 and the precision filter 15, respectively, and becomes a passage through which tap water passing through the inlet line 21 moves to the precision filter 15.

In addition, the moving line 23 is connected to the precision filter 15 and the inflow line 21, respectively, and becomes a passage through which tap water passing through the precision filter 15 moves to the inflow line 21.

In addition, the first drain line 24 is connected to the precision filter 15 and becomes a passage through which tap water passing through the precision filter 15 is drained to the outside.

Meanwhile, the water quality measurement unit 30 includes a first measurement unit 31 and a second measurement unit 32.

First, the first measuring unit 31 is provided on one side of the inlet line 21 and measures the quality of tap water flowing into the inlet line 21 in real time.

In addition, the second measuring unit 32 is provided on the other side of the inflow line 21 and measures the quality of tap water discharged from the precision filter 15 in real time.

Meanwhile, the precision filter 15 may be configured to include a filter 62 inside that filters foreign substances contained in tap water.

FIG. 2 is a block diagram of the smart water quality measurement and micro-filtration system 5, and FIG. 3 is a data flow diagram of the smart water quality measurement and micro-filtration system 5.

Referring to Figures 2 and 3, the smart water quality measurement and precision filtration system 5 according to the present invention includes a first valve (V1), a second valve (V2), a third valve (V3), and a fourth valve (V4). ), a controller 45, and a display unit 55.

First, the first valve V1 is provided at the center of the inflow line 21 and is configured to be open and closed.

Additionally, the second valve V2 is provided at the center of the supply line 22 and is configured to be open and closed.

Additionally, the third valve V3 is provided at the center of the moving line 23 and is configured to be open and closed.

Additionally, the fourth valve V4 is provided at the center of the first drain line 24 and is configured to be open and closed. At this time, multiple valves may be implemented in the form of electronic solenoid valves.

In addition, the controller 45 controls the opening and closing of a plurality of valves according to the measurement value measured by the water quality measurement unit 30.

Additionally, the display unit 55 displays the measured values measured by the water quality measuring unit 30 and whether or not there are any abnormalities in the measured values, respectively. At this time, the display unit 55 may be provided in the form of an electronic signboard, kiosk, or wall pad inside an apartment.

Figure 4 is a data flow diagram of the controller 45.

Referring to FIG. 4, the controller 45 further includes an alarm unit 46, a valve control unit 47, an alarm control unit 48, a screen control unit 49, a storage unit 50, and a communication unit 51. It can be configured.

First, the alarm unit 46 emits an alarm sound according to the measurement value measured by the water quality measurement unit 30.

And, the valve control unit 47 controls a plurality of valves according to the measurement value measured by the water quality measurement unit 30.

And, the alarm control unit 48 controls the alarm unit 46 according to the measurement value measured by the water quality measurement unit 30.

And, the screen control unit 49 controls the display unit 55 according to the measurement value measured by the water quality measurement unit 30.

And, the measurement value measured by the water quality measurement unit 30 is stored in the storage unit 50.

And, the communication unit 51 transmits and receives data between the water quality measurement unit 30, the display unit 55, and the controller 45.

At this time, the communication unit 51 may be implemented in the form of wired or wireless communication.

FIG. 5 is a data flow diagram according to measurement values measured by the first measurement unit 31.

Referring to FIG. 5, the valve control unit 47 controls the first measuring unit 31 to allow tap water to pass through the inflow line 21 when the measurement value measured by the first measuring unit 31 falls within a preset normal range. 1 valve (V1) is opened, and the second valve (V2), third valve (V3), and fourth valve (V4) are controlled to be closed, respectively.

In addition, when the measurement value measured by the first measurement unit 31 falls within the normal section, the display unit 55 outputs a voice message indicating that the measurement value of the first measurement unit 31 is normal. Or control it to display as text.

Meanwhile, if the measurement value measured by the first measurement unit 31 does not fall within the normal section, the valve control unit 47 allows tap water to flow into the precision filter 15 from the inlet line 21. The first valve (V1) and the second valve (V2) are controlled to open and close, respectively.

Additionally, the alarm control unit 48 controls the alarm unit 46 to emit a first alarm sound when the measurement value measured by the first measurement unit 31 does not fall within the normal section.

Additionally, the screen control unit 49 controls the display unit 55 to display by voice or text that the precision filter is in operation when the alarm unit 46 emits the first alarm sound.

FIG. 6 is a data flow diagram according to measurement values measured by the second measurement unit 32.

Referring to FIG. 6, the valve control unit 47 controls the third valve to allow tap water to flow into the moving line 23 when the measurement value measured by the second measuring unit 32 falls within the normal section. (V3) is opened, and the first valve (V1), the second valve (V2), and the fourth valve (V4) are controlled to be closed, respectively.

In addition, when the measurement value measured by the second measurement unit 32 falls within the normal section, the display unit 55 outputs a voice message indicating that the measurement value of the second measurement unit 32 is normal. Or control it to display as text.

Meanwhile, the valve control unit 47 controls the fourth valve V4 and the third valve so that tap water can be drained to the outside if the measurement value measured by the second measurement unit 32 does not fall within the preset normal range. The valve V3 is controlled to open and close, respectively.

Additionally, the alarm control unit 48 controls the alarm unit 46 to emit a second alarm sound when the measurement value measured by the second measurement unit 32 does not fall within the normal range. At this time, the size of the second alarm sound is set to be 1.8 to 2.3 times the size of the first alarm sound.

In addition, the screen control unit 49 is configured so that when the alarm unit 46 displays the second alarm sound, the display unit 55 displays the content that the precision filter 15 and filter 62 need to be replaced by voice or text. Control. Through this, the manager can immediately proceed with the replacement work of replacing the filter 62 of the precision filter 15.

Figure 7 is a configuration diagram of a smart water quality measurement and precision filtration system including the water tank 10.

Referring to FIG. 7, the smart water quality measurement and precision filtration system 5 according to the present invention further includes a water tank 10.

First, the water tank 10 has an inlet 11 formed on one side, an outlet 12 formed at the top of the other side, and a drain 13 formed at the bottom of the other side. At this time, the inlet portion 11, the discharge portion 12, and the drain portion 13 may each be formed in the left and right directions in the shape of a circular pipe.

Meanwhile, the flow path 20 further includes a discharge line 25 and a second drain line 26.

And, the discharge line 25 is connected to the discharge part 12 and becomes a passage through which tap water is discharged from the water tank 10.

And, the second drain line 26 is connected to the drain part 13 and becomes a passage through which tap water contained in the water tank 10 is drained to the outside.

Meanwhile, the water quality measuring unit 30 further includes a third measuring unit 33.

First, the third measuring unit 33 is provided on one side of the discharge line 25 and measures the quality of tap water discharged from the water tank 10 in real time.

Referring to FIG. 7, the smart water quality measurement and precision filtration system 5 according to the present invention further includes a fifth valve V5.

First, the fifth valve V5 is provided in the center of the second drain line 26 and is configured to be open and closed.

FIG. 8 is a data flow diagram according to measurement values measured by the third measurement unit 33.

Referring to FIG. 8, when the measurement value measured by the third measurement unit 33 does not fall within the normal section, the valve control unit 47 opens the fifth valve V5 and opens the first valve V1. and the third valve V3 are controlled to close, respectively. Through this, tap water is blocked from flowing into the water tank 10, and tap water contained in the water tank 10 can be drained to the outside.

Additionally, the alarm control unit 48 controls the alarm unit 46 to emit a third alarm sound when the measurement value measured by the third measurement unit 33 does not fall within the normal section. At this time, the size of the third alarm sound is set to be 1.8 times or more and 2.3 times or less the size of the first alarm sound.

In addition, the screen control unit 49 controls the display unit 55 to display the sentence that the water tank 10 needs to be cleaned by voice or text when the alarm unit 46 displays the third alarm sound. Through this, the manager can immediately proceed with cleaning the water tank 10.

FIG. 9 is a front cross-sectional view of the precision filter 15, FIG. 10 is a front cross-sectional view of the precision filter 15 when the filter 62 is raised, and FIG. 11 is a top view of the precision filter 15.

Referring to Figures 9 to 11, the precision filter 15 includes a body part 60, a rail part 61, a filter 62, a lifting part 63, a support part 64, a bending part 65, and a washing part. (66) and a vibration unit (67).

First, the body portion 60 forms the exterior of the precision filter 15. At this time, the body portion 60 is formed in the shape of a rectangular parallelepiped with an empty interior.

In addition, a plurality of rail parts 61 are provided to be spaced apart from each other on the inside of the body part 60. At this time, the rail portion 61 is formed in the vertical direction. Additionally, a plurality of rail portions 61 are provided to be spaced apart in the left and right directions.

Additionally, a plurality of filters 62 are provided inside the body portion 60 and move in the vertical direction along the rail portion 61. At this time, the number of filters 62 may be 5 or more and 7 or less.

And, the raising and lowering unit 63 is provided at the lower part of the filter 62 and moves the filter 62 in the vertical direction.

At this time, the elevating and lowering unit 63 may be implemented in the form of a pneumatic or hydraulic cylinder that expands or contracts.

Additionally, the support portion 64 is provided on the upper portion of the body portion 60 and is formed to be movable in the left and right directions.

In addition, the bent portion 65 is provided at the lower part of the support portion 64, is formed to be curved, and moves in the left and right directions by the support portion 64. At this time, the bent portion 65 is formed to be convex toward the left.

Additionally, the cleaning unit 66 moves along the curved portion 65 when the filter 62 is raised and lowered, and washes the filter 62 with water. When the cleaning unit 66 moves along the bending portion 65, the cleaning unit 66 can more effectively clean the edge of the filter 62 by changing the spray direction of water. Here, the edges of the filter 62 refer to the top and bottom of the filter 62.

When the washing unit 66 sprays water in an inclined direction, the spraying force of the water can be increased compared to when the washing unit 66 sprays water in a horizontal direction, removing foreign substances attached to the edge of the filter 62. It can be removed more effectively.

Specifically, when the washing unit 66 moves along the upper part of the curved part 65, the water is obliquely sprayed toward the lower right side, thereby removing foreign substances attached to the upper part of the filter 62. can be cleaned more effectively. And, when the cleaning unit 66 moves along the center of the bent portion 65, it sprays water in the right direction. In addition, when the washing unit 66 moves along the lower part of the curved part 65, the washing unit 66 sprays water obliquely toward the upper right side to remove foreign substances attached to the lower part of the filter 62. Can be cleaned effectively.

In addition, the vibration unit 67 is provided at the upper front and rear of the body unit 60, respectively, and is formed to be movable in the left and right directions, so that vibration is applied to the filter 62 when the filter 62 is raised and lowered, thereby vibrating the filter (62). 62) Remove foreign substances attached to the outside.

Meanwhile, the filter 62 may include a first filter 62a, a second filter 62b, a third filter 62c, a fourth filter 62d, and a fifth filter 62e.

First, the first filter 62a is disposed on the leftmost side inside the body portion 60. And, the second filter 62b is arranged to be spaced apart to the right of the first filter 62a.

And, the third filter 62c is arranged to be spaced apart to the right of the second filter 62b. And, the fourth filter 62d is arranged to be spaced apart to the right of the third filter 62c.

And, the fifth filter 62e is arranged to be spaced apart to the right of the fourth filter 62d.

Meanwhile, the controller 45 may further include a driving control unit 68. First, the drive control unit 68 controls the driving of the raising and lowering unit 63, the filter 62, the washing unit 66, and the vibration unit 67, respectively.

Specifically, the drive control unit 68 controls the number of filters 62 to be cleaned to change according to the measurement value measured by the first measurement unit 31.

First, when the measurement value measured by the first measurement unit 31 exceeds the first reference value and is below the second reference value, the drive control unit 68 uses the first filter 62a disposed on the leftmost side among the plurality of filters 62. Controls it to go up and down. Through this, the drive control unit 68 can determine that the first filter 62a disposed on the leftmost side among the plurality of filters 62 is contaminated, and control the first filter 62a to be cleaned.

Meanwhile, when the measurement value measured by the first measurement unit 31 is greater than the second reference value and less than the third reference value, the drive control unit 68 selects the first filter 62a and the second filter (62a) among the plurality of filters 62. 62b) is controlled to rise and fall sequentially. Through this, the drive control unit 68 determines that the first filter 62a and the second filter 62b among the plurality of filters 62 are contaminated, and the first filter 62a and the second filter 62b are contaminated. It can be controlled to be washed sequentially.

Specifically, the drive control unit 68 controls the first filter 62a among the plurality of filters 62 to be raised and lowered when the measurement value measured by the first measuring unit 31 exceeds the second reference value and is below the third reference value. do.

Additionally, the drive control unit 68 controls the first filter 62a to descend when the cleaning of the first filter 62a is completed.

Additionally, the drive control unit 68 controls the second filter 62b disposed immediately to the right of the first filter 62a to go up and down when the first filter 62a goes down.

Meanwhile, when the measurement value measured by the first measurement unit 31 exceeds the third reference value and is below the fourth reference value, the drive control unit 68 selects the first filter 62a and the second filter (62a) from among the plurality of filters 62. 62b) and the third filter 62c are controlled to rise and fall sequentially. Through this, the drive control unit 68 determines that the first filter 62a, the second filter 62b, and the third filter 62c among the plurality of filters 62 are contaminated, and the first filter 62a, The second filter 62b and the third filter 62c can be controlled to be washed sequentially.

Specifically, the drive control unit 68 controls the first filter 62a among the plurality of filters 62 to be raised and lowered when the measurement value measured by the first measuring unit 31 exceeds the third reference value and is below the fourth reference value. do.

Additionally, the drive control unit 68 controls the first filter 62a to descend when the cleaning of the first filter 62a is completed.

Additionally, the drive control unit 68 controls the second filter 62b disposed immediately to the right of the first filter 62a to go up and down when the first filter 62a goes down.

And, the drive control unit 68 controls the second filter 62b to descend when the cleaning of the second filter 62b is completed.

Additionally, the drive control unit 68 controls the third filter 62c disposed immediately to the right of the second filter 62b to go up and down when the second filter 62b goes down.

Meanwhile, the drive control unit 68 controls the washing unit 66 to move to the right when the first filter 62a is raised and lowered so that the washing unit 66 is disposed on one side of the filter 62.

Additionally, the drive control unit 68 controls the cleaning unit 66 to move along the curved portion 65 when the cleaning unit 66 is disposed on one side of the first filter 62a.

And, the drive control unit 68 controls the washing unit 66 to wash the first filter 62a with water while the washing unit 66 moves along the curved portion 65.

And, the drive control unit 68 controls the vibration unit 67 to move to the right when the first filter 62a is raised and lowered, so that the vibration unit 67 is disposed at the front and rear of the first filter 62a, respectively. do.

Additionally, the drive control unit 68 controls the vibration unit 67 to apply vibration to the first filter 62a when the vibration unit 67 is disposed in front and behind the first filter 62a.

The smart water quality measurement and precision filtration system according to the present invention has the effect of supplying filtered tap water through a precision filter by changing the path of the electromagnetic valve when the tap water measured by the water quality measurement unit exceeds the standard value. .

In addition, the smart water quality measurement and precision filtration system according to the present invention can replace the filter of the precision filter according to the measured value of tap water, thereby reducing filter replacement costs by extending the filter replacement cycle, enabling efficient management and operation. There is a possible effect.

In addition, the smart water quality measurement and precision filtration system according to the present invention can solve the problem of uncertainty in the supply of clean and safe tap water to the consumer due to the aging of the pipe network and the inflow and generation of contaminants in the pipe, and provide reliable, high-quality water to consumers. It has the effect of supplying tap water.

As described above, the main technical idea of the present invention is to provide a smart water quality measurement and precision filtration system (5), and the embodiment described above with reference to the drawings is only one embodiment, and is the true embodiment of the present invention. The scope of rights is based on the scope of the patent claims, but also extends to various equivalent embodiments that may exist.

5: Smart water quality measurement and micro-filtration system
10: Water tank
11: inlet
12: discharge part
13: drain part
15: Fine filter
20: Euro
21: Inlet line
22: supply line
23: moving line
24: first drain line
25: discharge line
26: second drain line
30: Water quality measurement unit
31: first measuring unit
32: second measuring unit
33: Third measuring unit
V: valve part
V1: first valve
V2: Second valve
V3: Third valve
V4: 4th valve
V5: Fifth valve
45: controller
46: Alarm unit
47: valve control unit
48: Alarm control unit
49: Screen control unit
50: storage unit
51: Department of Communications
55: display unit
60: body part
61: Rail part
62: filter
62a: first filter
62b: second filter
62c: third filter
62d: fourth filter
62e: Fifth filter
63: Elevation and descent section
64: support part
65: bend part
66: Washing department
67: Vibration unit
68: Drive control unit

Claims (4)

A precision filter (15) that filters tap water;
Flow paths (20) each connected to the precision filter (15) through which tap water flows in or out; and
It includes a water quality measuring unit 30 provided on the flow path 20 to measure the quality of tap water in real time,
The euro 20 is
An inlet line (21) through which tap water flows;
A supply line (22) connected to the inlet line (21) and the precision filter (15), respectively, through which tap water passing through the inlet line (21) moves to the precision filter (15);
A moving line (23) connected to the precision filter (15) and the inflow line (21), respectively, through which tap water passing through the precision filter (15) moves to the inflow line (21); and
A first drain line 24 is connected to the precision filter 15 and drains the tap water that has passed through the precision filter 15 to the outside.
The water quality measuring unit 30 is
A first measuring unit 31 provided on one side of the inlet line 21 to measure the quality of tap water flowing into the inlet line 21 in real time; and
A second measuring unit 32 is provided on the other side of the inlet line 21 and measures the quality of tap water discharged from the precision filter 15 in real time,
The precision filter (15) is
It includes a filter 62 on the inside that filters foreign substances contained in tap water,
a first valve (V1) provided at the center of the inlet line (21) and configured to be open and closed;
a second valve (V2) provided at the center of the supply line (22) and configured to be open and closed;
a third valve (V3) provided at the center of the moving line (23) and configured to be open and closed;
a fourth valve (V4) provided at the center of the first drain line (24) and configured to be open and closed;
A controller 45 that controls the opening and closing of a plurality of valves according to the measurement value measured by the water quality measurement unit 30; and
It further includes a display unit 55 that displays the measured values measured by the water quality measuring unit 30 and the presence or absence of abnormalities in the measured values, respectively,
The controller 45 is
An alarm unit 46 that emits an alarm sound according to the measurement value measured by the water quality measurement unit 30;
A valve control unit 47 that controls a plurality of valves according to the measurement value measured by the water quality measurement unit 30;
an alarm control unit 48 that controls the alarm unit 46 according to the measurement value measured by the water quality measurement unit 30;
a screen control unit 49 that controls the display unit 55 according to the measurement value measured by the water quality measurement unit 30;
a storage unit 50 that stores the measurements measured by the water quality measurement unit 30; and
It includes a communication unit 51 that transmits and receives data between the water quality measurement unit 30, the display unit 55, and the controller 45,
The valve control unit 47 is
When the measurement value measured by the first measuring unit 31 falls within a preset normal range, the first valve V1 is opened to allow tap water to pass through the inlet line 21, and the second valve (V2), the third valve (V3), and the fourth valve (V4) are controlled to be closed, respectively,
The screen control unit 49 is
If the measurement value measured by the first measurement unit 31 falls within the normal range, the display unit 55 is controlled to display by voice or text that the measurement value of the first measurement unit 31 is normal,
The valve control unit 47 is
If the measurement value measured by the first measuring unit 31 does not fall within the normal section, the first valve (V1) and the 2 Control the valve (V2) to open and close respectively,
The alarm control unit 48 is
If the measurement value measured by the first measurement unit 31 does not fall within the normal section, the alarm unit 46 is controlled to emit a first alarm sound,
The screen control unit 49 is
A smart water quality measurement and precision filtration system, characterized in that when the alarm unit 46 emits the first alarm sound, the display unit 55 is controlled to display by voice or text that the precision filter is in operation. delete delete According to clause 1,
The valve control unit 47 is
When the measurement value measured by the second measuring unit 32 falls within the normal section, the third valve V3 is opened to allow tap water to flow into the moving line 23, and the first valve V1 ), controlling the second valve (V2) and the fourth valve (V4) to be closed, respectively,
The screen control unit 49 is
If the measurement value measured by the second measurement unit 32 falls within the normal range, the display unit 55 is controlled to display by voice or text that the measurement value of the second measurement unit 32 is normal,
The valve control unit 47 is
If the measurement value measured by the second measuring unit 32 does not fall within the preset normal section, the fourth valve V4 and the third valve V3 are opened and closed, respectively, so that tap water can be drained to the outside. Control as much as possible,
The alarm control unit 48 is
If the measurement value measured by the second measurement unit 32 does not fall within the normal section, the alarm unit 46 is controlled to emit a second alarm sound,
The size of the second alarm sound is
It is set to 1.8 times to 2.3 times the size of the first alarm sound,
The screen control unit 49 is
Smart water quality measurement and precision filtration, characterized in that when the alarm unit 46 displays the second alarm sound, the display unit 55 is controlled to display by voice or text the message that the filter of the precision filter 15 needs to be replaced. system.