KR102578566B1 - Non-Point Pollution Reduction Facility Smart Maintenance System - Google Patents

Abstract

The present invention relates to a smart maintenance system for non-point pollution reduction facilities. The management and operation control of non-point pollution reduction facilities for the reduction and treatment of non-point pollution substances can be performed remotely through the manager's remote control terminal, resulting in more efficient facility management. indicates possible effects.
In particular, the application of smart control technology shows the advantage of enabling safe monitoring through short- and long-distance communication without access to existing facilities.

Description

Non-Point Pollution Reduction Facility Smart Maintenance System}

The present invention relates to a non-point pollution reduction facility management system, and more specifically, to a smart maintenance system to improve management efficiency by enabling the management and control of facilities for the reduction and treatment of non-point pollution substances generated with rainwater to be performed remotely. It's about management systems.

Water pollution sources are classified into point pollution sources and non-point pollution sources depending on the nature of the pollution source. Point pollution sources are pollution sources that are discharged in the form of sewers or ditches from points where pollution discharge can be clearly identified, while non-point pollution sources are pollution sources that are discharged from a wide area by rainwater, etc. This means that pollutants are discharged while being washed and are discharged from scattered pollutants, making it difficult to determine exactly where the emission source is.

In general, non-point pollution sources are also called non-specific pollution sources, surface pollution sources, mobile pollution sources, or other water pollution sources. Unlike point pollution sources that have a specific discharge route, non-point pollutants are generated through unspecified discharge routes such as urban surface drainage or agricultural drainage. It refers to the place or area where it is ordered. Here, the non-point pollutants are mainly pollutants that run off with surface runoff when it rains, such as fertilizers or pesticides sprayed on farmland, soil erosion, livestock runoff, traffic pollutants, dust and waste in urban areas, and natural flora and fauna. It refers to residues, air pollutants that fall on the ground surface, etc.

Recently, it is difficult to confirm the exact outflow path, and management of non-point pollutants generated from roads and parking lots where pollutants inflow is non-continuous is being strengthened. Specifically, dust floating in the air and heavy metals contained in this dust fall and deposit on the road surface, and furthermore, fine particles contained in exhaust gases resulting from vehicle operation, tire wear caused by vehicle operation, Environmental pollutants such as asphalt wear and tear are also accumulated. These environmental pollutants contain heavy metals such as cadmium and eutrophic salts such as nitrogen and phosphorus, and can have a harmful effect on the human body.

In this way, various pollutants accumulated on the road surface are discharged into the river through road drains during rainfall. Although the overall pollutant concentration of the runoff water discharged into the river with rainfall is low, the total amount greatly exceeds that of point pollution sources, so it is stable. To preserve water quality, non-point pollution treatment devices are installed to treat surface drainage from impervious areas such as roads and parking lots.

However, the non-point pollution treatment device in the prior art had a problem in that it was difficult to maintain the facility because the manager had to manually measure the inflow flow rate and manage the operation.

Republic of Korea Patent Registration No. 2479060 (registered on December 14, 2022) Korean U.S. Patent Registration No. 2005510 (registered on July 24, 2019)

The present invention was proposed to improve the problems in the prior art described above, and its purpose is to improve the management efficiency of facilities by providing a smart maintenance system that can remotely maintain and control non-point pollution device facilities. There is.

The present invention for achieving the above object includes a pretreatment tank in which rainwater flows in from the outside through a rainwater inlet pipe, and a purification filter so that rainwater overflowing from the pretreatment tank flows into an overflow barrier and filters out contaminants. In the smart maintenance system of a non-point pollution reduction facility including a filtration tank and a treatment tank in which rainwater is stored through the filtration tank and discharged to the outside through a discharge pipe, the upper part of the purification filter is operated under high pressure by backwash pump operation. A backwash injection nozzle is configured to spray washing water; A bubble supply part is formed at the lower part of the purification filter to supply bubbles by operating a bubble pump; A first drainage pump is configured at the bottom of the pretreatment tank to drain sludge through a drain pipe; At the bottom of the filter tank, a second drainage pump is configured to drain the sludge from the pretreatment tank through a drain pipe; A first filter screen for removing foreign substances is formed on the outlet side of the rainwater inflow pipe; A second filter screen is configured to remove foreign substances from rainwater overflowing from the filtration tank to the treatment tank; The rainwater inlet pipe is each configured with a flow switch for detecting pressure differences due to fluid flow fluctuations and a flow meter for measuring flow rate; The pretreatment tank and the filtration tank are equipped with a water level gauge to detect changes in water level; a microcomputer control unit that controls operations and signals of the first and second drain pumps, bubble pump, backwash pump, water level sensor, flow switch, and flow meter; a control panel connected to the microcomputer control unit via wired or wireless means; It is characterized in that it comprises a remote control terminal that is remotely connected to the control panel and the microcomputer control unit and allows management of the facility by the manager.

The smart maintenance system of the present invention allows management and operation control of non-point pollution reduction facilities to be performed remotely by the manager's remote control terminal, enabling more efficient facility management.

In particular, the application of smart control technology shows the advantage of enabling safe facility monitoring and control through short- and long-distance communication without accessing the non-point pollution facility site.

1 is a configuration diagram of a smart maintenance system according to an embodiment of the present invention.
Figure 2 is a detailed cross-sectional structural diagram of the non-point pollution reduction facility in the present invention.
Figure 3 is a partially cut away perspective view of the inlet filter screen installation part in the present invention.
Figure 4 is a block diagram of a smart maintenance system in the present invention.
Figure 5 is a system operation flow chart in the present invention.
Figure 6 is a cross-sectional structural diagram of a filter screen installation part according to another embodiment of the present invention.
7 is an enlarged view of main parts in another embodiment of the present invention.
Figure 8 is an enlarged cross-sectional view of part A of Figure 7.

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

Embodiments of the present invention may be modified in various forms, and the scope of the present invention should not be construed as being limited to the embodiments described in detail below. This example is provided to more completely explain the present invention to those with average knowledge in the art.

Accordingly, the shapes of components expressed in the drawings may be exaggerated to emphasize a clearer description. It should be noted that the same configuration may be indicated by the same reference numeral in each drawing. Additionally, detailed descriptions of the functions and configurations of known technologies that are judged to unnecessarily obscure the gist of the present invention may be omitted.

First, the configuration of the smart maintenance system for non-point pollution reduction facilities according to an embodiment of the present invention is as follows through Figures 1 to 4.

The non-point pollution reduction facility in this embodiment includes a pretreatment tank (10) through which rainwater flows in from the outside through a rainwater inflow pipe (11), and an overflow from the pretreatment tank (10) to the overflow prevention berm (21). A filtration tank (20) equipped with a purification filter (23) at a mid-level height so that rainwater flows in and filters out contaminants, and the rainwater flows through the filtration tank (20) and is discharged to the outside through the storage and discharge pipe (41). This constitutes the treatment tank 30.

At this time, the smart maintenance system in the present invention is configured with a backwash injection nozzle 25 that sprays high-pressure washing water by the operation of the backwash pump 35 on the upper part of the purification filter 23, and the purification filter 23 At the bottom of the bubble pump 26, a bubble supply unit 24 is provided to supply air bubbles, and at the bottom of the pretreatment tank 10 is a first drainage pump 12a for discharging sludge through the drain pipe 12. is configured, and at the bottom of the filter tank 20, a second drainage pump 22a is configured to drain the sludge to the pretreatment tank 10 through the drain pipe 22, and foreign matter is disposed on the outlet side of the rainwater inlet pipe 11. A first filter screen 14 for removal is configured, a second filter screen 33 is configured to remove foreign substances from rainwater overflowing from the filtration tank 20 to the treatment tank 30, and the rainwater inflow pipe ( 11) is configured with a flow switch 16 to detect pressure differences due to fluid flow fluctuations and a flow meter 17 to measure flow rate, and the pretreatment tank 10 and filtration tank 20 are configured to detect water level changes. Water level gauges (13, 29) are configured for the first and second drain pumps (12, 22), bubble pump (26), backwash pump (35), water level sensor (13), flow switch (16), and flow rate. A microcomputer control unit 50 that controls the operation and signals of the measuring device 17, a control panel 40 that is connected to the microcomputer control unit 50 by wired or wireless connection, and a remote control unit with the control panel 40 and the microcomputer control unit 50. It is configured to include a remote control terminal 60 that is connected and manages the facility by the manager.

The filter blockage state of the purification filter 23 is determined by detecting a change in water level in the water level gauges 13 and 29 included in the pretreatment tank 10 and the filtration tank 20, and when the water level rises above a certain level above the effective water level, the purification filter 23 ) is judged to be blocked.

In addition, the pretreatment tank 10 and the filtration tank 20 are each equipped with TSS 1 (51) and TSS 2 (52), which are sensors that measure changes in turbidity through detection of suspended solids, and transmit data to the microcomputer control unit (50). It will come true.

Meanwhile, an inflow guide box 15 is formed at the upper part of the pretreatment tank 10 to guide rainwater flowing in through the rainwater inflow pipe 11, and the first filter screen 14 is an inflow guide box 15. You can see that it is connected to the inner lower part of the.

In the drawing, unexplained symbols 18, 28, and 38 respectively represent manholes.

The effect of the operation of the non-point pollution reduction facility smart maintenance system of the present invention configured as described above will be examined with reference to the flow chart in FIG. 5.

First, in the system standby state, the initial rainwater flows in through the rainwater inlet pipe 11 of the pretreatment tank 10 and water is stored at a certain level, and the rainwater overflows the overflow barrier 21 in the pretreatment tank 10. is moved to the filtration tank (20).

At this time, the change in the flow of rainwater flowing in through the rainwater inlet pipe 11 is detected by the flow switch 16, and the flow rate is detected by the flow meter 17, and the change in the water level inside the pretreatment tank 10 is It is detected by the water level gauge (13) and transmitted in real time to the control panel (40) through the MyCup control unit (50).

In addition, rainwater flowing into the rainwater inflow pipe 11 collects impurities such as fallen leaves while passing through the first filter screen 14 with a plurality of through holes. The impurities collected in this way can be easily discharged to the outside through the upper manhole 18 using a basket (not shown).

Thereafter, in the filtration tank 20, fine pollutants mixed in rainwater are captured as they pass through the purification filter 23 and move upward.

Rainwater that has been purified by passing through the purification filter 23 in this way overflows into the treatment tank 30 and is then discharged into an external drainage facility or river through the discharge pipe 31 formed on one side of the treatment tank 30. It will come true.

At this time, in the process of overflowing into the treatment tank 30, the remaining fine foreign matter passes through the second filter screen 33 and is screened.

Meanwhile, the water level gauge 13 installed in the pretreatment tank 10 detects changes in water level, and when the water level is 10 cm higher than the effective water level, it is determined that the purification filter 23 is blocked and cannot function again, so filter cleaning can be performed. , the drain pump 22 is operated by a control signal from the control panel 40 to lower the water level in the filtration tank 20 by the height of the purification filter 23, and the bubble supply unit 24 and the backwash injection nozzle 25 are operated. Filter cleaning is performed.

That is, when bubbles are generated from the bubble supply unit 24, the generated bubbles flow into the purification filter 63, separate foreign substances adhering to the pores in the filter, and are discharged to the top.

At the same time, when the backwash pump 35 operates and high-pressure wash water is sprayed through the backwash spray nozzle 25, the high-pressure wash water is sprayed onto the upper surface of the purification filter 23, thereby separating foreign substances adhering to the surface. Clogging and contamination of the pores of the purification filter 23 can be prevented.

In particular, in the present invention, the manager can use the remote control terminal 60 to transmit control signals to the control panel 40 and the microcomputer control unit 50 through remote access, thereby enabling automatic control, thereby improving the management efficiency of non-point pollution reduction facilities. It can be seen that this can be improved.

In addition, when the water level in the pretreatment tank 10 rises rapidly and reaches the set emergency water level, a message is sent to the manager's remote control terminal 60 so that emergency response can be quickly accomplished.

Therefore, the smart maintenance system of the present invention allows management and operation control of non-point pollution reduction facilities to be performed remotely by the manager's remote control terminal, resulting in more efficient facility management.

In particular, the application of smart control technology shows the advantage of enabling safe facility monitoring and control through short- and long-distance communication without accessing the non-point pollution facility site.

Meanwhile, Figures 6 to 8 show another embodiment of the present invention, and between the inlet guide box 15 and the first filter screen 14, there is a buffer pad 70 to absorb shock generated by the inflowing rainwater pressure. ) is composed.

In addition, inside the first filter screen 14, a distribution plate 71 is formed with an inclined surface at a certain angle for uniform distribution of rainwater flowing in through the rainwater inflow pipe 11, and the distribution plate 71 A guide wire mesh 72 is extended at the lower part to provide support by connecting to the bottom surface of the first filter screen 14, and the distribution plate 71 includes a magnet 73 for magnetic action and an elastic elastic for elastic support. A spring 74 is configured.

In addition, a buffer surface (71a) is coated on the surface of the distribution plate (71) to reduce rainwater noise and prevent contamination, and the buffer surface (71a) is made of 5 to 20% by weight of polytetrafluoroethylene and polysulfone. Resin 10-30% by weight, methyl fluoride 1-10% by weight, urethane powder 10-20% by weight, phenylalanine tetrahydroxylase 1-15% by weight, chromium oxide 1-10% by weight, sodium hexanitrocobaltate 5~ It is preferable to form a mixed composition in a ratio of 15% by weight, 1 to 10% by weight of silica sand, 1 to 10% by weight of calcium carbonate, and 1 to 10% by weight of potash feldspar.

When this configuration is achieved, rainwater flowing in through the rainwater inlet pipe 11 is guided along the slope of the distribution plate 71, thereby reducing the impact and noise of falling water. At this time, initial foreign matter removal and buffering action are performed by the guide wire mesh 72 and the elastic spring 74, and fine metal foreign matter can be collected by the magnet 73.

In addition, since the distribution plate 71 is coated with a buffer surface 71a, the effect of reducing noise from falling water can be maximized.

In particular, since the coating composition forming the buffer surface 71a contains a mixture of polytetrafluoroethylene components, deterioration and discoloration of the polysulfone resin are prevented, and methyl fluoride and phenylalanine tetrahydroxylase increase the bonding strength between the mixtures. It has the function of improving the durability of the coating layer, and chromium oxide and sodium hexanitrocobaltate can improve surface lubricity. In addition, the additionally added silica sand and calcium carbonate suppress the generation of bubbles on the buffer surface 71a during the coating process, and the potash feldspar exhibits an advanced effect of improving coating density.

In addition, although specific embodiments of the present invention have been described and shown above, it is obvious that the structure of the non-point pollution reduction device of the present invention can be implemented in various modifications by those skilled in the art.

Therefore, such modified embodiments should not be understood individually from the technical spirit or scope of the present invention, and such modified embodiments should be included within the scope of the appended claims of the present invention.

10: Pretreatment tank 11: Rainwater inflow pipe
12: drain pipe 12a: first drain pump
13: water level gauge 14: first filter screen
15: Inflow guide box 16: Flow switch
17: flow meter 18,28,38: manhole
20: filtration tank 21: overflow barrier
22: drain pipe 22a: second drain pump
23: purification filter 24: bubble supply unit
25: Backwash injection nozzle 26: Bubble pump
27: filter sensor 29: water level gauge
30: treatment tank 31: discharge pipe
33: second filter screen 35: backwash pump
40: control panel 50: microcomputer control unit
51: TSS 1 52: TSS 2
60: remote control terminal

Claims (5)

A pretreatment tank (10) in which rainwater flows in from the outside through the rainwater inflow pipe (11), and rainwater overflowing from the pretreatment tank (10) flows into the overflow barrier (21) to filter and process pollutants. A non-point pollution reduction facility comprising a filtration tank (20) equipped with a purification filter (23) and a treatment tank (30) in which rainwater is stored through the filtration tank (20) and discharged to the outside through a discharge pipe (41). In the smart maintenance system,
A backwash spray nozzle 25 is provided on the upper part of the purification filter 23 to spray high-pressure wash water by the operation of the backwash pump 35;
A bubble supply unit 24 is provided at the lower part of the purification filter 23 to supply bubbles through the operation of the bubble pump 26;
A first drainage pump (12a) is configured at the lower part of the pretreatment tank (10) to drain sludge through the drain pipe (12);
A second drainage pump (22a) is provided at the lower part of the filtration tank (20), which drains the sludge to the pretreatment tank (10) through the drain pipe (22);
A first filter screen 14 for removing foreign substances is provided on the outlet side of the rainwater inflow pipe 11;
A second filter screen 33 is provided to remove foreign substances from rainwater overflowing from the filtration tank 20 to the treatment water tank 30;
The rainwater inflow pipe 11 is provided with a flow switch 16 for detecting pressure differences due to fluid flow fluctuations and a flow meter 17 for measuring the flow rate;
The pretreatment tank 10 and the filtration tank 20 are equipped with water level gauges 13 and 29 for detecting water level changes;
The operation and signal control of the first and second drainage pumps (12a, 22a), bubble pump (26), backwash pump (35), water level sensor (13), flow switch (16), and flow meter (17) are controlled by the control panel ( 40) and the microcomputer control unit 50, and the control panel 40 and the microcomputer control unit 50 are connected wired or wirelessly;
The pretreatment tank 10 and the filtration tank 20 are each equipped with sensors TSS 1 (51) and TSS 2 (52) that measure changes in turbidity through detection of suspended solids;
The control panel 40 and the microcomputer control unit 50 are remotely connected to the remote control terminal 60 so that the facility can be managed by the manager;
An inflow guide box 15 is formed at the top of the pretreatment tank 10 to guide rainwater flowing in through the rainwater inflow pipe 11, and the first filter screen 14 is located inside the inflow guide box 15. Smart maintenance non-point pollution reduction facility is comprised of a buffer pad (70) between the inflow guide box (15) and the first filter screen (14) to absorb shock generated by incoming rainwater pressure. Management system. In claim 1,
The filter blockage state of the purification filter 23 is determined by detecting a change in water level in the water level gauges 13 and 29 included in the pretreatment tank 10 and the filtration tank 20, and when the water level rises above a certain level above the effective water level, the purification filter 23 ) A smart maintenance system for non-point pollution reduction facilities, characterized in that it is determined to be clogged. delete In claim 1,
Inside the first filter screen 14, a distribution plate 71 is formed with an inclined surface at a certain angle for uniform distribution of rainwater flowing in through the rainwater inflow pipe 11, and at the bottom of the distribution plate 71 The guide wire mesh 72 is extended and supported by connection with the bottom surface of the first filter screen 14, and the distribution plate 71 is equipped with a magnet 73 for magnetic action and an elastic spring for elastic support ( 74) A smart maintenance system for non-point pollution reduction facilities. delete

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