KR101759931B1 - Light filter type terraced filtering wetland - Google Patents

Abstract

The present invention relates to an artificial wetland type filter bed in which a plurality of unit treatment tanks 10 provided with a vegetation material 30 at the upper portion thereof are coupled and connected in a multi-stage manner. In the unit treatment tank 10, A loading box 50 on which the vegetation material 30 is placed is installed on the upper part of the unit treatment tank 10 and an upward flow is formed on the treated water in the unit treatment tank 10, The backwashing of the lightweight filter medium 20 is performed by cleaning the filtered water passing through the filter medium 20 in contact with the purifying plant of the loading box 50 so that the bottom plate of the loading box 50 can be opened and closed. The ultrasonic oscillator 17 is installed inside the unit treatment tank 10 to operate the sewage backwash in order to separate contaminants deposited in the light weight filter media 20 will be.
Through the present invention, it is possible to fundamentally solve the problems in the backwashing operation of the filter media, which has been a maintenance problem in the conventional artificial wetland type filter, and can solve the problems of the vegetation material 30 and the purification It is possible to use the semi-permanent use of the filter media while maintaining the function of the wetland filter perfectly, thereby remarkably improving the treatment performance and maintenance convenience of the wetland filter, Operating costs can also be drastically reduced.

Description

{LIGHT FILTER TYPE TERRACED FILTERING WETLAND}

The present invention relates to an artificial wetland type filter bed in which a plurality of unit treatment tanks 10 provided with a vegetation material 30 at the upper portion thereof are coupled and connected in a multi-stage manner. In the unit treatment tank 10, A loading box 50 on which the vegetation material 30 is placed is installed on the upper part of the unit treatment tank 10 and an upward flow is formed on the treated water in the unit treatment tank 10, The backwashing of the lightweight filter medium 20 is performed by cleaning the filtered water passing through the filter medium 20 in contact with the purifying plant of the loading box 50 so that the bottom plate of the loading box 50 can be opened and closed. The ultrasonic oscillator 17 is installed inside the unit treatment tank 10 to operate the sewage backwash in order to separate contaminants deposited in the light weight filter media 20 will be.

Wetland remnants (ie, wetlands) are facilities that perform physical filtration and wetland functions simultaneously. They are designed to treat wastewater, treat nonpoint pollution sources, improve river water quality, provide biological habitats, and create a hydrophilic environment.

Wastewater treatment by wetland is applied to various fields such as industrial wastewater such as urban sewage, combined sewer water, dairy wastewater, landfill leachate, hospital wastewater, etc. and treatment of pollutants originating from nonpoint source such as storm water and runoff water And is particularly attracting attention as a non-point pollution source treatment facility.

Wetlands may be composed of a single wetland or a combination of various types of unit wetlands. The combined wetland landscapes are composed of a plurality of unit wetlands with different operating levels in a stepped manner, The retention time and the retention path are extended to ensure the purification treatment efficiency. As a related art, Japanese Patent No. 459503 is cited.

Conventional multi-stage wetland wastewater including patent No. 459503 is formed by connecting unit wastewater, that is, treatment wastewater in a stepwise manner. In each treatment wastewater, a filter material such as soil or crushed stone is installed, and a structure in which plants are planted , And the treated water treated through the entire unit wetland is firstly introduced into the uppermost treatment tank, and then the treated water is sequentially passed through the subsequent treatment tank.

The treated water in the multistage wetland is filtered while passing through the particulate filter media installed in the treatment tank, and then purified while being in contact with the planted plants. Especially, in such multi-stage wetland filtration, Horizontal flow) as well as a vertical phase flow, so that it is advantageous to utilize the entire cross-sectional area of the treatment tank for the filtration treatment.

As described above, the conventional multistage wetland filter can obtain many advantages in terms of the space utilization as well as the purification effect of the treated water. However, when the pollutants are deposited on the filter media for a long period of operation, the treatment effect is drastically reduced and the practical function is lost. there was.

In order to solve such a problem, as in a conventional filtration type water treatment facility, there is a method of artificially inducing a reverse flow of the treated water flow in a normal time or injecting backwash water to separate and remove contaminants attached to the filter media However, in the multistage wetland treatment tank, the forward flow of the treatment water flow is upward. In order to backwash the high-pressure backwash water should be injected from the upper side of the treatment tank. In this process, There is a problem that it is difficult to recover the injected backwash water and the washed contaminants.

Therefore, it is possible to consider a method in which a filter is installed in advance of the treatment tank and a filter material is installed in advance, and the reverse water is supplied upward, that is, in the forward direction of the normal treatment water flow, This is not in agreement with the preliminary meaning of backwash that supplies backwash water in the reverse direction of the treatment water flow but it can be considered as a significant solution because it can expect a substantial removal effect of filter attachment stain. However, The serious contamination side effects of the plants planted with the pollutants in the stationary water discharged into the vegetation material 30 are caused.

As the upper part vegetation material 30 for treatment of wetland wastes, an expensive functional vegetation material 30 including a natural fiber-based vegetation material 30 such as coir fiber is applied, and these vegetation materials 30, If the contaminants are deposited in the fibrous vegetation, it is practically impossible to remove them, so that the entire vegetation material 30 must be replaced, and the planting and cultivation of the purified plants must be repeated.

Therefore, if the function of the filter material is lost due to the deposition of the contaminants, the function of the wetland filter is maintained by removing the existing filter material and installing a new filter material. Not only the replacement of the filter media itself but also the disposal of the waste filter material and the restoration of the upper vegetation are costly and there is a serious problem accompanied by a long-term operation interruption.

SUMMARY OF THE INVENTION The present invention has been made in view of the above-described problems, and it is an object of the present invention to provide a unit treatment tank in which a plurality of unit treatment tanks 10, in which a filter material is loaded and a vegetation material 30 is installed, The flow of the treated water in the unit treatment tank 10 is generated due to the supply of the compressed air or the backwash water to the inner bottom surface of the unit treatment tank 10 and an ultrasonic oscillator 17 And an ultrasonic wave is propagated to the treated water in the unit treatment tank 10 and an inlet 13 into which the treated water flows is formed in the lower portion of the side wall 11 of the unit treatment tank 10, The lightweight filter medium 20 for filtering contaminants in the treatment water is loaded so that the treated water flowing into the inlet 13 is filtered while passing through the lightweight filter medium 20 and the vegetation material ) 30 are stacked on the bottom plate and a plurality of water supply holes (51) And the treated water having passed through the light weight filter medium 20 is discharged after being brought into contact with plants planted in the vegetation material 30 and discharged to the upper part of the unit treatment tank 10 The discharge port 71 connected to the valve 72 is formed to discharge the backwash water in the unit treatment tank 10 as the discharge valve 72 opens when the light weight filter medium 20 is backwashed, A plurality of incision openings 56 are closely fitted to the opening and closing plate 55 so that the opening and closing plate 55 formed at the same interval as the water supply holes 51 can be reciprocated, The treated water in the unit treatment tank 10 sequentially passes through the incision port 56 and the water supply hole 51 and flows into the loading box 50. The opening and closing plate 55 is moved, And the inflow of the treated water into the loading box (50) is blocked in a state of being separated from the air hole (51).

A floatation restraining plate 40 for passing treatment water through the lightweight filter medium 20 of the unit treatment tank 10 and blocking the floating of the lightweight filter medium 20 is provided on the wall of the unit treatment tank 10, (45) is provided on one side wall (11) of the unit treatment tank (10) with an active roller (47) mounted on the lower side thereof, And a slanting action groove 42 is formed at an upper portion of one side of the floatation restraining plate 40. The active roller 47 is coupled to the slanting action groove 42, The floatation restraining plate 40 is lifted and lowered while the active rollers 47 travel along the inclined action grooves 42 as the pivoting lever 45 is rotated.

Through the present invention, it is possible to fundamentally solve the problems in the backwashing operation of the filter media, which has been a maintenance problem in the conventional artificial wetland type filter, and can solve the problems of the vegetation material 30 and the purification It is possible to use the semi-permanent use of the filter media while maintaining the function of the wetland filter perfectly, thereby remarkably improving the treatment performance and maintenance convenience of the wetland filter, Operating costs can also be drastically reduced.

In addition, the lightweight filter medium 20 is applied so that the lightweight filter medium 20 vibrates or floats when the aeration or backwash water is supplied through the air diffuser. At the same time, the ultrasonic wave oscillator It is possible to effectively separate contaminants deposited on the lightweight filter medium 20 by operating the filter 17 so that it is possible to remove deposits or sticky contaminants which can not be expected in simple washing of the backwash, can do.

In addition, it is also possible to provide a flotation-restraining plate 40 capable of adjusting the pressing state of the light-weight filter medium 20 so as to maximize the filtration effect while maintaining a tightly stacked state of the light- The filtration efficiency and the backwashing effect can be secured at all by ensuring free flow of the lightweight filter medium 20 by releasing the pressing state of the lightweight filter medium 20.

BRIEF DESCRIPTION OF THE DRAWINGS FIG.
2 is a partial cutaway perspective view of the present invention
Fig. 3 is an exploded perspective view of the backwash-
Fig. 4 is an exploded perspective view of the main part of the present invention.
5 is a longitudinal sectional view of the present invention
Figure 6 is a graphical representation of the operational state representative section of the present invention
FIG. 7 is a schematic cross-sectional view
8 is an explanatory view of the operation of the flotation plate of the present invention

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS The present invention will now be described in detail with reference to the accompanying drawings.

1 is a perspective view showing an outer appearance of the present invention. As shown in FIG. 1, the present invention includes a plurality of unit treatment tanks 10 connected in a stepped manner, The yarn tribune 91 and the filtration tank 93 can be constructed to control the inflow amount and to filter the final discharge water.

1, the entire configuration is shown as being exposed, but the settling tank 91, the unit treatment tank 10, the filtration tank 93, and the piping connected thereto are installed in a state of being buried in the ground And only the planting portion of the purification plant (vegetation plant) such as the vegetation material 30 at the upper end of the unit treatment tank 10 may be exposed to the upper side of the ground.

2, which is a partially cutaway perspective view of the present invention, an injection port 15 is provided in an inner bottom surface of the unit treatment tank 10 constituting the present invention, and the compressed air or backwash water is supplied to the inside of the unit treatment tank 10 A flow of the treated water is generated and an inlet 13 into which the treated water flows is formed below the one side wall 11 of the unit treatment tank 10.

A wobbling wall 12 is formed on the other side of the wall 13 forming the inlet port 13 of the unit treatment tank 10 so that the wastewater inflowed from the lower side of the unit wastewater treatment tank 10 12 are formed in the upstream direction.

2, an ultrasonic oscillator 17 is installed on the inner bottom surface of each unit treatment tank 10 constituting the multistage wetland filter of the present invention and is operated in a backwash process to be described later. Although not shown in the drawing, a drive circuit and a control board for driving the oscillator of the ultrasonic oscillator 17 are provided outside the unit treatment tank 10 and are electrically connected through wiring.

2, an outlet 71 is formed in the upper portion of each unit treatment tank 10 in the present invention so that the backwash water reversal weight of the unit light weight filter medium 20, which will be described later, The discharge valve 72 is connected to the discharge port 71 of each unit treatment tank 10 so that the discharge port 71 can be opened and closed as shown in FIG. And each of the discharge valves 72 is connected to a backwash water treatment tank 94 installed at the downstream side of the wetland through the discharge pipe 75.

That is, the discharge port 71 of each unit treatment tank 10 that can be opened and closed through the discharge valve 72 is connected to the single discharge pipe 75, whereby the backwash generated in each unit treatment tank 10 is collected, And is collected (collected) by the backwash water treatment tank 94 of the sewage treatment plant.

In the embodiment shown in FIG. 2, the backwash water treatment tank 94 installed downstream of the wetland sorghum is formed as a simple sedimentation tank. However, a high speed sedimentation tank or a coagulating sedimentation tank may be used. The first solid-liquid separated backwash water may be separated into a second solid-liquid separation through a separate mechanical filtration apparatus, a screw decanter or a hydro cyclone.

2 and 3, a conveyance pipe 78 for connecting the backwash water treatment tank 94 to the settling tank 91 on the upstream side of the wet paper feeder is provided. The conveyance pipe 78 is provided with a return pump 77, And a circulation type backwash structure for supplying the upper water of the backwash water treatment tank 94, that is, the reverse oily water separated by solid-liquid separation, as the treated water for the wetland wastewater can be constructed.

In the present invention, the vegetation structure on the upper part of the unit treatment tank 10 is constructed by the vegetation material 30 loaded on the loading box 50 installed on each unit water tank as shown in FIG. 1, and the vegetation material 30 ) May be applied to general granular vegetation as well as natural fiber regenerated vegetation material (30) such as coir fibrous vegetation material (30).

As shown in FIGS. 2 and 4, the loading box 50 on which the vegetation material 30 is loaded is constituted by a box having a plurality of water holes 51 punctured at regular intervals (equally spaced) In the illustrated embodiment, the side plate of the loading box 50 is attached to the side wall of the unit treatment tank 10 by screws, but a part of the upper end of the loading box 50 is laterally projected, The loading unit 50 and the unit treatment tank 10 can be detachably attached.

4, a plurality of cut-outs 56 are formed on the outer bottom surface of the loading box 50 so that the opening / closing plate 55 formed at the same interval as the water supply holes 51 of the loading box 50 can be reciprocated So that the water supply hole 51 of the loading box 50 can be opened and closed.

That is, in the state in which the cut-off port 56 of the opening / closing plate 55 overlaps the water supply hole 51 of the loading box 50, the water supply hole 51 is opened so that the treated water of the unit treatment tank 10 And the water supply hole 51 and flows into the loading box 50. When the opening and closing plate 55 is horizontally moved and the incision opening 56 is separated from the water supply hole 51, And the inflow of the treated water into the loading box 50 is blocked.

Through the selective opening and closing structure of the water tank 51 of the loading box 50, it is possible to prevent the inflow of the contaminant-containing stationary water 50, which may be generated in the backwash process to be described later, It is possible to prevent contamination.

4, when the opening / closing plate 55 is mounted on the bottom surface of the loading box 50, the opening / closing plate 55 is formed with a long moving groove 58, The support rod 57 having the support portion 57 formed thereon is passed through the movement groove 58 and is fastened to the bottom plate of the loading box 50 so that the head of the support rod 57 supports the opening and closing plate 55, A reciprocating lever 59 protruding upward is provided on one side of the opening / closing plate 55 so as to enable easy operation on the ground, Respectively.

5 is a longitudinal sectional view of an operation state of the multistage wet paper feeder to which the present invention is applied. As shown in the figure, the coagulant solids flowing into the settling tank 91 through the inflow pipe 61, The primary settled treated water enters the unit treatment tank 10 through the inlet 13 at the lower end of the wall 11 of the unit treatment tank 10 and then passes through the lightweight filter medium 20, The treated water that has passed through the lightweight filter medium 20 flows into the loading box 50 and permeates into the vegetation material 30 to be contacted with the planted plant And is discharged through the overflow wall 12 through the overflow.

As shown in FIGS. 2 and 5, the treated water overflowing the flood walls 12 is temporarily stored in the intermediate storage tank 92 formed at the connection site between the unit treatment tanks 10, Is introduced into the unit treatment tank 10 which is provided on the downstream side of the unit treatment tank 10 at the front end and forms a lower elevation surface and is treated in the same manner as the treatment water treatment method in the unit treatment tank 10 The process water treatment by the unit treatment tank 10 is repeated for each unit treatment tank 10 constituting the entire wetland sorghum, and then the process of the overflow treatment in the last unit treatment tank 10 as shown in FIG. 5 The fine wastewater is introduced into the filtration tank 93 located downstream of the wetland so that the finely divided filter media loaded on the filtration tank 93 is finally filtered to discharge the treated water to the outflow pipe 69, Is completed.

6 is a cross-sectional view showing in detail the manner of transferring and purifying the treated water in the unit treatment tank 10. As shown in the figure, the basic flow of the treated water in the unit treatment tank 10 is one side An inflow port 13 formed at the lower end of the wall 11 and an upward flow reaching the upper end of the other side wall 12 constitute a lightweight filter medium 20 And then flows into the loading box 50 and comes into contact with the vegetation material 30 and the purifying plant and then flows over the upper end of the louver 12.

The treated water flows into the loading box 50 on which the vegetation material 30 is loaded and also flows upward so that the treated water passes through the plurality of perforated water holes 51 on the bottom plate of the loading bay 50, An opening and closing plate 55 for opening and closing the water supply hole 51 is closely attached to the bottom outside surface of the bottom plate of the loading box 50 as described above and the top of the unit treating tank 10 In the operation, that is, when the treatment water is allowed to flow into the loading box 50, the water hole 51 of the loading box 50 is opened and during backwashing operation of the unit treatment tank 10 as shown in FIG. 7, The flow-through hole 51 of the loading box 50 is closed.

The opening / closing function of the water supply hole 51 of the loading box 50 is performed in the same manner as in the enlarged portion in the ellipse in Figs. 4 and 6 and the enlarged portion in the ellipse in Fig. 7, Closing plate 55 as shown in FIG. 6 is formed by equally spacing cut-outs 56 formed at equal intervals in an opening / closing plate 55 which is in close contact with an outer bottom surface of the loading box 50, The treated water in the unit treatment tank 10 passes through the cut-off port 56 and the water supply hole 51 in the stacking direction 50 in a state where the cut-out port 56 of the loading unit 50 and the water supply hole 51 of the loading unit 50 are overlapped, The opening and closing plate 55 is moved as the user operates the reciprocating lever 59 as shown in FIG. 7 and the cutout 56 is separated from the water supply hole 51, The flow of the treated water is blocked.

7, the attachment of the opening / closing plate 55 to the loading box 50 is performed by inserting the supporting rod 57 with the tofu enlarged at the lower end thereof into the opening / closing plate 55, as in the enlarged portion in the ellipse and the enlarged portion in the ellipse in Fig. The effective length on the plane of the moving groove 58 or the clearance of the moving groove 58 coupled with the supporting rod 57 The water passage hole 51 can be precisely opened and closed in accordance with the horizontal reciprocation of the in-play opening / closing plate 55 of the moving groove 58. [

7, the discharge port 71 formed in the upper portion of the unit treatment tank 10 is opened and compressed air or backwash water of high pressure is supplied through the injection port 15 provided in the lower portion of the unit treatment tank 10, When the backwashing of the filter media 20 is performed, the water supply holes 51 of the loading box 50 are tightly closed, thereby effectively preventing the adhering contaminants contained in the reverse water from flowing into the loading box 50.

7, the lightweight filter medium 20 vibrates or floats and floats, so that the solid contaminants deposited in the air gap between the lightweight filter media 20 Of course, the contaminants adhering to the surface of the lightweight filter medium 20 can also be effectively separated. The lightweight filter medium 20 applied to the present invention can be made of a porous lightweight volcanic stone or an artificially produced ceramic and synthetic resin As a comparatively lightweight filter material having a specific gravity close to 1 or 1 or less, compressed air or backwash water is supplied and accompanied with the generation of the treated water flow in the unit treatment tank 10.

7, the floatation flow of the lightweight filter medium 20 is induced and the ultrasonic oscillator 17 mounted on the inner bottom surface of the unit treatment tank 10 is operated to operate the unit treatment tank 10, It is possible to effectively separate the viscous contaminants closely deposited on the surface of the lightweight filter medium 20 by propagating the ultrasonic wave into the interior of the lightweight filter medium 10, thereby remarkably improving the cleaning effect of the lightweight filter medium 20.

Particularly, as described above, a porous filter material such as a volcanic stone or a ceramic can be applied to the lightweight filter medium 20 of the present invention. The contaminants deposited in the microcavity formed in the lightweight filter medium 20 can also be supplied to the ultrasonic oscillator 17, So that the life of the lightweight filter medium 20 can be remarkably prolonged.

In order to create a vibration or float flow environment of the lightweight filter medium 20 in this backwash, an active space that is greatly expanded compared to the lightweight filter medium 20 in the seating state is required.

However, when the active space of the lightweight filter medium 20 is constantly secured and free flow of the lightweight filter medium 20 becomes possible, the air gap between the lightweight filter media 20 is enlarged to lose the substantial filtering function. 20, the space for loading the lightweight filter media 20 is limited to maintain a tightly stacked state. In the backwash operation as shown in FIG. 7, the active space of the lightweight filter media 20 is dramatically increased In the present invention, the above-described object is achieved by providing a floatation restraining plate 40 which can be raised and lowered by an external operation on the light weight filter medium 20.

That is, as shown in FIGS. 4 and 8, a lattice-shaped or network-shaped plate that performs a screen or grating function, The lifting plate 40 is provided so as to be able to move up and down so as to pressurize the lightweight filter medium 20 to maintain a tightly stacked state and to release the pressure when backwashing to allow free flow of the lightweight filter medium 20 .

7 and 8, the floatation-inhibiting plate 40 of the present invention is free to move up and down while sliding along the wall 11 of the unit treatment tank 10, A plurality of support rollers 43 that are freely rotatable on the outer periphery of the floatation restraining plate 40 are provided so that the support rollers 43 can be moved in the unit treatment tank Or along the surface of the wall 11 or the wall 10 of the wall 10.

4 and 8, a rotation lever 45 hingedly connected to the one side wall 11 of the unit treatment tank 10 through a rotary shaft 46 is provided as an elevating operation means of the floatation restraining plate 40 And an active roller 47 is mounted on the lower end of the rotation lever 45 so that the rotation lever 45 45 are rotated, the lifting plate 40 is lifted and lowered while the active roller 47 is traveling along the tilting action grooves 42.

8, the inclined action groove 42 formed in the flotation plate 40 is formed with a bracket 41 protruding upward on one side of the upper surface of the flotation plate 40, The tilting action groove 42 is formed in an arcuate shape so that the tilting lever 45 is engaged with the lower action roller 47 ) Can be smoothly performed in a single step.

10: Unit treatment tank
11: Wall
12: Wolli Walls
13: inlet
15: nozzle
17: Ultrasonic Oscillator
20: Lightweight filter media
30: Vegetation material
40:
41: Bracket
42: incline activity home
43: support roller
45: Tilting lever
46:
47: Activity Rollers
50: Loading
51: water ball
55: opening / closing plate
56: incision opening
57: support rod
58: Moving home
59: Reciprocating lever
61: inlet pipe
69: Outflow tube
71: outlet
72: discharge valve
75: discharge pipe
77: return pump
78: Return pipe
91:
92: Middle storage tank
93: Filtration tank
94: Backwaters water treatment tank

Claims (2)

And a plurality of unit treatment tanks 10 in which vegetation material 30 is installed in the upper part of the unit treatment tank 10 is connected to the unit treatment tank 10 in a multistage manner. The flow of the treated water in the unit treatment tank 10 is caused by the supply of the air or the backwash water and the ultrasonic oscillator 17 is installed in the unit treatment tank 10 so that ultrasonic waves An inlet 13 into which the process water flows is formed in a lower portion of the side wall 11 of the unit treatment tank 10 and a light weight filter medium 20 for filtering contaminants in the process water is loaded in the unit treatment tank 10 The treated water flowing into the inlet 13 is filtered while passing through the lightweight filter medium 20 and the vegetation material 30 is loaded on the unit treatment tank 10 and a plurality of water holes 51 are installed at equal intervals and are provided with a light-weight filter medium 20 And a discharge port 71 connected to the discharge valve 72 is formed in the upper part of the unit treatment tank 10 so that the backwash of the lightweight filter medium 20 is formed. A plurality of incision openings 56 are formed in the outer bottom surface of the loading box 50 so as to have the same size as the water supply holes 51 In the state where the incision opening 56 and the water supply hole 51 are overlapped with each other so that the opening and closing plate 55 formed in the unit treatment tank 10 can reciprocate, 51 are sequentially passed through the loading box 50 and flow into the loading bay 50. When the opening and closing board 55 is moved and the incision opening 56 is separated from the water supply hole 51, In lightweight multi -
The floatation restraining plate 40 for passing the treatment water and blocking the floating of the lightweight filter medium 20 is disposed above the wall 11 of the unit treatment tank 10 on the light weight filter medium 20 of the unit treatment tank 10, And is prevented from moving sideways;
A rotary lever 45 having an active roller 47 mounted on a lower end thereof is hingedly connected to a side wall 11 of the unit treatment tank 10 through a rotary shaft 46;
A slanting action groove 42 is formed on one side of the floating plate 40 and the active roller 47 is engaged with the slanting action groove 42 so that the active roller 47 Is moved along the inclined action grooves (42) to raise and lower the floatation restraining plate (40). delete

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