KR20120097938A - System to purging sewage and wastewater using soil, microorganisms and water plant - Google Patents

Abstract

PURPOSE: A system for purifying sewage and wastewater based on soil, microorganisms, and aquatic plants is provided to dilute and purify sewage and wastewater by maximizing the supply of air. CONSTITUTION: A system for purifying sewage and wastewater based on soil, microorganisms, and aquatic plants includes an introducing part(10), a settling part(20), a filtering part(30), a water fountain part(40), a soil-based filtering part(50), a natural purifying material filled part(55), a soil-filled water path(60), a plant-based purifying part(70), and a discharging part(80). The introducing part primarily purifies sewage and wastewater. The water fountain part raises and drops purified water through the filtering part to be secondarily purified. The soil-based filtering part is based on microorganism-inoculated soil. The natural purifying material filled part includes a sand filled part, a charcoal filled part, and a gravel filled part. Soil blocks composed of microorganisms and soil are arranged in a net to form the soil-filled water path. A plurality of purifying plants-based purifying baths and a plurality of storing baths are arranged to form the plant-based purifying part. [Reference numerals] (10) Introducing part; (20) Settling part; (30) Filtering part; (40) Water fountain part; (5) Pollution detecting unit; (50) Soil-based filtering part; (55) Purifying material filled part; (60) Soil-filled water path; (70) Plant-based purifying part; (80) Discharging part

Description

System to purging sewage and wastewater using soil, microorganisms and water plant}

The present invention relates to a wastewater purification system using soil, microorganisms and aquatic plants, and more particularly, to purify wastewater using soil, microorganisms and aquatic plants utilizing the power of eco-friendly wastewater purification by moving water to be purified through waterways without power. It is about the system.

In recent years, the pollution of living environment is getting serious day by day due to the rapid development of various industries with the increase of population.

Moreover, pollution by sewage and industrial wastewater is one of the most urgent problems that threaten the healthy life of people and endanger the life of natural life.

Therefore, to solve the above problems, currently used wastewater treatment methods are largely divided into physical methods, chemical methods, and biological methods, and among them, physicochemical treatment methods have a lower construction cost than biological treatment methods. On the other hand, there is a disadvantage in that the operating cost is high, and a biological method suitable for the treatment of wastewater containing mainly organic compounds is used.

Recently, microorganisms are genetically modified and applied to gradually change to biological treatment methods.

However, in the case of treating wastewater by microorganisms as described above, if there is a hardly degradable substance or toxic substance in the wastewater, wastewater treatment is impossible, in which case the wastewater has to be diluted.

In addition, the installation of the physicochemical and biological treatment methods such as electricity is enormous, which requires a lot of installation space. Before completely removing the contaminants in the equipment, it is difficult to repair in the operating state and locked in the contaminants, making it impossible to check and check the related matters. There were various disadvantages such as high maintenance cost

An object of the present invention for solving the above problems, by utilizing the purifying ability of the soil and plants and the sterilization action of sunlight and maximizing the supply of air to utilize eco-friendly purification ability to activate microorganisms, the conventional wastewater The present invention provides a wastewater purification system using soil, microorganisms, and plants that are not limited to vast facilities and large places for purifying water and have no difficulty in diluting and purifying wastewater.

Wastewater purification system using soil, microorganisms and plants that purify wastewater by using environmentally friendly purification ability according to an embodiment of the present invention for achieving the object as described above, operating with electrical energy generated by solar cells Using a motor, the wastewater stored in the wastewater storage unit is introduced, but the microorganism inoculation unit inoculates the microorganisms into the introduced wastewater, and the sediment removal unit is allowed to precipitate and remove the additives mixed in the wastewater and observe the precipitate from the outside. An inlet to purify the waste water primarily; Precipitating unit consisting of a plurality of sedimentation chamber each having a separate sedimentation tank for sedimentation and removal of the precipitate mixed in the primary purified water coming from the inlet; A filter unit configured to filter the primary purified water introduced from the inlet in a plurality of stages by equipping the filtration chamber with a plurality of inlets and filtration chambers through which the primary purified water discharged from the precipitation unit flows; A fountain having a fountain for upwardly spreading and falling off the primary purified water filtered by the filter to purify the secondary purified water through sunlight and air, and a pedestal for collecting and discharging secondary purified water falling from the fountain; A soil filter unit for placing a plurality of soil dumps inoculated with microorganisms into a net and allowing the second purified water discharged from the fountain to pass through the soil dump and naturally purify with tertiary purified water; A natural purifier filling unit configured to purify the third purified water introduced from the soil filter unit while passing through the sand filling unit, the charcoal filling unit, and the gravel filling unit; A soil channel part for installing a soil block formed by mixing microorganisms and soil into a net and hanging on a hook of a wall part and a bottom part to purify the tertiary purified water naturally purified by the soil filter part using a microorganism and soil to a fourth purified water; A plant purification unit for arranging a plurality of plant purification tanks in which a plurality of storage tanks and purification plants are planted in a stepwise manner to purify the fourth purification water discharged from the soil channel using a plant as a fifth purification water; And a discharge unit for temporarily storing and discharging the fifth purified water discharged from the plant purification unit.

When using the waste water purification system according to the present invention as described above, by utilizing the purification ability of soil and plants and the sterilization action of sunlight and by maximizing the supply of air to utilize the eco-friendly purification ability to activate microorganisms, waste water It provides the effect of eliminating the need for extensive facilities and large areas for the purification and dilution and purification of waste water.

1 is a schematic view showing a waste water purification system using soil, microorganisms and plants according to an embodiment of the present invention.
Figure 2 is a cross-sectional view showing the inlet of the wastewater purification system using the soil, microorganisms and plants of the present invention.
Figure 3 is a plan view showing a waste water storage unit of the waste water purification system using soil, microorganisms and plants of the present invention.
Figure 4 is a side view showing the waste water storage unit of the waste water purification system using soil, microorganisms and plants of the present invention.
Figure 5 is a cross-sectional view showing the sedimentation part of the wastewater purification system using the soil, microorganisms and plants of the present invention.
Figure 6 is a cross-sectional view showing a filter portion of the waste water purification system using the soil, microorganisms and plants of the present invention.
7 is a view showing a fountain of the wastewater purification system using the soil, microorganisms and plants of the present invention.
8 is a plan view showing a soil filter of the waste water purification system using the soil, microorganisms and plants of the present invention.
9 is a view of the soil filter unit AA of FIG.
10 is a plan view showing a natural purifier filling part of the waste water purification system using the soil, microorganisms and plants of the present invention.
11 is a view showing a soil channel of the waste water purification system using soil, microorganisms and plants of the present invention.
12 is a sectional view of BB of FIG. 11;
Figure 13 is a view showing the plant purification unit and the discharge part of the wastewater purification system using soil, microorganisms and plants of the present invention.
14 is a side cross-sectional view of the plant purification unit of FIG.

Hereinafter, exemplary embodiments of a wastewater purification system using soil, microorganisms, and plants according to the present invention will be described in detail with reference to the accompanying drawings.

1 is a schematic view showing a wastewater purification system using soil, microorganisms and plants according to an embodiment of the present invention, Figure 2 is a cross-sectional view showing an inlet of the wastewater purification system using soil, microorganisms and plants of the present invention, Figure 3 Is a plan view showing a waste water storage unit of the waste water purification system using soil, microorganisms and water plants of the present invention, Figure 4 is a side view showing a waste water storage unit of the waste water purification system using soil, microorganisms and plants of the present invention, Figure 5 6 is a cross-sectional view showing a sediment of the waste water purification system using the soil, microorganisms and plants of the invention, Figure 6 is a cross-sectional view showing a filter portion of the waste water purification system using the soil, microorganisms and plants of the present invention, Figure 7 is a soil of the present invention, 8 is a view showing a fountain of a wastewater purification system using microorganisms and plants, and FIG. 8 is a wastewater purification system using soil, microorganisms and plants of the present invention. 9 is a plan view of the soil filter unit of FIG. 8, FIG. 9 is a view of the soil filter unit AA of FIG. 8, and FIG. 10 is a plan view illustrating a natural purifier filling unit of a wastewater purification system using soil, microorganisms, and plants of the present invention. 11 is a view showing the soil channel of the waste water purification system using the soil, microorganisms and plants of the present invention, Figure 12 is a cross-sectional view of BB of Figure 11, Figure 13 is a waste water purification using soil, microorganisms and plants of the present invention FIG. 14 shows a plant purifying part and a discharging part of the system, and FIG. 14 is a side cross-sectional view of the plant purifying part of FIG.

As shown in the drawings, the wastewater purification system using the soil, microorganisms and plants to purify the wastewater by using the environmentally friendly purification ability of the embodiment of the present invention, the inlet 10, sedimentation unit 20, The filter unit 30, the fountain unit 40, the soil filter unit 50, the natural purifier filling unit 55, the soil channel 60, the plant purification unit 70 and the discharge unit 80.

In addition, the soil filter unit 50, the natural purifier filling unit 55 and the soil channel 60 in the rear of the filter, measuring the soil dumplings and dirt and the like when the level of loss of their purification ability exchange Pollution detecting device (5) is provided to inform the timing and to replace.

In the wastewater purification system equipped with the above components, in order to disinfect and cleanse the wastewater, the maximum amount of time and the amount of exposure to sunlight is inoculated, and the microorganisms, especially EM microorganisms, useful for the purification are inoculated to purify the water. In order to help the microorganisms to activate, the exposure time to the air is maximized to allow a large amount of oxygen to be supplied.

The inlet 10 is the first inlet for purification of wastewater such as sewage or industrial wastewater, and is introduced using a motor 11 that operates with electrical energy generated by a solar cell.

Here, the wastewater of the sewage or factory is to be stored in the wastewater storage unit 100 temporarily before being introduced into the inlet 10 immediately before being discharged and without being directly discharged into the river or river, where the wastewater to a certain level. It is preferable to purify the inflow to the inlet (10).

That is, the waste water storage unit 100, as shown in Figures 3 and 4, the granulation settling tank 101 and the plastic bag for collecting relatively large grains, such as boulder and cement debris mixed with the waste water Floating sieve (102) for collecting the dirt floating on the water, such as styrofoam pieces, and the relatively small and heavy boulder or cement debris, etc. that were not collected in the grain settling tank 101 due to the flow rate of the incoming wastewater Grain collection unit 103 for moving along the bottom of the photograph to be collected and removed, a plurality of filters 104 for filtering the waste water first, and the waste water filtered by the filter 104 and collected in the collecting section Is composed of a discharge port 105 to be discharged through the motor (11).

The electric energy supplied to the motor 11 may be obtained by the hydrophobic power generator 90 generated by the flow rate of the flowing purified water, as shown in FIG. 11.

As shown in FIG. 2, the inlet part 10 includes a microbial inoculation part 12 and a precipitate removing part 13.

The microorganism inoculation unit 12 supplies and inoculates the stored microorganisms automatically or semi-automatically every time the wastewater flows along the passage to allow the wastewater to be purified by the primary purified water and flow at the same time.

The sediment removal unit 13 serves to allow the additives mixed in the wastewater introduced by the motor 11 to be precipitated and to remove the sediment and to collect a sample for analysis of the composition of the wastewater. It is also possible for the outer wall to be made of transparent glass windows for viewing from the outside.

As described above, the primary purified water purified in the inlet 10 moves to the settling unit 20 for sedimenting other precipitates mixed therein.

As shown in FIG. 5, the sedimentation unit 20 includes a plurality of sedimentation chambers 21 so that the precipitate mixed in the primary purified water coming from the inlet 10 may be precipitated through a plurality of steps. It plays a role.

Therefore, in order to precipitate and remove the precipitate mixed in the primary purified water, the settling chamber 21 of the settling unit 20 includes a settling membrane 23, a switch 25, and a separate settling tank 22.

The sedimentation membrane 23 is preferably a concave shape for easy discharge after sedimentation as a place where the precipitate is precipitated.

In addition, the precipitation membrane 23 is preferably provided below the inlet in the precipitation chamber 21 in consideration of the inflow state of the primary purified water.

The switch 25 is installed in the middle portion of the precipitation membrane 23 is installed to be separated from the bottom serves to discharge the precipitate precipitated on the precipitation membrane 23 to the sedimentation precipitation tank 22.

Here, in order to be able to visually check the precipitate deposited on the precipitation membrane 23, the sight glass 27 is provided in the precipitation membrane 23 portion of the precipitation chamber 21.

Therefore, the operator checks the state of the precipitate precipitated in the precipitation membrane 23 through the see-through window 27, and then open the switch 25 to be discharged.

The sediment discharged through the opening of the switch 25 is accumulated in the sedimentation settling tank 22.

Here, the separable sedimentation tank 22 is a container that can be separated after pulling in a sliding manner, if sediment accumulates therein, the operator may pull it forward to separate and then throw the sediment into another container on the outside.

As described above, the primary purified water precipitated in a plurality of stages in the plurality of settling chambers 21 moves to the filter unit 30.

As illustrated in FIG. 6, the filter unit 30 includes a plurality of filtration chambers 32, each of which has an inlet 31, a plurality of filters 33, and an outlet 34. , The discharge induction part 35, the induction valve 36 and the temporary storage 37 is provided.

As described above, the inlet 31 allows the primary purified water discharged from the settling unit 20 to flow into the filtration chamber 32.

The filter 33 is provided in plural in each filtration chamber 32, to filter the fine precipitates mixed in the introduced primary purified water in a number of stages.

In addition, a lower portion of the filtration chamber 32 is provided with a discharge port 34 so that the precipitates mixed therein are precipitated and discharged before the primary purified water introduced into the filter is filtered. Open or closed by operation).

Here, an induction valve for selectively introducing and blocking the primary purified water into a plurality of filtration chambers 32 in the middle of the induction furnace for guiding the primary purified water from the sedimentation unit 20 to the filter unit 30 ( 36) are installed.

That is, in order to shut off the supply of purified water to clean any one of the plurality of filtration chambers 32 or replace the filter 33, the corresponding induction valve 36 is locked, but the other filtration chambers 32 The induction valve (36) is placed in the open state to allow the purified water to be continuously supplied, such that the induction valve (36) is selectively opened or locked.

In other words, as shown in FIG. 6, when the filtration chamber 32 on the left side is cleaned and repaired, the related induction valve 36 is closed and the induction valve 36 of the filtration chamber 32 on the right side is closed. By opening), although one side is closed, the purified water is continuously introduced into the filter unit 30 because the other side is open.

The temporary storage 37 is a place for temporarily storing the purified water filtered by the filter 33 before it is discharged.

Therefore, when the purified water filtered into the temporary storage 37 is filled and automatically flows to the discharge guide unit 35 to be described later.

The discharge guide unit 35 serves to discharge the purified water stored in the temporary storage 37 to the outside.

As described above, the primary purified water filtered by the filter unit 30 moves to the fountain 40 as illustrated in FIG. 7.

The fountain 40 is composed of a fountain 41 and the pedestal 42.

The fountain 41 serves to purify the primary purified water filtered by the filter unit 30 so that the primary purified water rises and falls off to purify the secondary purified water through sunlight and air.

When the primary purified water falls, a wide water wall is formed, and at this time, an excessive amount of sunlight and air (oxygen) are supplied to the water wall to activate microorganisms, thereby further purifying the primary purified water.

The pedestal 42 serves to collect and discharge secondary purified water falling from the fountain 41, and a groove 43 is formed at the outermost side thereof to collect and discharge secondary purified water falling from the fountain 41. .

Here, the pedestal 42 of the fountain 40 is made to be a step-down step toward the outside so that the secondary purified water receives the maximum of sunlight and air to be naturally purified.

That is, the pedestal 42 gives an inclination lowering toward the outside, and by installing a reverse memory stepped protrusion 44 protruding outwardly around its circumference, the secondary purified water receives sunlight and air by increasing the contact area of the water surface. Received more and can be purified naturally.

In addition, due to the reverse memory type step (44), the lower portion thereof to form a space for trapping the air (oxygen) when the secondary purified water flows, thereby further purifying the secondary purified water by the trapped air It is also possible.

Secondary purified water purified by the fountain 40 as described above moves to the soil filter unit 50 as shown in FIG.

The soil filter unit 50 is placed by placing a plurality of soil dump 56 56 inoculated with microorganisms in the net 53 so that the secondary purified water discharged from the fountain 40 passes through the soil dump 56 It serves to naturally purify the tertiary purified water, consisting of a number of stages, and consists of a temporary storage 52 and the filtering unit 54.

The temporary storage 52 is composed of a front wall 52-1, a rear wall 52-2 and a side wall 52-3 to temporarily store the secondary purified water discharged from the fountain 40 to filter the filter ( 54).

That is, the secondary purified water in the temporary storage 52 is introduced through the upper portion of the front wall 52-1, as shown in Figure 9, and then through the lower portion of the rear wall 52-2 By allowing it to be discharged, the secondary purified water passes through the soil dump 56 to naturally purify.

The filtering unit 54 is filtered through the soil dump 56 while moving the secondary purified water discharged from the temporary storage 52 and at the same time to be purified by the tertiary purified water.

The tertiary purified water purified by the soil filter unit 50 as described above moves to the natural purifier filling unit 55 as shown in FIG. 10.

The natural purifier filling part 55 is provided with a sand filling part 55-1, a charcoal filling part 55-2, and a gravel filling part 55-3, and the third filter is introduced from the soil filter part 50. The purified water passes through the sand filling unit 55-1, the charcoal filling unit 55-2 and the gravel filling unit 55-3, and serves to purify once again.

Here, the sand filling unit 55-1, the charcoal filling unit 55-2, and the gravel filling unit 55-3 may be provided in a stepwise manner to smoothly flow the tertiary purified water.

As described above, the tertiary purified water naturally purified by the natural purifier filling unit 55 moves to the soil channel 60 as shown in FIG. 11.

The soil channel 60, as shown in Figure 12, the soil block 65, which is a mixture of microorganisms and soil is put into the mesh 63 to the hook 64 of the wall portion 61 and the bottom portion 62 Installed on the), and serves to purify the third purified water naturally purified by the soil filter unit 50 using the microorganisms and soil.

The soil channel 60 is operated by the flow rate of the fourth purification water to move to generate electricity to be provided with a hydropower generator 90 to supply to the motor (11).

Accordingly, the motor 11 may select and use the electric energy obtained by either the solar cell or the hydrophobic power generator 90 as described above.

The power generation using the hydropower generator 90 is a power generation method using the flow rate and low drop turbine by artificially inducing water in a small stream, and in the present invention, determines the waterway of the slanted slope along the soil channel 60 and the soil. By using the steepness and bend of the waterway portion 60, the drop or flow rate is obtained by the waterway.

Here, the soil channel 60 is also possible to install a narrow length of the bone and the valley to the maximum length per unit area in order to form a long channel so as to be the maximum purification length even in a narrow place, the hydropower generator By adjusting the number of installation of the soil block 65 in order to obtain a flow rate for the sufficient power generation by the (90) it is possible to adjust the width of the bone.

In addition, the soil channel 60 as described above can be installed in other places than the soil, such as cement or asphalt.

As described above, the fourth purified water purified by the soil channel 60 moves to the plant purification unit 70 as illustrated in FIGS. 13 and 14.

The plant purification unit 70 is formed by arranging a plurality of plant purification tanks 72 in which a plurality of storage tanks 71 and purification plants (aquatic plants) are planted stepwise, thereby discharging the fourth water discharged from the soil channel 60. The purified water flows down the cascade using plants to purify the fifth purified water.

The reservoir 71 or the plant purification tank 72 of the plant purification unit 70 is provided with a sluice gate 74 for discharging the purified water when cleaning the inside thereof.

In addition, the plant septic tank 72, the height adjuster 75 for controlling the amount of discharged fifth purified water in order to adjust the water level in the interior and the discharge amount of the fifth purified water flowing down, and the height Sliding guide portion 73 is provided with a guide hole (73-1) to guide the vertical movement of the adjuster 75, the fixture 76 and the fixing hole to be fixed when the height adjuster 75 is a predetermined height 77 is provided.

Therefore, by adjusting the height of the height adjuster 75 is to control the discharge amount of the fifth purified water moving from the previous plant purification tank 72 to the next plant purification tank 72.

And, by installing a wide upper portion of the height adjuster 75 to protrude to the front portion, when introduced into the storage tank 71 and the rear plant purification tank 72 from the plant purification tank 72 in the front, to form a water wall 5th By moving the purified water to maximum contact with sunlight and air to allow for natural purification.

The discharge unit 80 serves to temporarily store the fifth purified water discharged from the plant purification unit 70 and discharged to the widow.

Looking at the operating state of the waste water purification system using the soil, microorganisms and plants in accordance with an embodiment of the present invention made in the above configuration in order as follows.

1) First, the motor 11 is operated to purify wastewater such as sewage or industrial wastewater so that the wastewater flows into the inlet 10, and precipitates and removes the sediments contained therein. Let cleanse.

2) The first purified water purified in the inlet 10 is moved to the settling section 20 consisting of a plurality of settling chamber 21 to precipitate the precipitates mixed therein once again.

3) The primary purified water precipitated in a plurality of steps in the settling section 20 is moved to the filter section 30 for filtering.

4) The primary purified water filtered by the filter unit 30 is moved to the fountain unit 40 to be exposed to sunlight and air to activate microorganisms to naturally purify the secondary purified water.

5) The secondary purified water purified by the fountain 40 is moved to the soil filter unit 50 to be purified by the tertiary purified water through the soil.

6) The third purified water purified by the soil filter unit 50 is moved to the natural purifier filling unit 55 to be naturally purified once again.

7) The third purified water naturally purified by the natural purifier filling unit 55 is moved to the soil channel 60 to be purified by the fourth purified water through soil and microorganisms.

8) The fourth purified water purified by the soil channel 60 is moved to the plant purification unit 70 to be purified to the fifth purified water through the plants.

9) The fifth purified water purified and discharged from the plant purification unit 70 is temporarily stored in the discharge unit 80 and then discharged to the outside.

Although preferred embodiments of the present invention have been described above, the present invention is not limited to the above, and various modifications and changes can be made within the scope of the claims and the detailed description of the invention. Belongs to the scope of.

5: pollution detection device
10: inlet 11: motor
12: microorganism inoculation part 13: precipitate removal part
20: settling portion 21: settling chamber
22: sedimentation type sedimentation tank 23: sedimentation membrane
25: switchgear 27: viewing window
30: filter part 31: inlet
32: filtration chamber 33: filter
34: discharge port 35: discharge guide portion
36: induction valve 37, 52: temporary storage
40: fountain 41: fountain
42: base 43: groove
50: soil filter 52-1: front wall
52-2: rear wall 52-3: side wall
53, 63: net 54: filtering unit
56: soil dumpling 55: natural purifier filling
55-1: Sand Filling Unit 55-2: Charcoal Filling Unit
55-3: browning part 60: soil channel part
61: wall portion 62: bottom portion
64: Loop 65: Earth Block
70: plant purification unit 71: reservoir
72: plant purification tank 73: guide
73-1: Pilot 74: Sluice
75: height adjuster 76: fixture
77: fixing hole 80: discharge part
90: hydropower generator 100: wastewater storage unit
101: grain settling tank 102: float sieve
103: granule collection 104: filter
105: outlet

Claims (10)

In the wastewater purification system using soil, microorganisms and plants that purify wastewater using environment-friendly purification ability,
The waste water stored in the waste water storage unit 100 is introduced by using the motor 11 operating by the electric energy generated by the solar cell, and the microorganism inoculation unit 12 inoculating microorganisms into the introduced waste water is mixed with the waste water. An inlet part 10 having a sediment removal part 13 for sedimenting and removing the added additives and observing and collecting the sediment from the outside;
Precipitating unit 20 consisting of a plurality of sedimentation chamber 21 is provided with a separate sedimentation tank 22 for sedimentation and removal of the precipitate mixed in the primary purified water coming from the inlet 10;
The inlet 31 is provided with a plurality of inlets 31, a filtration chamber 32, and a plurality of filters 33 in the filtration chamber 32 to allow the primary purified water discharged from the precipitation unit 20 to enter. A filter unit 30 for filtering the primary purified water introduced from the 31;
The primary purified water filtered by the filter unit 30 is soared upwards to expand and fall to collect the secondary purification water to purify the secondary purified water through sunlight and air, and collect the secondary purified water falling from the fountain 41 A fountain 40 having a pedestal 42 for discharging;
A plurality of soil dumps 56 inoculated with microorganisms are placed in the net 53 to be purified by the third purified water while passing through the soil dumps 56 through the secondary purified water discharged from the fountain 40. Soil filter unit 50;
Natural purification to allow the third purified water introduced from the soil filter unit 50 to pass through the sand filling unit 55-1, charcoal filling unit 55-2 and gravel filling unit 55-3 Purifier filling part 55;
The soil block 65 is a mixture of microorganisms and soil is put into the mesh (63) and installed on the hook (64) of the wall portion 61 and the bottom portion 62 is purified by the natural purifier filler 55 A soil channel 60 for purifying the third purified water to the fourth purified water using microorganisms and soil;
Plant purification to purify the fourth purification water discharged from the soil channel 60 by using a plant by arranging a plurality of storage tanks 71 and a plurality of plant purification tanks 72 planted with purification plants stepwise. Part 70; And
The waste water purification system using soil, microorganisms and plants, characterized in that consisting of; discharge unit 80 for temporarily storing and discharging the fifth purified water discharged from the plant purification unit 70. The soil filter unit of claim 1, wherein the soil filter unit 50, the natural purifier filling unit 55, and the soil channel 60 to measure the degree of contamination to inform the replacement time of the filter, the soil dump and the soil block. Waste water purification system using soil, microorganisms and aquatic plants, characterized in that the sensing device (5) is provided. The waste water storage unit 100 of claim 1,
A grain settling tank 101 for collecting grains of boulder or cement debris mixed with waste water,
Float sieve (102) for collecting dirt floating on water such as plastic bags or strofoam,
Granule collection unit 103 for collecting and removing the granules that are not collected in the granule settling tank 101 by the inflow rate of the waste water is moved and collected along the inclined bottom portion,
A plurality of filters 104 for firstly filtering wastewater,
The waste water purification system using soil, microorganisms and water plants, characterized in that consisting of a discharge port 105 which is filtered by the filter 104 and the waste water collected in the water collecting unit is discharged through the motor (11). The method of claim 1, wherein the precipitation chamber 21 of the precipitation unit 20, the concave sedimentation membrane 23 to allow the precipitate is precipitated, and the precipitates that are settled in the middle portion of the precipitation membrane 23 Wastewater using soil, microorganisms and aquatic plants, characterized in that the switchgear 25 to be discharged to the sedimentation settling tank 22, and a sight window 27 for visually checking the precipitate deposited on the sedimentation membrane 23 Purification system. The method of claim 1, wherein the filter unit 30, the temporary storage 37 for temporarily storing the purified water filtered by the filter 33, and to guide the purified water stored in the temporary storage 37 to be discharged to the outside Soil, characterized in that each of the induction valve 36 is installed in the discharge guide portion 35 and the primary clarification water induction furnace is provided with a plurality of induction valves 36 for controlling the inflow and blocking of the primary clarified water, Wastewater purification system using microorganisms and plants. The method of claim 1, wherein the pedestal 42 of the fountain portion 40 is made of a stepped lower toward the outside, consisting of an inclined surface lowered toward the outside in a circumference protruding outward stepped step 44 Is installed, the outermost wastewater purification system using soil, microorganisms and plants, characterized in that the groove portion 43 is formed to collect and discharge the secondary purified water falling from the fountain (41). The method of claim 1, wherein the soil filter unit 50,
Temporary storage 52 consisting of the front wall (52-1), the rear wall (52-2) and the side wall (52-3) to temporarily store and discharge the secondary purified water discharged from the fountain 40,
The secondary purification water discharged from the temporary storage 52 is made of a filtering unit 54 to be filtered through the soil dump 56 while moving, the soil, microorganisms and myelin, characterized in that composed of a plurality of steps Wastewater purification system using. The method of claim 7, wherein the secondary purified water in the temporary storage 52 is introduced through the upper portion of the front wall 52-1, and then discharged through the lower portion of the rear wall 52-2. Waste water purification system using soil, microorganisms and plants. The soil and microorganism of claim 1, wherein the soil channel 60 includes a hydrophobic power generator 90 that operates by the flow rate of the fourth purified water flowing and generates electricity to supply the motor 1. And wastewater purification system using plants. The method according to claim 1, In order to adjust the discharge amount of the fifth purified water in the plant purification tank 72,
A height adjuster 75 for controlling the amount of the fifth purified water discharged therein, a sliding guide 73 provided with a guide hole 73-1 to guide the vertical movement of the height adjuster 75, and Soil water purification system using soil, microorganisms and plants, characterized in that the height adjuster 75 is provided with a fixture (76) and a fixing hole (77) to be fixed when the predetermined height.

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