KR101784886B1 - Continuous Filtration Apparatus using Distribution Chamber - Google Patents

Abstract

A continuous filtration apparatus using a distribution chamber, comprising: a filtration tank having a sand filtration layer at a predetermined height; A hopper having an upper surface opened to receive the sand of the sand filtration layer and a slope at a predetermined angle lower than the filtration tank; A distribution chamber installed at an upper portion of the hopper and having a plurality of distribution pipes arranged at equal intervals so that wastewater flowing from the inlet of the wastewater flows uniformly through the sand filtration layer; An air lift tube installed from the lower portion of the hopper to the upper portion of the reverse osmosis chamber to suck and feed the sand of the sand filtration layer; And a reverse osmosis chamber provided to supply sand to the sand filtration layer by cleaning the sand fed through the air lift pipe and supplying the ozone into the distribution chamber of the filtration apparatus to supply the same to the plurality of distribution pipes. The waste water supplied to the distribution chamber flows in the form of swirls to filter off the contaminants such as the gravel contained in the waste water and the distribution pipe is inclined vertically and horizontally toward the sand filtration layer So that the wastewater can be widened and the wastewater can be evenly sprayed to the entire area of the sand filtration layer accommodated in the hopper.

Description

[0001] Continuous Filtration Apparatus using Distribution Chamber [

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a continuous filtration apparatus using a distribution chamber, and more particularly, to a continuous filtration apparatus using a distribution chamber for purifying contaminated wastewater by bringing contaminated wastewater into contact with a filter medium while raising from bottom to top.

In general, an upflow type sand filter has a small installation area, and an upflow type cleaning method is adopted for cleaning the filter material (sand), so that the sand can be continuously cleaned at the same time as filtration. Recycling and desalination industries.

1 is a view showing a conventional upflow sand filter.

As shown in FIG. 1, the upflow type sand filter has a sand filtration layer 1a formed therein, and the wastewater having passed through the sand filtration layer 1a is moved upward, A filtration tank 1 in which a treatment water pipe 1c is formed at an upper portion so as to be overflowed in a filtration tank 1b and a wastewater introduced into the filtration tank 1 through an inflow pipe 2a is introduced into a sand filtration layer 1a An air lift tube 3 in the form of a double tube which is vertically installed in the filtration tank 1 and injects air supplied from an air compressor (not shown) to lower the contaminated sand, .

A cleaning water chamber 4 installed at the upper end of the air lift tube 3 to collect the washing water cleaned by the firstly cleaned sand through the air lift tube 3, A washing water pipe (5) having one end connected to the washing water chamber (4) and the other end connected to the outside so as to discharge the water; a first washing unit that is located below the washing water chamber (4) And a sand cleaning section 6 in which a zigzag flow path 6a for secondary cleaning is formed.

The sand cleaning section 6 is made of a rubber material, and the channel areas of the upper and lower portions are the same.

In the upflow type sand filter constructed as described above, the wastewater supplied through the inflow pipe 2a is distributed uniformly over the entire sand filtration layer 1a by the distributor 3 installed in the sand filtration layer 1a, At this time, the pollutant SS is collected by the sand filtration layer 1a, and the filtered water moves upward and overflows in the treatment water ware 1b and is discharged to the outside through the treatment water pipe 1c.

The contaminated sand, which has trapped the polluted material by filtering the wastewater, filters the wastewater into the compressed air injected from the outer tube (3a) of the air lift tube (3) The upward movement of the contaminated sand, water, and air rising through the inner cylinder 3b at different speeds is caused by the upward flow of the compressed air from the outer cylinder 3a of the inner cylinder 3b through the inner cylinder 3b The pollutants are separated from the contaminated sand and gathered in the washing water chamber 4.

The sand collected in the washing water chamber 4 is further uniformly dispersed in the upper cone 6b while falling downward through the staggered flow path 6a of the sand washing section 6, As shown in FIG.

In addition, the treated water flowing into the washing water chamber 4 together with the sand is discharged to the outside through the washing water pipe 5.

For example, Patent Document 1 below discloses an " upflow sand filter ".

In the upflow type sand filter according to Patent Document 1, a sand filtration layer is formed therein, and the wastewater passing through the sand filtration layer is moved upward, A filtration tank formed on the filtration tank, and an injection unit including an inlet pipe and a distribution pipe for injecting the wastewater flowing into the filtration tank through the inlet pipe into the sand filtration layer.

An air lift pipe vertically installed in the filtration tank and spraying air supplied from the air compressor to lower side to raise contaminated sand; an air lift pipe installed at an upper end of the air lift pipe, And a reverse osmosis chamber in which the sand and the contaminated water collect.

A backwash water pipe communicating with the reverse osmosis chamber at one end to discharge treated water collected in the reverse osmosis chamber and exposed to the outside at the other end and a backwash water pipe located at the lower side of the reverse osmosis chamber, And a sand cleaning section in which a zigzag flow path for cleaning is formed.

Korean Patent Registration No. 10-1158765 (registered on June 15, 2012) Korean Patent Registration No. 10-1224510 (Registered on January 15, 2013)

However, in the upflow type filter according to the related art, since the distributor to which the sewage is introduced is installed in the lower part of the sand filtration layer, the sewage is not uniformly supplied to the sand filtration layer in proportion to the area of the sand filtration layer, and a large number of distributors There is a problem that the filtration efficiency is deteriorated due to the drift phenomenon when the waste water is discharged.

In addition, due to the drift phenomenon, only a part of the sand filtration layer is partially circulated, or only the center portion is depressed or circulated to contaminate the sand filtration layer, and the filtration function is deteriorated due to the mud effect due to the floating matter (turbidity) There was a problem.

In addition, the air lift tube transfers the sand to the upper end of the air lift tube by using the air pressure. The sand and the turbidity (especially mud, clay, microorganisms, etc.) as the filter medium are not well separated, So that the filtration efficiency is lowered.

On the other hand, the backwash flow rate should be adjusted according to the inflow amount of wastewater or the contamination concentration of the wastewater. The conventional backwash flow rate adjustment method can not cope with a change in flow rate by manually adjusting the backwash water pipe in the cleaning chamber, Since the polluted filter medium is caused to proliferate as a second pollutant factor in the treated water, disinfection and sterilization treatment of the filter medium are difficult without a separate facility.

In addition, the conventional upflow type filter is provided with a separate reaction tank on the upper part of the filter in order to feed the coagulant (lactic acid anhydride, PAC, ferric chloride, etc.) for advanced treatment such as phosphorus (TP) A mixer and the like have to be added.

In addition, in the conventional upflow type filter, since the filter material cleaning unit is composed of a spiral-shaped inflow pipe or a labyrinth structure for gravity-type washing, a height space of the upper part is required, and in order to facilitate the downward center movement of the lower- A downward biased movement of the filter medium is required. Therefore, the height of the conventional upflow type sand filter is required to be high, the structure of the filtration device is increased, and the installation and manufacturing costs are increased.

SUMMARY OF THE INVENTION An object of the present invention is to provide a continuous filtration apparatus using a distribution chamber in which wastewater supplied from a distributor is uniformly supplied into a filtration layer.

According to an aspect of the present invention, there is provided a continuous filtration apparatus using a distribution chamber, comprising: a filtration tank having a sand filtration layer at a predetermined height; A hopper having an upper surface opened to receive the sand of the sand filtration layer and a slope at a predetermined angle lower than the filtration tank; A distribution chamber installed at an upper portion of the hopper and having a plurality of distribution pipes arranged at equal intervals so that wastewater flowing from the inlet of the wastewater flows uniformly through the sand filtration layer; An air lift tube installed from the lower portion of the hopper to the upper portion of the reverse osmosis chamber to suck and feed the sand of the sand filtration layer; A reverse osmosis chamber installed to clean the sand fed through the air lift tube and supply it to the sand filtration layer; And a control unit.

Wherein the distribution chamber has a hollow cylindrical shape having a predetermined diameter so as to fill the wastewater flowing through the inlet of the waste water inlet; One or more fluid inlet ports connected to the chamber body such that wastewater flows into the chamber body in a cyclone form; A diluter installed inside the chamber body to move the contaminants contained in the wastewater introduced through the wastewater inlet to the bottom surface of the chamber body; And a plurality of distribution pipes installed so that the wastewater filled in the chamber body is uniformly sprayed.

The distribution pipe having a first connection pipe connected to the inside of the hopper inside the distribution chamber; And a second connection pipe which is inclined at the same angle as the hopper and is integrally connected to the first connection pipe so as to be twisted toward the sand filtration layer, wherein the first connection pipe and the second connection pipe And a plurality of spray holes are formed so as to discharge the wastewater radially toward the sand filtration layer.

Wherein the distribution chamber includes a contaminant transfer pipe installed to be discharged from the filtration tank, the contaminants accumulated in the chamber body, A sewage discharge pipe installed to discharge the sewage filled in the chamber body; And an open / close valve installed to control the opening and closing of the sewage discharge pipe.

Wherein the reverse osmosis chamber comprises: a first chamber having a first swash plate installed to allow the sand fed through the air lift tube to fall; A first diaphragm having an opening opened to allow sand in the first chamber to be transferred; A second chamber provided with a second diaphragm so as to be spaced apart from the first diaphragm, an impeller rotated by a motor so that the sand transferred through the opening is evenly distributed, and a sand hole formed in the bottom to drop sand; A third chamber formed by a third partition provided between the first partition and the second partition; A fourth chamber in which a second swash plate is installed so that the swirling flow occurs between the second diaphragm and the fourth diaphragm spaced apart; A contaminant transfer pipe installed in the chamber body so as to transfer impurities accumulated in the chamber body to the fifth chamber; And a spiral orifice holder having a spiral orifice formed therein for discharging the washing water and discharging the contaminants fed by the contaminant transfer pipe according to the washing water level of the filtration tank.

As described above, according to the continuous filtration apparatus using the distribution chamber according to the present invention, as the wastewater is supplied to the distribution chamber of the filtration apparatus, wastewater of uniform amount and pressure is supplied to the plurality of distribution pipes, The distribution pipe is installed to be inclined vertically and horizontally toward the sand filtration layer to enlarge the discharge area of the wastewater, So that the effect that the wastewater can be uniformly sprayed to the entire area of the sand filtration layer accommodated in the hopper can be obtained.

Further, according to the continuous filtration apparatus using the distribution chamber according to the present invention, since the coagulant is introduced into the distribution chamber together with the wastewater, phosphorus (TP) or turbidity included in the wastewater can be easily removed and the distribution chamber serves as a reaction tank Accordingly, it is not necessary to provide a separate reaction tank, and the structure of the filtration apparatus can be manufactured more easily, and a sterilizing agent can be added to the reverse osmosis chamber to sterilize the virus contained in the filter medium.

1 is a cross-sectional view of a conventional upflow filter,
FIG. 2 is a cross-sectional view illustrating a continuous filtration apparatus using a distribution chamber according to a preferred embodiment of the present invention. FIG.
3 is a cross-sectional view illustrating a continuous filtration apparatus using a distribution chamber according to another preferred embodiment of the present invention.
FIG. 4 is a three-dimensional view showing a distribution chamber of a continuous filtration apparatus using a distribution chamber according to a preferred embodiment of the present invention,
5 is a plan view of a dispensing chamber of a continuous filtration apparatus using a dispensing chamber according to an embodiment of the present invention,
FIG. 6 is a three-dimensional view showing a water-repellent chamber of a continuous filtration apparatus using a distribution chamber according to a preferred embodiment of the present invention; FIG.

Hereinafter, a continuous filtration apparatus using a distribution chamber according to a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings.

FIG. 2 is a cross-sectional view illustrating a continuous filtration apparatus using a dispensing chamber according to a preferred embodiment of the present invention, and FIG. 3 is a cross-sectional view illustrating a continuous filtration apparatus using a dispensing chamber according to another preferred embodiment of the present invention.

The continuous filtration apparatus using the distribution chamber according to the preferred embodiment of the present invention includes a filtration tank 10 having a sand filtration layer 11 formed therein at a predetermined height and an upper surface opened to receive the sand of the sand filtration layer 11 The hopper 20 is installed at an upper portion of the hopper 20 so that the wastewater flowing from the wastewater inlet 33 flows into the sand filtration layer 11, A distribution chamber 30 in which a plurality of distribution pipes 35 are equally spaced so as to uniformly distribute the wastewater through the hopper 20 to the bottom of the hopper 20 so as to suck and feed the sand of the sand filtration layer 11, An air lift tube 40 installed up to the upper portion of the chamber 50 and a reverse osmosis chamber 50 installed to supply the sand filtration layer 11 with the sand pushed along the air lift tube 40, .

The continuous filtration apparatus using the distribution chamber according to the embodiment of the present invention uniformly supplies the wastewater to the sand filtration layer 11 uniformly to improve the purification efficiency of the wastewater. That is, the hopper 20 and the distribution chamber 30 are installed so that the wastewater is uniformly distributed in the sand filtration layer 11.

As the filter medium in the present invention, sand, anthracite, artificial filter media, activated carbon, zeolite, ferrous manganese material, ion exchange resin, etc. may be used, and these filter media may be mixed with each other.

The hopper 20 is installed at a lower portion of the sand filtration layer 11 and has a narrow bottom portion and a wide top portion. This is to ensure that the wastewater is evenly distributed through the distribution chamber 30 so that sand as a filter medium does not become entangled or aggregated.

That is, the hopper 20 forms a narrow space in the lower portion to accommodate a small amount of sand and a wide upper portion to accommodate a large amount of sand. The filtration tank 10 is provided with a discharge pipe 12 through which purified water purified by sand, which is a filter medium, is discharged.

The hopper 20 is opened at an upper portion and is installed at an inclination at a predetermined angle.

A dispensing chamber 30 for uniformly discharging wastewater is installed in the upper part of the hopper 20.

The distribution chamber 30 includes a chamber body 31 having a hollow cylindrical shape having a predetermined diameter, a wastewater inlet 33 connected to supply wastewater into the chamber body 31, And a distribution pipe 35 for discharging the wastewater filled in the chamber body 31 to the sand filtration layer 11 evenly.

The distribution chamber 30 serves as a reaction tank for advanced treatment of wastewater (such as total phosphorus treatment or reuse water treatment). That is, a certain amount of a coagulant for removing turbidity and total phosphorus (T-P) or nitrogen (N) is introduced into the sump inlet 33.

The water and the coagulant introduced into the distribution chamber 30 through the wastewater inlet pipe 33 and the coagulant flow into the distribution chamber 30 through the wastewater inlet pipe 33, Lt; / RTI >

Since the wastewater and the coagulant are circulated in the cyclone form by the reducer 34, the reaction between the wastewater and the coagulant becomes more smooth.

FIG. 4 is a three-dimensional view showing a distribution chamber of a continuous filtration apparatus using a distribution chamber according to a preferred embodiment of the present invention, and FIG. 5 is a cross-sectional view illustrating a distribution chamber of a continuous filtration apparatus using a distribution chamber according to an embodiment of the present invention. Fig.

A plurality of legs 32 having a predetermined height are fixed to the bottom surface of the chamber body 31 and one or more water inlet pipes 33 are connected to the chamber body 31. As shown in FIGS. 4 and 5, two inlet pipes 33 are connected to the chamber body 31, and two inlet pipes 33 are connected to the chamber body 31 by one side.

This is to allow the sewage introduced through the sewage inlet 33 to flow into the cyclone form. This ensures that the contamination or foreign matter contained in the wastewater is collected in the center while circulating in a cyclone shape. Thus, the contaminants or foreign matter collected at the center of the chamber body 31 are accumulated at the center of the chamber body 31.

In addition, although two poured water inlet pipes 33 are shown as installed, one pouched water inlet pipe 33 can be installed. It is a matter of course that the single inlet 33 of the wastewater is biased to one side of the chamber body 31.

In addition, a reducer 34 is installed inside the chamber body 31 so that wastewater flows into the cyclone. The reducer 34 has a larger diameter at its upper portion and a smaller diameter at its lower portion.

As described above, the reducer 34 allows the wastewater flowing into the wastewater inlet 33 to flow in a cyclone form. That is, the flow velocity of the wastewater is allowed to flow more quickly so that the contaminants or foreign matter contained in the wastewater can be accumulated on the center bottom surface of the chamber body 31.

A plurality of distribution pipes 35 for supplying wastewater to the sand filtration layer 11 are installed in the distribution chamber 30. It is needless to say that about 6 to about 12 such distribution pipes 35 are installed, and the number of installed distribution pipes 35 can be increased or decreased as needed.

The distribution pipe 35 includes a first connection pipe 36 disposed inside the chamber body 31 toward the hopper 20 and a second connection pipe 36 extending vertically from the front end of the first connection pipe 36 at a predetermined angle And a second connection pipe (37) which is twisted at a predetermined angle with respect to the first connection pipe (37).

As shown in FIG. 2, the first connection pipe 36 is inclined at a predetermined angle with respect to the horizontal direction, or the first connection pipe 36 is installed in a horizontal direction .

In addition, the second connection pipe 37 is installed so as to be inclined at the same angle as the hopper 20, and is twisted at a predetermined angle when viewed from the side.

This is to allow the wastewater discharged through the distribution pipe 35 to be ejected more evenly to the sand filtration layer 11.

That is, the first connection pipe 36 and the second connection pipe 37 are inclined at different angles so that wastewater is more widely distributed in the sand filtration layer 35.

In addition, a plurality of spray holes through which the wastewater supplied from the chamber body 31 is sprayed are formed in the distribution pipe 35.

The spray holes may be formed in the first connection pipe 36 and the second connection pipe 37, and the spray holes 35 may be formed horizontally or vertically as well as at a plurality of inclined angles.

The chamber body 31 is also provided with a waste water discharge pipe 38 for discharging waste water at the time of cleaning. The wastewater discharge pipe (37) is provided with an on-off valve (39) for controlling the flow of wastewater. That is, the on-off valve 39 is opened when the wastewater is to be discharged, and the wastewater discharge pipe 38 is blocked when the wastewater is not discharged.

A strainer 31a is provided on the bottom surface of the chamber main body 31 to filter foreign substances or contaminants contained in the wastewater. The strainer 31a is formed as a pair, and the pair of strainer 31a are connected to each other And is installed in the chamber main body 31. As shown in FIG.

That is, the chamber body 31 is provided with a hole (not shown) for installing the strainer 31a, and is detachably installed from the chamber body 31 as the strainer 31a is engaged or disengaged from each other.

An air lift tube 40 is installed on the lower side of the distribution chamber 30 to prevent the sand, which is a filter medium, from being entangled or bunched. An air supply pipe 41 is installed in the filtration tank 10 and an air compressor (not shown) is connected to the air supply pipe 41 to discharge high pressure air.

The air lift tube 40 is installed so as to reach a predetermined height from the bottom surface of the filtration tank 10 to the reverse osmosis chamber 50. The high-pressure air supplied from the air supply pipe 41 feeds sand and wastewater under the hopper 20 to the reverse osmosis chamber 50.

A cover (42) is installed on the air lift tube (40) so as to prevent sand and wastes from being scattered. The cover 42 is formed in a substantially Λ shape.

The reverse osmosis chamber 50 is formed by cleaning the sand as a filter medium which has been transported by the air lift pipe 40 and then supplying the sand back to the sand filtration layer 11 and washing it in the filtration tank 10 according to the level of the wash water Water is discharged to maintain proper water level.

The reverse osmosis chamber 50 includes a first chamber 51 in which the air lift tube 40 is installed, a second chamber 55 through which the washed sand is discharged, a third chamber 55 installed at one side of the second chamber 55, A fourth chamber 64 in which the second swash plate 66 is installed to adjust the level of the washing water and a fifth chamber 67 in which the contaminant transfer pipe 68 and the spiral orifice ware 69 are installed, .

An air lift pipe 40 is installed in the first chamber 51 and a first swash plate 52 inclined at a predetermined angle is installed so that the sand fed by the air lift pipe 40 can flow down .

A first diaphragm 53 is vertically provided on one surface of the first diagonal plate 52 and a second diagonal plate 52 is formed on the first diaphragm 52. The first diagonal plate 52 is provided with a first diaphragm 53, An opening 54 having a predetermined size is formed so as to be moved to the chamber 55.

The opening 54 is formed so as to be opened so that the second chamber 55 can be moved to the first chamber 51.

The second chamber 55 includes a second diaphragm 60 disposed at a position spaced apart from the first diaphragm 53 and a third diaphragm 60 disposed between the first diaphragm 53 and the second diaphragm 60 And an impeller 57 is provided in the second chamber 55 to be rotated by the motor 56 so that the sand is evenly distributed.

The second chamber 55 is filled with a sterilizing agent for sterilizing viruses and the like. As this bactericide, sodium hypochlorite and the like are used. This makes it possible to kill the remaining virus attached to the filter medium, thereby preventing the second contamination of the treated water, and sterilizing the reverse water.

In the second chamber 55, a sand hole 58 is formed to allow the sand to escape. A third chamber 62 is formed by the third partition plate 63 at one side of the second chamber 55 and a third chamber 62 is formed at the second partition plate 60 by the fourth chamber 64 from the third chamber 62. [ The open channel 61 is formed.

The fourth chamber 64 is formed by a fourth diaphragm 65 spaced apart from the second diaphragm 60 by a predetermined distance. The fourth chamber 64 is formed with a predetermined angle A second swash plate 66 is provided.

The fourth diaphragm 65 is installed from one side of the reverse osmosis chamber 60 to the upper end of the second diagonal plate 66 and is separated from the fourth chamber 64 by the fourth diaphragm 65, (67) are formed.

The fifth chamber 67 is provided with a contaminant transfer pipe 68 through which the accumulated accumulation of contaminants is transferred to the chamber body 31. The washing water is discharged according to the washing water level of the filtration tank 10, 68 is provided with a spiral orifice wear 69 for discharging the impregnated matter.

The spiral orifice wear 69 is formed in a hollow cylindrical shape and a spiral hole 70 formed in a spiral shape is formed in the spiral orifice wear 69. A reverse discharge water pipe 71 is connected to the spiral orifice wear 69 do.

The operation of the continuous filtration apparatus using the distribution chamber according to the preferred embodiment of the present invention will be described in detail with reference to FIGS. 1 to 3. FIG.

1 to 3, the continuous filtration apparatus using the distribution chamber according to the embodiment of the present invention is filled with the sewage in the distribution chamber 30 through the sewage inlet 33.

One or two water inlet pipes 33 are installed in the distribution chamber 30 and these water inlet pipes 33 are connected to the distribution chamber 30 in a state of being offset to one side. The wastewater flows into the distribution chamber 30 while rotating in a spiral form.

Thus, the wastewater flows into the distribution chamber 30 while being rotated, and is introduced into the chamber body 31 while being rotated in the form of a spiral by the reducer 34 installed in the chamber body 31. Accordingly, the contaminants such as soil and the like that are introduced together with the wastewater are moved to the center where the pressure of the vortex is lowest, and are accumulated on the bottom surface of the chamber body 31.

Since the pressure is maintained by the incoming wastewater in the distribution chamber 30, the contaminants accumulated on the bottom surface of the distribution chamber 30 are compressed by the water pressure into the fifth chamber 67 through the contaminant transfer pipe 68 And the contaminants are discharged through the reverse water discharge pipe 71 together with the reverse water wash.

Alternatively, a valve or the like for discharging the contaminants may be provided in the contaminant transfer pipe 68 to discharge the contaminants as necessary.

The distribution chamber 30 is filled with wastewater, and the wastewater filled in the distribution chamber 30 is discharged to the sand filtration layer 11 through the distribution pipe 35.

At this time, the chamber main body 31 is sprayed with sewage through the distribution pipe 35 in a state in which the wastewater flowing from the wastewater inlet pipe 33 is filled. The wastewater filled in the chamber body 31 is supplied to approximately six to sixteen distribution pipes 35 with a uniform amount of wastewater and uniform pressure.

That is, the wastewater is supplied in a state filled in the chamber body 31 having a predetermined space without being directly distributed in the wastewater inlet pipe 33, so that wastewater of a uniform amount and pressure is supplied.

The wastewater supplied to the distribution pipe 35 in this way is supplied to the first connection pipe 36 and the second connection pipe 37.

The wastewater supplied to the first connection pipe 36 and the second connection pipe 37 is sprayed to the sand filtration layer 11 through the spray hole.

While the first connecting pipe 36 of the distribution pipe 35 is connected to the sand filtration layer 11 in a downwardly inclined manner in the distribution chamber 30 and the second connecting pipe 37 is connected to the sand filtration layer 11 And is inclined at a predetermined angle with respect to the first connection pipe 36 while being inclined downward.

The wastewater supplied from the distribution chamber 30 is ejected at a high pressure along the circumferential direction of the lower portion of the sand filtration layer 11 and the hopper 20. [

The wastewater is ejected toward the sand filtration layer 11 by the inclined height of the first connection pipe 36. The wastewater is radially ejected to the sand filtration layer 11 through the ejection hole of the first connection pipe 36.

The wastewater supplied to the second connection pipe 37 is sprayed toward the sand filtration layer 11 by the inclined height of the second connection pipe 37. The wastewater is discharged to the end of the second connection pipe 37, To the sand filtration layer (11).

Since the wastewater fed to the distribution pipe 35 is supplied to the distribution chamber 30 in a full state, the wastewater of the same amount and pressure is supplied to each of the distribution pipes 35. Thereby preventing the drift phenomenon in which different pressures and amounts are ejected from the respective distribution pipes 35.

As described above, the sand filtration layer 11 is supplied with the wastewater filled in the distribution chamber 30, so that the filling pipe 35 can be supplied with the wastewater of a uniform amount and pressure.

Since the wastewater discharged from the distribution pipe 35 is supplied to the sand filtration layer 11 by the inclined height of the first connection pipe 36 and the second connection pipe 37, The sewage is sprayed to a height of.

Since the first connection pipe 36 and the second connection pipe 37 are formed with a large number of spray holes, the wastewater is sprayed toward the sand filtration layer 11.

The wastewater is uniformly distributed to the sand filtration layer 11 so that the wastewater is uniformly supplied to the sand filtration layer 11 so that the sand around the distribution pipe 35 is not entangled or aggregated.

Further, the hopper 20 is installed adjacent to the outer periphery of the distribution pipe 35, so that the phenomenon such as entanglement of the sand as the filter material does not occur due to the wastewater ejected from the distribution pipe 35, And a part of the filter material is circulated while being moved.

Although the present invention has been described in detail with reference to the above embodiments, it is needless to say that the present invention is not limited to the above-described embodiments, and various modifications may be made without departing from the spirit of the present invention.

10: Filtration tank 11: Sand filtration layer
12: Exhaust pipe 20: Hopper
30: dispensing chamber 31: chamber body
32: Bridge 33: Osuyu entrance
34: Reducer 35: Distribution pipe
36: first connection pipe 37: second connection pipe
38: sewage discharge pipe 39: opening / closing valve
40: air lift tube 41: air supply pipe
42: cover 50: reverse osmosis chamber
51: first chamber 52: swash plate
53: opening 55: second chamber
56: motor 57: impeller
58: Sand hole
62: Third chamber 68: Contamination conveying pipe
69: Spiral orifice wear 70: Spiral hole
71 station

Claims (5)

A filtration tank in which a sand filtration layer is installed at a predetermined height;
A hopper having an upper surface opened to receive the sand of the sand filtration layer and a slope at a predetermined angle lower than the filtration tank;
A chamber main body having a hollow cylindrical shape is installed in the upper part of the hopper so as to fill the wastewater flowing through the inlet of the wastewater and a plurality of distribution pipes are installed at regular intervals so that the wastewater flowing into the sand filtration layer is uniformly sprayed chamber;
An air lift tube installed from the lower portion of the hopper to the upper portion of the reverse osmosis chamber to suck and feed the sand of the sand filtration layer;
And a reverse osmosis chamber installed to clean the sand fed through the air lift tube and supply the sand to the sand filtration layer,
Wherein the wastewater inlet is tangentially connected to the chamber body of the dispensing chamber,
The distribution pipe having a first connection pipe connected to the inside of the hopper inside the distribution chamber; And a second connection pipe which is inclined at the same angle as the hopper and is integrally connected to the first connection pipe so as to be twisted toward the sand filtration layer, wherein the first connection pipe and the second connection pipe Wherein a plurality of spray holes are formed to discharge wastewater radially toward the sand filtration layer. The method according to claim 1,
Wherein the dispensing chamber includes at least one sump inlet connected to the chamber body such that wastewater enters the chamber body in a cyclone form;
A diluter installed inside the chamber body to move the contaminants contained in the wastewater introduced through the wastewater inlet to the bottom surface of the chamber body;
And a plurality of distribution pipes installed so that wastewater filled in the chamber body is uniformly sprayed. delete The method according to claim 1,
Wherein the distribution chamber includes a contaminant transfer pipe installed to be discharged from the filtration tank, the contaminants accumulated in the chamber body,
A sewage discharge pipe installed to discharge the sewage filled in the chamber body;
And an open / close valve installed to control the opening and closing of the waste water discharge pipe. The method according to claim 1,
Wherein the reverse osmosis chamber comprises: a first chamber having a first swash plate installed to allow the sand fed through the air lift tube to fall;
A first diaphragm having an opening opened to allow sand in the first chamber to be transferred;
A second chamber provided with a second diaphragm so as to be spaced apart from the first diaphragm, an impeller rotated by a motor so that the sand transferred through the opening is evenly distributed, and a sand hole formed in the bottom to drop sand;
A third chamber formed by a third partition provided between the first partition and the second partition;
A fourth chamber in which a second swash plate is installed so that the swirling flow occurs between the second diaphragm and the fourth diaphragm spaced apart;
A contaminant transfer pipe installed in the chamber body such that the impurities accumulated in the chamber body are press-fed to the fourth chamber;
And a spiral orifice holder having a spiral orifice for discharging the washing water and discharging the contaminants fed by the contaminant transfer pipe according to the washing water level of the filtration tank.

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