KR101841463B1 - Filtration device - Google Patents

Abstract

A filtering device of the present invention includes: a pretreating part comprising a first chamber and a discharge pipe installed in the first chamber to spray sewage to repeat a procedure of discharging some of the sewage, from which pollutants have been removed, out of a vortex-shaped screen including a plurality of opening protrusions while filtering some of the sewage, which contains pollutants, by making the sewage join sewage discharged from the discharge pipe; and a main treating part filtering the sewage by making the sewage go through a filter unit installed in a second chamber with an ascending air current of the sewage, from which particle pollutants have been removed, by increasing sewage pressure in the second chamber while making the filter unit float with the pressure of the sewage while directing the sewage purified in the pretreating part into the bottom of the second chamber. As such, the present invention is capable of improving the performance of filtering pollutants.

Description

Filtration device

More particularly, the present invention relates to a filtration apparatus, and more particularly, to a filtration apparatus that filters a pollutant in the form of particles while flowing sewage in a swirl flow type, performs primary filtration, forcibly passes filtered sewage through a filter, The present invention relates to a sewage filtration apparatus for performing filtration.

The pollutants generated in urban areas are classified into point pollution sources and nonpoint pollution sources. Point pollution sources are pollution sources that have a specific discharge route that pollution sources such as domestic sewage and factory wastewater can be expressed as a single point. Their route of travel is clear and relatively easy to handle. Nonpoint pollution sources are cities, roads, agricultural land, (See Law Concerning the Preservation of Water Quality and Aquatic Ecosystems).

Unlike point sources, which are continuously generated at specific points such as domestic sewage or factory wastewater, these nonpoint source pollutants are scattered sources and it is difficult to identify the correct outflow route and the inflow is non-persistent. Especially, it is difficult to collect pollutant outflow and discharge route clearly, and it is difficult to collect pollutant, and the amount of emission and the amount of emission depend greatly on weather conditions such as precipitation and the pollutant is diluted and diffused and is discharged to a large area. The types of nonpoint pollutants include soil, nutrients (suspended matter, nitrogen, phosphorus), bacteria and viruses, oil and grease, heavy metals, organic matter, pesticides, and impurities.

In addition, the nonpoint source was not recognized as a source because the outflow of nonpoint source was concentrated only during rainfall and dispersed in a wide area.

However, the first-flush effluent, which is the source of non-point pollutants in the early stage of rainfall, has a high outflow concentration of non-point pollutants, especially in urban areas, it is highly likely to contain toxic substances such as heavy metals. have.

In other words, nonpoint source pollution from rainfall is very irregular, contains many kinds of non-degradable nonpoint pollutants, has large fluctuation amount of overhead, And the like.

Therefore, it is difficult to collect and treat pollutants such as soil, nutrients, and heavy metals that leach out along with rainfall in nonpoint source pollutants. When they enter river directly without special treatment, they pollute water quality, The habitat is destroyed and the ecosystem is disturbed.

Also, when we look at the characteristics of urban areas, according to urbanization and population concentration, our living surroundings are covered with roads and buildings, and it is becoming harder to step on or touch the soil which is the source of life. So, when it rains, we can say that shoes and clothes are no longer wetted by muddy water, but the soft soil smell and texture of the soil have been distanced from us, and many useful things brought by the soil have disappeared. In addition, due to the progress of urbanization and industrialization, the development of land is accelerated and the area of roads, industrial complexes, residential floors, and landless floors are increasing, and water quality of rivers and lakes due to nonpoint pollution sources is increasing.

Also, rather than just stopping, when it rains, rainwater quickly moves along paved roads and gutters, and flows into the river with many non-point pollutants along the road while moving. As the surface of the earth is packed, the amount of water that becomes ground water through the soil is gradually decreased. In the rivers, when the rain comes, the water is quickly blown or overflowed. The vegetation-based soils in the parks and gardens are often washed down in the rainwater and hardened to harden the underground creatures. It is also difficult to take down the rainwater to the groundwater.

Currently, the facilities to reduce non-point pollution sources include retention type, permeation type, vegetation type, device type, sewage treatment type and the like, but it is to remove the specific pollution source contained in the polluted water. Therefore, There is a need for an integrated treatment facility that removes the nonpoint source contained in the rainwater and at the same time leads the rainwater to the groundwater.

In addition, conventionally, the filter material layer provided in the filter material portion is not partially used efficiently but partially.

The contaminated water flows into the upstream side (inlet side) of the filter medium layer only until the inflow amount of the contaminated water flowing into the filter medium portion increases to such an extent as to overflow, So that the middle-stream flow side of the filter medium layer is hardly used.

Therefore, conventionally, it is impossible to uniformly and efficiently use the filter medium layer of the filter medium as a whole, thereby increasing the size of the facility, thereby reducing the efficiency of land use in urban areas.

In particular, water treatment techniques for wastewater treatment include physico-chemical treatment, aerobic treatment, anaerobic treatment, bioprocessing by animals, plants, microorganisms, and physico-chemical treatment with unit processes such as coagulation, precipitation, separation, A multistage process for combining chemical processes and biological treatment processes in a unit process and combining them is being developed. However, the conventional methods such as screen filtration, flocculation by chemical loading, and sedimentation activated carbon filtration require a lot of operation costs And the treatment water quality is not good because the efficient and stable water treatment can not be performed. The biological treatment using the activated sludge requires a large processing space, requires a long treatment time, requires professional management, and has an excessive processing cost.

Korean Patent No. 10-0557985, (2006.2.27) Korean Patent No. 10-20160114506, (2006.2.27)

In order to solve the above problems, the filtration apparatus of the present invention filters the pollutants in the form of particles while flowing sewage in a swirl flow type, performs primary filtration, forces the filtered sewage to pass through the filter So that secondary filtration can be performed.

It is another object of the present invention to provide a sewage disposal system capable of collecting sewage and pollutants by blowing sewage flowing in a swirl flow type into a discharge pipe to form a water film having a dense particle pore, I have to.

In addition, it is an object of the present invention to provide a method and an apparatus for controlling a pressure of a fluid, which is capable of increasing the pressure of fluid through sewage in a stagnant space which is a space between a lower portion of a filter means installed in an inner space of a second chamber and a hopper, So that the filtration ability passing through the filter means is improved.

In addition, the object of the present invention is to increase the filtration efficiency by allowing the water flowing from the lower part of the filtration apparatus to pass through the bottleneck section and then spreading to the wide space in the upper section to eliminate the bottleneck to reduce the flow rate and increase the retention time .

According to an aspect of the present invention, there is provided a filtration apparatus including a first chamber and a discharge pipe installed in the first chamber to discharge sewage water, wherein the sewage flows into a swirl flow screen having a plurality of open- A pretreatment unit which repeats a process of discharging a part of the sewage from which pollutants have been removed to the outside of the screen and a part of the sewage containing pollutants circulating on the screen and joining with the sewage sprayed from the discharge pipe and filtering through the screen; When the sewage purified by the pre-treatment unit flows into the lower part of the second chamber provided inside, the filter means installed in the second chamber floats due to the supply pressure of the sewage, and the sewage pressure inside the second chamber rises, And a main processing unit for passing the filtered sewage water through the filter means with an upward flow of the sewage and filtering the sewage water.

According to the present invention, the pre-processing unit includes: a first chamber; A discharge tube installed inside the first chamber to discharge sewage; And a screen having a plurality of open protrusions formed on a surface thereof so that sewage can be rotated and turned in front of the discharge pipe, and the sewage injected is circulated on the inner surface of the screen, The sewage is discharged to the outside of the screen, and some of the sewage containing pollutants is blown by the centrifugal force on the screen while being blown into the discharge pipe, whereby the pollutant particles are dispersed in the sewage.

According to the present invention, as the sewage is struck in the discharge pipe, the particles of the fine particles are formed into a water-film-like shape having a narrow space, so that the pollutants are collected into the contamination passage of the chamber.

According to the present invention, the discharge pipe is composed of a first pipe, a second pipe connected to the first pipe and having a length equal to the screen width, and the second pipe is provided with a plurality of injection holes, .

According to the present invention, the first chamber vertically connects the partition wall to the lower part of the screen, and constitutes a part of the sewage containing the pollutant circulating through the screen into the wastewater section partitioned by the first chamber.

According to the present invention, a collecting space is formed on the bottom surface of the first chamber to collect a part of sewage containing the pollutant.

According to the present invention, a sewage pipe connected to the external space is installed in the sewage hole, and the sewage in the collecting space is extracted to the outside through the pressure.

According to the present invention, the inner space of the first chamber is partially partitioned by further including a swash plate at a lower portion of the partition wall.

According to the present invention, a cleansing screen is installed in a direction opposite to the sewage hole to remove sewage whose pollutants have passed through the swirling screen.

According to the present invention, the main processing unit includes a second chamber which is supplied with the sewage filtered by the pre-processing unit and is supplied to the inside space of the second chamber, and is floated by the sewage supplied from the pre- And a filter means for up-filtering the water.

According to the present invention, the main processing unit includes at least one filter means movably installed in the inner space of the second chamber.

According to the present invention, the filter means comprises a plurality of balls housed in a net.

According to the present invention, a nozzle is provided on the upper portion of the filter means, and the air is sprayed by the filter means so as to desorb the contaminants between the ball voids.

According to the present invention, the ball is selected from pearlite, zeolite, ceramic, loess, wood chip, sericite, foamed glass molding material, natural gravel, recycled aggregate and recycled sludge.

The filtration apparatus of the present invention as described above has a first chamber and a discharge pipe installed inside the first chamber and discharging sewage, and the sewage flows into the swirl flow screen having the plurality of openings, A preprocessing unit for discharging a part of the sewage to the outside of the screen, a part of the sewage containing the pollutant pivoting on the screen, joining with the sewage sprayed from the discharge pipe, and filtering through the screen; When the sewage purified by the pre-treatment unit flows into the lower portion of the second chamber, the filter means installed in the second chamber floats due to the supply pressure of the sewage, and the sewage pressure in the second chamber rises, And a main processing unit for filtering the air passing through the filter means by an air flow.

As a result, the sewage is flowed in the swirl flow type to filter the pollutants in the form of particles to perform primary filtration, and the filtered sewage is forcibly passed through the filter to the secondary filtration.

As a result, it is possible to filter the contaminants having a large volume through the primary filtration process, and to disperse the pollutants into fine particles by scattering the wastewater by blowing, and then to filter the contaminant particles through the filter means, Is improved.

In addition, the filtration apparatus of the present invention is characterized in that the sewage flowing in a swirl flow type is blown into the discharge pipe to scatter a part of sewage and pollutants to form a water film having a dense particle porosity so as to atomize pollutants and sewage, So that the filtration ability can be further maximized.

In addition, the filtration apparatus of the present invention increases the fluid pressure through the sewage in the stagnant space, which is the space between the lower part of the filter means installed in the inner space of the second chamber and the hopper, The pressure is increased, and the filtration ability passing through the filter means is improved.

In addition, the filtration apparatus according to the present invention has the effect of increasing the filtration efficiency by reducing the flow velocity and increasing the retention time by allowing the water flowing from the lower part to pass through the bottleneck section, .

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a configuration diagram showing a filtration apparatus according to the present invention;
2 is a plan view showing a filtration apparatus of the present invention.
3 is a configuration diagram showing a pretreatment section of the filtration apparatus of the present invention.
4 is a block diagram showing the present processing section of the filtration apparatus of the present invention.
5 is an enlarged view showing the present processing unit of the filtration apparatus of the present invention.
6 is a configuration diagram showing a collecting section of the filtration apparatus of the present invention.
7 is a perspective view showing a discharge pipe of the filtration apparatus of the present invention.
8 is a cross-sectional view showing a discharge tube of the filtration apparatus of the present invention.
9 is a sectional view showing another embodiment of the discharge pipe of the filtration apparatus of the present invention.
10 is a perspective view showing a refinish screen of the filtration apparatus of the present invention.
11 is a perspective view showing a second chamber of the present treatment section of the filtration apparatus of the present invention.

Hereinafter, a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings.

First, in the drawings, it is noted that the same components or parts are denoted by the same reference numerals as possible. In the following description of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted so as to avoid obscuring the subject matter of the present invention.

2 is a plan view showing a filtration apparatus of the present invention, FIG. 3 is a structural view showing a pretreatment unit of the filtration apparatus of the present invention, and FIG. 4 is a cross- Fig. 5 is an enlarged view showing the main processing unit of the filtration apparatus of the present invention. Fig. 6 is a configuration diagram showing the collecting unit of the filtration apparatus of the present invention. Fig. 9 is a cross-sectional view showing another embodiment of the discharge tube of the filtration apparatus of the present invention, and Fig. 10 is a cross-sectional view of the discharge tube of the filtration apparatus of the present invention. Fig. Fig. 11 is a perspective view showing a second chamber of the present treatment section of the filtration apparatus of the present invention. Fig.

As shown in FIG. 1, the filtration apparatus 10 of the present invention includes a pretreatment unit 100 for primarily filtering sewage water through a swirling flow screen 130, a main processing unit 200 for secondarily filtering sewage water in a floating manner, And a collecting unit 300 collecting the secondary filtered water and taking it out to the outside.

First, the preprocessing unit 100 is provided with a discharge pipe 120 for discharging sewage, and the sewage is introduced into the swirling flow screen 130 having the plurality of open protrusions 131, and part of the sewage having the pollutant removed is discharged to the outside of the screen 130, Is circulated through the screen 130 and merged with the sewage sprayed from the discharge pipe 120, and is filtered through the screen 130, and the process is repeated.

That is, the sewage water injected from the discharge pipe 120 is discharged to the arc-shaped screen 130.

The sewage circulates the inner surface of the swirling flow screen 130 vertically.

At this time, the sewage is caught by the open protrusion 131 projecting out of the screen 130.

That is, the pollutant having a larger volume than the opening of the open protrusion 131 does not pass through the screen 130 and turns with some sewage along the inner surface, and some of the polluted material, which has passed through the open protrusion 131, First, the wastewater is filtered.

Particularly, the bulky contaminants and some sewage which have not been passed to the outside of the screen 130 by the open protrusions 131 are sent to the discharge pipe 120 side while being swirled into the screen 130 by the centrifugal force.

The contaminants struck in the discharge pipe 120 and a part of the bottom part are scattered by a strong blowing pressure and are formed into a water film having a dense particle porosity.

Here, the contaminants may be collected into the collecting space 161 separately provided together with the wastes which are crushed and scattered in the form of fine particles by the impact while being struck by the discharge pipe 120.

The specific configuration of the preprocessing unit 100 configured as described above is as follows.

The preprocessing unit 100 includes a discharge tube 120 and a screen 130.

Here, as shown in FIGS. 7 and 8, the discharge tube 120 may be accommodated in the first chamber 110.

The discharge pipe 120 discharges sewage supplied from the outside in the direction of the screen 130.

Particularly, the discharge pipe 120 can be applied as a hollow pipe, or the sewage can be sprayed with a width equal to the width direction of the screen 130 while raising the pressure of the sewage.

At this time, the discharge tube 120 may be formed in a plate shape other than a hollow pipe shape.

7, the discharge pipe 120 includes a first hollow pipe 121 and a second pipe 122 connected to the first pipe 121 and having a length equal to the width of the screen 130, And a plurality of injection holes 123 branched to the two-pipe conduit 122 are communicated with the first conduit 121.

The second channel 122 is formed to have a width and a plurality of discharge holes 123 are communicated with the first channel 121.

Here, the injection hole 123 is formed to have a diameter smaller than that of the first conduit 121 to reduce the flow space area of the sewage water, thereby increasing the flow rate of the sewage water, thereby increasing the speed of turning the screen 130, thereby improving the filtration ability.

In addition, the position where the sewage is struck to the discharge pipe 120 is the second pipe 122, which increases the striking area of the sewage, thereby further increasing the scattering of the pollutant, and increasing the range of the water film having the dense particle porosity .

The operation of the pre-processing unit 100 configured as above will be described below.

First, sewage containing pollutants is sprayed onto the screen 130 through the first pipe 121 and the second pipe 122 of the discharge pipe 120.

The sewage circulates along a curved inner surface of the screen 130 while vertically descending clockwise.

At this time, the sewage is pivoted on the inner surface of the screen 130 together with the pollutant having a volume larger than the inlet of the open protrusion 131 formed on the screen 130 and some sewage, and the other part of the sewage from which the pollutant is removed passes through the open protrusion 131 And is discharged to the outside of the screen 130.

Here, the open protrusion 131 has a hole 132 penetrating the surface of the screen 130, and the protrusion is protruded toward the outer surface side.

As the wastewater circulates, the pollutant having a volume larger than the hole 132 swirls on the inner surface of the screen 130 with some wastewater which has not passed through the hole 132 and has not passed through the hole 132 due to the centrifugal force, And is discharged to the outside of the screen 130 through the hole 132 of the screen 130. [

Here, the wastewater discharged to the outside of the screen 130 is subjected to a primary filtration process through the screen 130.

Some of the wastewater and contaminants circulating on the inner surface of the screen 130 are swung upward by the centrifugal force and struck on the lower surface of the second pipe 122 of the discharge pipe 120 having a wide width.

In addition, the pollutants struck in the discharge pipe 120 and some of the sewage are scattered by strong striking pressure, so that the particle pores of the condensed matter are formed into a dense water film.

Here, the contaminants may be collected into the collecting space 161 separately provided in the chamber together with some wastewater which is pulverized in the form of fine particles and impacted by impact while being struck by the discharge pipe 120.

Here, the lower surface of the second pipe 122 of the discharge pipe 120 may be formed with a symmetrically inclined surface, and a water film may be formed over a wider area through inclined surfaces while the wastewater is struck.

As described above, the sewage filtered first through the screen 130 and the striking method is collected to the lower portion of the pretreatment unit 100.

The primary filtered sewage is re-filtered and externally extracted through the following configuration.

The partition wall 173 is vertically connected to the lower portion of the screen 130 so that the primary filtered sewage and a part of sewage containing contaminants can be partitioned.

In addition, a swash plate 163 is further included in the lower part of the partition wall 173.

At this time, a cleansing screen 170 is installed in front of the swash plate 163, and the sewage having passed through the swirling screen is removed.

Here, the primary filtration sewage collides against the swash plate, and then is guided and guided to the sub screen screen side.

A plurality of biostrins 171 are accommodated in the detail screen 170.

In the biostone 171, microorganisms are deposited on a plurality of voids on the surface of the spherical surface, so that contaminants of the primary filtrate and sewage are interposed in the pores and decomposed by the microorganisms.

The purified water discharged through the screen 170 is transported to the processing unit 200 via the channel 151.

In addition, the discharge port 172 can be selectively opened and closed at the lower portion of the screen, so that the discharge port 172 can be connected to the pipe.

The contaminants filtered through the screen 130 and the screen 170 are collected into the collecting space 161 formed on the bottom surface of the pretreatment unit 100.

A collecting space 161 is formed at one side of the bottom of the pretreatment unit 100 and a lower part of the sewage pipe 162 connected to the outer space and vertically installed in the pretreatment unit 100 is placed in the collecting space 161.

Thus, contaminants filtered through the screen 130 and the refinement screen 170 can be taken out to the outside.

The wastewater that has been primarily filtered through the pretreatment unit 100 is subjected to a secondary filtration process through the treatment unit 200.

The main processing unit 200 has a second chamber 210 therein, and a plurality of filter means 220 having buoyancy is installed in the inner space 211 of the second chamber 210.

The second chamber 210 is formed with a mesh or perforated hole.

As a result, the filter means 220 installed in the second chamber 210 floats due to the supply pressure of the sewage, and the sewage pressure in the second chamber 210 rises, Passed through the filter means 220 by an air flow, and filtered.

That is, when the sewage purified by the preprocessing unit 100 flows into the lower portion of the second chamber 210, the filter means 220 is floated by the sewage so that the sewage pressure inside the second chamber 210 rises and the sewage, And filtered.

Here, as shown in FIGS. 4 and 5, the main processing unit 200 filters the sewage through the filter means 220 that moves the primary filtered sewage in a floating manner.

The present processing unit 200 includes a second chamber 210 and a filter unit 220 to enable this.

The second chamber 210 accommodates the filter means 220 in the inner space 211, and the filter means 220 moves up and down in the second chamber 210 through buoyancy of the sewage.

Alternatively, the filter means 220 is installed in the inner space 211 so as to be movable up and down, and is filtered while being floated by the sewage supplied through the hopper 213.

At this time, the filter means 220 is composed of a plurality of balls 221. At this time, the plurality of balls 221 usually fill only about 2/3 of the space height of the second chamber 210.

The ball is selected from pearlite, zeolite, ceramic, yellow soil, wood chip, sericite, foamed glass molding material, natural gravel, recycled aggregate and recycled sludge.

Specifically, the sewage treatment function of the treatment unit 200 through buoyancy is as follows.

The sewage pressure in the stagnation space 212, which is the space between the lower portion of the filter means 220 installed in the inner space 211 of the second chamber 210, and the hopper 213, is increased.

As the area of the stagnation space 212 becomes wider, the pressure rises and the filtration ability passing through the filter means 220 is improved.

The processing unit 200 configured as described above allows one or more filter means 220 to be installed in the inner space 211 of the second chamber 210 so as to be movable up and down, respectively, so that a plurality of filtrations are performed to filter the sewage.

Particularly, when the pressure of the stagnation space 212 between the filter means 220 and the hopper 213 rises in the inner space 211 while the sewage is filtered through the gap of the filter means 220, the stagnation space 212 is enlarged, Increase the time.

That is, the filter means 220 installed in the inner space 211 of the second chamber 210 determines the floating height of the filter means 220 in accordance with the level at which the sewage to be pumped is filled into the second chamber 210 through the hopper 213.

The reason for floating the filter means 220 is that when the amount of water supplied through the hopper 213 is large compared with the amount of drainage of the plurality of balls 221 housed in the net and the filling of the second chamber 210 into the fine voids of the balls 221 The filter means 220 is raised by the sewage pressure.

That is, when the contaminated water flows into the second chamber 210, the ball 221 is normally floated by the gravity and is filled with about 2/3 of the bottom, So that the upper two-thirds of the height of the second chamber 210 is filled, and the lower one-third is filled only with the water without the balls 221. [

In addition, when rainfall is terminated and the necessity of operation of the facility is lost, or when it is necessary for maintenance, if water is drained, the flow of water is blocked and the water level naturally lowers.

Accordingly, the ball 221, which has been in a compressed state on the upper side of the second chamber 210, sinks to the lower side of the second chamber 210 by the gravity along with the lowered water level. In this process, Are settled to the bottom, and the backwash effect is obtained.

At this time, the bottleneck section of the second chamber 210 functions to increase the filtration efficiency by controlling the flow rate of the water and the rising pressure under normal processing conditions. However, when the water level is lowered due to the removal of water or the inflow of polluted water, So that the sedimentation induction of the sludge and the withdrawal of the sedimentation sludge in the future can be performed smoothly.

After the filtration process is completed or after completion of the filtration process, air or water is sprayed through the first nozzle 222 provided at the lower part of the filter means 220 so as to desorb contaminants between the voids of the balls 221.

Here, there are three kinds of washing, air washing, water washing and natural backwash.

In other words, in general, although air cleaning and water washing which are legally required in other methods are simply applied, in the present invention, water washing may be unnecessary through natural backwashing, and even if necessary, Can be reduced.

In addition, a plurality of second nozzles 223 are provided vertically in the filter means 220 so that water supplied from the outside can be sprayed to remove contaminants from a plurality of balls 221 accommodated in the filter means 220 .

The pollutants desorbed from the treatment section 200 are collected into the catchment space 161 through the pipeline 151 and taken out through the sewage pipe 162.

The purified water filtered through the treatment unit 200 flows to the collecting unit 300 to be drained.

In particular, the present invention is a process that is essential for maintaining the efficiency of the apparatus by periodically removing contaminants.

And a discharge port 172 is provided at the boundary between the preprocessing unit 100 and the main processing unit 200 so as to be opened and closed.

When the water in the pretreatment unit 100 is drained, the discharge port 172 is opened to allow the contaminants in the bottom of the treatment unit 200 to easily move to the pretreatment unit 100. When the pretreatment unit 100 is filled with water, .

Accordingly, if the contaminants accumulated in the collecting space 161 are taken out through the upper end of the sewage pipe 162 of the pretreatment unit 100, the discharge port 172 is opened by the suction pressure and the contaminants accumulated in the bottom of the second chamber 210 of the present treating unit 200 are sucked So that it can flow into the catchment space 161 and be taken out to the outside.

As a result, depending on whether the sewage pipe 162 is operated or not, the suction pressure difference of the pre-processing unit 100 is generated to determine whether the discharge port 172 is opened. At this time, the bottom surface of the treatment unit bottom and the pre- Respectively.

Particularly, the coarse foreign matter filtered by the screen 130 of the pretreatment unit 100 functions to easily sink to the floor, and to prevent the upward flow of the water from the screen 140. Also, the water purified by the screen 130 does not mix with the lower sludge So that it can be introduced into the detail screen 170.

The filtration apparatus configured as described above filters the contaminants having a volume through the primary filtration process and splashes the wastewater by hitting to subdivide the contaminants into particulate form and then filters the contaminant particles through the filter means So that the pollutant filtering ability is improved.

In addition, the filtration apparatus of the present invention is characterized in that the sewage flowing in a swirl flow type is blown into the discharge pipe to scatter a part of sewage and pollutants to form a water film having a dense particle porosity so as to atomize pollutants and sewage, So that the filtration ability can be further maximized.

In addition, the filtration apparatus of the present invention increases the fluid pressure through the sewage in the stagnant space, which is the space between the lower part of the filter means installed in the inner space of the second chamber and the hopper, The pressure is increased, and the filtration ability passing through the filter means is improved.

In addition, the filtration apparatus according to the present invention has the effect of increasing the filtration efficiency by reducing the flow velocity and increasing the retention time by allowing the water flowing from the lower part to pass through the bottleneck section, .

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the inventions. It will be apparent to those of ordinary skill in the art.

10: Filtration apparatus 100: Pretreatment unit
112: first pump 120: discharge pipe
121: first conduit 122: second conduit
123: minute sprayer 130: screen
131: open protrusion 132: hole
151: channel 160: sewage hole
161: collecting space 162: sewage pipe
163: swash plate 170:
171: Bioston 172: Outlet
200: main processing unit 210: second chamber
211: inner space 212: congestion space
213: hopper 220: filter means
221: ball 222: first nozzle
223: Second nozzle

Claims (14)

A swirling flow screen having a plurality of open protrusions formed on a surface thereof so as to be pivoted by rotating the sewage in front of the discharge pipe is installed in the first chamber and is provided with a discharge pipe for spraying sewage, Some of the sewage whose contaminants have been removed by the open projections while the sewage circling the inner surface of the screen discharges the sewage to the outside through the screen and some of the sewage that does not pass through the screen circulates the screen by the centrifugal force, A pretreatment unit that repeats the process of dispersing the pollutant particles in the sewage while being struck in the sewage;
When the sewage purified by the pre-treatment unit flows into the lower part of the second chamber provided inside, the filter means installed in the second chamber floats due to the supply pressure of the sewage, so that the sewage pressure inside the second chamber rises, And a main processing unit for passing the filtered sewage water through the filter means with an upward flow of the sewage.
delete The method according to claim 1,
Wherein the particles of the fine particles are formed into a densely watered membrane shape while the sewage is struck to the discharge pipe, so that the pollutant is collected into the collection space of the chamber.
The method according to claim 1,
The discharge tube
A first conduit,
And a second conduit connected to the first conduit and having a length equal to the screen width,
And a plurality of jet holes are communicated with the first conduit in the second conduit.
The method according to claim 1,
Wherein the first chamber comprises:
Wherein a partition wall is vertically connected to a lower portion of the screen, and a part of sewage containing contaminants circulating through the screen is introduced into the sewage holes partitioned by the first chamber.
The method according to claim 1,
And a collecting space is formed on the bottom surface of the first chamber to collect a part of the sewage containing the pollutant.
The method according to claim 6,
And a sewage pipe connected to the external space is installed in the sewage hole to extract the wastewater from the collection space through the pressure.
6. The method of claim 5,
Further comprising a swash plate at a lower portion of the partition wall to partially partition the internal space of the first chamber.
6. The method of claim 5,
And a cleansing screen is installed in a direction opposite to the waste water hole to purify the sewage from which pollutants having passed through the swirling flow screen have been removed.
The method according to claim 1,
The present processing unit,
A second chamber that is supplied with the sewage filtered by the pre-processing unit,
And a filter unit installed in the inner space of the second chamber so as to be movable upward and downward and float up and filtrate by the sewage supplied from the pre-processing unit.
11. The method of claim 10,
The present processing unit,
Wherein at least one filter means is vertically movably installed in an inner space of the second chamber. 11. The method of claim 10,
Wherein the filter means comprises a plurality of balls housed in a net.
13. The method of claim 12,
Characterized in that a nozzle is provided on the upper part of the filter means and the air is blown out by the filter means so as to desorb the contaminants between the ball voids.
13. The method of claim 12,
Wherein the ball is selected from any one of pearlite, zeolite, ceramic, yellow soil, wood chip, sericite, foamed glass molding material, natural gravel, recycled aggregate and recycled sludge.

Images