KR100425050B1 - Filter which simultaneously filtering and cleaning processing - Google Patents

Abstract

The present invention relates to a continuous filter in which filtration and backwashing are simultaneously performed. In particular, the present invention relates to a filter, in particular, to a continuous filter in which filtration and backwashing are simultaneously performed. More specifically, A backwash fluid injection pipe formed at an inner bottom of each of the independent chambers of the filtration tank and having a through hole formed at a predetermined interval along the longitudinal direction of the outer circumferential surface of the filtration tank, A back filtration fluid inlet for selectively introducing the backwash fluid into the backwash fluid injection pipe outside the independent chambers, a filtration layer formed of fiber filter media supported on the upper filter media bag, And a reverse water discharge formed on the upper part of the partition wall separating the chambers Wherein the filtration process of the raw water is continued in each of the independent chambers and the backwashing is simultaneously carried out by the shearing force and the levitation force by the backwashing fluid in the selected independent chamber. .

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a continuous filter for filtering and backwashing,

The present invention relates to a filter, and more particularly, to a continuous filter in which filtration and backwashing are simultaneously performed. Specifically, the filter is divided into separate chambers by partition walls, and raw water introduced through the inlet conduits is accommodated in each of the independent chambers. ; A backwash fluid injection pipe formed at an inner bottom of each of the independent chambers of the filtration tank and having a through hole formed at regular intervals along the longitudinal direction of the outer circumferential surface; A filtration layer formed of a fibrous filter material supported on an upper filter material band and a lower filter material band formed in respective independent chambers of the filtration tank; A backwash fluid injector for selectively introducing backwash fluid into the interior of the backwashing fluid injection pipe outside each of the independent chambers; And a backwash water discharge channel formed above the partition walls separating the chambers. The filtration process of the raw water into the independent chambers continues while backwashing is performed simultaneously with shearing force and floating force by the backwash fluid in the selected independent chamber Wherein the filtration and the backwashing are simultaneously performed.

The operation of a general filtration device is divided into a filtration process and a cleaning process.

The filtration process is a process in which raw water containing suspended solids is introduced into a filtration apparatus to discharge clean raw water from which suspended solids have been removed. The suspended solids in the raw water are sieved into the pores in the filtration layer of the filtration apparatus, It is a process of capturing and trapping with complex mechanisms such as blocking, adsorption, and coagulation, and discharging clean water only as raw water.

Continuing with the filtration process, the voids in the filtration layer are increasingly filled with suspended solids and the filtration resistance increases to a state in which the filtration process can no longer be continued.

At this time, it is necessary to perform a washing process for injecting clean wash water and air in the opposite direction to the filtration process to exclude the suspended substances trapped in the pores. (Hereinafter, the flow of the washing water is opposite to the flow of the raw water, )

Therefore, the performance of the filtration device is determined by the removal efficiency of the suspended material, the filtration speed, the filtration duration, the amount of the washing water, the frequency of washing, and the washing time.

Inorganic materials such as sand, anthracite, anthracite, etc. have been mainly used as the filter material to be filled in the filtration layer.

Such a filter material has the advantage that it can be easily obtained and it is possible to remove particles smaller than the pore size formed by these filters.

However, the filtration layer formed by this filter material has a rapid increase in the filtration resistance due to the clogging of the pores because the space capable of trapping the suspended material is limited near the surface layer.

Therefore, there is a disadvantage that backwashing must be performed frequently.

In order to solve the disadvantage that the suspended material is mainly caught near the surface of the filtration layer, there has been developed a filtration device in which the filtration layer is improved to a multi-layer or multi-layer. However, filter media having different particle diameters and densities are used for each layer, If the washing process is repeated, the boundary between the filtration layers becomes ambiguous and it is difficult to achieve the first purpose.

In addition, when granular filter media are used, there still remains the problem of loss of filter media during backwashing.

In recent years, in order to further improve the performance of a filtration device, a fiber yarn is used as a filter material, a fiber yarn is fixed to the lower end of the filter, a filter material is squeezed with raw water supply pressure, (Registration No. 10-0241198). However, since the filtration layer is a single layer and the degree of compression of the filter medium is determined by the raw water supply pressure, the filtration space is small and the filtration duration is short, And it is not easy to cope with fluctuations in the water quality of the inflow water.

However, for the backwash process, there is a problem that the backwashing can be performed because the filtration process must be stopped. In fact, there is a problem that time factor is involved and the filtration capacity is reduced.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a continuous filter in which filtering and backwashing can be maintained at the same time while keeping the filter layer clean at all times.

It is also an object of the present invention to provide a continuous filter in which there is no interruption of the filtration duration, and filtration and backwashing are simultaneously performed so as to respond positively to fluctuations in the water quality of the influent water.

1 is a schematic view of an embodiment of a continuous type filter in which filtration and backwashing are simultaneously performed according to the present invention.

Fig. 2 is a side cross-sectional view of a continuous filter in which filtration and backwashing simultaneously proceed according to the present invention

3 is a side cross-sectional view of an independent chamber illustrating backwashing of a continuous filter in which filtration and backwashing are simultaneously performed according to the present invention

4 is a plan view of another embodiment of a continuous type filter in which filtration and backwashing are simultaneously performed according to the present invention.

Figure 5 is a side cross-sectional view of the embodiment of Figure 4;

Description of the Related Art

10: stationary water passage 20: inlet conduit

27: Reverse movement

30: Reverse water discharge water 55: Backwash fluid injection unit

57: backwash fluid injection pipe 60: fiber media

100: Filtration tank 110:

The present invention relates to an inflow conduit into which raw water flows to achieve the above object; A filtration tank divided into independent chambers by barrier ribs, the raw water flowing through the inflow conduits being accommodated in respective independent chambers; Wherein the backwashing fluid is formed in the inner bottom portion of each of the independent chambers of the filtration tank and has a through hole formed at regular intervals along the longitudinal direction of the outer circumferential surface thereof, A backwash fluid injection pipe through which the fluid is uniformly ejected; A filtration layer formed of a fibrous filter material supported on an upper filter material band and a lower filter material band formed in respective independent chambers of the filtration tank; A backwash fluid injector for selectively introducing backwash fluid into the interior of the backwashing fluid injection pipe outside each of the independent chambers; The backwash fluid is drawn through the backwash fluid injecting unit and is evenly sprayed to the backwash fluid spraying pipe. The turbulent flow generated by the backwash fluid causes the backwash fluid The micro-contaminants are elevated together with the air bubbles by the shear force, the floating force or the buoyant force, and when the level of the independent chamber is raised by the injection of the backwashing fluid and the backwash water is swollen, A stationary water passage which moves and guides the stationary water; A reverse water discharge channel for collecting and discharging reverse osmosis water moved by the reverse osmosis water passage; Wherein the filtration process of the raw water is continued in each of the independent chambers and the backwashing is simultaneously performed by the shearing force and the levitation force by the backwash fluid in the selected independent chamber, It is technically essential.

Wherein the backwashing fluid injection pipe is formed by forming the lower filter bag as a pipe and forming a through hole in a longitudinal direction of the outer circumferential surface of the pipe, wherein the continuous filter is a filtration and backwashing process.

Preferably, the inflow conduit is a continuous type filter in which filtration and backwashing are simultaneously performed, in which reverse osmosis is formed so that the raw water flowing into each of the chambers and the backwashed water raised in each chamber are separated from each other.

The present invention also relates to a filtration apparatus comprising: a cylindrical filtration tank in which a partition wall is radially formed to form a radial chamber and rotated by external driving means; An inlet conduit formed in the filtration tank for guiding the introduced raw water to each of the independent chambers of the filtration tank; A pipe formed radially on the inner bottom of each of the independent chambers of the filtration tank and having a through hole formed at a predetermined interval along the longitudinal direction of the outer circumference thereof and a backwashing fluid uniformly blown out along the longitudinal direction through the through hole, A fluid injection pipe; A filtration layer formed of a fibrous filter material supported on an upper filter material band and a lower filter material band formed in respective independent chambers of the filtration tank; A backwash fluid injection unit formed at the center or outer side of the filtration tank and selectively connected to the backwash fluid injection pipe by rotating the filtration tank by the external driving unit to draw the backwash fluid into the interior; When the backwash fluid is uniformly sprayed through the backwashing fluid injection pipe, the sludge intercalated in the filtration layer is backwashed by the backwash fluid, and the fine contaminants are raised together with air bubbles by shear force, floating force or buoyancy A backwash water passage for receiving and circulating the backwash water when the level of the independent chamber is raised by the injection of the backwash fluid and the backwash water is swollen; A reverse water discharge passage for discharging the reverse water discharged by the reverse water discharge passage; The filtration process of the raw water is continued in each independent chamber, the cylindrical filtration tank is rotated to select the independent chamber, and backwashing is simultaneously performed by the shearing force and the levitation force by the backwash fluid in the selected independent chamber The filtration and the backwashing are performed at the same time.

Hereinafter, the present invention will be described with reference to the drawings.

2 is a side cross-sectional view of a continuous filter in which filtration and backwashing are simultaneously performed according to the present invention, and FIG. 3 is a cross-sectional view of a continuous filter according to the present invention. 4 is a plan view of still another embodiment of a continuous filter in which filtration and backwashing are simultaneously performed according to the present invention, and Fig. 5 Is a side cross-sectional view of the embodiment of Fig.

As shown in the drawing, the present invention mainly includes a filtration tank 100 divided into an inlet conduit 20 and a partition wall 110, a backwash fluid injection pipe 57, a filtration layer 60, a backwash fluid injection unit 55, (10) and a reverse water discharge water passage (30).

The inflow conduit 20 of the present invention is a guide path through which raw water flows, and is formed of a U-shaped channel as shown in FIG. 1 or a pipe, and guides the raw water to the filtration tank 100.

The filtration tank (100) of the present invention is a filtration space divided into several chambers independent of the partition (110).

Raw water introduced through the inlet conduit 20 is branched and guided to each independent chamber of the filtration tank 100.

For this purpose, when the inlet conduit 20 is constituted by the U-shaped channel shown in FIG. 1, the path must be opened for each independent chamber of the filtration tank. In the case of a pipe, .

The backwashing fluid injection pipe 57 of the present invention is formed at an inner bottom portion of each independent chamber of the filtration tank 100.

In the backwashing fluid injection pipe 57, through-holes are formed at regular intervals along the longitudinal direction of the outer circumferential surface, and when backwashing fluid is introduced into the inside of the pipe, the backwash fluid .

The filtration layer 60 of the present invention is supported on a lower filter member 50 and an upper filter member 40 formed in respective chambers of the filtration tank 100 to form a filtration layer.

The filtration layer 60 has an advantage in that the size of the pores can be easily controlled. This is merely an example of the filter medium, and the present invention is not necessarily limited to this. The structure of the filtration and backwashing A filter material of various materials may be used as long as it does not escape.

The backwashing fluid injecting unit 55 of the present invention selectively introduces the backwashing fluid into each of the backwashing fluid injection pipes 57 outside the respective chambers.

The selection of the backwash fluid injection pipe 57 of each of the chambers will be realized by slidably configuring the backwashing fluid injection pipe to make contact with each backwash fluid injection pipe 57 or using a self-regulating valve.

As described above, the upper filter bag 40 and the lower filter bag 50 are inserted into the filtration tank 100 as described above. The upper and lower ends of the filtration layer 60 (fiber bundle) are bundled, It is a support for mounting in the filtration tank.

However, it is also contemplated that the backwashing fluid injection pipe 57 of the present invention is formed to also serve as the lower filter bank 50.

In this case, the space efficiency of the inner structure of the filtration tank is improved, and air can be blown out from the bottom surface of the filtration layer 60.

The U-shaped water passage (10) of the present invention is a U-shaped channel formed on the upper part of the partition 110 separating the chambers. Of course).

When a backwashing fluid such as high-pressure air or the like (various selections of fluid such as high-pressure air and reverse osmosis can be selected as needed) is introduced into one chamber selected through the backwashing fluid injecting unit 55 The fluid for backwashing is uniformly sprayed to the backwashing fluid injection pipe 57 located at the lower end of the selected chamber and the sludge trapped in the filtration layer 60 by the backwashing fluid is separated from the filter material by the shear force And simultaneously moves upward with the backwash fluid.

And the level of the independent chamber selected by the injection of the backwash fluid rises above the level of the other chambers in the filtering operation.

At this time, a counterflow (27) is installed to prevent the rising pollutant from flowing back to the raw water inflow conduit (20).

FIG. 3 shows only the independent chamber of the filtration tank. The filtration level 20-1 and the backwash level 30-1 are shown.

That is, since the steady-state water level of the independent chamber in which filtration is taking place is determined by the inflow rate of the raw water and the resistance by the filtration layer 60, the proper level of the filtration tank is adjusted by the inflow amount of the raw water, .

Therefore, when the level of the independent chamber selected by injection of the backwashing fluid in the selected chamber rises above the level of the other chamber as shown in Fig. 3, the overturned reverse osmosis water is overflowed, And flows over the mobile waterway (10).

The backwater discharge water path (30) of the present invention is a channel for collecting and discharging backwash water transferred by the backwatering water passage.

In the embodiment of FIG. 1, the backwater drainage water line 30 is shown as a U-shaped channel formed on the outer wall of the filtration tank.

According to the present invention, the raw water flowing through the inflow conduit 20 is transferred to each independent chamber and subjected to a filtration process. As a result, the backwash fluid is supplied to the chamber selected by the backwash fluid infusion section 55 from the lower side to the upper side The backwashing is advanced by the shear force and the levitation force due to the fluid for backwashing.

On the other hand, when the backwash water flows backward into the inlet conduit 20 due to the rise in the water level of the reverse water as described above, there is a fear that contaminants may flow into the other chamber and contaminate the filtration layer 60 of the other chamber.

Therefore, the inflow conduit 20 forms a backflow 27 in the inflow portion into the chamber so that the raw water flowing into each chamber and the backwash water raised in the respective chambers are separated from each other.

The backwashing (27) blocks the inlet conduit (20) when the water level rises, thereby preventing reverse flow of the polluted water.

Although the hexagonal type filtration tank has been described in the present invention, the embodiment of the present invention is not limited to this.

Hereinafter, the cylindrical embodiment will be described in detail with reference to FIGS. 4 and 5. FIG.

4 is a plan view of the filtration tank constructed in a cylindrical shape.

The continuous type filter, which is composed of the cylindrical filtration tank 100 according to another embodiment of the present invention, includes a cylindrical filtration tank 100, an inlet conduit 20, a backwashing fluid injection pipe 57, a filtration layer 60, A backwash fluid inlet portion 55, a reverse osmosis water passage 10 and a reverse water discharge water passage 30.

As shown in the figure, the cylindrical filtration tank 100 has a partition wall formed radially to form a radial chamber with respect to the center of the cylinder.

In the present invention, when the cylindrical filtration tank 100 is formed, the cylindrical filtration tank is rotated by the external driving means.

The external driving means may be constituted by a motor, a piston, a gear, etc., which is a technical content deviating from the gist of the present invention, and therefore, a detailed description thereof will be omitted.

The inlet conduit 20 of the present invention is a conduit formed along the upper circumferential surface of the filtration tank, and guides the raw water introduced through the inlet to a separate chamber.

In the illustrations of Figures 4 and 5, the conduit is shown as a channel that guides the raw water to each chamber.

In the case of the example shown in the figure, it is constituted by a flanged channel on the outer circumferential surface of the filtration tank.

The backwashing fluid injection pipe (57) of the present invention is a pipe formed in an inner bottom portion of each independent chamber of the filtration tank. When a backwashing fluid is introduced into the backwashing fluid injection pipe (57), the backwashing fluid is uniformly ejected through the opening.

The filtration layer 60 is supported as a fiber yarn bundle to the lower filter member 50 and the upper filter member 40 formed in the respective chambers of the filtration tank.

The backwashing fluid injecting unit 55 of the present invention is formed at the center or the outside of the filtration tank and selectively connected to the backwashing fluid injection pipe by rotating the filtration tank by the external driving unit, .

Needless to say, the backwashing fluid injection pipe 57 may be formed in the lower filter bank 50.

Therefore, in the case of the cylindrical filtration tank 100, it can be said as a turntable type rotary filter.

The reverse osmosis moving tube 10 of the present invention is formed in the same direction as the backwashing fluid injecting section 55 and in the case of the example shown in the drawing the inlet conduit 20 formed on the upper outer periphery of the cylindrical filtration tank 100 And the partition wall 110 is divided into the inlet conduit 20 and the inlet conduit 20.

When the backwash fluid is uniformly sprayed to the backwash water moving pipe 10 through the backwashing fluid injection pipe 57, the sludge trapped in the filtration layer 60 is removed by the backwash fluid, The wash water is raised together with the backwash fluid and the water level of the independent chamber is also raised by the inflow of the backwash fluid to guide the backwash water to be discharged when the backwash water overflows.

According to the present invention of the cylindrical filtration tank 100 as described above, the raw water flows into each of the independent chambers and the filtration process is continued. In the independent chamber selected by the rotation of the cylindrical filtration tank, the shear force and back- Is performed at the same time.

According to the present invention as described above, there is an advantage that a continuous filter in which filtration to maintain the filtration layer at all times and backwash simultaneously proceeds is provided.

Further, there is an advantage that there is no interruption of the filtration duration, and a continuous filter is provided, in which the filtration and backwashing are simultaneously performed so as to respond positively to fluctuations in the water quality of the influent water.

Claims (4)

The inflow conduit into which the raw water flows A filtration tank divided into independent chambers by barrier ribs, the raw water flowing through the inflow conduits being accommodated in respective independent chambers; Wherein the backwashing fluid is formed in the inner bottom portion of each of the independent chambers of the filtration tank and has a through hole formed at regular intervals along the longitudinal direction of the outer circumferential surface thereof, A backwash fluid injection pipe through which the fluid is uniformly ejected; A filtration layer formed of a fibrous filter material supported on an upper filter material band and a lower filter material band formed in respective independent chambers of the filtration tank; A backwash fluid injector for selectively introducing backwash fluid into the interior of the backwashing fluid injection pipe outside each of the independent chambers; The backwash fluid is drawn through the backwash fluid injecting unit and is uniformly jetted to the backwashing fluid injection pipe. When the fluid is backwashed by the backwash fluid, When the backwash water swollen due to the rise of the level of the independent chamber by the injection of the backwashing fluid and the swollen backwash water swollen, A stationary water passage for moving and guiding the water; A reverse water discharge channel for collecting and discharging reverse osmosis water moved by the reverse osmosis water passage; Wherein the filtration process of the raw water is continued in each of the independent chambers, and backwashing is simultaneously performed by the shearing force and the levitation force by the backwash fluid in the selected independent chamber. The backwash fluid injection pipe according to claim 1, wherein the backwash fluid injection pipe Wherein the lower filter member is formed by a pipe and a through hole is formed in the longitudinal direction of the outer circumferential surface of the pipe. 2. The apparatus of claim 1 wherein the inlet conduit Wherein the reverse flow is formed so that the raw water flowing into each of the chambers and the backwashed water raised in each chamber are separated from each other. A cylindrical filtration tank in which a partition wall is radially formed to form a radial chamber and rotated by external driving means; An inlet conduit formed in the filtration tank for guiding the introduced raw water to each of the independent chambers of the filtration tank; A pipe formed radially on the inner bottom of each of the independent chambers of the filtration tank and having a through hole formed at a predetermined interval along the longitudinal direction of the outer circumference thereof and a backwashing fluid uniformly blown out along the longitudinal direction through the through hole, A fluid injection pipe; A filtration layer formed of a fibrous filter material supported on an upper filter material band and a lower filter material band formed in respective independent chambers of the filtration tank; A backwash fluid injection unit formed at the center or outer side of the filtration tank and selectively connected to the backwash fluid injection pipe by rotating the filtration tank by the external driving unit to draw the backwash fluid into the interior; When the backwash fluid is uniformly sprayed through the backwashing fluid injection pipe, the sludge trapped in the filtration layer is desorbed by the backwash fluid so that the backwash water is raised together with the backwash fluid, A backwash water passage for receiving and circulating the backwash water when the level of the independent chamber is raised by the injection of the fluid for the backwash, A reverse water discharge passage for discharging the reverse water discharged by the reverse water discharge passage; The filtration process of the raw water is continued in each independent chamber, the cylindrical filtration tank is rotated to select the independent chamber, and backwashing is simultaneously performed by the shearing force and the levitation force by the backwash fluid in the selected independent chamber Continuous filtration and backwash.