KR101541148B1 - Fiber filter comprising extensible strainer - Google Patents

Abstract

The present invention relates to a pulling type air gap control fiber filter in which a strainer in a filtration tank is structured such that its length is increased or decreased in accordance with a pulling motion of a pore control unit so that the processing efficiency of the strainer fiber filter .

Description

[0001] FIBER FILTER COMPRISING EXTENSIBLE STRAINER [0002]

The present invention relates to a variable strainer fiber filter, and more particularly, to a strainer extension cap formed on a strainer so as to extend the length of the strainer in a filtration tank, thereby greatly increasing the processing capacity of the fiber filter, To a variable strainer fiber filter capable of improving the processing efficiency of the strainer fiber filter.

It is desirable that pollutants such as organic matter, nitrogen, phosphorus, heavy metals and salt contained in various domestic sewage, factory waste water, livestock wastewater are removed and purified and discharged to a river or public water area. Such wastewater is discharged without purification and becomes a main source of pollutants such as rivers and lake waters which are the source of ecosystem. In particular, due to the increase in population density and the development of industries, the water quality in the neighborhood of the city and in the downstream area is getting worse and worse, various types of filtration devices are being developed to purify such polluted wastewater or sewage.

The filtration device is a device for introducing raw water containing a suspended substance into a filtration device to discharge treated water from which suspended substances have been removed. The suspended substance in the raw water is subjected to sieving, precipitation, blocking, adsorption, Etc., and discharges only the treated clean water as treated water.

Among the filtration apparatuses, the gap-controlled fiber filter developed by the present applicant has been attracting attention because of the use of the fiber filter material having a large specific surface area, the filtration speed is fast, the structure of the apparatus is simple, the installation area is small, .

As an example of the above-mentioned void control fiber filter, the applicant of the present invention has disclosed in Korean Patent No. 813114 that a fiber filter material composed of a bundle of fiber yarn wrapped around a perforated pipe is pulled upward and compressed to reduce a gap, And then the filter is backwashed with compressed air and pressurized water. 2 is a schematic cross-sectional view showing the structure of the pulling-type air gap control fiber filter during filtration, and Fig. 3 is a cross-sectional view showing the structure of the pulling air gap control fiber filter during backwashing Fig.

During the filtration process, as shown in FIG. 2, the piston 80 rises and the fiber filter media 20 is pulled around the outer circumferential surface of the strainer 30 to increase the length of the fiber filter media , In the backwash process, as shown in Fig. 3, the length of the fiber filter material is shortened by lowering the piston 52 of the pulling drive part 50 and removing the tension of the fiber filter material 20. [ 2 and 3, since the size of the strainer is made to match the length of the fiber filter material of the diaphragm, a relatively large space remains on the strainer in the filtration process, There is an undesirable problem in terms of efficiency.

SUMMARY OF THE INVENTION It is an object of the present invention to solve the above-mentioned problems of the prior art, and it is an object of the present invention to provide a strainer that can be expanded in a manner that maximizes a filtration gap, So that it is possible to provide a variable strain strainer fiber filter.

It is another object of the present invention to provide a strainer fiber filter which can further reduce the size of the entire fiber filter by maximizing the processing capacity per fiber filter.

According to one aspect of the present invention for achieving the above object,

A filtration tank in which a fiber filter material is mounted and which defines a filtration space; A strainer installed in the filtration tank, having a hollow portion therein, and having a plurality of filtrate inflow holes on a side surface thereof; A lower and upper fiber filter material fixing unit installed opposite to each other with the strainer interposed therebetween for fixing a fiber filter material to a side surface of the strainer; A fibrous filter material consisting of a plurality of fiber bundles fixed between the lower and upper fiber media fixing portions to form a fleece layer; And a pore control part for controlling pores of the fiber filter material by pulling up or down the upper fiber filter material fixing part to compress or relax the fiber filter material,

Further comprising a strainer extension cap connected to an upper portion of the strainer so that the lower end thereof is opened to cover the strainer and has a plurality of filtrate inflow holes on a side surface thereof,

The strainer extension cap is connected and fixed to the gap control unit so that when the upper fiber filter fixing unit is pulled up by the gap control unit during filtration, the strainer extension cap is extended to receive the pulling motion of the gap control unit, To the variable strainer fiber filter.

According to the variable strainer fiber filter of the present invention, the length of the strainer in the filtration tank can be extended to maximize the treatment efficiency even if a fiber filter of the same size is used.

In addition, in a fiber filter composed of a plurality of fiber filters, the processing capacity of each fiber filter is greatly increased, and the processing capacity per unit area can be greatly improved, and the installation site is reduced when the fiber filter of the target capacity is reduced, Can be greatly reduced.

1 is a cross-sectional view of a conventional pulling-type air gap control fiber filter.
2 is a schematic cross-sectional view showing the structure of a conventional pulling-type air gap control fiber filter during filtration.
3 is a schematic cross-sectional view showing a structure of a conventional pull-up type air gap control fiber filter during backwashing.
4 is a schematic cross-sectional view of a variable strainer fiber filter according to an embodiment of the present invention.
5 is a perspective sectional view of a filtration tank of a variable strainer fiber filter according to an embodiment of the present invention.
6 is a schematic perspective view of a filtration tank of a strainer fiber filter according to an embodiment of the present invention.
7 is a cross-sectional view showing an example of a connection relationship between the strainer and the strainer extension cap of the variable strainer fiber filter of the present invention.

The preferred embodiments of the present invention will now be described in more detail with reference to the drawings. In the following description of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear.

FIG. 4 is a schematic cross-sectional view of a strainer fiber filter according to an embodiment of the present invention, FIG. 5 is a perspective view of a filtration tank of a strainer fiber filter according to an embodiment of the present invention, Figure 3 is a schematic perspective view of a filtration tank of a strainer fiber filter according to the present invention.

As shown in FIG. 4, the fiber filter of an embodiment of the present invention includes a filtration tank 10 in which a fiber filter material is mounted and which defines a filtration space; A strainer (30) installed in the filtration tank, having a hollow portion therein, and having a plurality of filtrate inflow holes on a side surface thereof; Lower and upper fiber filter material fixing parts (40, 60) provided opposite to each other with the strainer interposed therebetween for fixing the fiber filter material (20) to the side surface of the strainer (30); A fiber filter material 20 made up of a plurality of fiber bundles fixed between the lower and upper fiber media fixing portions 40 and 60 to form an outer layer; And a cavity control part (50) for controlling the air gap of the fiber filter material by pulling up or down the upper fiber material fixing part (60) to compress or loosen the fiber filter material (20)

Further comprising a strainer extension cap (70) connected to an upper portion of the strainer (30) to open the lower end to cover the strainer (30) and having a plurality of filtrate inflow holes on a side surface thereof,

The strainer extension cap 70 is connected and fixed to the air gap control unit 50 so that when the upper fiber material fixing unit 60 is pulled up by the air gap control unit 50 during filtration, Is extended to receive the pulling motion of the gap control unit (50) to extend the length of the strainer (30).

A piston guide 31 embedded in the coaxial direction is formed on the upper portion of the strainer 30. The cavity control unit 50 includes a cylinder 51 fixed to the upper portion of the outer side of the filtration tank 10 by a support, And a piston 80 extending from the cylinder 50 through the strainer extension cap 70 to the piston guide 31 of the strainer 30 and driven by the cylinder 51 to guide the pulling motion . The piston 80 extends through the strainer extension cap 70 to the upper portion of the outer side of the filtration tank 10 so that the upward and downward movements of the piston 80 raise and lower the strainer extension cap 70 Can be adjusted. The structure of the air gap control unit 50 is not limited to the structure of the cylinder 51 and the piston 80. The structure of the air gap control unit 50 is not limited to the structure of the cylinder 51 and the piston 80, Other possible structures may be employed in accordance with the present invention, as long as they are capable of being disengaged or disengaged.

The strainer extension cap 70 is coaxially formed inside the filtration tank 10 opened at the bottom of the strainer 30 so that the fiber filter media 20 is pulled up by the stretched length during filtration, The fiber filter material is lowered as it is relaxed to form one variable strainer together with the strainer 30.

Both sides of the strainer 30 and the strainer expanding cap 70 include hooks 74 that are configured to come into close contact with each other in a concave and convex shape and the strainer extension cap 70 is in a state of being in close contact with the strainer 30 The slider may be slid upward in the direction of the gap control unit 50 or may be slid back to a state before the slider is lowered and extended again.

In the variable strainer fiber filter of the present invention, when the strainer extension cap 70 is pulled up by the piston 80 of the gap control unit 50 during filtration, the strainer extension cap 70 The concave portion 72 of the strainer 30 of the strainer 30 is in contact with the convex portion 72 of the strainer 30 and the concave portion 73 of the strap hole 74 of the inner circumferential surface of the strainer extension cap 70 is engaged with the convex portion 72 of the strainer 30. [ The strainer 30 can be moved in the strainer extension cap 70 so that the length of the strainer can be extended. The stoppers 74 and 74 prevent the strainer extension cap 70 from being separated from the strainer 30.

For example, on the lower inner surface of the strainer extension cap 70, a plurality of protrusions 74 formed of a plurality of protrusions and recesses are formed on both sides, and on both upper and lower outer surfaces of the strainer 30, a plurality of protrusions and recesses The strainer extension cap 70 is formed with an engagement hole 74 on the inner side of the strainer extension cap 70 and an outer surface of the strainer 30

The strap 74 can be engaged and the strainer can be extended in length.

The strainer extension cap 30 is formed at its lower inner surface with convex portions on both sides and has recesses formed on both sides of the outer surface of the strainer to be engaged with the convex portion of the strainer extension cap. The strainer may be coupled to the inside so that the length of the strainer is extended.

The structure for connecting the strainer to the strainer extension cap is not necessarily limited to the above-described structure of the protruding and recessed structure, and other possible connecting structures may be employed according to the present invention. For example, in another embodiment, a long convex portion may be formed on the inner circumferential surface of the strainer extension cap 70, and a long concave portion coupled to the convex portion may be formed on the outer surface of the strainer 30, The convex portion of the inner surface of the strainer extension cap 70 and the concave portion of the outer surface of the strainer can be slid while being in contact with each other

In the fiber filter of the present invention, a raw water inflow pipe 200 for inflow of raw water to be treated and a backwater water discharge pipe 200 for discharging waste water are connected to the filtration tank 10. The installation position of the raw water inlet pipe 200 and the reverse water drainage pipe 100 is not particularly limited and may be formed on the upper side or the upper side of the filtration tank 10. The filtration and back- Is selected.

An air inflow pipe 400 for injecting backwash air is connected to the lower end of the filtration tank 10 and the treated water discharge pipe 300 extending to the outside of the filtration tank 10 is connected to the bottom. A piston guide 31 is formed in the upper portion of the filtration tank 10 in a coaxial direction. The piston guide (31) guides the piston of the air gap control part and supports the upper end of the strainer (30) by the piston (80).

The air gap control unit 50 is generally composed of a cylinder 51 and a piston 80 that are operated by pneumatic or hydraulic pressure. The cavity control unit 50 is a mechanical unit for driving the piston 80 to receive the guidance of the piston guide 31. The cylinder 51 is fixed to the upper portion of the outside of the filtration tank 10 by a support. The movement of the piston (80) by the cylinder (51) may be performed by a simple linear movement or by a rotary cylinder in which linear motion and rotation are similar.

The upper fiber material fixing part 60 of the present invention is a part that is fixed to the piston 80 to the outside of the upper end of the strainer 30 within the filtration tank 10 and receives the pulling motion of the piston 80, The lower fiber media fixing part 60 is fixed to the outside of the bottom of the strainer 30 inside the filtration tank 10.

The fiber filter material 20 of the present invention is fixed to the upper fiber material fixing part 60 and the lower fiber filter fixing part 40 so that the air gap control part 50 is driven to form a filtration gap on the outer circumferential surface of the strainer 30 . The lower and upper fiber media fixing parts 40 and 60 are formed to have a diameter smaller than that of the strainer 30 in order to make the fiber filter media have a directionality to be pressed toward the strainer 30, It is not always necessary that the lower fiber filter media fixing portion has the same diameter.

Air is blown from the bottom of the fiber filter media 20 through the air inlet pipe and the air distribution plate (not shown) is attached to the bottom of the strainer 30 in the filtration tank 10 ) May be provided.

The filtration and backwashing operation of the fiber filter of the present invention will be described below. First, the raw water to be treated is fed into the inside of the filtration tank 10, and then filtered by a fiber filter. The filtering ability of the fiber filter media 20 is determined by the pores formed by the fiber filter media 20, and the pores are formed by the tensile tension of the fiber filter media 20. In the present invention, the tensile tension of the fiber filter material 20 is formed by the movement of the piston 80 by the gap control unit 50. That is, when the piston 80 rises, the upper filter material fixing part 60 fixed to the piston 80 pulls the fiber filter material 20 upward, and tensile tension is formed, and the tensile tension of the fiber filter material 20 is The internal voids are reduced to form filtration voids. When the piston 80 of the rotary cylinder is used to generate the linear motion and the rotary motion of the piston 80 of the cavity control unit 50 at the same time, Is pulled around the outer peripheral surface of the strainer (30). The strainer extension cap 70 also rises due to the upward movement of the piston 80. As the fiber filter media 20 is pulled and elongated, the length of the strainer is increased by the extension of the strainer extension cap 70, The capacity is increased. For example, when the length of the strainer 30 is 1 m and the length of the strainer extension cap 70 is 1 cm, the capacity of the filtration layer during the compression filtration is increased by 10% as compared with the conventional fiber filter.

Next, the backwashing process of the fiber filter will be described. The backwash process can be performed automatically or manually, and the raw water valve of the fiber filter is closed and the backwash water drain valve is opened to form a backwash path composed of the treatment water drain pipe 300, the fiber filter, and the reverse water drain pipe 100 . When the backwashing is performed, the piston 80 of the air gap control unit 50 is lowered to remove the tension of the fiber filter media 20. At this time, when the piston 80 descends, the upper fiber material fixture 60 fixed to the piston 80 and the strainer extension cap 70 are lowered together, thereby loosening the fiber filter material 20, The inner space of the filter medium 20 is expanded.

When the fibrous filter material is loosened, the fibrous filter material 20 is easily washed, vibrated, rubbed and backwashed by the water jetted from the strainer 30. At this time, air is injected from the bottom of the fiber filter material 20 through the air inlet pipe, and the backwash efficiency is improved. The water introduced through the treated water drain pipe 300 is blown into the fiber filter media 20 through the strainer 30 to back up the fiber filter media 20 and return to the inside of the fiber filter media 20, Is drained to the outside through the reverse water drainage pipe. If it is determined that the suspended particulate matter trapped in the fibrous filter material 20 has been sufficiently desorbed, the process returns to the filtration step.

While the present invention has been particularly shown and described with reference to preferred embodiments thereof, it will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the following claims Those skilled in the art will readily understand. Accordingly, the scope of protection of the present invention should be determined by the scope of the appended claims and their equivalents.

10: Filtration tank 20: Fiber media
30: Strainer 31: Piston guide
40: lower filter material fixing part 50: air gap control part
51: cylinder 80: piston
53: support member 54: length adjusting means
60: upper filter material fixing part 70: strainer extension cap
72, 72: convex portion 74:
3, 73: lumbar part 100: station water drainage pipe
200: raw water inlet pipe 300: treated water pipe
400: air inlet pipe

Claims (5)

A filtration tank in which a fiber filter material is mounted and which defines a filtration space; A strainer installed in the filtration tank, having a hollow portion inside and having a plurality of filtrate inflow holes on a side surface thereof; A lower and upper fiber filter material fixing unit installed opposite to each other with the strainer interposed therebetween for fixing a fiber filter material to a side surface of the strainer; A fibrous filter material consisting of a plurality of fiber bundles fixed between the lower and upper fiber media fixing portions to form a fleece layer; And a pore control part for controlling pores of the fiber filter material by pulling up or down the upper fiber filter material fixing part to compress or relax the fiber filter material,
Further comprising a strainer extension cap connected to an upper portion of the strainer so as to cover the strainer, the strainer extending cap having a plurality of filtrate inflow holes at a side thereof,
The strainer extension cap is connected and fixed to the gap control unit so that when the upper fiber filter fixing unit is pulled up by the gap control unit during filtration, the strainer extension cap is extended to receive the pulling motion of the gap control unit, Is extended to extend in the longitudinal direction.
2. The filtration apparatus according to claim 1, wherein the gap control unit comprises: a cylinder fixed by a supporter on an outer side of the filtration tank; and a piston extending from the cylinder to the piston guide of the strainer and being driven by the cylinder to guide the pulling motion, Wherein the strainer is formed with a piston guide which is coaxially inserted into an upper portion of the strainer, and the piston extends through the strainer extension cap to the piston guide.
2. The air conditioner according to claim 1, wherein the strainer and the strainer expandable cap have hooks that are configured to come into close contact with each other in a concavo-convex shape, and the strainer extension cap is slidable in the direction of the air gap control unit in close contact with the strainer So that the strain of the strainer is reduced.
The strainer according to claim 3, further comprising: a plurality of protrusions formed on both sides of the lower inner surface of the strainer extension cap, the protrusions being formed by a plurality of convex portions and concave portions, And the length of the strainer is extended by engaging the strainer having the latching part formed on both sides of the outer surface thereof.
4. The air conditioner according to claim 3, wherein a convex portion is formed on both inner sides of the lower inner surface of the strainer extension cap, and a recess is formed on both sides of the outer surface of the strainer to be engaged with the convex portion of the strainer extension cap, And the strainer is coupled to the inside of the strainer extension cap so as to extend the length of the strainer.

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