KR20140110345A - Filtration apparatus - Google Patents

Abstract

The purpose of the present invention is to provide a filtering device capable of increasing the efficiency of filtering foreign materials and washing media by enabling the uniform twist of the media. To achieve this, the present invention comprises: a filtering tank (100) for introducing raw water and discharging treated water having foreign materials filtered; a driving part (200) for linearly reciprocating a shaft (240) connected to the rod (220) of a cylinder (210) extending toward the inside of the filtering tank (100); a first rotating plate (300) and a second rotating plate (400) arranged vertically at intervals inside the filtering tank (100) and rotated forward or backward around the shaft (240) by the drive of the driving part (200), wherein the first rotating plate and the second rotating plate rotate simultaneously in opposite directions; and a media (700) composed of a plurality of bundles fixed in a circumferential direction at the edges of the first rotating plate (300) and the second rotating plate (400).

Description

FILTRATION APPARATUS

More particularly, the present invention relates to a filtration apparatus in which a first rotating plate and a second rotating plate, on which upper and lower ends of a filter medium are fixed by a single driving unit, are simultaneously rotated in mutually opposite directions to uniformly twist the filter media The present invention relates to a filtration device capable of improving the efficiency of filtration of foreign matters and cleaning of filter media, as well as maintenance and replacement of filter media.

In general, the operation of the filtration device is divided into a filtration process and a cleaning process. The filtration process is a process for introducing raw water containing foreign matters such as floating matters into a filtration device, capturing foreign substances into the voids in the filtration layer of the filtration device, and discharging clean treated water from which foreign substances have been removed. When the filtration process is continued, the voids in the filtration layer are gradually filled with foreign substances and the filtration resistance is increased, so that the filtration process can no longer be continued. In this case, a washing process is required to inject clean water and air, etc., to remove suspended substances trapped in the pores and discharge them.

As a prior art relating to a device for filtering foreign substances into the voids in the frit layer as described above, Japanese Patent No. 10-0362594 discloses a void-controlled filtration device shown in Fig. The gap control type filtration apparatus includes a radial upper filter member 23 coupled to an upper rotary shaft 25 and a lower radial filter member 24 coupled to a fixed shaft of the pore tube 22, The upper and lower filter media blocks 23 and 24 are connected to the upper and lower filter media blocks 23 and 24 to form an additional layer 21a, (21) hung on the upper and lower filter members (23, 24) according to the rotating direction and degree of rotation of the upper rotating shaft (25) Is wound around the pore tube (22) located on the central axis and at the same time receives a tensile force and collects at the center along the upper and lower filter media (23, 24) So that the size of the pores can be arbitrarily increased, . Reference numerals 28 and 28a denote an upper handle 28 connected to the upper rotary shaft 25 and an upper handle fixing pin 28a for fixing the rotation of the upper handle 28. [

However, the gap-controlled filtering apparatus is constructed in such a manner that the filter material 21 caught by the upper and lower filter media 23 and 24 is twisted and twisted by the rotation of the upper rotation shaft 25 connected to the upper filter material block 23 There is a problem that the twisting between the filter material 21 in the vicinity of the upper filter material block 23 and the filter material 21 in the vicinity of the lower filter material block 24 is not uniform and the porosity is varied and the filtration efficiency is lowered.

In addition, in the conventional filtration apparatus, the filter material 21 is installed inside the closed filtration tank 2. In the conventional filtration apparatus, There is a problem that the maintenance and replacement work of the filter material 21 is not easy.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a filtration apparatus capable of improving the efficiency of filtration of foreign substances and cleaning of filter media by uniformly twisting the filter media.

Another object of the present invention is to simplify the structure of the driving part for winding or unwinding the filter media, and to filter the foreign matter and to clean the filter media by freely adjusting the size of the filter media as necessary Device.

It is still another object of the present invention to provide a filtration apparatus which can perform maintenance and replacement operations of filter media easily and efficiently.

The filtration apparatus of the present invention for realizing the above-mentioned object comprises: a filtration tank (100) for discharging treated water into which raw water flows and foreign substances are filtered; A driving unit 200 for linearly reciprocating the shaft 240 connected to the rod 220 of the cylinder 210 extending to the inside of the filtration tank 100; A plurality of rotatable shafts 240 rotatably disposed in the filtration tank 100 so as to be rotatable in a direction opposite to the rotation direction of the shaft 240 by driving the driving unit 200, A first rotating plate 300 and a second rotating plate 400; And a plurality of bundles 700 fixed in parallel to the circumferential direction at the edges of the first and second rotating plates 300 and 400.

In this case, the shaft 240 includes a first helical groove 242 and a second helical groove 243 in opposite directions to each other on the outer peripheral surface of both side portions; The first rotating plate 300 and the second rotating plate 400 include a first rotating part 500 and a second rotating part 600 that transmit power to rotate in a forward or reverse direction in conjunction with driving of the driving part 200 But; The first rotating part 500 includes a first body part 511 coupled to the first rotating plate 300 and a second body part 511 protruding from the first body part 511 and inserted into the first helical groove 242 And a first rotation guide member 510 formed of a first protrusion 512 and rotatably supported in the filtration tank 100. The second rotation unit 600 includes a first rotation plate 500, And a second protrusion 612 protruded from the second body 611 and inserted into the second spiral groove 243. The inner surface of the inner portion of the filtration tank 100 And a second rotation guide member 610 rotatably supported by the second rotation guide member 610.

The first helical groove 242 is formed in a double structure symmetrical to an opposing position of the outer circumferential surface of the shaft 240. The first rotational guide member 510 is formed in the double helical groove And the second helical groove 243 is formed in a double structure having a shape symmetrical to the outer circumferential surface of the shaft 240. The second helical groove 243 is formed at a position opposite to both sides of the shaft 240, And the second rotation guide member 610 may be provided at opposite positions on both sides of the shaft 240 so as to correspond to the second helical groove 243.

The first rotary plate 300 includes a first rotary plate portion 300a to which one end of the filter media 700 is coupled and a second rotary plate portion 300b extending to one side of the central portion of the first rotary plate portion 300a, And a first cylindrical portion 300b through which the first rotation guide member 510 is coupled and the first cylindrical portion 300b is connected to the filtration tank 100 through a first bearing 530. [ ) Supported by a first support plate (140) mounted on the inside of the upper portion of the first support plate The second rotating plate 400 includes a second rotating plate part 400a to which the other end of the filtering material 700 is coupled and a second rotating plate part 400b extending from the center of the second rotating plate part 400a, And the second cylindrical portion 400b is connected to the filtration tank 100 through the second bearing 630. The second cylindrical portion 400b is coupled to the second rotation guide member 610, And a second support plate 150 mounted on a lower inner side of the support plate 150.

A first fixing member 520 for supporting the first bearing 530 is coupled to the first cylindrical portion 300b of the first support plate 140, And a second fixing member 620 for supporting the second bearing 630 is coupled between the first cylindrical portion 400b and the second cylindrical portion 400b.

The shaft 240 has a first circular groove 244 connected to the first helical groove 242 and a second helical groove 243 and connected to the outer circumferential surface of the shaft 240, When the first protrusion 512 and the second protrusion 612 are positioned in the first circular groove 244 and the second circular groove 245 respectively, The first rotating plate 300 and the second rotating plate 400 can be manually rotated.

The rod 220 of the cylinder 210 and the shaft 240 are coupled by a coupling 230 and 230a and 230b. When the coupling 230 is separated from the shaft 240, And the first circular groove 244 and the second circular groove 245 may be positioned on the first projection 512 and the second projection 612, respectively.

The inner space of the filtration tank 100 includes a first support plate 140 and a second support plate 150 which support the first rotary plate 300 and the second rotary plate 400 and are vertically spaced apart and mounted in the horizontal direction, A second chamber 100b in which raw water is filtered and a third chamber 100c in which filtered water is discharged and the second chamber 100b is divided into a first chamber 100a through which raw water flows, The porous plate 160 is disposed between the first rotating plate 300 and the second rotating plate 400 and is wound around the outer circumferential surface of the filter media 700. The porous plate 160 is rotatably supported by the second rotating plate 400, And the third chamber 100c through the first connection pipe 161 and the second connection pipe 162 passing through the second support plate 150. [

The second rotation plate 400 is spaced apart from the center axis of the pore tube 160 by a different length so that the first and second connection pipes 161, Shaped first connection pipe insertion hole 413 and a second connection pipe insertion hole 414 are formed in the first connection pipe insertion hole 413 and the second connection pipe insertion hole 414, respectively.

In addition, a door 110a for opening and closing the filtration tank 100 may be provided on one side of the filtration tank 100. [

The second rotating plate 400 includes a first plate portion 410 having a hooking ring 411 and a hooking pin 415 protruding upward in the circumferential direction at a top edge portion thereof, And is formed at a distance corresponding to the filter material hooking ring 411 so as to prevent the detachment of the filter material 700 from the detachment of the filter material 700. [ And a second plate portion 420 provided with a release prevention pin 422 for preventing the first rotation plate 300 and the second rotation plate 400. The first rotation plate 300 may have a laminated structure symmetrical with the second rotation plate 400. [

When the second plate portion 420 is rotated in one direction so that the engaging pin 415 is engaged with the inner side surface of the elongated hole 421 and the engaging pin 415 is fastened by the engaging means 416, The locking member 416 is brought into a locked state in which the filter media hook 411 and the separation preventing pin 422 are vertically aligned so as to prevent the filter media 700 from being released, When the second plate 420 is rotated in the other direction so that the separation preventing pin 422 is caught by the other inner side surface of the elongated hole 421, the filter retaining hook 411 and the separation preventing pin 422 And can be configured to be spaced apart from each other in the circumferential direction to be in an unlocked state in which the filter media 700 can be replaced.

A plurality of connection links 221 are radially coupled to the rod 220 of the cylinder 210 and a plurality of filtration vessels 100-1, 100-2, 100-3, and 100-4 are connected to the plurality of connection links 221. [ A plurality of shafts 240 extending from the plurality of filtration tanks 100 are connected to one another so that the filtration operation is simultaneously performed by the plurality of filtration tanks 100 by one driving unit 200.

According to the filtration apparatus of the present invention, since the first rotating plate and the second rotating plate, both ends of which are fixed by one driving unit, are simultaneously rotated in mutually opposite directions, uniform twisting of the upper and lower portions of the filter medium is possible, The filtering efficiency of the foreign matter can be improved.

In addition, since the first and second rotary plates are rotated in conjunction with the vertical movement of the shaft coupled to the rod of the cylinder, the structure of the drive unit can be simplified.

Further, since the amount of rotation of the first rotating plate and the second rotating plate is adjusted in proportion to the amount of up-and-down movement of the driving unit, the pore size of the filtering material can be arbitrarily adjusted as required according to filtration conditions.

In addition, in the maintenance and replacement of the filtration media, a coupling for connecting the rod and the shaft of the cylinder is separated to form a first circular groove and a second circular groove in the shaft, The maintenance and replacement work of the filter media can be easily performed while rotating the first and second rotary plates in a state where the first projection of the rotation guide member and the second projection of the second rotation guide member are positioned.

The first rotating plate and the second rotating plate are formed in a laminated structure of the first plate portion and the second plate portion, respectively, and the second plate portion is rotated to adjust the spaced positions between the filtering member hook and the separation preventing pin, 2 The structure in which both ends of the filter material are detachably attached to the rotary plate can be simplified.

Figure 1 shows a prior art filtration device,
2 is a cross-sectional view of a filtration apparatus according to an embodiment of the present invention,
3 is an enlarged view of a portion 'A' in FIG. 2,
4 is an enlarged view of a portion 'B' in FIG. 2,
5 is an enlarged view of the shaft,
6 is an exploded perspective view showing a laminated structure of the second rotary plate,
7 is an operational state diagram of the second rotating plate when the filter material is replaced,
8 is a front view of a filtration apparatus according to the present invention,
Fig. 9 is an operational state diagram for maintenance and replacement of filter media,
Fig. 10 is an operational state diagram of filtering foreign matters,
Fig. 11 is a diagram showing the operation state of the filter material at the time of cleaning,
12 is a perspective view of a filtration apparatus according to another embodiment of the present invention,
13 is a perspective view of a filtration apparatus according to another embodiment of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

FIG. 2 is a cross-sectional view of a filtration apparatus according to an embodiment of the present invention, FIG. 3 is an enlarged view of a portion A of FIG. 2, FIG. 4 is an enlarged view of a portion B of FIG. .

The filtration apparatus according to an embodiment of the present invention includes a filtration tank 100 through which raw water flows and filtered to remove process water and is connected to a rod 220 of a cylinder 210 extending to the inside of the filtration tank 100 A driving unit 200 that reciprocates the shaft 240 in a linear direction and a driving unit 200 that is vertically spaced apart from the inside of the filtration tank 100. The driving unit 200 drives the shaft 240 A first rotating plate 300 and a second rotating plate 400 which are rotated in the opposite direction to each other in the forward and reverse directions and are rotated simultaneously with the driving of the driving unit 200. The first rotating plate 300 and the second rotating plate The first rotating part 500 and the second rotating part 600 that transmit power to rotate the first rotating plate 400 and the second rotating plate 400 in the forward or reverse direction and the first rotating part 500 and the second rotating part 600, And a plurality of bundled filter media (700).

The filtration tank 100 includes a cylindrical housing 110 and an upper lid 120 and a lower lid 130 that cover the upper and lower portions of the housing 110. A first pipe 101 into which raw water containing foreign substances flows is connected to one side of the upper lid 120 and a second pipe 101 connected to the other side of the upper lid 120 is detached from the filter media 700 by a washing process of the filter media 700 And a third pipe 103 through which foreign substances, washing water, and air are discharged is connected. The second pipe 102 is connected to one side of the lower portion of the housing 110 through which the washing water for removing the foreign substances contained in the raw water is discharged, An air injection tube 111 through which air for a cleaning process is supplied is connected. A valve (not shown) for interrupting the flow of raw water, treated water, and washing water is installed in each of the pipelines connected to the first pipe 101, the second pipe 102, and the third pipe 103.

The inner space of the filtration tank 100 is divided into a first chamber 100a and a second chamber 100b by a first support plate 140 and a second support plate 150 mounted transversely to the upper and lower portions of the housing 110, The chamber 100b and the third chamber 100c. That is, the inner space of the filtration tank 100 includes a first chamber 100a between the upper lid 120 and a first support plate 140 through which a plurality of perforations 141 are vertically passed, a first support plate 140, A second chamber 100b between the second support plate 150 and the third chamber 100c between the second support plate 150 and the lower lid 130,

The second chamber 100b is provided with a pore tube 160 having a cylindrical shape and a plurality of pores 160a formed on the outer surface thereof. The pore tube 160 extends downwardly from the bottom of the pore tube 160, And is supported by the first connection pipe 161 and the second connection pipe 162 which are coupled to the support plate 150 such that the lower end of the support pipe 150 is penetrated.

 The driving unit 200 includes a cylinder 210 driven by hydraulic or pneumatic pressure and a rod 220 whose length is varied in the vertical direction by driving the cylinder 210 to be fixedly mounted on the upper lid 120 A shaft 230 which is coupled to the rod 220 of the cylinder 210 through a coupling 230 and 230a and 230b and passes through the pore tube 160 at a central portion of the inside of the filtration tank 100, 240).

5, the shaft 240 includes a first helical groove 242 (242a, 242b) and a second helical groove 243 (242a, 242b) along the spiral direction on the upper and lower outer circumferential surfaces of the cylindrical shaft body 241, 242a and 242b and the second helical grooves 243 and 243a and 243b are formed on the outer circumferential surface of the shaft 240 at an angle of 180 ° with respect to the circumferential surface of the shaft 240. The first helical groove 242, And are symmetrically formed at positions opposed to each other. The shaft 240 is connected to the upper end of the first helical groove 242 and the second helical groove 243 and is connected to the outer circumferential surface of the shaft 240 through a first circular groove The first circular groove 244 and the second circular groove 245 are formed to have a predetermined width. The first spiral grooves 242 and 242b and the second spiral grooves 243a and 243b rotate in conjunction with the upward and downward movement of the shaft 240 to rotate the first rotary plate 300 and the second rotary plate 400 The first circular groove 244 and the second circular groove 245 serve as power transmission means for avoiding interference between the first rotary plate 140 and the second rotary plate 150 during manual rotation The operation will be described later.

3, the first rotary plate 300 includes a first rotary plate portion 300a to which the upper end of the filter media 700 is fixed, and a second rotary plate portion 300b extending upward from the central portion of the first rotary plate portion 300a, And a first cylindrical portion 300b through which the second arm portion 240 penetrates.

The first rotating part 500 converts the upward and downward movement of the shaft 240 into rotational motion and transmits the rotational force to the first rotating plate 300, A first body portion 511 which is coupled to the cylindrical portion 300b by a fastening means 513 and a first projection portion which protrudes from the first body portion 511 and is inserted into the first helical groove 242 A first fixing member 520 coupled to a central portion of a first support plate 140 through which the shaft 240 passes by fastening means 521, And a first bearing 530 coupled to the first cylindrical portion 300b by a bearing fixing means 531 between the first fixing member 520 and the first cylindrical portion 300b. The first rotation guide member 510 is provided at the opposed positions on both sides of the shaft 240 so as to correspond to the first helical groove 242 (242a, 242b). When the shaft 240 is moved up and down by the driving unit 200, the first spiral groove 242 (242a, 242b) formed in the shaft 240 and the first spiral groove 242 The first rotation guide member 510 and the first rotation plate 300 coupled to the first rotation guide member 510 are rotated in the forward or reverse direction by the relative movement between the first rotation guide member 510 The first rotating plate 300 and the first rotating plate 300 can smoothly rotate without being subjected to rotational interference due to the lubricating action of the first bearing 530. Accordingly, Is rolled or unwound along the rotating direction of the first rotating plate 300.

4, the second rotary plate 400 includes a second rotary plate portion 400a to which the lower end of the filter media 700 is fixed, a second rotary plate portion 400b extending downward from the central portion of the second rotary plate portion 400a, And a second cylindrical portion 400b through which the second electrode 240 penetrates.

The second rotary part 600 converts the upward and downward movement of the shaft 240 into a rotary motion and transmits the rotational force to the second rotary plate 400. The second rotary part 600 includes a second rotary part 400, A second body portion 611 coupled to the cylindrical portion 400b by a fastening means 613 and a second projection portion protruding from the second body portion 611 and inserted into the second helical groove 243 A second fixing member 620 coupled to a central portion of a second support plate 150 through which the shaft 240 passes by a fastening means 621, And a second bearing 630 which is coupled by the bearing fixing means 631 between the second cylindrical portion 400b and the second fixing member 620. The second rotation guide member 610 is provided at an opposite position on both sides of the shaft 240 so as to correspond to the second helical groove 243 (243a, 243b). When the shaft 240 is moved up and down by the driving unit 200, the second spiral groove 243 (243a, 243b) formed in the shaft 240 and the second spiral groove The second rotation guide member 610 and the second rotation plate 400 coupled to the second rotation guide member 610 are moved relative to the first rotation guide member 510 and the first rotation plate 300 by the relative movement of the second projection 612 inserted into the first rotation guide member 610, The second rotation guide member 610 and the second rotation plate 400 can rotate smoothly without being subjected to rotational interference due to the lubricating action of the second bearing 630 So that the filter material 700 whose lower end is fixed to the second rotating plate 400 is wound or unwound along the rotating direction of the second rotating plate 400. [

As described above, in the present invention, the first spiral groove 242 and the second spiral groove 242 are formed on the upper and lower outer circumferential surfaces of the shaft 240 moving up and down by the driving of one driving unit 200, The first and second rotating parts 500 and 600 convert the linear motion of the shaft 240 into rotational motion in different directions and transmit the rotational force to the first rotating plate 300 and the second rotating part 600. [ The upper and lower portions of the filter media 700 having both ends fixed to the first and second rotary plates 300 and 400 are uniformly twisted to each other to be uniformly formed .

Fig. 6 is an exploded perspective view showing the lamination structure of the second rotary plate, Fig. 7 is an operational state view of the second rotary plate when replacing the filter media, Fig. 8 is a front view of the filtration device according to the present invention, It is an operation state diagram at the time of replacement.

The second rotating plate 400 is provided between the lower end of the pore tube 160 and the second supporting plate 150 and is capable of preventing interference between the first connecting pipe 161 and the second connecting pipe 162 Is required. The first connection pipe 161 and the second connection pipe 162 connected to the lower portion of the pore tube 160 are spaced apart from each other by a distance from the center axis of the pore tube 160, The first and second connection pipe insertion holes 413 and 414 are formed in the second rotation plate 400 so that the first connection pipe 161 and the second connection pipe 162 are inserted. . The first connection pipe insertion hole 413 and the second connection pipe insertion hole 414 are formed so that the center of the shaft through hole 412 formed at the center of the second rotation plate 400 is centered on the radius, And is formed in a predetermined rotation angle range. Therefore, even if the angle formed by the first and second connection tube insertion holes 413 and 414 is greater than 180 degrees, the rotation of the second rotation plate 400 can be performed without causing interference between the first and second connection tube insertion holes 413 and 414 . In the present embodiment, the first connection pipe 161, the second connection pipe 162, the first connection pipe insertion hole 413, and the second connection pipe insertion hole 414 are formed at two locations, respectively However, the present invention is not limited thereto, and it is needless to say that the present invention can be configured to be installed in a plurality of locations in a position where they do not interfere with each other.

In the present invention, in order to improve the convenience of maintenance and replacement of the filter media 700, both ends of the filter media 700 are attached to the bottom edge of the first rotating plate 300 and the top edge of the second rotating plate 400 And hooked to the hooks 311 and 411 of the filter media which are coupled to each other along the circumferential direction.

6 and 7, the first rotating plate 300 and the second rotating plate 400 can be easily attached to and detached from the filtering material hooks 311 and 411, respectively. The structure of the second rotary plate 400 will be described with reference to the first rotary plate 300 and the first rotary plate 300 except for the first connection pipe insertion hole 413 and the second connection pipe insertion hole 414 Since the second rotating plate 400 has the same structure as that of the second rotating plate 400, its description will be omitted.

6, the second rotating plate 400 includes a first plate portion 410 having a hooking hook 411 and a hooking pin 415 protruding upwardly along the circumferential direction at a top edge portion thereof, The first plate portion 410 has a slotted structure in which the engaging pin 415 is passed through and a space corresponding to the filter hooking ring 411 is formed. And a second plate portion 420 provided with a release prevention pin 422 for preventing the first plate portion 420 and the second plate portion 420 from coming off.

7 (a), the second plate portion 420 is rotated in one direction so that the engaging pin 415 is engaged with the inner side surface of the elongated hole 421, The locking member 411 and the separation preventing pin 422 are vertically aligned with each other so that the separation of the filter media 700 is prevented.

The second plate 420 is rotated in the other direction after the engaging means 416 is separated from the engaging pin 415 as shown in FIG. 7 (b) The locking hooks 411 and the separation preventing pins 422 are spaced apart from each other in the circumferential direction to be in an unlocked state in which the filter media 700 can be replaced.

Referring to FIG. 8, a door 110a for opening and closing the filtration tank 100 is provided on one side of the housing 110. As shown in FIG. In this case, it is preferable that the door 100a is made of a transparent material so that the door 100a can see the state of the filter media 700 installed in the filtration tank 100. [

9, the door 110a is opened and a coupling (not shown) for connecting the rod 220 and the shaft 240 of the cylinder 210 The shaft 240 is moved downward by its own weight to form a first circular groove 244 formed on the outer circumferential surface of the shaft 240 and a second circular groove 244 formed on the outer circumferential surface of the shaft 240. [ The second circular groove 245 is positioned on the first protrusion 512 of the first rotation guide member 510 and the second protrusion 612 of the second rotation guide member 610 respectively. Accordingly, the first rotating plate 300 and the second rotating plate 400 are rotatable by manual operation.

The operator rotates the first rotating plate 300 and the second rotating plate 400 at a predetermined angle through the space opened by the door 110a and rotates the first rotating plate 300 and the second rotating plate 400, The upper and lower ends of the filter media 700 connected to each other by the operation as shown in FIG. 7 can be separated and the maintenance and replacement work of the filter media 700 can be easily performed.

Hereinafter, operations of the filtration process and the cleaning process of the present invention will be described with reference to FIGS. 10 and 11. FIG. Fig. 10 is an operation state diagram for filtering foreign matters, and Fig. 11 is an operational state diagram for cleaning filter media. 10, when the filtration process is performed, the valve provided in the washing water discharge passage of the third pipe 103 is shut off, and the valve provided in the raw water supply passage of the first pipe 101 and the valve provided in the second pipe 102, Thereby opening the valve provided in the process water discharge flow path. When the shaft 240 is moved upward by driving the driving unit 200, the first rotating plate 300 and the second rotating plate 400 are rotated in opposite directions in conjunction with the upward movement of the shaft 240, So that the space 700 between the filter media 700 is wound around the outer surface of the porous tube 160 and becomes twisted. In this case, the pore size of the filter media 700 can be arbitrarily adjusted in accordance with the required filtration conditions in proportion to the rotation angle of the first rotating plate 300 and the second rotating plate 400, which are linked with the up / down driving of the shaft 240.

The raw water supplied through the first pipe 101 flows into the first chamber 100a and then flows into the second chamber 100b through the perforations 141 formed in the first support plate 140, 700 and the hole 160a of the porous tube 160. The treated water flowing into the interior of the porous tube 160 passes through the first connection pipe 161 and the second connection pipe 162, Flows into the third chamber 100c, and then is discharged to the treated water discharge channel through the second pipe 102. [

11, when performing the cleaning process of the filtering material 700, the valves provided in the raw water supply flow path of the first pipe 101 and the valves provided in the process water discharge flow path of the second pipe 102 are blocked, The valve provided in the washing water supply passage of the second piping 102 and the valve provided in the washing water discharge passage of the third piping 103 are opened. At the same time, air is injected into the filtration tank 100 through the air inlet 111.

When the shaft 240 is moved downward by driving the driving unit 200, the first rotating plate 300 and the second rotating plate 400 are rotated in the filtering process in conjunction with the downward movement of the shaft 240. And is twisted in a direction opposite to the rotating direction, so that the air gap between the filter media 700 is loosened as the gap between them increases. In this state, the washing water supplied through the second pipe 102 flows into the third chamber 100c, passes through the first connecting pipe 161 and the second connecting pipe 162, And the foreign materials adhering to the holes 160a and the filter media 700 are removed while passing through the plurality of holes 160a formed in the porous tube 160 and the filter media 700, The washing water including the separated foreign matters is raised to the first chamber 100a through the perforations 141 of the first supporting plate 140 and then passes through the third pipe 103 to be discharged to the washing water discharge port 100a, . The cleaning action by the washing water and the aeration effect by the air introduced through the air inlet 111 further increase the desorption effect of the foreign matter adhered to the hole 160a of the porous tube 160 and the filter material 700 .

In order to increase the desorption effect of the foreign material in the filtering medium 700, the driving unit 200 may be repeatedly driven in the opposite direction to repeat the winding and unwinding of the filtering medium 700.

FIG. 12 is a perspective view of a filtration apparatus according to another embodiment of the present invention, and FIG. 13 is a perspective view of a filtration apparatus according to another embodiment of the present invention. Although the present invention has been described with reference to the case where the filtration apparatus is performed in one filtration tank 100 in the above embodiment, the present invention can be applied to the filtration apparatuses 100, . ≪ / RTI >

A plurality of connection links 221 are radially coupled to the rod 220 of the cylinder 210 and a plurality of filtration vessels 100-1, 100-2, and 100- A plurality of shafts 240 extending from the plurality of shafts 3, 100 and 4 are connected to the plurality of filtration tanks 100 to perform filtering and cleaning operations simultaneously. In this case, the first piping 101 and the second piping 102 are used in common, and the other structures provided in the respective filtration tanks 100 (100-1, 100-2, 100-3, and 100-4) are the same as those of the first embodiment And the same principle can be applied, so that a description thereof will be omitted.

As described above, according to the present invention, it is possible to uniformly twist the upper and lower portions of the filter media to prevent a change in the porosity, thereby improving the filtration efficiency of foreign substances and simplifying the structure of the drive portion. Since the amount of rotation of the first rotating plate and the second rotating plate is adjusted, the size of the pore size of the filter media can be arbitrarily adjusted as required according to filtration conditions, and the door for opening and closing one side of the filtration tank is made of a transparent material, It is possible to improve the operating efficiency of the apparatus for maintenance and replacement of the filter media by simplifying the structure in which both ends of the filter medium are detached.

100: Filtration tank 100a: First chamber
100b: second chamber 100c: third chamber
101: first piping 102: second piping
103: Third piping 110: Housing
110a: door 111: air inlet
120: upper cover 130: lower cover
140: first support plate 141: piercing
150: second support plate 160: porous member
200: driving part 210: cylinder
220: rod 230: 230a, 230b: coupling
240: shaft 241: body
242: first spiral groove 243: second spiral groove
244: first circular groove 245: second circular groove
300: first rotating plate 300a: first rotating plate part
300b: first cylindrical portion 311: filter material hook ring
400: second rotating plate 400a: second rotating plate part
400b: second cylindrical portion 410: first plate portion
411: filter material hook ring 412: shaft through hole
413: first connector insertion hole 414: second connector insertion hole
415: engaging pin 416: fastening means
420: second plate portion 421: long hole
422: release prevention pin 500: first rotation part
510: first rotation guide member 511: first body part
512: first protrusion 520: first fixing member
530: first bearing 531: bearing fixing means
600: second rotating portion 610: second rotation guide member
611: second body part 612: second projection
620: second fixing member 630: second bearing
631: bearing fixing means 700:

Claims (13)

A filtration tank (100) through which raw water flows and the foreign substances are filtered;
A driving unit 200 for linearly reciprocating the shaft 240 connected to the rod 220 of the cylinder 210 extending to the inside of the filtration tank 100;
A plurality of rotatable shafts 240 rotatably disposed in the filtration tank 100 so as to be rotatable in a direction opposite to the rotation direction of the shaft 240 by driving the driving unit 200, A first rotating plate 300 and a second rotating plate 400; And
And a plurality of bundles of filter media (700) fixed in parallel to the circumferential direction at the edges of the first and second rotating plates (300, 400). The method according to claim 1,
The shaft 240 includes a first helical groove 242 and a second helical groove 243 in opposite directions to each other on the outer peripheral surface of both side portions;
The first rotating plate 300 and the second rotating plate 400 include a first rotating part 500 and a second rotating part 600 that transmit power to rotate in a forward or reverse direction in conjunction with driving of the driving part 200 But;
The first rotating part 500 includes a first body part 511 coupled to the first rotating plate 300 and a second body part 511 protruding from the first body part 511 and inserted into the first helical groove 242 And a first rotation guide member (510) made of a first protrusion (512) and rotatably supported in the filtration tank (100)
The second rotating part 600 includes a second body part 611 coupled to the second rotating plate 400 and a second body part 611 protruding from the second body part 611 and inserted into the second helical groove 243 And a second rotation guide member (610) composed of a second projection (612) and rotatably supported in the filtration tank (100). 3. The method of claim 2,
The first helical groove 242 is formed in a double structure symmetrical to the opposite positions of the outer circumferential surface of the shaft 240. The first rotational guide member 510 is formed in the double helical groove 242 , Respectively, at opposite positions on both sides of the shaft 240,
The second helical groove 243 is formed in a double structure symmetrical to the opposing position of the outer circumferential surface of the shaft 240 and the second rotation guide member 610 is formed in the second helical groove 243) of the shaft (240), respectively. 3. The method of claim 2,
The first rotating plate 300 includes a first rotating plate portion 300a to which one end of the filter material 700 is coupled and a second rotating plate portion 300b extending from the center portion of the first rotating plate portion 300a, And the first cylindrical portion 300b is coupled to the filtration tank 100 through a first bearing 530. The first cylindrical portion 300b is coupled to the first rotation guide member 510, Is supported by a first support plate (140) mounted on the inside of an upper portion of the first support plate
The second rotating plate 400 includes a second rotating plate part 400a to which the other end of the filtering material 700 is coupled and a second rotating plate part 400b extending from the center of the second rotating plate part 400a, And the second cylindrical portion 400b is connected to the filtration tank 100 through the second bearing 630. The second cylindrical portion 400b is coupled to the second rotation guide member 610, Is supported by a second support plate (150) mounted on the inside of the lower part of the housing. 5. The method of claim 4,
A first fixing member 520 for supporting the first bearing 530 is interposed between the first support plate 140 and the first cylindrical portion 300b,
Wherein a second fixing member (620) for supporting the second bearing (630) is coupled to the second support plate (150) with the second cylindrical portion (400b). The method according to claim 2 or 3,
A first circular groove 244 connected to the outer circumferential surface of the shaft 240 and connected to the first helical groove 242 and the second helical groove 243 on the outer circumferential surface of the shaft 240, Grooves 245 are formed,
When the first protrusion 512 and the second protrusion 612 are positioned in the first circular groove 244 and the second circular groove 245, the first rotary plate 300 and the second rotary plate 400 Is brought into a state in which manual rotation is possible. The method according to claim 6,
The rod 220 of the cylinder 210 and the shaft 240 are coupled by a coupling 230 and 230a and 230b and when the coupling 230 is separated from the shaft 240, And the first circular groove (244) and the second circular groove (245) are located on the first projection (512) and the second projection (612), respectively. The method according to claim 1,
The inner space of the filtration tank 100 is divided into a first support plate 140 and a second support plate 150 which support the first and second rotary plates 300 and 400 and are vertically spaced apart and mounted in a horizontal direction, A first chamber 100a into which raw water flows, a second chamber 100b through which raw water is filtered, and a third chamber 100c through which filtered treated water is discharged.
The second chamber 100b is provided with a porous tube 160 positioned between the first and second rotary plates 300 and 400 and wound around the outer circumferential surface of the filter media 700,
The perforated pipe 160 is connected to the third chamber 100c by a first connecting pipe 161 and a second connecting pipe 162 passing through the second rotating plate 400 and the second supporting plate 150, Wherein the filter is a filter. 8. The method of claim 7,
The second rotation plate 400 is spaced apart from the center axis of the pore tube 160 by a different length and has a circular arc shape in which the first connection pipe 161 and the second connection pipe 162 are inserted Wherein a first connection pipe insertion hole (413) and a second connection pipe insertion hole (414) are formed in the first connection pipe (413). The method according to claim 1,
And a door (110a) for opening and closing the filtration tank (100) is provided on one side of the filtration tank (100). The method according to claim 1,
The second rotating plate 400 includes a first plate portion 410 having a hooking ring 411 and a hooking pin 415 protruding upward in a circumferential direction at a top edge portion thereof, A slot 421 in which the engaging pin 415 is inserted and an interval corresponding to the filter hooking ring 411 are formed to prevent the detachment of the filter media 700 And a second plate portion 420 provided with a release preventing pin 422,
Wherein the first rotating plate (300) has a laminated structure symmetrical with the second rotating plate (400). 12. The method of claim 11,
When the second plate portion 420 is rotated in one direction so that the engaging pin 415 is engaged with the inner side surface of the elongated hole 421 and the engaging pin 415 is fastened by the engaging means 416, The hooking hook 411 of the filter media and the release preventing pin 422 are vertically aligned with each other so that the filter media 700 is prevented from being released,
The second plate 420 is rotated in the other direction after the engaging means 416 is detached from the engaging pin 415 so that the detachment pin 422 is caught by the other inner side surface of the elongated hole 421 , The filter material hooking ring (411) and the separation preventing pin (422) are spaced apart from each other in the circumferential direction so that the filter material (700) can be replaced. The method according to claim 1,
A plurality of connection links 221 are radially coupled to the rod 220 of the cylinder 210 and a plurality of filtration vessels 100-1, 100-2, 100-3, and 100-4 are connected to the plurality of connection links 221 And a plurality of shafts (240) extending from the plurality of shafts (240) are connected to each other, so that the filtration operation is simultaneously performed by the plurality of filtration tanks (100) by one driving unit (200).

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