KR20230167671A - Pore Size Controlable Filter - Google Patents

Abstract

The present invention creates a filter layer by connecting highly elastic filter media to radial upper and lower media braces that face each other at a certain distance, and the upper media brace and the lower filter media brace are formed according to the rotation direction and degree of rotation of an automatically controlled rotation axis. As the filter media hanging on is wound around the porous pipe located on the central axis, it receives a tensile force and gathers to the center along the upper and lower filter bars, arbitrarily reducing the size of the pores or allowing the filter media to be restored to its original state. It relates to an automatic pore control filtration device that can be arbitrarily large in size and facilitates filtration and cleaning.

Description

Pore automatically controlled filtration device {Pore Size Controlable Filter}

The present invention relates to an automatic pore control type filtration device, and more specifically, to create a filter layer by connecting highly elastic filter media to radial upper and lower filter bars that face each other at a certain distance, and to determine the rotation direction and rotation of the rotating shaft. Depending on the degree, the filter media hanging on the upper and lower media racks is wound around the porous tube located on the central axis and receives a tensile force so that it gathers in the center along the upper and lower filter racks, thereby arbitrarily reducing the size of the pores or reducing the filter media. It relates to a filtration device that allows for easy filtration and washing by allowing the pores to be restored to their original state and arbitrarily enlarging the size of the pores.

As shown in Figure 1, a general filtration device consists of a raw water supply pipe (2), a treated water discharge pipe (7), a washing water supply pipe (6) and a discharge pipe (1), and a filter bed (4) filled with filter media, and is easy to clean. To do this, an air supply pipe (5) and a pressure control and air discharge valve (8) are attached.

The operation of this filtration device is divided into a filtration process and a washing process. The filtration process is a process in which raw water containing suspended substances flows into a filtration device and discharges clean treated water from which the suspended substances have been removed. The suspended substances in the raw water are separated into the pores in the filter layer of the filtration device through sieving, sedimentation, inertial collision, etc. It is a process of detention and capture through complex mechanisms such as blocking, adsorption, and coagulation, and only clean water is discharged as treated water. As the filtration process continues, the pores within the filter layer become increasingly filled with suspended solids, and filtration resistance increases, reaching a state where the filtration process can no longer be continued. At this time, a washing process is necessary to exclude suspended substances captured in the pores by injecting clean washing water and air.

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

Inorganic granular materials such as sand, anthracite, and anthracite have been mainly used as filter media for filling the filter layer.

These filter media have the advantage of being easily available and the ability to remove particles smaller than the size of the pores formed by them. However, since the space for capturing suspended solids in the filter layer formed with this filter media is limited near the surface layer, the filtration resistance rapidly increases due to occlusion of the pores.

Therefore, it has the disadvantage of having to be backwashed frequently. In order to solve the problem that suspended solids are mainly captured near the surface of the filter layer, filtration devices that improve the filter layer into a double or multi-layer structure have been developed. However, filter media with different particle sizes and densities are used in each layer, and the classification by layer is not complete. Therefore, if the washing process is repeated, the boundary between the layers becomes ambiguous, making it difficult to achieve the initial goal. Also, when using granular filter media, the problem of the filter media being lost during backwashing still remains.

Recently, in order to further improve the performance of the filtration device, fiber yarns are used as a filter medium. The fiber yarns are fixed to the bottom of the filter, the filter media is compressed by the raw water supply pressure, and the filter media is expanded by the air and washing water supply pressure. has been developed (registration number 10-0241198), but in this method, because the filter layer is a single layer and the degree of compression of the filter media is determined by the raw water supply pressure, the space for trapping suspended solids is small, so the filtration duration is short and the frequency of washing is frequent. It is not easy to cope with changes in the water quality of inflow water, and it is difficult to arbitrarily control the desired water quality and quantity.

Therefore, a permanent filtration device with a variable filter layer using a piston (Publication No. Special 1999-030247) was developed. However, this method compresses and relaxes the filter medium in the vertical direction by the piston, so if used for a long time, the filter medium becomes tangled, causing problems when washing. The relaxation of the filter media becomes incomplete, making perfect cleaning impossible.

In addition, there is a filtration device (registration number patent 1997-0007944) developed by installing a filter media concentrically between a floating disk and a fixed disk and compressing the filter media by rotating the fluid disk. However, this method does not compress the filter media around the disk. There is a serious defect that cannot be achieved, and since the floating disk itself is configured to move toward the fixed disk and be compressed in order to prevent the filter media from receiving tensile force, the filtration cross-sectional area is too small compared to the size of the filtration tank (2), and the filtration cross-sectional area is too small in comparison to the size of the filtration tank (2) It has structural defects, such as the fact that pressure filtration is practically difficult because the rotation axis moves.

Korean Patent No. 10-0362594

The purpose of the present invention is to improve the filtration speed and filtration duration by complementing and improving the various shortcomings described above, and to develop a filtration device that can effectively remove suspended solids in water by reducing the frequency of washing and the amount of washing water used, as well as the overall The purpose is to simplify the water treatment process.

In the present invention, radial filter media struts fastened to a rotating shaft or a fixed shaft are installed to face each other at a certain distance in the filtration tank (2), filter media with good elasticity are connected to the filter media struts on both sides to create a filter layer, and the rotation shaft is rotated. Depending on the direction and degree of rotation, the filter media hanging on the filter rack is wound around a porous tube located on the central axis and at the same time receives a tensile force so that it gathers to the center along the filter rack, thereby arbitrarily reducing the size of the pores for filtration, or filtering the media in its original state. It is a pore-controlled filtration device that can be backwashed by arbitrarily increasing the size of the pores.

In particular, since the filter media around the filter pedestal can be gathered in the center along the filter pedestal, not only can a uniform pore size be maintained around the porous pipe, but the length of the filter can be varied or the length of the filter can be changed by distinguishing the inside and outside of the filter layer. By changing the type, the size of the pores can be varied depending on the distance from the porous pipe, the filtration cross-sectional area can be maximized, and cleaning can be done while the filter media is repeatedly relaxed and compressed, eliminating the various problems identified above. It can be solved at the same time.

In addition, since the present invention rotates and twists the filter medium using a handle, the same degree of compression can be maintained with less force than the method of squeezing the filter medium using a piston, and even if used for a long time, the filter medium can always be cleaned without inconvenience. It can be relaxed, and while the filtration cross-sectional area of a general filter is limited to the vertical cross-sectional area of the filtration tank (2), the filtration cross-sectional area of the present invention corresponds to the surface area of the porous pipe, so only the diameter of the porous pipe is increased or the filtration tank (2) is By simply increasing the height, the filtration cross-sectional area can be arbitrarily increased without increasing the cross-sectional area of the filtration tank (2).

In order to achieve the above object, the present invention installs a radial upper filter holder fastened to an upper rotating shaft and a radial lower filter holder fastened to a porous tube fixed shaft to face each other at a certain distance in the filtration tank, and has good elasticity. The filter media is connected to the upper and lower filter racks to create a filter layer, and the upper and lower filter media racks are connected to porous pipes and installed so that they do not move due to the rotation of the upper rotation shaft. As the filter medium hanging on the filter rack is wound around the porous tube located on the central axis, it receives a tensile force and gathers to the center along the upper and lower filter racks, thereby arbitrarily reducing the size of the pores for filtration or restoring the filter medium to its original state. It is characterized in that backwashing can be performed by arbitrarily increasing the size of the pores.

As seen above, the present invention installs radial filter media struts fastened to a rotating or fixed shaft to face each other at a certain distance in a filtration tank, connects highly elastic filter media to the filter media struts on both sides to create a filter layer, and creates a filter media with a rotating shaft. Depending on the rotation direction and degree of rotation, the filter media hanging on the filter holder is wound around a porous tube located on the central axis and at the same time receives a tensile force and gathers to the center along the filter holder, thereby arbitrarily reducing the size of the pores for filtration, or filtering the filter media as it was originally. Since it is designed to be restored to its original state and can be backwashed by arbitrarily increasing the size of the pores, not only can suspended solids of various sizes in the solution be effectively separated, but also the suspended solids captured in the filter layer can be easily separated and excluded. It is designed to maximize the filter layer and can be used as a practical filtration device that can reduce the frequency of washing and the amount of washing water used.

1 shows a typical conventional filtration device.
Figure 2 is a filtration device with automatic pore control (filter media compressed state) according to an embodiment of the present invention.
Figure 3 shows an automatic pore control type filtration device (filter media relaxed state) according to an embodiment of the present invention.
Figure 4 is a filtration device according to another embodiment of the present invention.

Figure 2 is a one-stage rotating pore automatically controlled filtration device corresponding to an embodiment of the present invention. It is composed of a raw water supply unit (1), a filtration layer (21a), and a treated water discharge unit (3) extending from the circumferential direction of the filtration tank (2) toward the center.

The upper flange (13) of the filter tank (2) has a hole for the upper rotating shaft (25) and an upper rotating shaft sealing portion (26) to prevent water from leaking through the gap between the upper rotating shaft (25) and the upper flange (13). Drill a hole for fastening and weld a pipe for measuring pressure and mounting the safety valve (14). A porous pipe 22 is penetrated and welded to the lower flange 33 of the filtration tank 2, and a pipe to which the cleaning air supply pipe 34 can be connected is welded. One side of the upper rotating shaft (25) is connected to the upper handle (28), and an upper media rack (23) on which the filter media (21) can be attached is radially mounted on the outside of the other side.

A lower media rack (24) on which the filter media (21) can be hung is radially welded to the porous tube (22) welded to the lower flange (33) of the filtration tank (2), and one end of the porous tube (22) is Make sure it can be inserted into the lower rotating shaft (36). At this time, the porous portion of the porous pipe 22 is positioned only between the media rests on both sides.

The upper filter holder 23 attached to the upper rotating shaft 25 rotates in the same direction as the upper rotating shaft 25, but the lower media holder 24 attached to the porous tube 22 does not rotate because it is fixed. Therefore, when the upper rotating shaft 25 is turned, the filter media 21 hanging on the upper and lower filter media racks not only receives a tensile force as it is wound around the porous pipe 22 located in the center, but also gathers at the center and gathers the filter media ( The air gap between the filter medium 21 and the filter medium 21 at all positions within 21a) becomes smaller.

At this time, in order for the filter medium (21) to be sufficiently wound around the porous pipe (22) and then receive a tensile force, the filter medium (21) must be mounted longer than the distance between the upper and lower filter racks, and the filter medium (21) with the smallest diameter must be inserted into the upper and lower filter racks. The extra length of the filter media (21) located outside must be longer to enable the function of double-layer filtration. Also, after installing the filter medium (21), a filter media separation prevention ring (15) is installed at the ends of the upper and lower filter media racks to prevent the filter media (21) from coming off.

In the filtration process, after cleaning the filter layer (21a), the filter media (21) is compressed around the porous pipe (22) by turning the upper handle (28) with only the treated water discharge valve (31a) and the raw water supply valve (11a) open. Then, the upper handle (28) is fixed with the upper handle fixing pin (28a) to allow raw water to flow in and be filtered. If the filtration process continues in this state, the suspended solids held in the filter layer 21a within the filtration device increase, increasing the filtration resistance, and the discharge rate of the treated water decreases or the pressure increases, causing the captured suspended particles to be discharged into the treated water. It is done. At this time, if the discharge rate of the treated water becomes less than the set value, the pressure in the filtration tank 2 becomes higher than the set value, or the water quality of the treated water becomes worse than the desired value, the filtration process is stopped and switched to the washing process.

The cleaning process can be performed automatically or manually. First, close the raw water supply valve (11a) and the treated water discharge valve (31a), then lower washing water discharge valve (35a), cleaning air supply valve (34a), and washing water supply valve. Open (32a) in order, close all remaining sides, pull out the upper handle fixing pin (28a), turn the upper handle (28) in the opposite direction to loosen the filter medium (21), and continue to tighten the upper handle (28). Wash the filter medium (21) by turning it in both directions. As if washing clothes under running water, by repeating relaxation and compression, the suspended substances captured inside the filter layer 21a are detached, and the contaminated washing water is discharged to the lower washing water discharge pipe 35. When it is determined that the suspended solids captured in the filter layer 21a have been sufficiently separated, the process switches to the filtration process again.

A feature of the present invention is that the upper rotating shaft 25 is connected to a driving means and the driving means is connected to a control unit so that the rotation of the upper rotating shaft 25 can be controlled.

The embodiments of the present invention described above and shown in the drawings should not be construed as limiting the technical idea of the present invention. The scope of protection of the present invention is limited only by the matters stated in the claims, and those skilled in the art can improve and change the technical idea of the present invention into various forms. Therefore, if such improvements and changes are obvious to those skilled in the art, they will fall within the scope of protection of the present invention.

Claims (1)

In removing suspended solids present in liquid,
The radial upper filter rack (23) fastened to the upper rotating shaft (25) and the radial lower filter rack (24) fastened to the fixed axis of the porous pipe (22) are installed facing each other at a certain distance in the filtration tank (2). , the highly elastic filter medium (21) is connected to the upper and lower filter struts (23, 24) to create a filter layer (21a), and the upper and lower filter struts (23, 24) are connected to the porous pipe (22), but the upper It is mounted so as not to move when the rotation shaft (25) rotates, and the filter medium (21), which is hung on the upper and lower filter racks (23, 24) depending on the rotation direction and degree of rotation of the upper rotation shaft (25), is located on the central axis of the porous tube. At the same time as it is wound around (22), it receives a tensile force and gathers in the center along the upper and lower filter holders (23, 24) to arbitrarily reduce the size of the air gap for filtration, or the filter media (21) is restored to its original state to fill the air gap. You can backwash by arbitrarily increasing the size,
The upper rotating shaft (25) is connected to a driving means, and the driving means is connected to a control unit so that the rotation of the upper rotating shaft (25) can be controlled.