KR102577775B1 - Disk filter type strainer - Google Patents

Abstract

The present invention relates to a disk filter type filter that facilitates the removal of cake-shaped sludge, and has a removal part inside the chamber, so that cake-shaped sludge accumulated to a certain thickness on the disk during the filtration process can be removed periodically or selectively. By configuring the removal unit so that the cake-shaped sludge stacked on the disk is not only convenient to remove, but also easy to remove, the purpose is to improve the efficiency of the removal operation.
For this purpose, the present invention includes a chamber; a support shaft configured to stand in a vertical longitudinal direction inside the center of the chamber; It is stacked in multiple layers at regular intervals along the longitudinal direction of the support shaft, and during the process of filtration through adsorption by mutual stirring of the contaminated liquid and diatomaceous earth flowing into the chamber, contaminated sludge is deposited on the surface and contaminants are removed. a disk supporting the filtrate to enter the inside and drain to the outside through the support shaft; and a removal unit configured on one side of the interior of the chamber to remove cake-shaped sludge created during the filtration process on the disk.

Description

Disk filter type strainer for easy removal of cake-type sludge

The present invention relates to a disk filter type filter that facilitates the removal of cake-shaped sludge.

In general, a filtration device is a device that catches residues from a liquid to be purified, and is being developed in various forms, and in particular, a purification system using diatomaceous earth is being released.

The purification system using the diatomaceous earth includes a mixing tank for adding and mixing the diatomaceous earth, a filtration means for purifying the purified liquid by pre-coating the diatomaceous earth on the filter, a deliquid means for separating the purified liquid into sludge and liquid, and a stock solution to be purified and purified. It consists of a purified liquid tank for storing the purified liquid, a filtration pump means for forced circulation of the purified liquid, a pneumatic pressurizing means for applying air pressure, and a plurality of valves that control the fluid flow in each line.

The above filtration system includes a pre-coat step in which the diatomaceous earth introduced into the mixing tank is passed through a filtration means and coated so that the diatomaceous earth forms a layer within the filtration means, and the residue to be purified is passed through the filtration means through the pre-coat step. Or, a filtration step of filtering out sludge, and a backwashing step of removing diatomaceous earth and sludge, etc. layered on the filtration means by strongly applying a flow of fluid in the reverse direction to the filtration means when filtration can no longer be performed in the filtration step, and the backwashing. It consists of a deliquification step to remove sludge, etc., which is removed through the step.

However, the above-described conventional purification system using diatomaceous earth must necessarily consist of components such as a mixing tank, a filtration tank, and a dehydration tank, and there is a problem in that the overall size of the purification system is large, and the manufacturing cost is high. There is a problem that arises.

As shown in FIG. 1, the conventional filtration device of Patent No. 10-857283 proposed to overcome this includes a tank body 10 having a discharge portion 16 on the lower side and a pedestal 15 formed therein, and , a lid 11 disposed on the upper side of the tank body 10 and locked and disassembled, a support pipe 20 mounted on the pedestal 15 and having a through hole 24 on the surface, and the lid 11. ) and a fixing part 60 that is disposed on the inner lower side and supports the upper end of the support pipe 20, is inserted into the support pipe 20, has a micro hole formed on the surface, and is connected to the inside of the support pipe 20. A filter plate (30) in communication, a strainer covered with the filter plate (30) and having a diatomaceous earth layer formed on the surface, and a column inserted into the support pipe (20) and disposed on the upper and lower sides of the filter plate (30). A member 50 is constructed.

Accordingly, the liquid phase of the object to be purified (hereinafter collectively referred to as ‘contaminated liquid phase’) and diatomaceous earth are added to the diatomaceous earth tank, and then a pre-coat is performed. When the pre-coat is performed, the stock solution in the diatomaceous earth tank is forcibly moved by the pump and circulated into the filtration device. A pre-coat layer is formed in the filtration device, and the liquid that has passed through the filtration device is returned to the diatomaceous earth tank.

Meanwhile, in the filtration device, the contaminated liquid phase and the diatomaceous earth entering the inside are agitated with each other, and are laminated with a filter plate 30 in which micro-holes are formed by the entry pressure. At this time, as the contaminants contained in the contaminated liquid are adsorbed to the diatomaceous earth and form a lump, they cannot be discharged through the fine holes of the filter plate (30), and the filtrated liquid phase from which the contaminants have fallen is in communication with the interior of the filter plate (30). Filtration is performed as drainage occurs through the inside of the support pipe 20 to the outside.

In addition, in the filtration device, contaminated diatomaceous earth with contaminants adsorbed is deposited on the filter plate through the above-described filtration effect, and after a certain period of time, a cake-shaped sludge in which contaminated diatomaceous earth of a certain thickness is deposited on the filter plate is formed, thereby forming the cake. As the filtration efficiency is reduced by the cake-shaped sludge, a sludge removal operation is performed periodically to remove the cake-shaped sludge.

The sludge removal operation is performed by opening the lid 11 on the tank body 10, removing the holding pipe 20 and the filtering plate 30 formed inside the tank body 10, and removing the outer circumference of the filtering plate 30. Remove the cake-shaped sludge accumulated on the.

However, the cake-shaped sludge stacked on the filter plate 30 maintains the stacked state by high pressure, making the work of removing the cake-shaped sludge from the filter plate 30 using a separate tool such as a knife difficult. There is a problem with .

In addition, when removing cake-shaped sludge using a sharp tool such as a knife, there is a problem that safety cannot be guaranteed as injuries may occur due to operator error.

In addition, since the cake-shaped sludge is laminated on the filter plate at high pressure, the weight of the cake-shaped sludge is significant as it maintains high density, so that the holding pipe 20 and the filter plate on which the cake-shaped sludge is stacked in the tank body 10 ( 30) When performing the work of taking out a separate take-out device, a separate take-out device must be used, which results in the complexity of the structure requiring the installation of a separate take-out device and the problem of reduced space utilization.

Republic of Korea Patent Publication No. 10-0857283 (announced on September 8, 2008) Republic of Korea Registered Utility Model Publication No. 20-0365150 (announced on October 16, 2004)

Proposed to solve the above problems, the purpose of the present invention is to configure a removal unit inside the chamber to periodically or selectively remove cake-shaped sludge that is deposited to a certain thickness on the disk during the filtration process. By configuring the removal unit, the removal operation of the cake-shaped sludge stacked on the disk is not only convenient, but also the removal operation is simple, providing a disk filter type filter that is easy to remove cake-shaped sludge to improve the efficiency of the removal operation. It is there.

The present invention for achieving the above object includes a chamber; a support shaft configured to stand in a vertical longitudinal direction inside the center of the chamber; It is stacked in multiple layers at regular intervals along the longitudinal direction of the support shaft, and during the process of filtration through adsorption by mutual stirring of the contaminated liquid and diatomaceous earth flowing into the chamber, contaminated sludge is deposited on the surface and contaminants are removed. a disk supporting the filtrate to enter the inside and drain to the outside through the support shaft; and a removal unit configured on one side of the interior of the chamber to remove cake-shaped sludge created during the filtration process on the disk.

In the present invention, a discharge part is provided at the inner lower part of the chamber to collect the contaminated sludge that has fallen off the disk or the contaminated sludge that has fallen downward through the removal unit, and to discharge the collected contaminated sludge to the outside. It is desirable to do so.

In the present invention, the removal part includes a removable blade formed at a certain length so that the lower end is in close contact with the disk; a rotating shaft with one end of the removable blade fixed to stand vertically on one side of the chamber so that the cake-shaped sludge accumulated on the disk can be swept away and removed by rotating the removable blade at regular intervals; a support bracket supporting both ends of the rotating shaft so that the rotating shaft rotates in place; and a first power unit configured on one side of the rotation shaft to provide rotational force so that the rotation shaft can be rotated forward and backward at a certain angle.

In the present invention, the removable blade is formed in a length such that it is configured between the center of the disk and the rotation axis; The removable blade is preferably formed in a streamlined shape so that it can be collected inward when sweeping cake-shaped sludge while rotating.

In the present invention, the side cross section of the removable blade is preferably formed with a depression of a certain depth so as to expand the surface area with the cake-shaped sludge.

In the present invention, the lower end of the removable blade does not directly contact the disk, but is configured to be spaced apart at a certain interval, the upper end is fixed to the lower end of the removable blade, and the lower end is in contact with the top of the disk. It is preferable to include a close contact pad that rotates with the removable blade and supports it to improve the removal efficiency of cake-shaped sludge.

In the present invention, the support shaft is formed in the shape of a hollow tube with an empty interior; It is configured to communicate with one side of the disk, which is stacked in multiple layers along the longitudinal direction of the support shaft, and includes at least one inlet hole that supports the filtrate phase to enter the inside; It is preferable to include a rotating part on one side of the support shaft, which rotates the disk together with the support shaft to facilitate the removal of cake-shaped sludge accumulated on the disk through the removal part.

In the present invention, the disk includes a support portion; and a filtration unit formed at the top of the support unit to support the filtrated liquid phase from which contaminants are removed to enter the inside and diatomaceous earth adsorbed thereon to form cake-shaped sludge of a certain thickness. The support portion includes a support plate spaced apart from the filter portion at a predetermined interval so that the filtrate can be collected inside; a raised portion raised at a certain height from the center of the support plate and forming an insertion hole into which the support shaft is inserted; It is preferable to include at least one entry hole formed to penetrate the outer periphery of the ridge to support the filtrate collected by the support plate so that it can enter the inside through the support shaft.

In the present invention, the filtration unit includes a first filter net formed with mesh of several mm to several tens of mm; and a second filter net located at the bottom of the first filter net and having meshes of 0.1 mm to hundreds of micrometers.

In the present invention, the removable blade has at least one blowing hole provided on one side and provided from the outside or blowing out air to clean the disk, and a space is formed inside to communicate with the blowing hole or to allow the flow of air. Includes an accommodation space for this to occur; The rotating shaft preferably includes a hollow body that communicates with the receiving space of the removable blade fixed along the longitudinal direction and allows the cleaning liquid or air provided from the outside to be blown out through the receiving space to the blowing hole.

In the present invention, the blowing hole is preferably formed to be inclined from the top to the bottom so that the surface cleaning efficiency of the disk is improved by the ejected cleaning liquid or air.

According to the present invention, a removal unit is configured inside the chamber to periodically or selectively remove cake-shaped sludge layered to a certain thickness on the disk during the filtration process, thereby removing the cake-shaped sludge layered on the disk. Not only is the removal work convenient, but the removal work is simple, which has the effect of improving the efficiency of the removal work.

1 is a cross-sectional view of a conventional filtration device.
Figure 2 is a cross-sectional view of a filter according to the present invention.
Figure 3 is a partially exploded perspective view showing the structural relationship between the disk and the removal portion according to the present invention.
Figure 4 is a diagram of a disk according to the present invention,
4a is an exploded perspective view, and 4b is a combined cross-sectional view.
Figure 5 is a perspective view of the removal part according to the present invention.
Figure 6 is a top view of a filter according to the present invention.
Figure 7 is a side cross-sectional view of the removable blade according to the present invention,
7a is the basic configuration, and 7b is another example configuration.
Figure 8 is a diagram of a removal unit according to the present invention,
8a is an separated perspective view, and 8b is a top view.
Figures 9a to 9e are plan views showing the process of removing cake-shaped sludge through the removal unit of the present invention.
Figure 10 is a view of a removal part showing another example of the present invention,
10a is a perspective view showing the coupling relationship between the removable blade and the rotating shaft, and 10b is an enlarged cross-sectional view showing the structural relationship between the disk and the removal part.

A preferred embodiment of the present invention will be described in detail with reference to the attached drawings as follows.

As shown in Figure 2, the disk filter type filter of the present invention pressurizes diatomaceous earth and contaminated liquid from downward to upward, and filtration is performed through a multi-layered disk, and the filtration through the disk is carried out. It operates as a filtration system that drains the liquid to the outside through the inside of the support shaft.

The disk filter type filter includes a chamber 100, a support shaft 200, a disk 300, and a removal unit 400. In addition, one side of the chamber 100, that is, the lower inner side, includes a discharge portion 500 that facilitates discharge of sludge that falls or accumulates downward.

The chamber 100 performs the function of providing a closed space so that filtration can operate smoothly through the contaminated liquid and diatomaceous earth flowing into the chamber.

The chamber 100 has a space formed inside, a housing 110 with one end open, that is, the top, and one end of the housing 110, that is, the top is opened and closed to support the removal or maintenance of sludge. Includes a lid (120). In this case, one end of the lid 120 is hinged to the housing 110, and the lid 120 is opened and closed around the hinge. Of course, it is not limited to this, and any structure or configuration of the lid 120 that opens and closes one end of the housing 110 can be adopted.

In addition, the bottom of the lid 120 includes a support bracket that supports the upper part of the support shaft 200, so that the position of the support shaft 200 is fixed and rotation in place is performed smoothly.

In addition, the chamber 100 is made of stainless steel or aluminum to ensure resistance to high pressure acting on the inside and safety in that it does not cause chemical reactions or deterioration depending on the type of contaminated liquid. Of course, it is not limited to this, and the chamber 100 may be made of iron, synthetic resin, etc. depending on the type of contaminated liquid or the user's request.

The support shaft 200 is configured inside the chamber 100 and functions to discharge the filtrate liquid filtered through the disk 300 to the outside.

The support shaft 200 is formed in the shape of a hollow tube with an empty interior, and at least one inlet hole 210 is formed so that the filtrate phase filtered through the disk 300 can enter the inside.

The inlet hole 210 is configured along the longitudinal direction of the support shaft 200 to correspond to each of the disks 300 stacked in plurality along the longitudinal direction of the support shaft 200.

In addition, on one side of the support shaft 200, as the support shaft 200 rotates in place, the cake-shaped sludge 1 generated at the top of the disk 300 is smoothly removed through the removal unit 400. It includes a rotating part 220 so that it can be removed.

The rotating part 220 is located on one side of the support shaft 200 and functions to provide rotational force so that the support shaft 200 rotates in place.

In this case, the rotating part 220 is configured below the support shaft 200. Of course, it is not limited to this, and the rotation unit 220 may be configured in any position that allows the support shaft 200 to rotate smoothly in place.

In addition, the rotating part 220 is configured between a motor that generates rotational force through electricity or hydraulic power, and the motor and the support shaft 200, so that the support shaft 200 can be rotated through the rotational force provided by the motor. It consists of a power transmission member that allows The power transmission member is composed of a gear train method consisting of a combination of multiple gears, a belt and pulley method, or a chain and sprocket method.

In addition, the support shaft 200 rotates in place by the rotational force provided by the rotating unit 220, and as described above, it is not limited to rotating only when removing cake-shaped sludge stacked on the disk 300. , Even during the process of filtering the contaminated liquid, the disk 300 rotates together with the support shaft 200, so that the filtration efficiency for the contaminated liquid is improved. In other words, the rotating part 220 of the support shaft 200 can be configured to rotate during the filtration process or only during the process of removing the cake-shaped sludge 1, which can improve the filtration efficiency for the contaminated liquid phase. Any available method can be selectively used.

As shown in FIG. 3, a plurality of disks 300 are stacked along the longitudinal direction of the support shaft 200, and filtration is performed by mutual agitation of the diatomaceous earth and the contaminated liquid introduced into the chamber 100. , It performs the function of allowing only the filtrated liquid from which contaminants have been removed from the contaminated liquid to enter the inlet hole 210 of the support shaft 200.

As shown in FIG. 4, the disk 300 includes a support portion 310 and a filtering portion 320.

The support unit 310 supports the filter unit 320 being seated at the top and allows the filtrated liquid passing through the filter unit 320 to enter the inlet hole 210 of the support shaft 200. Performs a supporting function.

The support portion 310 includes a support plate 312 and a raised portion 314 that rises to a certain height from the center of the support plate 312.

The support plate 312 supports the filter unit 320 being seated at the top.

In addition, the support plate 312 is inclined downward so that the filtrate phase that has passed through the filter unit 320 mounted at the top is smoothly transferred to the protruding part 314.

In addition, the outer periphery of the supporting plate 312 supports the seating of the filtering unit 320 and allows the spacing between the supporting plate 312 and the filtering unit 320 to pass through the filtering unit 320. A support step 313 is formed to support the filtrate so that it can be smoothly transferred to the protruding portion 314.

The support step 313 protrudes from the outer periphery of the support plate 312 at a certain height and is formed with a certain width to support the seating of the filter unit 320 at the top.

In addition, the support plate 312 and the support step 313 are configured to maintain a mutually sealed state so that the filtrate phase can enter only through the filter unit 320.

The protrusion 314 is configured to protrude at a certain height from the center of the support plate 312, and supports stable seating of the filter unit 320 mounted on the top and ensures smooth collection of the filtrate. .

Additionally, an insertion hole 316 through which the support shaft 200 is inserted is formed in the center of the raised portion 314.

In addition, the protrusion 314 is in communication with the inlet hole 210 formed in the support shaft 200, and at least one entry hole 318 is formed to allow the filtrate phase to enter the inlet hole 210. do. In this case, the entry holes 318 are formed in the same size and number as the inlet holes 210. Of course, it is not limited to this, and the entry holes 318 can be of any size, number, or shape that allows the filtrate to drain smoothly into the inlet holes 210.

In addition, the protrusion 314 is configured to be recessed at a certain length at the bottom of the support plate 312, so that the disks 300 stacked in multiple layers along the longitudinal direction of the support shaft 200 are spaced at a certain interval. , so that filtration is performed through the space between the disks 300.

Of course, it is not limited to this, and the raised portion 314 may be configured to be horizontal with the lower end of the support plate 312. In this case, a column is configured to form a space between the disks 300. do.

The filter unit 320 is configured at the top of the support unit 310, and performs a filtration operation in which polluted sludge with contaminants adsorbed onto the diatomaceous earth is separated from the filtrate phase by mutual stirring of the diatomaceous earth and the contaminated liquid phase, and is formed in this way. It performs the function of allowing the contaminated sludge to be stacked upward and allowing the filtrate to enter the interior of the support portion 310.

The filtering unit 320 is configured such that the first and second filtering nets 322 and 324 are sequentially stacked. Of course, it is not limited to this, and the filtration unit 320 may be configured as one or more depending on the type of contaminated liquid or required filtration efficiency.

The first filter net 322 is formed at the top of the support part 310 and is formed as a mesh or perforated plate with mesh sizes ranging from several millimeters to tens of millimeters.

The second filter net 324 is located at the bottom of the first filter net 322 and performs a secondary filtration on the liquid that has passed through the first filter net 322, thereby improving the purity of the filtrate. .

In this case, the second filter net 324 is formed as a mesh or perforated plate with mesh sizes ranging from 0.1 mm to hundreds of ㎛.

Of course, it is not limited to this, and the first and second filter nets 322 and 324 are sequentially seated on the top of the support portion 310 to perform filtration on the contaminated liquid, and the type of contaminated liquid. Alternatively, it can be formed with various mesh sizes and materials depending on the required filtration efficiency, etc.

The removal unit 400 is configured on one side of the interior of the chamber 100 to facilitate removal of the contaminated sludge 1 by periodically or selectively removing the contaminated sludge 1 stacked on the top of the disk 300. performs its function.

As shown in FIGS. 5 and 6, the removal unit 400 includes a removal blade 410, a rotating shaft 420, a support bracket 430, and a first power unit 440.

The removal blade 410 has one end in close contact with the surface of the filtering unit 320 of the disk 300, and has the function of substantially removing the contaminated sludge 1 accumulated on the filtering unit 320 by filtration. Perform.

In addition, one end of the removable blade 410 is fixed to one end of the rotating shaft 420 and is configured to rotate together with the rotation of the rotating shaft 420. In this case, the removable blades 410 are configured in multiple numbers so that each disk 300 is stacked along the longitudinal direction of the support shaft 200.

In addition, as shown in FIG. 6, the other end of the removable blade 410 is configured to contact the central end of the disk 300, that is, the outer periphery of the raised portion 314 of the support portion 310, so that the disk Contaminated sludge (1) can be removed from the entire surface of (300).

That is, the removable blade 410 is configured so that one end is fixed to the rotation shaft 420 and the other end is in contact with the outer periphery of the raised portion 314 of the support portion 310 formed on the disk 300, so that the rotation shaft ( While rotating together with 420), the contaminated sludge 1 accumulated on the disk 300 is removed.

In addition, the removal blade 410 is formed in a streamlined shape from the rotation axis 420 to the center of the disk 300, so that it is gathered inward when removing the contaminated sludge 1, thereby increasing the removal efficiency of the contaminated sludge 1. Let it improve.

In addition, as shown in FIG. 7A, the lower end of the removal blade 410 is maintained in close contact with the disk 300, making it possible to remove the contaminated sludge 1 accumulated on the surface of the disk 300. It is designed to be easily accomplished.

In addition, the removable blade 410 is formed to have a certain width and thickness, and the surface in contact with the contaminated sludge 1 based on the moving direction forms a recessed surface 412 that is depressed to a certain depth, so that the removable blade 410 The surface area between (410) and the contaminated sludge (1) is expanded to improve the removal efficiency for the contaminated sludge (1).

Alternatively, as shown in FIG. 7B, the removable blade 410 is such that the lower end of the removable blade 410 does not directly contact the disk 300 but is spaced apart at a certain interval, and the lower end of the removable blade 410 A contact pad 414 is formed that protrudes a certain length and directly contacts the surface of the disk 300.

The contact pad 414 is configured at the bottom of the removable blade 410 and is configured to directly contact the surface of the disk 300, thereby rotating with the removable blade 410 and touching the surface of the disk 300. Ensure that the contaminated sludge (1) accumulated on is removed.

That is, the contact pad 414 is made of a softer material than the disk 300, such as synthetic resin such as rubber or silicone, and protects the disk 300 and adheres firmly to the surface of the disk 300. The removal efficiency of the stacked contaminated sludge (1) is improved.

The rotation shaft 420 is erected vertically along the longitudinal direction on one side of the interior of the chamber 100 and functions to rotate the removal blade 410 as it rotates back and forth.

The support bracket 430 is provided at each end of the rotation shaft 420 and functions to support the rotation shaft 420 to rotate smoothly in place.

The first power unit 440 generates rotational force to rotate the rotation shaft 420 at a certain angle.

The first power unit 440 includes a motor 442 and a power transmission member 444.

The motor 442 performs a function of generating rotational force and generates rotational force through electricity or hydraulic pressure. In this case, as shown in FIG. 6, the motor 442 provides a constant angle reciprocating rotational force that allows the removal blade 410 to reciprocate at a rotation angle sufficient to sweep one side of the surface of the disk 300. do.

The power transmission member 444 is configured between the motor 442 and the rotating shaft 420, and transmits the reciprocating rotational force provided by the motor 442 so that the rotating shaft 420 can reciprocate and rotate at a certain angle. Let it happen. In this case, the power transmission member 444 may be configured as a belt and pulley type, chain and sprocket type, or gear train type, and can stably transmit the rotational force of the motor 442 to the rotating shaft 420. Any structure, composition or method can be adopted.

As shown in FIG. 2, the discharge unit 500 is located at the inner bottom of the chamber 100 and discharges the contaminated sludge 1 that falls off the disk during the filtration process or the contaminated sludge that falls through the removal unit 400. (1) It performs the function of collecting so that it can be discharged to the outside. In some cases, the discharge unit 500 may be omitted.

As shown in FIG. 8, the discharge unit 500 includes a collection plate 510, a rotation guide unit 520, a second power unit 530, and an opening/closing unit 540.

The collection plate 510 is located at the lower end of the housing 110 of the chamber 100 and functions to collect the contaminated sludge 1 that falls off the disk 300.

In addition, an outlet 512 of a certain size is formed on one side of the collection plate 510 so that the contaminated sludge 1 guided through the rotation guide 520 can be discharged to the outside.

The rotation guide unit 520 is configured above the collection plate 510 and performs the function of guiding the contaminated sludge 1 collected above the collection plate 510 to the discharge port 512 so that it can be discharged. .

The rotation guide unit 520 includes rotary blades 522 and a guide plate 524.

The rotary blade 522 functions to support the guide plate 524 formed at the bottom. In this case, the rotary blades 522 are configured in three radial positions. Of course, it is not limited to this, and the rotary blades 522 may be configured as one or in a plurality in a radial shape, and are not limited as long as the number allows for easy collection of the contaminated sludge 1.

The guide plate 524 is configured at the bottom of the rotary blade 522, and rotates with the rotary blade 522 to discharge the contaminated sludge 1 collected on the collection plate 510 to the outlet 512. It performs the function of inducing you to do so.

The guide plate 524 is configured so that its upper end is fixed to the lower end of the rotary blade 522 and its lower end is in contact with the collection plate 510, so that the contaminated sludge 1 collected on the collection plate 510 is discharged ( 512) Ensure that guidance to the side is carried out smoothly.

The second power unit 530 generates rotational force to rotate the rotation guide unit 520, so that the contaminated sludge 1 can be discharged to the discharge port 512 by the rotation of the rotation guide unit 520. In this case, the second power unit 530 is composed of a motor and a power transmission member, and is configured to transmit the rotational force generated by the motor to the rotation induction unit 520 through the power transmission member.

The opening/closing unit 540 opens and closes the outlet 512 of the collection plate 510, allowing the contaminated sludge 1 to be discharged according to the selection of the user or manager.

Referring to FIG. 9, the process of removing the cake-shaped sludge stacked on the disk through the disk filter type filter configured as described above is as follows.

As shown in Figure 9a, when the cake-shaped sludge 1 of a certain thickness is stacked on the disk 300, a rotational force is generated in the rotating part 220 formed at one end of the support shaft 200, and in addition, the removal part 400 ) Rotational force is generated in the second power unit 440.

Accordingly, as shown in FIG. 9B, the disk 300 continues to rotate, and the rotation shaft 420 rotates due to the rotational force generated by the second power unit 440 of the removal unit 400, As the removable blade 410, one end of which is fixed to the rotation axis 420, rotates together with the rotation axis 420, it moves from the outer periphery of the disk 300 to the center as shown in FIGS. 9C and 9D, thereby forming the disk 300. Sweep away the sludge (1) piled on.

In addition, as shown in Figure 9e, the removal blade 410 rotates continuously so as to leave the surface of the disk 300, so that the cake-shaped sludge 1 stacked on the disk 300 is removed from the disk. The removal work of the sludge (1) is completed by completely leaving (300).

And, when the removal of the sludge 1 on the disk 300 is completed, the removable blade 410 is returned to its original position as the second power unit 440 provides reverse rotation force.

Meanwhile, the sludge 1 dropped from the disk 300 falls downward through the removal unit 400, and the fallen sludge 1 is released to the outside by the action of the discharge unit 500. It is discharged as

Therefore, the disk filter type filter of the present invention performs the task of removing the support shaft 200 and the disk 300 from the chamber 100 as in the prior art in order to remove the sludge 1 stacked on the disk 300. The sludge 1 can be easily removed from the disk 300 through the removal unit 400, thereby improving work efficiency, such as work convenience and work time reduction.

Meanwhile, as shown in FIG. 10, at least one blowing hole 416 is formed in the removable blade 410 at regular intervals along the longitudinal direction. In this case, the removable blade 410 is formed with a receiving space 418 on the inside that can receive cleaning liquid or air provided from the outside.

The blowing hole 416 is formed on one side of the removable blade 410, that is, along the longitudinal direction, or is formed at least one at one end, and discharges the cleaning liquid or air entering the receiving space 418 into the disk 300. ) By spraying it on the surface, the surface of the disk 300 is cleaned by the cleaning liquid or air. In this case, the physical properties of the cleaning liquid or air are not limited, and any physical properties that support the surface of the disk 300 to be easily cleaned can be used. Also, for example, the cleaning liquid or air can be formed at high pressure.

In addition, the blowing hole 416 is formed slanted from upward to downward, as shown in the enlarged view of FIG. 10b, so that when the cleaning liquid or air is blown out through the blowing hole 416, it hits the surface of the disk 300. Pressure ejection is performed to improve the surface cleaning efficiency of the disk 300.

In addition, the rotating shaft 420, on which one end of the removable blade 410 is fixed, is in communication with the receiving space 418 of the removable blade 410, so that the cleaning liquid or air provided from the outside is connected to the rotating shaft 420. A hollow 422 is formed so that the removable blades 410 can be supplied to each of the plurality of removable blades 410 along the longitudinal direction.

As above, a blowing hole 416 and a receiving space 418 are formed in the removable blade 410, and a hollow 422 is formed in the rotating shaft 420, so that the disk ( By performing a cleaning process on the surface of 300, the disk 300 is cleaned in the chamber 100. The surface of the disk 300, that is, the filtering unit 320, is cleaned without cleaning, thereby maintaining the filtration efficiency of the filtering unit 320 and providing convenience of operation.

What has been described above is only one example of implementing a disk filter type filter that can easily remove cake-shaped sludge, and the present invention is not limited to the above-described examples. Those skilled in the art will understand that various changes can be made without departing from the gist of the present invention.

100: chamber 110: housing
120: Lid 200: Support shaft
210: inlet hole 220: rotating part
300: Disk 310: Support portion
312: support plate 313: support step
314: ridge 316: insertion hole
318: Entry hole 320: Filtration unit
322: first filter net 324: second filter net
400: Removal unit 410: Removal blade
412: recessed surface 414: adhesion pad
420: Rotation axis 430: Support bracket
440: second power unit 442: motor
444: Power transmission member 500: Discharge unit
510: collection plate 512: outlet
520: rotation guidance unit 530: second power unit
540: opening and closing part

Claims (11)

With chamber;
a support shaft configured to stand in a vertical longitudinal direction inside the center of the chamber;
It is stacked in multiple layers at regular intervals along the longitudinal direction of the support shaft, and during the process of filtration through adsorption by mutual stirring of the contaminated liquid and diatomaceous earth flowing into the chamber, contaminated sludge is deposited on the surface and contaminants are removed. a disk supporting the filtrate to enter the inside and drain to the outside through the support shaft; and
A removal unit configured on one side of the interior of the chamber to remove cake-shaped sludge created during the filtration process and layered on the disk.
The removal part,
A removable blade formed at a predetermined length so that its lower end is in close contact with the disk; and
One end of the removable blade is fixed, and a rotating shaft configured to stand vertically on one side of the chamber so that the cake-shaped sludge accumulated on the disk can be swept away and removed as the removable blade rotates.
The removable blade is
A depression of a certain depth is formed on the side section to expand the surface area with the cake-shaped sludge.
It includes at least one blowing hole that blows out cleaning liquid or air provided from the outside to clean the disk, and an accommodation space that communicates with the blowing hole to allow the cleaning liquid or air to flow,
A disk filter type filter that facilitates the removal of cake-shaped sludge, wherein the blowing hole is formed inclined in the direction of the disk from the removal blade to improve surface cleaning efficiency of the disk by the ejected cleaning liquid or air. According to paragraph 1,
a discharge unit provided at the inner lower end of the chamber to collect contaminated sludge that has fallen off the disk or fallen downward through the removal unit, and to discharge the collected contaminated sludge to the outside;
A disk filter type filter that facilitates the removal of cake-type sludge, comprising a. The method of claim 1, wherein the removal unit,
a support bracket supporting both ends of the rotating shaft so that the rotating shaft rotates in place; and
a first power unit configured on one side of the rotation shaft to provide rotational force so that the rotation shaft can rotate forward and backward at a certain angle;
A disk filter type filter that facilitates the removal of cake-type sludge, comprising a. According to paragraph 3,
The removable blade is formed in a length such that it is configured between the center of the disk and the rotation axis;
The removal blade is streamlined so that it can be collected inward when sweeping away cake-shaped sludge while rotating;
A disk filter type filter that facilitates the removal of cake-shaped sludge, characterized in that it is formed. delete According to paragraph 3,
The lower end of the removable blade does not directly contact the disk, but is configured to be spaced apart at regular intervals. The upper end is fixed to the lower end of the removable blade, and the lower end touches the top of the disk to remove the removable blade. An adhesion pad that rotates with the blade and supports it to improve the removal efficiency of cake-shaped sludge;
A disk filter type filter that facilitates the removal of cake-type sludge, comprising a. The method of claim 1, wherein the support shaft is:
The inside is formed in the shape of an empty hollow tube;
It is configured to communicate with one side of the disk, which is stacked in multiple layers along the longitudinal direction of the support shaft, and includes at least one inlet hole that supports the filtrate phase to enter the inside;
On one side of the support shaft, a rotating part that rotates the disk together with the support shaft to facilitate the removal of cake-shaped sludge stacked on the disk through the removal part;
A disk filter type filter that facilitates the removal of cake-type sludge, comprising a. The method of claim 1, wherein the disk is:
pedestal; and
It includes a filtration unit formed at the top of the support unit to support the filtrated liquid phase from which contaminants are removed to enter the inside and diatomaceous earth adsorbed thereon to form cake-shaped sludge of a certain thickness.
The support portion includes a support plate spaced apart from the filter portion at a predetermined interval so that the filtrate can be collected inside;
a raised portion raised at a certain height from the center of the support plate and forming an insertion hole into which the support shaft is inserted;
At least one entry hole formed to penetrate the outer periphery of the protrusion to support the filtrate collected by the support plate to enter the inside through the support shaft;
A disk filter type filter that facilitates the removal of cake-type sludge, comprising a. The method of claim 8, wherein the filtering unit,
A first filter network formed with mesh of several mm to tens of mm; and
A second filter net configured at the bottom of the first filter net and formed with mesh of 0.1 mm to hundreds of micrometers;
A disk filter type filter that facilitates the removal of cake-type sludge, characterized in that it consists of. According to paragraph 3,
A hollow body that communicates with the receiving space of the removable blade fixed along the longitudinal direction of the rotating shaft and allows the cleaning liquid or air provided from the outside to be ejected through the receiving space to the blowhole;
A disk filter type filter that facilitates the removal of cake-type sludge, comprising a. delete