KR20230072530A - Disk filter type strainer - Google Patents

Abstract

The present invention relates to a disc filter-type filter for easy discharge of sludge, by configuring a discharge unit on one side of the inside of the chamber to easily discharge the sludge accumulated inside the chamber to the outside, thereby effectively removing the sludge in the chamber. The purpose is to prevent deterioration in filtration efficiency due to remaining sludge by keeping the chamber always clean, along with ease of work through removal.
To this end, the present invention, the chamber; a support shaft configured to be erected in a vertical longitudinal direction inside the center of the chamber; Stacked in multiple layers at regular intervals along the longitudinal direction of the support shaft, contaminated sludge is deposited on the surface and contaminants are removed during the process of filtration by adsorption by mutual stirring of the contaminated liquid phase and diatomaceous earth flowing into the chamber. a disk for supporting the filtrate phase to enter the inside and draining the filtrate to the outside through the support shaft; and a discharge unit provided at one side of the inside of the chamber to collect polluted sludge that has fallen off the disk or to the lower side, and to support the collected polluted sludge to be discharged to the outside.

Description

Disk filter type strainer for easy discharge of sludge {Disk filter type strainer}

The present invention relates to a disc filter type filter that facilitates the discharge of sludge.

In general, a filtering device is a device that traps residues in a liquid to be purified, and has been developed in various forms, and in particular, a purification system using diatomaceous earth has been released.

The purification system using diatomaceous earth includes a mixing tank for introducing and mixing diatomaceous earth, a filtering means for pre-coating diatomaceous earth on a filter to purify the purified liquid, a deliquidating means for separating the purified liquid into sludge and liquid, and a crude liquid to be purified and purified It consists of a purified liquid tank for storing one liquid, a filtration pump means for forcibly circulating the purified liquid, an air pressure pressurizing means for applying air pressure, and a plurality of valves for controlling the flow of fluid in each line.

The filtration system as described above includes a pre-coating step of coating the diatomaceous earth in a layer in the filtering means by passing the diatomaceous earth introduced into the mixing tank through the filtering means, and passing the undiluted solution to be purified into the filtering means through the pre-coating step to remove the residue Alternatively, a filtration step of filtering out the sludge, and a backwashing step of removing diatomaceous earth and sludge forming a layer in the filtering means by applying a strong flow of fluid in the reverse direction to the filtering means when filtering is no longer possible in the filtering step, and the backwashing It consists of a deliquid step to remove sludge and the like removed through the step.

However, the conventional purification system using diatomaceous earth described above has a problem in that components such as a mixing tank, a filtering tank, and a dehydration tank are essential, and the overall size of the purification system is enlarged, and the manufacturing cost is expensive. There is a problem with taking it.

As shown in FIG. 1, the conventional filtering device of Patent No. 10-857283 proposed to overcome this problem has a tank body 10 having a discharge part 16 on the lower side and a support 15 formed therein, and , The lid 11 disposed on the upper side of the tank body 10 to be locked and dismantled, the holding pipe 20 mounted on the support 15 and having a through hole 24 formed on the surface, and the lid 11 A fixing part 60 disposed on the inner lower side of the holding pipe 20 and supporting the upper end of the holding pipe 20, and a micro-hole formed on the surface of the holding pipe 20 and inserted into the holding pipe 20 and the inside of the holding pipe 20 A filter plate 30 in communication, a filter screen covered with the filter plate 30 and having a diatomaceous earth layer formed on the surface, and a column inserted into the holding pipe 20 and disposed on the upper and lower sides of the filter plate 30 A member 50 is constituted.

Accordingly, pre-coating is performed after the liquid phase of the object to be refined (hereinafter collectively referred to as 'contaminated liquid phase') and diatomaceous earth are introduced into the diatomaceous earth tank. As the pre-coating progresses, the undiluted solution in the diatomaceous earth tank is forcibly moved by a pump and circulated into the filtration device, where a pre-coat layer is formed, and the liquid passing through the diatomaceous earth tank is returned to the diatomaceous earth tank.

On the other hand, the filtering device is laminated with a filtering plate 30 formed with micro-holes by an entry pressure while the contaminated liquid phase and diatomaceous earth entering the inside are mutually stirred. At this time, the contaminants contained in the contaminant liquid phase are adsorbed to diatomaceous earth to form lumps, so that they are not discharged through the micropores of the filtering plate 30, and the filtrate phase from which the contaminants are eliminated communicates with the inside of the filtering plate 30 As drainage is made to the outside through the inside of the holding pipe 20, the filtering action is performed.

In addition, in the filtering device, contaminated diatomaceous earth in which contaminants are adsorbed is stacked on the filtering plate by the above-described filtering action, and when a predetermined time elapses, cake-type sludge in which contaminated diatomaceous earth of a predetermined thickness is stacked on the filtering plate is formed, thereby forming the cake Since the filtration efficiency is lowered by the type sludge, a sludge removal operation to periodically remove the cake type sludge is performed.

The sludge removal operation is performed after opening the lid 11 from the tank body 10, and then removing the holding pipe 20 and the filtering plate 30 configured inside the tank body 10 to remove the outer circumference of the filtering plate 30 to remove the cake-type sludge accumulated on the

However, since the cake-type sludge stacked on the filtering plate 30 maintains the stacked state by high pressure, the complexity of the work of removing the cake-type sludge from the filtering plate 30 using a separate tool such as a knife There is a problem with .

In addition, during the process of removing the holding pipe and the filtering plate from the tank body for the sludge removal operation, the sludge falls downward and accumulates below the tank body, and in order to remove the sludge accumulated inside the tank body, the holding pipe and filter There is a problem in that the plate is taken out and a separate cleaning tool is inserted into the empty tank body to remove the sludge, which is cumbersome.

In addition, the contaminated sludge accumulated on the filtering plate in the form of lumps by mutual stirring of the contaminated liquid phase and diatomaceous earth is arbitrarily dropped downward to accumulate sludge under the tank body, As entry is interfered, there is a problem in that the filtration efficiency for the contaminated liquid phase is lowered.

Republic of Korea Patent Publication No. 10-0857283 (2008.09.08. Notice) Republic of Korea Registered Utility Model Publication No. 20-0365150 (Announced on October 16, 2004)

As proposed to solve the above problems, an object of the present invention is to construct a discharge unit on one side of the inside of the chamber to easily discharge the sludge accumulated inside the chamber to the outside, thereby removing the sludge in the chamber. It is an object of the present invention to provide a disc filter-type filter that is easy to discharge sludge so that the chamber is always kept clean, along with ease of operation through effective removal, to prevent deterioration in filtration efficiency due to remaining sludge.

The present invention for achieving the above object, and the chamber; a support shaft configured to be erected in a vertical longitudinal direction inside the center of the chamber; Stacked in multiple layers at regular intervals along the longitudinal direction of the support shaft, contaminated sludge is deposited on the surface and contaminants are removed during the process of filtration by adsorption by mutual stirring of the contaminated liquid phase and diatomaceous earth flowing into the chamber. a disk for supporting the filtrate phase to enter the inside and draining the filtrate to the outside through the support shaft; and a discharge unit disposed at one side of the inside of the chamber to collect polluted sludge that has fallen off the disk or has fallen downward, and to support the collected polluted sludge to be discharged to the outside.

In the present invention, it is configured on one side of the interior of the chamber, it is preferable to include; a removal unit to remove the cake-type sludge generated and stacked on the disk during the filtration process.

In the present invention, the discharge unit is configured at the lower end of the chamber to collect sludge falling from above, and a collection plate on one side of which a discharge port of a predetermined size is formed so that the sludge can be discharged to the outside; a rotation guidance unit configured at an upper end of the collection plate and guiding the sludge collected in the collection plate to a discharge port and supporting the discharge; and a second power unit configured to provide rotational force to the rotation guide unit so that the sludge collected in the collection plate is guided to the discharge port while the rotation guide unit rotates.

In the present invention, the rotation guide unit is configured to be spaced apart from the collection plate upward at a predetermined interval, and the center is connected to the second power unit, rotating blades that rotate together with the rotational force provided from the second power unit; and at least one guide plate, the upper end of which is fixed to the lower end of the rotary blade and the lower end of the guide plate is configured to contact the collecting plate to guide the sludge to the discharge port while rotating together with the rotary blade.

In the present invention, the rotary blade is composed of a plurality of radially; The guide plate is composed of a main wing formed on the outermost part of the rotary blade and an auxiliary wing formed in an inward direction symmetrically with the main wing; It is preferable that the auxiliary blades are configured such that the sludge moves from the middle to the outer portion as the width gap between the main blade and the auxiliary blade is sequentially narrowed in the plurality of rotary blades.

In the present invention, each of the main blade and the auxiliary blade is preferably configured to be tilted symmetrically with each other at a certain angle so that the sludge is collected in the center.

In the present invention, the outlet of the collection plate preferably includes an opening and closing portion that opens and closes the outlet to control arbitrary discharge of the sludge.

According to the present invention, by configuring the discharge unit on one side of the inside of the chamber to easily discharge the sludge accumulated inside the chamber to the outside, along with the ease of work through effective removal of the sludge in the chamber, the chamber is always It has the effect of preventing the deterioration of filtration efficiency due to the remaining sludge by maintaining a clean state.

1 is a cross-sectional view of a conventional filtering device showing an example.
2 is a cross-sectional view of a filter according to the present invention.
3 is a partially exploded perspective view showing a configurational relationship between a disk and a removal unit according to the present invention;
4 is a diagram of a disk according to the present invention;
4a is an exploded perspective view, and 4b is a coupling cross-sectional view.
5 is a view of a removal unit according to the present invention,
5a is a perspective view and 5b is a plan view.
Figure 6 is a partially enlarged view showing the configuration of the discharge unit according to the present invention.
Figure 7 is an exploded perspective view of the discharge unit according to the present invention.
8 is a view of the rotation guidance unit according to the present invention,
8a is a perspective view, and 8b is a bottom view.
9 is a view showing the configuration relationship of the guide plate in the rotary blade according to the present invention.
10A to 10C are operating state diagrams showing a state in which contaminated sludge is discharged by the rotation guide part of the discharge unit according to the present invention.

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

As shown in FIG. 2, the disc filter-type filter of the present invention pressurizes diatomaceous earth and liquid phase from the bottom to the top, filtration is performed through multi-layered discs, and filtration through the discs is performed. It works as a filtration system that drains the liquid phase 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, a removal part 400 and a discharge part 500.

The chamber 100 performs a function of providing an airtight space so that the filtering action can be smoothly performed through the contaminated liquid phase and diatomaceous earth flowing into the chamber 100 .

The chamber 100 has a space formed therein, one end, that is, a housing 110 with an open top, and one end, that is, the top of the housing 110 is opened and closed to support removal or maintenance of sludge. Includes 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 based on the hinge. Of course, it is not limited thereto, and any structure or configuration of the lid 120 to open and close one end of the housing 110 may be adopted.

In addition, a support bracket is included at the lower end of the lid 120 to support the upper end of the support shaft 200 so that the position of the support shaft 200 can be fixed and rotated in place smoothly.

In addition, the chamber 100 is formed of stainless steel or aluminum to have resistance to high pressure acting therein and safety in which chemical reactions or deterioration according to the type of contaminant liquid phase do not occur. Of course, it is not limited thereto, and the chamber 100 may be made of iron, synthetic resin, etc. according to the type of contaminated liquid or a user's request.

The support shaft 200 is configured inside the chamber 100 and performs a function of discharging the filtrate phase filtered through the disk 300 to the outside.

The support shaft 200 is formed in a hollow hollow tube shape, 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 formed along the longitudinal direction of the support shaft 200 to correspond to each of the disks 300 stacked in plurality along the length 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-type sludge 1 generated on 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 configured on one side of the support shaft 200 and performs a function of providing 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 thereto, and the rotation unit 220 may be configured anywhere as long as the support shaft 200 is positioned so that rotation in place can be performed smoothly.

In addition, the rotation unit 220 is configured between a motor that generates rotational force through electricity or hydraulic pressure, 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 a plurality of 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 rotation unit 220, and as described above, the cake-type sludge stacked on the disk 300 is not limited to rotating only when removing In the process of filtering the contaminated liquid phase, the disk 300 rotates together with the support shaft 200, so that the filtration efficiency of the contaminated liquid phase is improved. That is, the rotation part 220 of the support shaft 200 can be configured to rotate during the filtration process or to rotate only during the process of removing the cake-type sludge 1, which can improve the filtration efficiency for the contaminated liquid phase. Any method that exists can be selectively used. Of course, it is not limited thereto, and the rotating part 220 can be omitted.

As shown in FIG. 3, a plurality of disks 300 are stacked along the longitudinal direction of the support shaft 200, and a filtering action is performed by mutual stirring of the diatomaceous earth and the contaminant liquid phase introduced into the chamber 100. , It performs a function of allowing only the filtrate phase in which contaminants are removed from the contaminant liquid phase to enter the inlet hole 210 of the support shaft 200.

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

The support part 310 supports that the filtering part 320 is seated on the upper end, and allows the filtrate phase passing through the filtering part 320 to enter the inlet hole 210 of the support shaft 200 perform a supporting function.

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

The support plate 312 supports that the filtering unit 320 is seated on the top.

In addition, the support plate 312 is inclined downward so that the filtrate phase passing through the filtration unit 320 seated on the top is smoothly transferred to the ridge 314 side.

In addition, the outer periphery of the support plate 312 supports the seating of the filtering unit 320 and the spacing between the supporting plate 312 and the filtering unit 320 is spaced apart, thereby passing the filtering unit 320. A support step 313 is formed to support the filtrate phase to be smoothly transferred to the raised portion 314 side.

The support step 313 protrudes from the outer periphery of the support plate 312 at a certain height and has a certain width, thereby supporting the seating of the filtering unit 320 on the top.

In addition, the support plate 312 and the support step 313 maintain a mutually sealed state, so that the filtrate phase can enter only through the filtering part 320.

The raised portion 314 is configured to protrude from the center of the support plate 312 at a certain height, and to support the stable seating of the filtering portion 320 seated on the top and to smoothly collect the filtrate phase. .

In addition, an insertion hole 316 into which the support shaft 200 is inserted is formed at the center of the raised portion 314 .

In addition, at least one entry hole 318 is formed in the raised portion 314 to allow the filtrate phase to enter the inlet hole 210 as it communicates with the inlet hole 210 formed in the support shaft 200. do. In this case, the entrance hole 318 is formed in the same size and number as the inlet hole 210 . Of course, it is not limited thereto, and the entrance hole 318 may be any size, number, or shape that allows the filtrate phase to be smoothly drained through the inlet hole 210 .

In addition, the raised portion 314 is configured to be recessed at a predetermined length at the lower end of the support plate 312 so that the discs 300 stacked in multiple layers along the longitudinal direction of the support shaft 200 are spaced apart at regular intervals. , so that the filtration action is performed through the spaced space between the disks 300.

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

The filtering unit 320 is configured at the upper end of the supporting unit 310 so that the diatomaceous earth and the polluted liquid phase are mutually stirred to perform a filtration action in which pollutants adsorbed to the diatomaceous earth are separated into the filtrate phase and the filtrate phase. It performs the function of allowing the contaminated sludge to be deposited on the upper side and allowing the filtrate phase to enter the inside of the supporting part 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 thereto, and the filtering unit 320 may be composed of one or more depending on the type of polluted liquid phase or required filtration efficiency.

The first filtering net 322 is formed at an upper end of the supporting portion 310 and is formed of a mesh or perforated plate having meshes having a size of several mm to several tens of mm.

The second filtration net 324 is configured at the lower end of the first filtration net 322, and performs a secondary filtration action on the liquid phase that has passed through the first filtration net 322, thereby improving the purity of the filtrate phase. .

In this case, the second filtering net 324 is formed of a mesh or perforated plate having meshes of 0.1 mm to several hundreds of μm.

Of course, it is not limited thereto, and the first and second filter nets 322 and 324 are sequentially seated on the upper end of the supporting part 310 so that the filtration action for the contaminated liquid phase is performed, and the type of contaminated liquid phase Alternatively, it may be formed in various mesh sizes and materials according to the required filtration efficiency.

The removing unit 400 is configured on one side of the inside of the chamber 100 to temporarily or selectively remove the contaminated sludge 1 stacked on top of the disk 300, thereby facilitating the removal of the contaminated sludge 1. perform a function In some cases, the removal part 400 may be omitted.

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

One end of the removal blade 410 is in close contact with the surface of the filtering part 320 of the disk 300, and has a function of substantially removing the contaminated sludge 1 accumulated on the filtering part 320 by a filtering action. carry out

In addition, one end of the removal blade 410 is fixed to one end of the rotating shaft 420, and is configured to rotate along with the rotation of the rotating shaft 420. In this case, the number of removal blades 410 is configured to each of the plurality of stacked disks 300 along the longitudinal direction of the support shaft 200 .

In addition, the other end of the removal blade 410 is configured to come into contact with 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 entire surface of the disk 300 The contaminated sludge 1 can be removed.

That is, the removal blade 410 is configured such that one end is fixed to the rotation shaft 420 and the other end is configured such that the outer periphery of the raised portion 314 of the support portion 310 formed on the disk 300 comes into contact with the rotation shaft ( 420) to remove the contaminated sludge 1 stacked on the disk 300.

The rotating shaft 420 is erected vertically along one side of the inside of the chamber 100 along the longitudinal direction, and performs a function of rotating the removal blade 410 as it rotates here and there.

The support brackets 430 are provided at both ends of the rotating shaft 420 and perform a function of supporting the rotating shaft 420 to smoothly rotate in place.

The first power unit 440 generates rotational force to rotate the rotational shaft 420 at a predetermined angle. In this case, the first power unit 440 includes a motor 442 and a power transmission member 444 .

In addition, the motor 442 generates positive and reverse rotational force so that the removal blade 410 can reciprocate at a rotational angle sufficient to sweep one side of the surface of the disk 300.

In the removal unit 400 configured as described above, as the support shaft 200 rotates in one direction by the rotation unit 220, the disk 300 rotates in one direction together with the support shaft 200, and the first power unit As the removal blade 410 enters onto the surface of the disk 300 along with the rotating shaft 420 by the forward rotational force provided at 440, the cake-type sludge 1 generated on the disk 300 is removed. By the sweeping action, the cake-type sludge 1 on the disk 300 is forcibly dropped along the rotational direction of the removal blade 410 and removed.

In addition, when the removal of the cake-type sludge 1 from the disk 300 is completed by the removal blade 410, the first power unit 440 generates reverse rotational force so that the removal blade 410 returns to its original position. By returning, the removal process of the caked sludge 1 is completed.

As shown in FIG. 2, the discharge unit 500 is configured at the inner lower end of the chamber 100, and polluted sludge 1 dropped from the disk during the filtration process or contaminated sludge dropped through the removal unit 400 (1) It performs the function of collecting so that it can be discharged to the outside.

As shown in FIGS. 6 and 7 , 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 formed at the lower end of the housing 110 of the chamber 100 and serves to collect the polluted sludge 1 dropped from the disk 300 .

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

The rotation guide part 520 is configured above the collection plate 510 and guides the contaminated sludge 1 collected above the collection plate 510 to the discharge port 512 to perform a function of discharging it. .

As shown in FIG. 8 , the rotation guide part 520 includes a rotary blade 522 and a guide plate 524 .

The rotary blade 522 is configured to be spaced apart from the collection plate 510 at a predetermined height and supports the guide plate 524 configured at the lower end, so that the guide plate 524 is provided from the second power unit 530 Rotation is performed smoothly by rotational force.

In addition, a seating hole 523 into which one end of the second power unit 530 is inserted is formed at the center of the rotary blade 522 as it is fastened with one end of the second power unit 530 .

The seating hole 523 maintains a state in which one end of the second power unit 530 is inserted and fixed so that the rotary blade 522 can be rotated by the rotational force of the second power unit 530. . Alternatively, the seating hole 523 does not separately constitute the second power unit 530, and supports rotating by the rotation unit 220 configured at one end of the support shaft 200 as the support shaft 200 is inserted. Together with the shaft 200, the rotary blades 522 can rotate.

On the other hand, as shown in FIG. 8, the rotary blade 522 will be described based on the fact that it is composed of first to third rotary blades 522a, 522b, and 522c at equal intervals of 120°. Of course, it is not limited thereto, and the rotary blades 522 may be composed of one or more depending on the state of the type, viscosity, density, etc. of the contaminated sludge 1.

The guide plate 524 is configured at the lower end of the rotary blade 522 and rotates together with the rotary blade 522 to guide the contaminated sludge 1 collected on the collector plate 510 toward the outlet 512, It performs the function of discharging the contaminated sludge 1.

The guide plate 524 is composed of main blades 5242 and auxiliary blades 5244 configured symmetrically with the main blades 5242.

The main blade 5242 is formed at the outermost part of the rotary blade 522 and guides the polluted sludge 1 to be collected from the end of the collecting plate 510 toward the center, that is, toward the inside. In this case, the main blade 5242 is composed of the rotating blade 522, that is, the first to third rotating blades 522a, 522b, and 522c, respectively.

The auxiliary blades 5244 are configured symmetrically with the main blades 5242 to guide the contaminated sludge 1 to be collected toward the main blades 5242.

In addition, as shown in FIG. 9, each of the main blade 5242 and the auxiliary blade 5244 has a mutually symmetrical inclination (α°) so that contaminated sludge 1 is collected based on the rotational direction of the rotor blade 522. ) is configured to have

In addition, the auxiliary blades 5244 are associated with the number of rotor blades 522 and adjust the distance from the main blade 5242, so that the contaminated sludge is removed by the guide plate 524 while rotating along the rotating blades 522. When (1) is guided toward the outlet 512, the resistance of the contaminated sludge 1 acting on the surface area of the guide plate 524 is minimized so that the contaminated sludge 1 is discharged smoothly.

For example, as shown in FIG. 9, the auxiliary blades 5244 are symmetrical with the main blades 5242 on the first to third rotary blades 522a, 522b, and 522c, respectively. Wings 5244a, 5244b, and 5244c are configured. In this case, the main blade 5242 and the auxiliary blade 5244 are configured to be tilted at a certain angle (α), but are formed to face each other, so that they are collected in the center when sweeping the contaminated sludge 1 while rotating. Thus, the discharge of the contaminated sludge 1 is facilitated.

In addition, the auxiliary blades 5244 adjust the width gap (W) with the main blades 5242 according to the configuration positions of the first to third rotor blades 522a, 522b, and 522c, so that the contaminated sludge 1 ) is not swept at once, but moved sequentially to minimize the resistance of the contaminated sludge 1 acting on the rotary blades 522 to facilitate discharge. For example, in the auxiliary blade 5244, the first to third auxiliary blades 5244a, 5244b, and 5244c are respectively formed on the first to third rotary blades 522a, 522b, and 522c, respectively, and The width gap between the main wing 5242 and the first auxiliary wing 5244a of the first rotary wing 522a is formed at the maximum width gap W1, and the main wing of the second rotary wing 522b (522b) 5242) and the second auxiliary wing 5244b are formed as an intermediate width gap W2, and the width of the main wing 5242 and the third auxiliary wing 5244c constituted by the third rotary wing 522c. The interval is formed as the minimum width interval W3.

In addition, as shown in FIG. 9, the first to third auxiliary blades 5244a, 5244b, and 5244c are formed to have a certain interval t, for example, the rotary blades 522 on the same line When the first to third auxiliary blades 5244a, 5244b, and 5244c are placed on the first to third auxiliary blades 5244, the adjacent auxiliary blades 5244 are configured to overlap with a certain width, so that the polluted sludge 1 located in the center of the first to the third auxiliary blades 5244a, 5244b, and 5244c, and is sequentially moved to be positioned at the outlet 512 formed on the outer circumference.

The second power unit 530 generates rotational force to rotate the rotation guide unit 520 so that the contaminated sludge 1 can be discharged through the outlet 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 rotational force generated by the motor to the rotation guidance unit 520 through the power transmission member.

The opening/closing unit 540 opens and closes the discharge port 512 of the collection plate 510 to discharge the contaminated sludge 1 according to a user's or manager's selection. Of course, it is not limited thereto, and may be omitted depending on the purpose of use of the opening/closing unit 540 .

As shown in FIG. 10, when a certain amount of contaminated sludge 1 is collected on the collection plate 510 in the discharge part of the disc filter type filter constructed as described above, the rotational force generated in the second power unit 530 is applied to the rotation induction unit ( 520), the rotation guide part 520 is rotated. At this time, the outlet 512 configured on one side of the collection plate 510 maintains an open state in the opening/closing part 540 .

In addition, the contaminated sludge 1 collected in the collecting plate 510 moves from the center to the outermost side along the guide plate 524 constituted by the rotor blades 522 of the rotation guide part 520 that rotates. The induced polluted sludge 1 is discharged through the open discharge port 512, so that the polluted sludge 1 is easily discharged from the inside of the chamber 100 to the outside.

What has been described above is only one embodiment for implementing a disk filter type filter that facilitates the discharge of sludge, and the present invention is not limited to the above embodiment. Those skilled in the art in the field belonging to the present invention will be able to understand that various modifications are possible 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
312: support plate 313: support step
314: ridge 316: insertion hole
318: entry hole 320: filtering unit
322: first filter net 324: second filter net
400: removal unit 410: removal blade
412: recessed surface 420: axis of rotation
430: support bracket 440: second power unit
500: discharge unit 510: collection plate
512: outlet 520: rotation guidance unit
522: rotary blade 522a: first rotary blade
522b: second rotary blade 522c: third rotary blade
524: guide plate 5242: main wing
5244: auxiliary wing 5244a: first auxiliary wing
5244b: second auxiliary wing 5244c: third auxiliary wing
530: second power unit 540: opening and closing unit

Claims (7)

with the chamber;
a support shaft configured to be erected in a vertical longitudinal direction inside the center of the chamber;
Stacked in multiple layers at regular intervals along the longitudinal direction of the support shaft, contaminated sludge is deposited on the surface and contaminants are removed during the process of filtration by adsorption by mutual stirring of the contaminated liquid phase and diatomaceous earth flowing into the chamber. a disk for supporting the filtrate phase to enter the inside and draining the filtrate to the outside through the support shaft; and
a discharge unit disposed at one side of the inside of the chamber to collect polluted sludge that falls off the disk or downward, and supports the collected polluted sludge to be discharged to the outside;
Disc filter type filter for easy discharge of sludge, characterized in that it comprises a. According to claim 1,
a removal unit disposed on one side of the inside of the chamber to remove cake-like sludge generated and stacked on the disk during the filtration process;
Disc filter type filter for easy discharge of sludge, characterized in that it comprises a. The method of claim 1, wherein the discharge unit,
a collection plate configured at a lower end of the chamber to collect sludge falling from above, and having a discharge port having a predetermined size on one side of the chamber so that the sludge can be discharged to the outside;
a rotation guidance unit configured at an upper end of the collection plate and guiding the sludge collected in the collection plate to a discharge port and supporting the discharge; and
a second power unit that provides rotational force to the rotation guide unit so that the rotation guide unit rotates and supports the sludge collected in the collecting plate to be guided to the discharge port;
Disc filter type filter for easy discharge of sludge, characterized in that it comprises a. The method of claim 3, wherein the rotation induction unit,
Rotating blades configured to be spaced apart from the collecting plate upward at a predetermined interval, the center connected to the second power unit, and rotating together with the rotational force provided from the second power unit; and
at least one guide plate, the upper end of which is fixed to the lower end of the rotary blade and the lower end thereof is in contact with the collecting plate, and configured to guide sludge to a discharge port while rotating together with the rotary blade;
Disc filter type filter for easy discharge of sludge, characterized in that it comprises a. According to claim 3,
The rotary blades are radially composed of a plurality;
The guide plate is composed of a main wing formed on the outermost part of the rotary blade and an auxiliary wing formed in an inward direction symmetrically with the main wing;
The auxiliary blade is a disk filter type filter for easy discharge of sludge, characterized in that the sludge is configured to move from the middle to the outer side as the width gap between the main blade and the auxiliary blade is sequentially narrowed in the plurality of rotary blades. According to claim 5,
Each of the main and auxiliary blades is a disc filter type filter for easy discharge of sludge, characterized in that the sludge is inclined symmetrically with each other at a certain angle so that the sludge is collected in the center. According to claim 3,
An opening and closing portion at the outlet of the collection plate to open and close the outlet to control random discharge of the sludge;
Disc filter type filter for easy discharge of sludge, characterized in that it comprises a.

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