KR101103570B1 - A Means For Filtration - Google Patents

Abstract

The present invention relates to a filtration column of water containing foreign substances such as sludge, waste water, water, sludge, etc. In more detail, the filtration of the foreign substances such as sludge as well as cleaning the filter medium by the rotational force without separation of the filtration column can be cleaned And it is related with the filtration column which can discharge sewage and wastewater at the same time and can carry out filtration of sewage and wastewater without stopping.

Description

Filtration Column {A Means For Filtration}

The present invention relates to a filtration column of water containing foreign substances such as sewage, waste water, sludge, etc., which will be described in more detail. And it is related with the filtration column which can discharge sewage and wastewater at the same time and can carry out filtration of sewage and wastewater without stopping.

Filtration means (apparatus) for filtering foreign matter such as sludge contained in water are used for pretreatment before various treatments of wastewater and wastewater, treatment of foreign matter such as sludge in water purification, or water treatment for recycling purposes.

The filtration means used for the purpose is to filter out foreign matter such as sludge having a larger particle than the gap physically by the gap of the filter medium to perform the filtration, foreign matters such as sludge deposited in the gap of the filter medium during the filtration process is inferior in filtration efficiency. There is a problem, and for this purpose, cleaning (washing) of the filter medium is required, and in some cases, the cleaning cannot be performed, so there is a problem in that the replacement is required.

Accordingly, the problem to be solved by the present invention is to provide a filtration means that is easy to clean the filter medium, the filtration action is not stopped during the cleaning of the filter medium.

The filtration column according to the problem to be solved by the present invention includes an upper chamber in which the inlet pipe and the outlet pipe communicate with each other, and a rotating plate in which an impeller is integrally formed to protrude therein; A drain chamber mounted to a lower portion of the upper chamber and having a rotary rod passing therein integrally with the rotary plate and having a drain pipe communicating with a side thereof; A filtration chamber mounted to rotate integrally with the rotary rod in a lower portion of the drain chamber and having a plurality of flow holes formed therein; A filter material placed inside the filtration chamber; Characterized in that the filtration chamber is composed of a support plate is placed.

Preferably, the upper chamber and the drain chamber are further configured with a gear chamber in which a plurality of gears of different diameters are mounted between the rotating plate and the rotating rod, so that the rotational force of the rotating plate is doubled to the filtration chamber.

In more detail, the gear chamber includes a first connecting rod integrally interlocked with the rotating plate, a first gear integrally interlocked with the first connecting rod, and a first diameter engaged with the first gear and smaller in diameter than the first gear. A second gear, a second connecting rod for fixing the second gear so as to be rotatable, a third gear having a diameter larger than that of the second gear, interlocking with the second connecting rod at a lower portion of the second gear, and A fourth gear meshing with the third gear and smaller in diameter than the third gear and interlocking with the rotating rod is mounted.

The filtration chamber is composed of an outer tube portion formed with a plurality of filtration holes and the inner tube portion formed with a plurality of filtration holes connected to the outer portion to form a predetermined gap, characterized in that the filter material is embedded between the outer portion and the inner tube portion. do.

In addition, a hemispherical protrusion is formed on a lower surface of the inner tube portion, and an upper surface of the support plate is formed with a settling groove in which the protrusion is placed so that the filtration chamber can be easily rotated while rotating on the support plate. Eccentricity does not work.

As described in detail above, in the present invention, the filter column may clean the filter medium by a rotational force by a pump or the like when foreign matter is deposited on the filter medium during the filtering action, and thus the efficiency of the filtering action decreases. There are advantages to it.

1 is a perspective view showing a state of use of the filter column of the present invention,
Figure 2a and Figure 2b is an exploded perspective view showing a basic example of the filter column of the present invention,
3A and 3B are side cross-sectional views showing an operating state of the filtration column shown in FIG. 1,
Figure 4 is a schematic diagram showing an embodiment of the present invention filter column.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a perspective view showing a state of use of the filter column of the present invention, Figures 2a and 2b is an exploded perspective view showing a basic example of the filter column of the present invention, Figure 3a and 3b is an operating state of the filter column shown in FIG. Figure 4 is a side cross-sectional view, Figure 4 is a schematic diagram showing an embodiment of the filter column of the present invention.

The filtration column of the present invention is used to treat foreign substances such as sludge from sewage and wastewater or water sources flowing into water collection wells, manholes, etc. at homes, stores, factories and roads, and can be used for various purposes. The filtration column is an upper chamber 100 to impart rotational force by inflow and outflow water, a gear chamber 200 to impart rotational force, a drainage chamber 300 to discharge treated water while holding a lower filtration chamber 400, and the The filtration chamber 400 rotated by the rotational force from the upper chamber 100, the filter medium 500 inside the filtration chamber 400, and the support plate 600 on which the filtration chamber 400 is placed are included as components. do.

In detail, the upper chamber 100 has a space formed therein as shown in FIGS. 1 and 2, and has an inlet pipe 120 and an outlet pipe 130 formed at a side thereof with an opening shape at a lower surface thereof. It is configured to communicate with the interior. In particular, the inside of the upper chamber 100, the impeller 111 is formed of a rotating plate 110 is formed integrally protruding bar, the rotating plate 110 is integral with the plate-shaped bottom plate 112 as shown in FIG. The impeller 111 is formed to protrude into the configuration, the impeller 111 is configured so that a plurality of wings to form a curved surface, each wing is configured so that the bone portion facing the inlet pipe 120 is the inlet pipe 120 The waste plate introduced from the wastewater (water in addition to the wastewater may be used, but in the following, water containing foreign substances such as sludge is referred to as wastewater). The rotational force is applied to the wastewater thus introduced into the outflow pipe 130. Although the above description has given the rotational force to the rotating plate 110 by the inflow of waste water, the present invention is not limited thereto. The air is introduced into the inlet pipe 120 to the rotating plate 110 by air pressure. Naturally, it can be given a rotational force.

The rotating plate 110 is not shown in the drawings, but can be directly connected to the rotating rod 210 to transmit the rotational force applied to the rotating plate 110 to the filtration chamber 400 which will be described below. As described above, the rotational force may be transmitted to the rotating rod 210 based on the interlocking of the plurality of gears. Hereinafter will be described a structure that can transmit the rotational force of the rotating plate 110 to the rotating rod 210 by the action of the gear.

The lower portion of the upper chamber 100 is equipped with a gear chamber 200, the method (structure) in which the upper chamber 100 is mounted to the gear chamber 200 can be presented in various ways, the description Is omitted.

The gear chamber 200 forms a space therein, and a first through hole 220 is formed on an upper surface thereof, and a first connection rod 230 to be described below as the first through hole 220 in an open shape of a lower surface thereof. ) Penetrates and is connected to the rotating plate 110.

A plurality of gears are mounted inside the gear chamber 200 to multiply the rotational force given to the rotating plate 110 based on the linkage to impart a doubled rotational force to the filtration chamber 400. A first connecting rod 230 penetrating the first through hole 220 and integrally interlocking with the rotating plate 110, a first gear 240 integrally interlocking with the first connecting rod 230, and the first connecting rod 230. A second gear 250 engaged with the gear 240 and having a diameter smaller than that of the first gear 240, and a second connecting rod 260 fixed to be rotatably integrated with the second gear 250; A third gear 270 having a diameter larger than that of the second gear 250 and integrally interlocked with the second connecting rod 260 at the lower portion of the second gear 250, and engaged with the third gear 270. The fourth gear 280 is smaller in diameter than the third gear 270 and integrally interlocks with the rotary rod 210.

Here, the second connecting rod 260 transmits the rotational force applied to the rotating plate 110, the first connecting rod 230, and the first gear 240 to the second gear 250 and the third gear 270. Both ends of the second connecting rod 260 is configured to have a first fastening groove 290 formed inside the upper surface of the gear chamber 200 as shown in FIGS. 2A and 2B and a drain chamber 300 to be described below. The second fastening grooves 330 configured at the outer side of the upper surface are respectively fixed to be rotatable.

As such, the rotational force from the rotating plate 110 is transmitted to the first gear 240 by the first connecting rod 230, and is larger by the second gear 250 having a smaller diameter while being engaged with the first gear 240. The rotation force is generated, and a larger rotation force is applied to the fourth gear 280 having a smaller diameter in which the third gear 270 having a larger diameter that is integrally rotated with the second gear 250 is engaged with the third gear 270. As a result, the rotational force generated in the rotating plate 110 is endowed with the rotational force doubled to the rotating rod 210 by the action of gears having different diameters. 2A and 2B show an example of the operation of four gears, it is natural that the number can be selectively configured as necessary.

The lower portion of the gear chamber 200 forms a space therein, and a second through hole 320 is formed on an upper surface thereof, and a drain pipe 310 communicates with a side thereof, and a drain chamber 300 having a lower opening is formed. . In addition, a second fastening groove 330 is configured on the outer side of the upper surface of the drain chamber 300 so that one end of the second connecting rod 260 is inserted as mentioned above.

In addition, the lower end of the drain chamber 300 has a receiving portion 340 is formed in the expansion pipe shape of the diameter is increased so that the upper end of the filtration chamber 400 is inserted into the receiving portion 340.

Through the drain pipe 310 to discharge the sewage, such as sludge, such as will be described below to the outside is discharged to the outside, the drain pipe 310 as shown in FIG. It is reasonable to prevent backflow of odor or the like from the drain pipe 310 to the drain pipe 310.

As shown in FIGS. 2A and 2B, the filtration chamber 400 includes an exterior portion 410 in which a plurality of first filtration holes 411 are formed, and a plurality of agents connected to each other in a predetermined gap with the exterior portion 410. It consists of an inner tube part 420 in which two filtration holes 421 are formed. The exterior part 410 and the inner tube part 420 are respectively connected by a joint part 430 at an upper end thereof, and a plurality of first flow holes 431 are formed in the joint part 430. In the space formed by the exterior part 410, the inner tube part 420, and the joint part 430, a filter medium 500 to be described below is disposed. In addition, the exterior portion 410 and the inner tube portion 420 are connected to each other by a closing plate 470 at the lower end, the closing plate 470 is hollow 471 is formed in the center. It is reasonable that the closing plate 470 is configured to be detachable to the exterior portion 410 and the inner tube portion 420, which means that the placement and disassembly of the filter medium 500 is based on the attachment and detachment of the closing plate 470. To facilitate it. The detachable structure of the closing plate 470 can be configured in various ways, the description thereof will be omitted.

In addition, the lower surface of the inner tube portion 420 is formed with a projection 422 to the closed surface to be inserted into the hollow 471 of the closing plate 470, the projection 422 is a hemispherical projection 423 is further The protrusion 423 is inserted into the settling groove 610 formed on the upper surface of the supporting plate 600 to be described below so that the eccentricity does not act on the entire rotation of the filtration chamber 400.

In addition, the upper end of the inner tube portion 420 is connected to the inner tube portion 420, the connection pipe 450 is integrally formed. The connecting pipe 450 is zigzag along the circumference of the connecting bone 451 and the connecting mountain 452 is configured to be fastened by the fastening frame 460 and the insertion fastening method to be described below.

The fastening frame 460 which is fastened to the connection pipe 450 is connected to the rotary rod 210 and is connected to the fastening pipe 461 and the fastening flange 462 at the end of the fastening pipe 461 is configured. do. A plurality of second flow holes 463 are formed in the fastening flange 462, and fastening peaks 465 and fastening bones 464 are formed at ends thereof to face the connecting bone 451 and the connecting mountain 452. Is formed. In this way, the fastening peak 465 and the fastening bone 464 of the fastening flange 462 are respectively inserted into and engaged with the connecting bone 451 and the connecting mountain 452 of the connecting pipe 450 facing each other from the rotating rod 210. Rotation is transmitted to the fastening frame 460, and the fastening frame 460 is integrally formed by being fastened to the connection pipe 450, and eventually the rotation force is applied to the entire filtration chamber 400.

In addition, an inserting portion 412 having a smaller diameter is formed at an upper portion of the exterior portion 410 such that the inserting portion 412 is inserted into the receiving portion 340. In this way, the filtration chamber 400 is prevented from being eccentric by the protrusion 423 and the settling groove 610 in the lower portion, the eccentricity is prevented by forming the insertion portion 412 and the receiving portion 340 in the upper portion of the filtration chamber 400 The chamber 400 is to be rotated without tilting.

The first filtration hole 411 of the exterior portion 410 is the waste water flows into the drainage pipe 310 through the first flow hole 431 of the joint 430 after being filtered by the filter medium 500 The waste water filtered by) is to be discharged, and when cleaning, foreign substances such as sludge caught in the filter medium 500 are discharged to the first filtration hole 411.

In addition, the second filtration hole 421 of the inner tube portion 420 passes through the first filtration hole 411 and the filter medium 500 so that the wastewater is filtered once again, so that the fastening flange of the fastening frame 460 is allowed. The wastewater filtered through the second flow hole 463 formed at 462 is to be discharged to the drain pipe 310.

The filter medium 500 is a cylindrical shape to form a hollow (not shown in the figure.), The inner tube portion 420 is embedded in the hollow, the filter medium 500 is not limited to the material, but an example of stainless The tangled shape of the strip may be presented, and thus, the filtration medium 500 may be formed in the tangled shape of the stainless strip, in order to filter foreign matter from the wastewater. Centrifugal force) and foreign matter deposited between the gaps of the filter medium 500 by the centrifugal force is easily discharged to the outside. In addition, to form a filter medium 500 by a stainless strip to prevent rust.

The support plate 600 is placed below the filtration chamber 400, and the support plate 600 is configured to be easily rotated when a rotation force is generated because the filtration chamber 400 is placed thereon. . To this end, an upper surface of the support plate 600 constitutes a settling groove 610, and a protrusion protrusion 423 formed in the filtration chamber 400 is inserted into the settling groove 610 so that the inside of the settling groove 610 is formed. The protrusion 423 is to be rotated.

Hereinafter will be described the operation of the filter column of the present invention with reference to 3a and 3b.

First, as shown in Figure 3a, the waste water is introduced through the first filtration hole 411 of the filtration chamber 400, the waste water is introduced through the filter medium 500, the foreign matter such as sludge is filtered and treated like this Waste water is introduced into the drainage chamber 300 through the first flow hole 431 formed in the joint 430, and the waste water introduced in this way is discharged to the outside through the drain pipe 310. In addition, the wastewater introduced through the first filtration hole 411 of the filtration chamber 400 passes through the filter medium 500 and is disposed in the inner tube part 420 of the filtration chamber 400 through the second filtration hole 421. The wastewater introduced in this way may be introduced into the drainage chamber 300 through the second flow hole 463 formed in the fastening frame 460, and the wastewater introduced in this way may be introduced into the drainage pipe 310. ) To be discharged to the outside.

Thus, when the wastewater is filtered using the filter column, foreign substances such as sludge are deposited on the filter medium 500, thereby lowering the filtration efficiency of the filter column. In this case, as shown in FIGS. 3B and 4, the control unit 40 is operated by automatic or manual operation to operate the suction pump 30 to suck down the waste water outside the filtration column and to the upper chamber through the inlet pipe 120. The wastewater is introduced into the wastewater 100, and the wastewater introduced in this way is discharged to the outside through the outlet pipe 130 while rotating the rotating plate 110. The rotational force is transmitted to each of the gears 240, 250, 270, and 280 in the gear chamber 200 by the rotating plate 110 in which the rotational force is generated, and the rotating plate 110 is based on the action of a large and small gear. The rotational force is doubled and the doubled rotational force is transmitted to the rotating rod 210 connected to the fourth gear 280. The rotational force of the rotating rod 210 is connected to the rotating rod 210 and the rotational force is transmitted to the filtration chamber 400 to rotate integrally, the rotational force of the filtration chamber 400 is the filter medium 500 inside the filtration chamber 400 ) By applying a centrifugal force to allow foreign substances such as sludge deposited in the gap of the filter medium 500 by this centrifugal force to be discharged to the outside through the first filtration hole 411 to clean the filter medium 500. When the rotational force is generated by the water pressure so that the cleaning of the filter medium 500 is finished, the filtration of wastewater as shown in FIG. 3a is operated again. That is, the action of the filter column in Figure 3b is to clean the filter medium 500, and the waste water is discharged to the outlet pipe 130 through the inlet pipe 120 and at the same time to clean the filter medium 500, the foreign matter such as sludge deposited. Will be able to perform a function.

In addition, in the present invention, as shown in Figure 4 when the waste water is forcibly suctioned through the filtration column to the outlet pipe 130, the waste water discharged through the outlet pipe 130 as another filtering means. By filtration, it is configured so that filtration of sewage and wastewater can be continued during cleaning.

The sludge treatment unit 20 is configured to communicate with the outlet pipe 130 as another filtering means. The sludge treatment unit 20 is placed in the casing 21 and the casing 21 as shown in FIG. 4. It consists of the filter barrel 22 which becomes.

The casing 21 allows the waste pipe introduced from the outlet pipe 130 through one side surface of the casing 21 to flow out into the filter barrel 22 placed in the casing 21, and the side surface thereof. By forming a side door in the casing 21 to allow the filter barrel 22 to be settled and separated, the upper surface is configured to the food waste and the like to open the upper door to discard the filter barrel 22. In addition, an opening protrusion is formed on the bottom surface of the casing 21 so that the one-way valve is opened while pushing the one-way valve of the filter barrel 22 when the filter barrel 22 is placed so as to communicate with the overflow pipe. .

In addition, the discharge pipe 23 on the lower surface of the casing 21 to communicate with the drain pipe 310 as shown in Figure 4 so that foreign matter such as sludge filtered by the filter barrel 22, wastewater discharge pipe 23 ) To fall into the drain pipe 310 and the flow of the waste water to the drain pipe 310 to eventually flow out to the storage tank (50). The casing 21 is preferably installed in a state exposed from the ground in order to allow the user to replace or clean the filter 22 or to directly throw food waste and the like. Therefore, it is reasonable to install the casing 21 to be used in parallel with the food waste collection box in a house.

Those skilled in the art will appreciate that various changes and modifications can be made without departing from the technical spirit of the present invention. Therefore, the technical scope of the present invention should not be limited to the contents described in the detailed description of the specification, but should be defined by the claims.

Explanation of symbols on the main parts of the drawings
100: upper chamber 200: gear chamber
300: drain chamber 400: filtration chamber
500: filter medium 600: support plate

Claims (5)

delete An upper chamber in which the inlet pipe and the outlet pipe communicate with each other, and a rotating plate having an impeller integrally formed therein is placed therein;
A drain chamber mounted to a lower portion of the upper chamber and having a rotary rod passing therein integrally with the rotary plate and having a drain pipe communicating with a side thereof;
A filtration chamber mounted to rotate integrally with the rotary rod in a lower portion of the drain chamber and having a plurality of flow holes formed therein;
A filter material placed inside the filtration chamber;
The filtration chamber is characterized in that consisting of a support plate,
Filtration column, characterized in that between the upper chamber and the drain chamber further comprises a gear chamber in which a plurality of gears of different diameters are mounted between the rotating plate and the rotating rod therein.
The method of claim 2,
A first connecting rod integrally interlocked with the rotating plate, a first gear integrally interlocked with the first connecting rod, a second gear meshing with the first gear and smaller in diameter than the first gear; A second connecting rod for fixing the second gear to rotate rotationally; a third gear having a diameter larger than that of the second gear and interlocking with the second connecting rod at a lower portion of the second gear; And a fourth gear having a diameter smaller than that of the third gear and integrally interlocked with the rotary rod.
The method of claim 2,
The filtration chamber is a filtration column, characterized in that consisting of the inner tube portion is formed with a plurality of filtration holes formed in the outer portion and a predetermined gap formed with a plurality of filtration holes.
The method of claim 4, wherein
Hemispherical protrusions are formed on the lower surface of the inner tube portion, and the filtration column is characterized in that the upper surface of the support plate is formed with a settled groove in which the protrusions are placed.

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