KR102555149B1 - Direct filtration apparatus having cleaning function - Google Patents

Abstract

A direct filtering device according to the present invention includes a filtering tank having an inner space with an open upper side; A large amount of flotation media introduced into the inner space of the filtration tank; a stirring tank having an inner space with an open upper side and mounted on the lower side of the inner space of the filtration tank, the inner space being divided up and down by a plurality of partition walls formed with openings in the center; A raw water supply pipe for supplying raw water to the inside of the stirring tank; a stirring shaft erected vertically to pass through the center of the stirring tank upwardly, rotated by a driving motor and a speed reducer, and having stirring blades generating vortex in the inner space of the stirring tank; a washing shaft arranged in line with the agitation shaft and having a lower end connected to an upper end of the agitation shaft to be integrally rotatable with the agitation shaft; a plurality of washing bars extending horizontally from the washing shaft; a spraying shaft arranged in line with the washing shaft and having a lower end connected to an upper end of the washing shaft to be integrally rotatable with the washing shaft; It is configured to include; a plurality of wash water spray bars extending in the horizontal direction from the spray shaft and spraying the wash water downward.

Description

Direct filtration apparatus having cleaning function {Direct filtration apparatus having cleaning function}

The present invention relates to a coagulation-mixing reaction-integrated direct filtration device for total phosphorus removal, and more particularly, to a direct filtration device having a washing function for removing particulate matter adhering to the surface of a flotation filter medium.

Phosphorus (P) acts as a major cause of algae growth in river water systems, and it is estimated that water pollution of organic substances by algae accounts for 25 to 30% of the total organic substance pollutant load. Sewage and wastewater treatment facilities It is necessary to secure agricultural water, restore the ecosystem of urban rivers that have been dry by supplying water for river maintenance, and secure water in areas without access to water supply. In addition, the pollution level of total phosphorus (TP), which is the cause of the occurrence of algae, is continuously increasing, and the chemical oxygen demand (COD) concentration, which is an indicator of recalcitrant organic matter, is also increasing due to the decay of dead algae, resulting in repeated occurrence of algae. As a result, it is difficult to manage water quality in water sources. Accordingly, total phosphorus (TP), a major growth proposition factor for algae, and chemical oxygen demand (COD), a measurement item for non-degradable organic substances, are being strengthened.

In addition, most sewage treatment plants remove phosphorus through advanced biological treatment, but it is difficult to respond to the degree of treatment of total phosphorus (TP) due to severe changes in microbial activity according to seasonal changes. Therefore, stable total phosphorus (TP) treatment by biological treatment has limitations, so various approaches to strengthen chemical treatment of total phosphorus (TP) using chemical input facilities, coagulants and treatment methods used to treat low-concentration phosphorus are technically A review is required.

In conclusion, a better treatment effect can be seen by introducing a filtration facility, a physical treatment method, after removing total phosphorus (TP) using floc formation using a coagulant and a precipitation process (sedimentation battery). However, technical solutions have been required for the problem of diffusion of the coagulant during injection of the coagulant, the rapid mixing process, the long residence time of the floc formation process, the site problem of the facility, and the effect of effective floc formation on the filtration efficiency.

In order to solve this problem, a direct filtering device in which the coagulation and blending process and the filtration process are integrated into a bottom-up filtration tank within a single filter paper to minimize the site area and facilitate operation and maintenance by integrating the conventional chemical treatment process using a coagulant. has been proposed

Hereinafter, a conventional direct filtration device will be described in detail with reference to the accompanying drawings.

1 is a schematic diagram of a conventional direct filtration device.

As shown in FIG. 1, the conventional direct filtration device has a lower filter body 3a and an upper filter between the raw water inlet tank 1 into which raw water of urban sewage flows and the wastewater tank 5 into which wastewater after filtering flows. A single filter paper (3) composed of a filter body (3b) is arranged so that the coagulation-mixing (floc formation)-filtration process is performed within the single filter paper (3) at once. This single filter paper (3) has a filtration tank (7) composed of an aggregation layer with an agitator (4) installed therein at the bottom and a filtration layer filled with the flotation filter medium (6) therein, and the upper surface of the filtration tank (7). It includes a strainer 8 disposed on and an overflow tank 9 connected to the top of the filtration tank 7 above the strainer 8. The internal space of the agitator 4 is partitioned into three zones 32, 33, and 34 by partition walls 30 and 31, and inside the three zones 32, 33, and 34, stirring blades 4a, 4b, 4c) is provided.

Raw water from urban sewage flows into zone1 (32) through the raw water inlet pipe (10), and coagulant such as aluminum sulfate (Alum) or polyaluminum chloride (PAC) to remove total phosphorus is passed through the chemical inlet pipe (14) to zone1 (32). It flows into (32). As the raw water moves, the contaminant particles mixed with the coagulant grow into micro-floc in zone2 (33), grow into macro-floc in zone 3 (34), and then move to the filtration layer to float as a flotation medium ( 6) is attached to the surface and is removed.

At this time, if the particulate matter is attached to the flotation filter medium (6) at a certain level or more, the filtering function deteriorates, so the process of backwashing while blowing air into the agitator (4) using the blower (15) is periodically required will do However, there is a limit to removing particulate matter attached to the flotation filter medium 6 only by backwashing while blowing air, and the backwashing cycle must be short, and thus the filtering performance is degraded.

In addition, when the floc rises in a state where a large amount of flotation filter media 6 is floating inside the upper filter body 3b, the floc is concentrated on the flotation filter media 6 located at the lower side of the large amount of flotation filter media 6. However, in the case of backwashing in the same manner as in the prior art, there is also a problem that the washing efficiency of the floating filter medium 6 is reduced because the high pressure backwashing pressure is not transmitted to the floating filter medium 6 located at the lower side.

KR 10-1999229 B1

The present invention has been proposed to solve the above problems, and can effectively wash the flotation media without a separate backwash pump or blower, and intensively cleans the flotation media in a desired area among a large amount of flotation media or It is an object of the present invention to provide a direct filtering device capable of evenly washing the entire surface.

A direct filtering device according to the present invention for achieving the above object includes a filtering tank having an inner space with an upper side open; A large amount of flotation media introduced into the inner space of the filtration tank; a stirring tank having an inner space with an open upper side and mounted on the lower side of the inner space of the filtration tank, the inner space being divided up and down by a plurality of partition walls formed with openings in the center; A raw water supply pipe for supplying raw water to the inside of the stirring tank; a stirring shaft erected vertically to pass through the center of the stirring tank upwardly, rotated by a driving motor and a speed reducer, and having stirring blades generating vortex in the inner space of the stirring tank; a washing shaft arranged in line with the agitation shaft and having a lower end connected to an upper end of the agitation shaft to be integrally rotatable with the agitation shaft; a plurality of washing bars extending horizontally from the washing shaft; a spraying shaft arranged in line with the washing shaft and having a lower end connected to an upper end of the washing shaft to be integrally rotatable with the washing shaft; It is configured to include; a plurality of wash water spray bars extending in the horizontal direction from the spray shaft and spraying the wash water downward.

It is mounted to connect the upper end of the washing shaft and the lower end of the spreading shaft, and further includes a spreading shaft power transmission device for transmitting or blocking the rotational force of the washing shaft to the spreading shaft.

It is manufactured in a structure that allows raw water to pass but the floating filter medium does not pass, and further includes a lower mesh network and an upper mesh network coupled to cross the lower and upper sides of the inner space of the filter tank, respectively.

A drain pipe installed below the point where the lower mesh network is installed in the filter tank to discharge raw water in the filter tank, and when the floating filter medium descends according to the discharge of the raw water in the filter tank, the floating filter medium contacts the lower mesh net. It further includes a detection sensor for detecting whether or not.

It is manufactured in a structure that allows raw water to pass through but the floating filter medium does not pass through, and further includes a stirring mesh network covering the top of the stirring tank.

A washing shaft power transmission device mounted to connect an upper end of the agitating shaft and a lower end of the washing shaft to transmit or block rotational force of the agitating shaft to the washing shaft is further included.

It further includes a spiral blade coupled so as to spirally surround a spraying shaft located between the washing bar and the washing water spraying bar, and pushing the floating filter medium upward when rotating integrally with the spraying shaft.

The spiral blade is formed with a plurality of through-holes having a size through which the particulate matter attached to the flotation filter medium can pass but the flotation filter medium cannot pass through.

If the direct filtration device according to the present invention is used, particulate matter attached to the flotation media can be effectively removed without a separate backwashing pump or blower, and the flotation media in a desired area among a large amount of flotation media can be intensively washed. It has the advantage of being able to evenly wash the entire floating filter medium.

1 is a schematic diagram of a conventional direct filtration device.
2 is a schematic diagram of a direct filtration device having a washing function according to the present invention.
3 and 4 are use state diagrams of the direct filtration device having a washing function according to the present invention.
5 is a schematic diagram of a second embodiment of a direct filtering device having a washing function according to the present invention.
6 and 7 are use state diagrams of a third embodiment of the direct filtering device having a washing function according to the present invention.

Hereinafter, an embodiment of a direct filtering device having a washing function according to the present invention will be described in detail with reference to the accompanying drawings.

2 is a schematic diagram of a direct filtration device having a washing function according to the present invention, and FIGS. 3 and 4 are use state diagrams of the direct filtration device having a washing function according to the present invention.

The direct filtration device according to the present invention is a type of water treatment device for total phosphorus (TP) treatment of treated water, and is configured to perform mixing, floc formation, and filtration at once, but suspended solids or colloids attached to the surface of the flotation filter medium. The biggest feature is that it is composed of a structure that applies a physical force to the suspended matter so that particulate matter such as a material can be effectively removed.

First, as shown in FIG. 2, the direct filtration device according to the present invention includes a filtration tank 100 having an inner space with an open upper side, and a large amount of flotation media 6 introduced into the inner space of the filtration tank 100. And, a stirring tank 200 having an inner space with an upper side open and mounted on the lower side of the inner space of the filtration tank 100, the inner space being divided up and down by a plurality of partition walls 210 having an opening formed in the center thereof; The raw water supply pipe 250 for supplying raw water to the inside of the stirring tank 200 and the center of the stirring tank 200 are erected vertically to pass through the center of the stirring tank 200 in an upward direction to rotate by the drive motor 500 and the reducer 510 and a stirring shaft 220 having stirring blades 230 generating vortexes in the inner space of the stirring tank 200 as a basic component.

When a large amount of raw water is supplied through the raw water supply pipe 250 and the stirring tank 200 and the filtration tank 100 are filled with raw water, the large amount of floating filter media 6 floats upward, as shown in FIG. As such, it is in a state of floating on the upper side of the filtration tank 100.

At this time, a coagulant such as aluminum sulfate (Alum) or polyaluminum chloride (PAC) is supplied to the lower space of the stirring tank 200 through a chemical inlet pipe (not shown) to remove total phosphorus, and the stirring blades 230 stir While rotating integrally with the shaft 220, it mixes the contaminant particles and coagulant in the raw water. Accordingly, the contaminant particles in the raw water grow into microflocs, and the microflocs grow into macro-flocs while moving upward in the stirring tank 200, and then contact the floating filter medium 6. When it is attached to the floating filter (6). As mentioned above, in the process of the raw water overflowing the filtration tank 100 and being discharged through the overflow tank 600, various particulate materials such as suspended matter and colloidal matter are adsorbed to the flotation filter medium 6, and the overflow tank 600 ), only filtered water flows, and the process of mixing raw water, floc formation, and filtration at once is implemented in the same way in the conventional direct filtration device shown in FIG. 1, and detailed description thereof is omitted. do.

At this time, the direct filtering device according to the present invention is arranged in a row with the stirring shaft 220 so that the floating filter medium 6 can be washed without a separate backwashing device and blower, but the lower end is at the upper end of the stirring shaft 220 The biggest feature of the configuration is that it includes a washing shaft 310 that is connected and rotatable integrally with the stirring shaft 220, and a plurality of washing bars 300 extending in a horizontal direction from the washing shaft 310. there is.

Since the washing shaft 310 is also rotated when the agitating shaft 220 is rotated by the rotational force of the driving motor 500, the plurality of washing bars 300 rotate around the washing shaft 310 and float the media ( 6), and thus the particulate matter attached to the surface of the flotation filter medium 6 is separated from the flotation filter medium 6. As described above, in the direct filtration device according to the present invention, the washing bar 300 directly hits the floating filter medium 6 to remove particulate matter, and the particulate matter attached to the surface of the floating filter medium 6 is more effectively removed. It has the advantage of being removable.

In addition, in the case of washing the flotation filter medium 6 in the backwashing method as in the prior art, there is a problem that raw water supply must be stopped during the backwashing process, that is, raw water filtration must be stopped. However, in the direct filtration device according to the present invention, since the washing bar 300 continuously cleans the flotation material while the stirring shaft 220 rotates, it is necessary to stop filtration of raw water to wash the flotation filter medium 6. There are also advantages to not having it.

On the other hand, the direct filtering device according to the present invention is arranged in a line with the washing shaft 310 so as to increase the washing effect of the floating filter medium 6, and the lower end is connected to the upper end of the washing shaft 310, so that the washing shaft 310 and integrally rotatable spraying shaft 410, and a plurality of washing water spraying bars 400 extending horizontally from the spraying shaft 410 to spray washing water downward. It has a characteristic.

When the spraying shaft 410 and the washing water spraying bar 400 are provided as described above, raw water and foreign substances in the filtration tank 100 are discharged to the outside through the drain pipe 130, and as shown in FIG. 3, the floating filter medium 6 When the water level is lowered, the washing effect of the floating filter medium 6 can be further increased by spraying the washing water through the washing water spray bar 400 while rotating the spray shaft 410. At this time, the washing water sprayed through the washing water spray bar 400 is sprayed at a high pressure higher than the standard value to wash the surface of the floating filter medium 6, and the washing water spray pressure is determined by various conditions such as characteristics of the floating filter medium 6 and particulate matter. can be changed in various ways depending on

In addition, since the particulate matter rising through the stirring tank 200 is intensively attached to the surface of the floating filter medium 6 located on the lower side of the large amount of floating filter medium 6, as shown in FIG. 2, the washing bar ( 300) is preferably driven to hit the flotation media 6 located on the lower side. However, as the raw water filtration period increases, particulate matter may be attached to the flotation filter medium 6 located in the middle or the flotation filter medium 6 located on the upper side.

Therefore, the direct filtration device according to the present invention partially discharges the raw water in the agitation tank 200, and as shown in FIG. It may also be driven to strike and clean. In this way, when the washing bar 300 is rotated while the raw water in the filter tank 100 is gradually discharged, the washing bar 300 can strike and wash all floating filter media 6 floating in the filter tank 100. , It is possible to obtain the effect of washing all the flotation media (6).

On the other hand, as shown in FIG. 2, when the washing water spray bar 400 is configured to rotate while spraying washing water in a state where it is buried in the floating filter medium 6, the spray nozzle of the washing water spray bar 400 is the floating filter medium 6 ) and may be damaged. Therefore, as shown in FIGS. 3 and 4, the spray shaft 410 and the washing water spray bar 400 coupled thereto rotate only when the raw water in the filter tank 100 is discharged at a certain amount or more and separated from the floating filter medium 6. can be configured to That is, the direct filtering device according to the present invention is mounted to connect the upper end of the washing shaft 310 and the lower end of the spreading shaft 410 to transmit the rotational force of the washing shaft 310 to the spreading shaft 410. Alternatively, a spray shaft power transmission device 420 that blocks may be further included.

In this way, when the washing shaft 310 and the spraying shaft 410 are configured to be connected by the spraying shaft 410 power steering device, the user can use the washing water spraying bar 400 to float the filter media 6 as shown in FIG. In the buried state, the transmission of the rotational force of the washing shaft 310 is blocked so that the spraying shaft 410 does not rotate along the washing shaft 310, and the washing water spraying bar 400 as shown in FIGS. 3 and 4 ) is separated from the floating filter medium 6, the rotational force of the washing shaft 310 is transmitted to the spraying shaft 410 so that the spraying shaft 410 rotates and sprays the washing water.

At this time, the spreading shaft power transmission device 420 may be configured in any structure, such as a structure for connecting and blocking power transmission in a clutch method or a structure for connecting and blocking power transmission in a solenoid valve method. Since such a power transmission device is commercialized in various ways in the technical field to which the present invention pertains, a detailed description of the internal configuration and operating principle of the spreading shaft power transmission device 420 will be omitted.

On the other hand, when the upper side of the filtration tank 100 is completely open, a portion of the floating filter medium 6 may pass over the top of the filtration tank 100 along with the raw water when the amount of raw water supplied is large. In addition, if the floating filter medium 6 is configured to be able to descend until it touches the bottom of the filter tank 100, there is a risk that a part of the floating filter medium 6 is discharged to the outside through the drain pipe 130.

Therefore, the direct filtration device according to the present invention prevents the floating filter medium 6 in the filter tank 100 from flowing into the overflow tank 600 beyond the filter tank 100 or discharged through the drain pipe 130, so that the filter tank 100 ) The lower mesh network 110 and the upper mesh network 120 may be mounted on the lower and upper sides, respectively. The lower mesh network 110 and the upper mesh network 120 are made in the form of a net having eyes of a size that allows raw water to pass through but does not allow the floating filter medium 6 to pass through, so that the inner space of the filter tank 100 is horizontally installed so as to

Therefore, the raw water supplied into the filtration tank 100 may pass through the upper mesh network 120 and pass through the top of the filtration tank 100 or pass through the lower mesh network 110 and be discharged to the outside through the drain pipe 130. there is. However, since the floating filter medium 6 is caught in the lower mesh net 110 and the upper mesh net 120 and cannot be discharged to the outside of the filter tank 100, loss of the floating filter medium 6 can be prevented.

In addition, when the floating filter medium 6 is introduced into the stirring tank 200, a problem may occur in that the floating filter medium 6 is pulverized by the stirring blades 230 or the stirring blades 230 are damaged. Therefore, at the upper end of the stirring tank 200, a stirring mesh network 240 made of a structure that allows raw water to pass but does not pass the flotation filter medium 6 may be installed.

A drain pipe 130 is installed below the point where the lower mesh network 110 is installed in the filtration tank 100 to discharge raw water in the filtration tank 100 or foreign substances sunk to the bottom of the filtration tank 100. Therefore, when the raw water level in the filter tank 100 descends below the lower mesh net 110, the flotation filter medium 6 is seated on the lower mesh net 110 as shown in FIG. 4, and the washing bar 300 The flotation filter 6 located on the upper side is washed by hitting it.

In this way, in a state in which the floating filter medium 6 is seated on the lower mesh net 110, the floating filter medium 6 does not descend any more, so there is no need to discharge raw water any more. Therefore, the direct filtering device according to the present invention has a sensor (not shown) for detecting whether the floating filter medium 6 is in contact with the lower mesh network 110 so that it can be determined that the floating filter medium 6 has descended as much as possible. may further include. If the detection sensor is additionally provided in this way, since the end point of raw water discharge through the drain pipe 130 can be accurately determined, there is an advantage in that the time required for washing the floating filter medium 6 can be minimized.

5 is a schematic diagram of a second embodiment of a direct filtering device having a washing function according to the present invention.

The stirring blades 230 and the stirring shaft 220 for generating a vortex inside the stirring tank 200 must be continuously rotated while filtering the raw water, but the washing shaft 310 coupled with the washing bar 300 floats It is sufficient even if the filter medium 6 is rotated only when cleaning is required.

At this time, when the washing shaft 310 is fixedly coupled to the stirring shaft 220, while the stirring shaft 220 rotates, the washing shaft 310 and the washing bar 300 coupled thereto also continuously rotate, so that the floating filter medium 6 ) may be damaged by excessively hitting the washing bar 300.

In order to solve this problem, the direct filtering device according to the present invention is mounted to connect the upper end of the agitation shaft 220 and the lower end of the washing shaft 310 so that the rotational force of the agitation shaft 220 is applied to the washing shaft A washing shaft power transmission device 320 that transmits or blocks to 310 may be additionally provided.

When the washing shaft power transmission device 320 is provided as described above, the washing bar 300 does not rotate all the time but can be rotated only when the washing of the floating filter medium 6 is required, thereby preventing damage to the floating filter medium 6. There are advantages to being able to do it. In addition, since unnecessary rotation of the washing bar 300 can be prevented, power consumption of the driving motor 500 can be reduced.

At this time, since the function of the washing shaft power transmission device 320 is substantially the same as that of the spreading shaft power transmission device 420, a detailed description of the washing shaft power transmission device 320 will be omitted.

6 and 7 are use state diagrams of a third embodiment of the direct filtering device having a washing function according to the present invention.

2 to 4, when the washing bar 300 is rotated while lowering the raw water level so that the flotation filter medium 6 in the filter tank 100 is seated on the lower mesh net 110, the washing bar 300 ) can hit the floating filter medium 6 in all parts, so the entire floating filter medium 6 can be washed evenly.

However, when the raw water level is lowered until the floating filter medium 6 is seated on the lower mesh net 110, a problem arises in that it takes a lot of time to wash the entire floating filter medium 6. Another aspect of the configuration is that the direct filtering device according to the present invention is configured to evenly wash all the floating filter media 6 even without descending the floating filter media 6 in the filter tank 100 to the lower mesh net 110. It has a characteristic.

That is, in the direct filtering device having a washing function according to the present invention, the spiral blade 700 coupled to spirally surround the spraying shaft 410 located between the washing bar 300 and the washing water spraying bar 400 ) can be provided. The spiral blades 700 are inclined in a direction in which the floating filter medium 6 located at the lower side is pushed upward when rotated integrally with the spreading shaft 410.

Therefore, when the spiral blade 700 is rotated in the state shown in FIG. 6, as shown in FIG. 7, the flotation medium 6 located on the lower side and contacted with the washing bar 300 for a certain period of time and cleaned is completed with the spiral blade ( 700), and the upper flotation filter medium 6, which has not yet been cleaned, is pushed by the flotation filter medium 6 climbing up on the spiral blades 700 and descends through the space between the spiral blades 700 and the inner wall of the filter tank 100. to come into contact with the washing bar 300. That is, when the spiral blade 700 rotates, the floating filter medium 6 is reciprocally circulated up and down, so the entire floating filter medium 6 can be washed evenly even without adjusting the water level of the raw water in the filter tank 100. there is.

At this time, when the spiral blade 700 is installed in the inner space of the filter tank 100, the particulate matter washed down by the washing water spray bar 400 interferes with the spiral blade 700 and may not descend smoothly. Therefore, the direct filtering device according to the present invention is capable of passing particulate matter through the spiral blade 700 but not passing the floating filter medium 6 so that the spiral blade 700 does not interfere with the downward movement of the particulate matter. It is preferable that a plurality of through-holes 710 of the same size are formed. That is, the spiral blade 700 may be manufactured in a mesh structure as shown in this embodiment, or may be manufactured in a structure in which a plurality of through holes 710 are formed in a plate-shaped blade.

In this way, when the plurality of through holes 710 are formed in the spiral blade 700, it is possible to minimize the blocking of the downward flow of the particulate matter washed away by the washing water while pushing the floating filter medium 6 upward, (6) It has the advantage of increasing the washing efficiency.

In the above, the present invention has been described in detail using preferred embodiments, but the scope of the present invention is not limited to specific embodiments, and should be interpreted according to the appended claims. In addition, those skilled in the art should understand that many modifications and variations are possible without departing from the scope of the present invention.

6: flotation media 100: filtration tank
110: lower mesh network 120: upper mesh network
130: drain pipe 200: stirring tank
210: bulkhead 220: stirring shaft
230: stirring wing 240: stirring mesh network
250: raw water supply pipe 300: washing bar
310: washing shaft 320: washing shaft power transmission
400: Washing water spray bar 410: Spray shaft
420: spreading shaft power transmission device 500: drive motor
510: reducer 600: overflow tank
700: spiral blade 710: through hole

Claims (8)

A filter tank having an inner space with an open upper side;
A large amount of flotation media introduced into the inner space of the filtration tank;
a stirring tank having an inner space with an open upper side and mounted on the lower side of the inner space of the filtration tank, the inner space being divided up and down by a plurality of partition walls formed with openings in the center;
A raw water supply pipe for supplying raw water to the inside of the stirring tank;
a stirring shaft erected vertically to pass through the center of the stirring tank upwardly, rotated by a driving motor and a speed reducer, and having stirring blades generating vortex in the inner space of the stirring tank;
a washing shaft arranged in line with the agitation shaft and having a lower end connected to an upper end of the agitation shaft to be integrally rotatable with the agitation shaft;
a plurality of washing bars extending horizontally from the washing shaft;
a spraying shaft arranged in line with the washing shaft and having a lower end connected to an upper end of the washing shaft to be integrally rotatable with the washing shaft;
a plurality of wash water spray bars that extend horizontally from the spray shaft and spray wash water downward;
A lower mesh network and an upper mesh network made of a structure in which raw water can pass but the floating filter medium cannot pass, and are coupled to cross the lower and upper sides of the inner space of the filtration tank, respectively;
a drain pipe installed below the point where the lower mesh network is installed in the filter tank to discharge raw water from the filter tank;
a spiral blade coupled so as to spirally surround a spraying shaft located between the washing bar and the washing water spraying bar, and pushing the floating filter medium upward when rotating integrally with the spraying shaft;
Including,
In the spiral blade, a plurality of through holes having a size that allows particulate matter attached to the flotation filter medium to pass through but does not pass the flotation filter medium are formed,
The floating filter material is raised and lowered in floating height between the lower mesh network and the upper mesh network according to the water level of the raw water supplied into the filtration tank, and when the floating filter material is lowered according to the discharge of the raw water in the filter tank, the floating filter material moves to the lower side. Direct filtering device characterized in that it further comprises a detection sensor for detecting whether or not contact with the mesh network. The method of claim 1,
Direct filtering device further comprising a spreading shaft power transmission device mounted to connect the upper end of the washing shaft and the lower end of the spreading shaft to transmit or block the rotational force of the washing shaft to the spreading shaft. delete delete The method of claim 1,
Direct filtering device characterized in that it further comprises a stirring mesh network that is manufactured in a structure that allows raw water to pass but does not pass the floating filter medium and covers the top of the stirring tank. The method of claim 1,
The direct filtering device further comprising a washing shaft power transmission device mounted to connect the upper end of the agitating shaft and the lower end of the washing shaft to transmit or block the rotational force of the agitating shaft to the washing shaft. delete delete

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