KR101753728B1 - Back wash filter system of 2 step filtering type - Google Patents

Abstract

The present invention relates to a double filtration type automatic backwash filter system, and its object is to minimize the clogging of a microfilter by a cyclone type and an automatic backwash function, thereby optimizing filtration efficiency, And to provide a double filtration type automatic backwash filter system that can be utilized in various industrial fields such as groundwater, surface water, seawater, process water, oil filtration process, seawater desalination and industrial RO and UF pre-treatment processes.
In the present invention, contaminants in the raw water that cause abrupt clogging of the microfilter in the microfilter filtration unit are firstly filtered by the cyclone filter filtration unit to generate the first treated water, and the first treated water is supplied to the microfilter filtration unit. And the target secondary processing water is generated. By the pressure difference between the microfilter filtration part and the filter backside detail according to the operation of the filter station details, the secondary processing water flows into the filter station detail through the microfilter filtration part, Backwashing is performed.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an automatic backwash filter system,

The present invention relates to a double filtration type automatic backwash filter system, in which contaminants in raw water are firstly filtered by cyclone filtration, and subsequently continuously filtered by a microfilter, To a double filtration type automatic backwash filter system capable of backwashing a microfilter.

In general, the fluid to be used in seawater, lake, ground water, surface water, river water, water, sewage, and various kinds of devices is divided into a sand filter type multi-layer filtration device, a separation membrane type filtration device, A filtration device, a microfilter type filtration device, and the like.

Although the sand filter type multi-layer filtration apparatus is widely used for filtration of ground water and surface water, since the multi-layer filtration apparatus is of a large size, the installation area of the facility is large and the filtration speed is limited, , Reduction in processing efficiency due to clogging of the filter media, and periodic replacement of the filter media.

Although the filtration apparatus of the separation membrane type has a high filtration efficiency and a high filtration rate, it is difficult to apply the filtration system to general application due to high initial installation cost and maintenance cost, and a fiber filtration type filtration apparatus has also been commercialized. However, like the separation membrane type filtration apparatus, So that there is a problem that maintenance burden is generated in operation.

The microfilter type filtration apparatus has been widely used for filtration of 50 μm or less in a fluid filtration process of fresh water, seawater, process water, oil, and the like.

However, the micro filter has a problem that the filter is suddenly clogged due to a sudden pollutant load in the raw water, and thus the filter function is deteriorated and the entire system is stopped due to the deterioration of the filter function have.

Particularly, in the case of microfilters used for ground water, surface water, fuel oil, and ballast water of ships, clogging due to the pollutant load in the fluid frequently occurs.

In addition, when a fluid is filtered for a long period of time in a microfilter type filtration apparatus, a phenomenon occurs in which a contaminant adheres to and accumulates on a filter wall of a microfilter, and resistance to fluid passing through the filter is increased , Which makes it difficult to filter the fluid.

In order to solve the problem of the above-mentioned micro filter, a method of installing a separate pretreatment facility in front of a micro filter has been used in the related art. However, when a separate pretreatment facility is installed, There is a problem that it is difficult to secure a space for installation, and the cost of installation of the pretreatment facility is increased.

In order to remove contaminants in the microfilter, a backwash device is installed to remove the contaminants adhering to the microfilter wall by passing the fluid through the filtration periodically and in the reverse direction. However, the clogging due to the sudden contaminant load It is not resolved.

Especially, in the case of ballast water treatment of vessels, it is frequent clogging in Micro Filter (40 ㎛) due to contamination in fluid in many water quality areas such as coast of China, west coast of Korea, and inland transportation line, The solution is not clear.

Published Patent Publication No. 10-2015-0055943 (May 05, 2015) Patent Registration No. 10-0380225 (2003.04.02)

It is an object of the present invention to minimize the clogging of the microfilter by the cyclone system and the automatic backwash function and to minimize the burden of operation and maintenance due to clogging while optimizing filtration efficiency and to prevent the groundwater, The present invention provides a double filtration type automatic backwash filter system that can be utilized in various industrial fields such as oil filtration, seawater desalination, industrial RO and UF pre-treatment.

In the present invention, contaminants in the raw water that cause abrupt clogging of the microfilter in the microfilter filtration unit are firstly filtered by the cyclone filter filtration unit to generate the first treated water, and the first treated water is supplied to the microfilter filtration unit. And the target secondary processing water is generated. By the pressure difference between the microfilter filtration part and the filter backside detail according to the operation of the filter station details, the secondary processing water flows into the filter station detail through the microfilter filtration part, Backwashing is performed.

In the present invention, the raw water is primarily filtered by a cyclone filtration method to remove contaminants in the raw water causing a sudden clogging of the microfilter, secondary filtration by a microfilter to achieve filtration at a target level, The micro filter for filtration can be automatically backwashed by the detailed and stationary water discharge portion, and the overall filtration efficiency can be increased.

In the present invention, raw water is firstly filtered by a cyclone filter unit, and then subjected to second filtration by a microfilter filtration unit, whereby particulate contaminants in raw water are effectively removed by double filtration.

In the present invention, since a large contaminant particle in the raw water is separated by a centrifugal force and stacked on the lower part of the cyclone housing, the filtration burden of the microfilter filtration part is reduced, thereby prolonging the life of the microfilter filtration part.

The present invention can be easily applied to filtration of various fluids such as fresh water, seawater, process water, oil, ship ballast water, etc., and is easy to manufacture and maintain.

1 is an illustration showing a configuration according to the present invention;
Figure 2 is another example showing the configuration according to the present invention.

1 and 2 illustrate an example of a configuration according to the present invention. In the present invention, a microfilter 21 in a microfilter filtration unit 20 is rapidly clogged by a cyclonic filter 10 The contaminants in the raw water that are generated are firstly filtered to generate the primary treatment water 51 and the primary treatment water 51 is supplied to the microfilter filtration unit 20 to be secondary filtered to obtain the target secondary treatment water 51 The secondary treatment water 52 is generated through the microfilter filtration unit 20 by the microfilter filtration unit according to the operation of the filter backside detail 30 and the pressure difference in the filter station detail, (30) and is backwashed with respect to the microfilter (21).

The present invention relates to a cyclone filter having a cyclone filter 10 having a raw water inlet 11 and a microfilter 21 having at least one microfilter 21, A filter reverse part 30 connected to the micro filter part 20 to automatically back-filter the micro filter and a reverse water discharge part 40 connected to the filter reverse part 30, The contaminants in the raw water 50 are firstly filtered by the cyclone filter 10 and supplied to the microfilter filtration unit 20 while the microfilter filtration unit 30 is operated, The microfilter 21 can be backwashed by the secondary treatment water filtered by the filter unit 20 so as to prevent clogging of the microfilter.

That is, according to the present invention, when the primary and secondary filtration of the raw water is performed by the cyclonic filter 10 and the microfilter 20, the micro filter 21 of the microfilter filtration unit is connected to one side The secondary treatment water 52 flows back into the microfilter 21 to be backwashed with respect to the microfilter 21 by the pressure difference.

The cyclone filter 10 filters the pollutants having a relatively large particle size in the raw water by causing the contaminants 70 in the raw water to be deposited under the cyclone housing by the centrifugal force, Prevent pollution loads.

The cyclonic filter 10 includes a cyclone housing 12, a raw water inlet 11 through which the cyclone housing is inserted to supply raw water into the cyclone housing, a cyclone housing 12 connected to the cyclone housing 12, (Not shown).

The cyclone housing 12 has a cylindrical housing body 14 and a hopper 15 integrally connected to the lower portion of the housing body 14 so that the hopper 15 The contaminants 70 can be easily stacked.

The raw water inlet 11 is connected to the microfilter filtration part 20 at an end thereof through the cyclone housing 12 so as to be positioned in a straight line with the treated water discharge port 22 and flows into the cyclone housing 12 One side 11a is opened so that the raw water 50 rotates along the inner wall 16 of the cyclone housing and a centrifugal force is generated in the cyclone housing 12. [

When the raw water 50 is supplied into the cyclone housing 12 through the cyclone filter 10 as described above, the raw water 50 is introduced into the inside 17 of the cyclone housing through the open side 11a of the raw water inlet, And the centrifugal force causes the contaminants 70 in the raw water 50 to be conveyed in the lower direction of the cyclone housing 12 to be stacked, The primary treated water 51, which is subjected to the primary filtration of the substance, is transferred into the microfilter filtration section 20.

The pollutant discharge unit 60 for discharging the pollutant 70 in the cyclone housing 12 to the outside is further installed in the cyclonic filter 10.

The pollutant discharging unit 60 has a function of discharging the pollutant 70 loaded in the cyclone housing 12 of the cyclonic filter filtering unit to the outside. The pollutant discharging unit 60 includes, for example, A suction pipe 61 penetrating the housing 12 and connected to the lower end of the cyclone housing 12 at its lower end and connected to a suction pump located outside the cyclone housing, Off valve 62 installed on the valve body 61.

The pollutant discharge unit 60 may further include a connection discharge line 63 connected to the reverse discharge water discharge line 41 of the reverse discharge water discharge unit 40. At this time, the connection discharge line 63 sucks the pollutant 70 in the cyclone housing 12 by the flow rate of the reverse water discharged through the reverse discharge water discharge line 41, Lt; / RTI >

The microfilter filtration unit 20 filters the primary treated water 51 filtered by the cyclone filter unit 10 to a target filtration level to generate secondary treatment water 52 do.

The microfilter filtration unit 20 includes a filter casing 23 disposed in the cyclone housing 12 and having a treated water outlet 22 at one side thereof and a filter casing 23 communicating with the interior 17 of the cyclone housing. And at least one micro filter (21) supported and installed in the housing (23).

The filter casing 23 is fixedly installed in the cyclone housing 12 such that the filter casing 23 is spaced apart from the inner wall 16 of the cyclone housing by a predetermined distance and the process water outlet 22 is formed on one side to penetrate the cyclone housing 12 A raw water inlet 11 is provided on the other side, and a lower portion is opened to communicate with the inside 17 of the cyclone housing.

The filter casing 23 is provided with a support plate 24 for supporting the microfilter 21. The support plate 24 is connected to the filter casing inner 27 and the cyclone housing inner 17 A plurality of inlets (25) are formed through.

The filter casing 23 is further provided with a reinforcing plate 23a at a portion to which the raw water inlet 11 is connected.

At least one of the micro filters 21 is installed so that the lower end of the micro filter 21 is opened in the longitudinal direction and supported by the filter casing 23. That is, the micro filter 21 is installed in the support plate 24 of the filter casing so that the lower end opening 26 communicates with the inlet 25 of the support plate so that the primary treatment water 51 in the cyclone housing flows into the interior of the cyclone housing. .

In the case of a microfilter of which the upper end is sealed, the lower end of the microfilter 21 is bolted and fixed to a support plate in the filter casing, The upper end may be hermetically sealed to the lid 18 of the cyclone housing and the lower end may be contactably supported on the support plate in the filter casing.

In addition, after the micro filter 21 has formed a predetermined insertion groove in the support plate of the filter casing, the lower end of the micro filter 21 is inserted into the insertion groove, and then the upper end of the micro filter 21 is closed by the lid 18 of the cyclone housing Can be installed. In addition, the microfilter 21 can be fixedly installed in the filter casing 23 by various known methods widely used in addition to the above-described methods.

The microfilter 21 may be composed of a basket type filter element 28 in which one is installed in the filter casing or a candle type filter element 29 in which a plurality of one or more filters are installed in parallel.

The microfilter filtration unit 20 configured as described above flows into the microfilter 21 through the lower end opening 26 of the primary treatment water 51 in the cyclone housing 12, The secondary treatment water 52 having a desired filtration level is generated by filtration and the generated secondary treatment water 52 is transported and discharged through the treated water discharge port 22.

The filter station details 30 are operated in a state in which the reverse water discharge valve 42 of the reverse discharge water discharge unit 40 is opened so that the secondary treatment water 52 is reversely introduced into the microfilter , And backwashing is performed on the microfilter.

The filter station details 30 may be provided with an upper rotatable filter station 31 or a lower rotatable filter station 32, depending on the type of micro-filter installed in the micro-filter unit.

1 is an illustration of a configuration according to the invention in which an upper rotating filter stationary detail 31 is installed and the upper rotating filter stationary detail 31 is shown when the basket type filter element 28 is installed with a microfilter 21 A reverse rotation drive unit 33 installed at the upper end of the cyclone housing 12 and a hollow central rotary shaft connected to the reverse rotation drive unit 33 and connected at the lower end to the support plate of the filter casing so as to be rotatable A backwash contact portion 35 provided in the filter inner wall 28a of the basket type filter element so as to be in tight contact with the filter inner wall 28a in the longitudinal direction and having a backwash space 35a therein, And a plurality of transfer lines 36 connected to the backwash contact portion 35 at the other end so as to communicate the central rotation shaft 34 and the backwash contact portion 35 with each other.

The back-pressure drive unit 33 may be a motor capable of continuous driving or step driving.

The central rotary shaft 34 has a hollow structure having a passage 34a therein so that the passage 34a communicates with the reverse discharge water discharge line 41 of the reverse discharge water discharge portion 40, 33 so as to rotate axially.

That is, the central rotation shaft 34 is axially coupled to the backwash drive unit 33 at its upper end and is supported on one side of the support plate 24 of the filter casing. And is connected to the backwash water discharge line (41) of the backwash water discharge portion (40). In this case, the reverse water wash 53 refers to the secondary water 52 flowing back into the filter and performing backwash.

The center rotary shaft 34 is inserted into the reversible water discharge line 41 so that the lower end thereof is rotatably inserted or the reversed water discharge line 41 is fixed to the support plate, 53 may be connected to the support plate 24 so as to be introduced thereinto.

The backwashing portion 35 is provided with a backwash space 35a which is open at one side toward the filter inner wall 28a and is installed such that one side thereof is in close contact with the filter inner wall 28a in the longitudinal direction.

In addition, it is preferable that the backwashing unit (35) is a slit type and a backwashing space (35a) is formed so that one side is opened.

In addition, it is preferable that the backwashing portion 35 is formed such that the backwashing space 35a has a trapezoidal cross-sectional shape so that the volume of the backwashing space increases from the upper side to the lower side.

When the backwashing space 35a has a trapezoidal cross-sectional shape as described above, the flow of the reverse osmosis water 53 smoothly flows over the entire backwashing space.

In other words, when the secondary treatment water 52 is admitted into the backwash space 35a by the operation of the filter backside detail 30 and the backwash water discharge unit 40 to perform the reverse osmosis water 53 function, The backwash water 53 flowing into the backwash water passage 35a flows downward due to gravity and the stagnation phenomenon of the reverse washwater 53 may occur under the backwashing space 35a due to the downward flow, , When the backwashing space 35a is formed in a reverse trapezoidal cross-sectional shape, reverse stagnation phenomenon does not occur under the backwashing space 35a.

A strip or an elastic contact strip 35b is further provided on one side of the backwash contact part 35 in close contact with the filter inner wall 28a to easily generate a pressure difference and to remove contaminants from the filter wall .

The transfer line 36 is provided so that the backwash space 35a in the backwashing contact portion and the flow path 34a in the central rotation axis are in communication with each other and one or more of the transfer backwashing line 35 is installed in the backwash contact portion 35 and the central rotation axis 34 And preferably, a plurality of transfer lines are installed with a predetermined interval therebetween.

In the upper rotary filter filter unit 31 configured as described above, the central rotary shaft 34 is rotationally driven by the driving of the backward driving unit 33, and the backward rotary unit 34, which is integrally connected by the central rotary shaft 34 and the transfer line 36, The contact portion 35 is rotated in the circumferential direction along the filter inner wall 28a together with the central rotary shaft 34. [

At this time, since the reverse water discharge valve 42 of the reverse water discharge portion 40 is in the open state, the pressure of the inside of the filter casing 27 in which the secondary treatment water 52 is located is lower than the pressure in the reverse water discharge portion 40 The secondary treatment water 52 flows back into the backwashing space 35a with respect to the filter inner wall 28a to which the backwash contact portion 35 of the filter backside is brought into contact, .

The backwash water 53 in the backwashing space 35a is transferred to the flow path 34a of the central rotary shaft through the transferring line 36 together with contaminants on the inner wall of the filter, So that it is transported and discharged to the outside.

FIG. 2 is a view showing a configuration according to the present invention in which a lower rotary filter reverse detail 31 is installed, and the lower rotary filter reverse detail 32 is applied when a candle type filter element 29 is installed with a microfilter A reverse drive unit 37 installed at the upper end of the cyclone housing 12 and a central drive shaft 38 connected to the reverse rotation drive unit 37 and connected to the lower end of the filter casing 24 through the support plate 24, And a rotation part 39 which is axially coupled to the lower end of the central drive shaft 38 and is rotated and communicated with the reverse water discharge part 40.

The backward driving unit 37 may be a motor capable of continuous driving or step driving.

The center drive shaft 38 is for transmitting the driving force of the backwash drive unit 37 to the rotation unit. The upper end of the center drive shaft 38 is axially coupled to the backwash drive unit 37, one side is supported by the filter casing 23, And the lower end thereof is connected to the rotation portion 39. [

The rotary part 39 has a hollow structure having a flow path through which the reverse water 53 flows and is rotated integrally with the central drive shaft 38 by driving the backwash drive part 37, A flow path through which the reverse water (53) flows is formed between the one-side filter element connected to the filter element and the reverse water discharge portion (40).

The rotation unit 39 includes a main pipe 39a axially connected to the central drive shaft 38 and connected to the water discharge unit 40, a branch pipe 39b branched from the main pipe 39a, And a sealing cap 39c integrally formed at an end of the branch pipe 39b to seal the inlet 25 formed in the support plate of the filter casing.

At this time, the main pipe 39a is installed such that the lower end of the main pipe 39a is rotatably inserted into the reverse water discharge line 41, or the reverse water discharge line 41 is fixed to one side of the filter casing, To the reverse discharge water discharge line 41 so that the reverse discharge water 53 flows into the stationary discharge water discharge line and the connection between the stationary discharge water discharge line and the main discharge pipe is made by a known technique , And a detailed description thereof will be omitted.

In addition, one or more branch pipes 39b provided with the sealing caps 39c may be installed on the main pipe 39a, preferably two symmetrical to each other.

The central drive shaft 38 is rotated by the backwash drive unit 37 and the main pipe 39a and the branch pipe 39b of the rotary unit are rotated by the center drive shaft 38. [ The sealing cap 39c is brought into close contact with one inlet port of the plurality of inlet ports 25 formed in the filter casing to perform filter cleaning between the inside of one filter element communicated with the inlet port and the reverse water discharge port 40 Thereby forming a backwashing flow path.

That is, since the reverse water discharge valve 42 of the reverse water discharge portion is open, the pressure inside the filter casing 27 where the secondary treatment water is located is higher than the force in the reverse water discharge portion, The one side filter element 29a to which the cap 39c is connected reversely inflows the secondary treatment water 52 into the filter and backwashes against the inner wall of the filter. The main pipe 39a and the main pipe 39a to be discharged to the outside.

The backwash water discharge unit 40 includes a backwash water discharge line 41 that is installed to be connected to the filter station detail through the cyclone housing and a reverse osmosis water discharge line 41 installed on the outside of the cyclone housing to be positioned on the backwash water discharge line 41. [ And a water discharge valve (42).

That is, when the filter station details 30 are made of the upper rotary filter, the reverse discharge water line 40 is connected to the reverse rotary water discharge line 41 so as to communicate with the channel 34a of the central rotary shaft, When the stationary detail 30 is made of the lower rotary filter inverse detail, the reverse discharge water discharge line 41 can be connected to the rotary part 39 so as to be connected.

The backwash discharge valve 42 is opened when backwashing is required, is closed during normal filtration operations, and is controlled automatically or manually.

In addition, the present invention is such that the connection part of the components is sealed, or an o-ring or the like is installed so as to maintain the watertightness so as not to affect the flow of fluid due to filtration and backwash. And the detailed description thereof will be omitted.

It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined in the appended claims and their equivalents. Of course, such modifications are within the scope of the claims.

(10): cyclone filter (11): raw water inlet
(12): Cyclone housing (13): Support
(14): housing body (15): hopper
(16): inner wall (17): inner wall of cyclone housing
(18): lid (20): micro filter section
(21): Micro filter (22): Process water outlet
(23): filter casing (24): support plate
(25): Inlet (26): Lower section
(27): inside the filter casing
(28): Basket type filter element
(29): Candle type filter element
(30): Filter station detail (31): Upper rotary filter station detail
(32): Lower Rotary Filter Reverse Details (33): Reverse Cycle Drive
(34): center rotation shaft (34a): channel
(35): backwash contact portion (35a): backwash space
(35b): strip or elastic contact strip (36): transfer line
(37): Reverse stroke drive unit (38): Central drive shaft
(39): rotating part (39a): main pipe
(39b): branch pipe (39c): sealing cap
(40): reverse water discharge unit (41): reverse water discharge line
(42): reverse water discharge valve (50): raw water
(51): primary treated water (52): secondary treated water
(53): reverse water wash (60): pollutant discharge unit
(61): suction pipe (62): opening / closing valve
(63): connection discharge line (70): pollutant

Claims (9)

A cyclone filter (10) having a raw water inlet (11); A microfilter filtration section 20 provided in the cyclone filter filtration section 10 and having a treated water discharge port 22 and having at least one microfilter 21; (30) connected to the microfilter filtration unit (20) and automatically backwashing the microfilter; A reverse water discharge unit 40 connected to the filter station 30; And a pollutant discharge unit 60 connected to the cyclonic filter 10 to discharge pollutants 70 in the cyclone housing 12 to the outside,
The pollutant discharge unit 60 includes a suction pipe 61 penetrating the cyclone housing 12 and connected to the lower end of the cyclone housing 12 and connected to a suction pump located outside the cyclone housing, Off valve 62 provided on the suction pipe 61 so as to be positioned outside the housing 12 and a connection discharge line 63 connected to the reverse discharge water discharge line 41 of the reverse discharge water discharge unit 40 ≪ / RTI >
The contaminants in the raw water 50 are firstly filtered by the cyclone filter 10 and supplied to the microfilter filtration unit 20 so that the microfilter filtration unit 20 The microfilter 21 is prevented from being clogged by the secondary treatment water filtered by the filtration treatment and the contaminant 70 in the cyclone housing 12 is removed by the reverse water flow rate And is discharged through a reverse discharge water discharge line (41).
The method of claim 1,
The cyclonic filter 10 includes a cyclone housing 12, a raw water inlet 11 through which the cyclone housing is installed to supply raw water into the cyclone housing, a cyclone housing 12 connected to the cyclone housing 12, (13) for supporting the support member
The microfilter filtration unit 20 includes a filter casing 23 disposed in the cyclone housing 12 and having a treated water discharge port 22 at one side and an end of a raw water inlet 11 at the other side, And one or more microfilters (21) supported and installed in the filter casing (23) to communicate with the interior (17) of the housing.
The method of claim 2,
The filter casing 23 is fixedly installed in the cyclone housing 12 so as to be spaced apart from the inner wall 16 of the cyclone housing by a predetermined distance and is opened to communicate with the inside 17 of the cyclone housing, Wherein a support plate (24) through which the micro filter (21) is inserted is installed inside the micro filter (21) to support the micro filter (21).
delete delete The method according to claim 1,
The filter stationary detail 30 comprises an upper rotary filter stationary detail 31 when the microfilter installed in the microfilter filtration unit is composed of a basket type filter element 28,
Characterized in that the filter stationary detail (30) comprises a lower rotary filter station detail (32) when the microfilter installed in the microfilter filtration unit comprises a candle type filter element (28) Backwash filter system.
The method of claim 6, further comprising:
The upper rotating filter stationary detail 31 includes a backwash driving unit 33 installed at the upper end of the cyclone housing 12 and connected to the backwash driving unit 33 so that the lower end thereof is rotatably connected to the supporting plate of the filter casing. A backward urging portion 35 provided in a longitudinally facing contact with the filter inner wall 28a of the basket type filter element and having a backwash space 35a therein, And a plurality of transfer lines 36 connected at one end to the rotating shaft 34 and connected at the other end to the backwash contact portion 35 to communicate the central rotation shaft 34 and the backwash contact portion 35 with each other. Automatic backwash filter system with double filtration system.
The method of claim 7,
Wherein the backwashing part (35) has an internal backwashing space (35a) formed in a trapezoidal cross-sectional shape so as to expand the volume of the backwashing space from the upper side to the lower side.
The method of claim 6, further comprising:
The lower rotating filter inverse detail 32 includes a backwash driving unit 37 installed at the upper end of the cyclone housing 12 and a lower rotating filter connected to the backwash driving unit 37 and having a lower end penetrating the supporting plate 24 of the filter casing And a rotation part 39 which is axially coupled to the lower end of the central drive shaft 38 and is rotated and communicated with the reverse discharge water discharge part 40,
The rotation unit 39 includes a main pipe 39a axially connected to the central drive shaft 38 and connected to the water discharge unit 40, a branch pipe 39b branched from the main pipe 39a, And a sealing cap (39c) integrally formed at an end of the branch pipe (39b) to seal the inlet (25) formed in the support plate of the filter casing.

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