KR101481075B1 - Continuous flow type apparatus for water treatment using submerged type membrane filtration and method for backwashing membrane thereof - Google Patents

Abstract

The present invention relates to a continuous flow and submerged type membrane apparatus, and a backwashing method thereof, wherein the continuous flow and submerged type membrane apparatus comprises a filtration supply unit, a submerged membrane filtration unit, a filtration discharge unit, a backwashing input unit, a backwashing output unit, and a flux control unit. The present invention provides a continuous flow and submerged type membrane apparatus, which backwashes some of filtered water filtered at a submerged type membrane filtration process to use the filtered water as backwashing water, and controls the flux of the introduced water and the filtered water, thereby providing effects of increasing a space efficiency as a treated water reservoir is not necessary in the membrane apparatus, and discharging the same flux of filtered water to the rear end process even when backwashing a partially submerged type membrane.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a submerged continuous membrane filtration apparatus and a backwashing method thereof,

The present invention relates to a submerged continuous flow membrane filtration apparatus and a backwashing method thereof, and more particularly, to a membrane filtration apparatus in which filtration water treated in a membrane filtration process without a separate treatment water reservoir for membrane backwashing and filtration water storage To a submerged continuous flow membrane filtration apparatus and a method of backwashing the submerged continuous flow membrane filtration apparatus.

In the membrane filtration process applied to the water treatment, the separation membrane is formed with voids on the surface thereof, thereby eliminating contaminants, thereby purifying the water. Depending on the characteristics of the water to be treated and the water quality requirements of the final treated water, May be applied alone or in combination with various kinds of treatment processes such as ozone treatment, activated carbon adsorption, reverse osmosis membrane filtration, etc., at the end of the membrane filtration step.

In the conventional method, when the membrane filtration process and the post-treatment process are combined, the filtration water produced from the membrane filtration process is collected in a storage tank, and a pump is installed to apply a driving force and a pressure for the supply flow to the post- Supply.

However, in this case, a separate treatment water storage tank for storing the filtered water passing through the separation membrane is required, and as the treatment capacity of the water treatment process is increased, the volume of the treatment water storage tank is increased to occupy a space, There is a problem that the driving pressure is lost in the treatment water storage tank, and additional driving equipment is required for driving the post-treatment process.

In addition, there is a problem in that contamination of the treated water storage tank occurs while the filtered water stays in the treated water storage tank, and the contamination of the membrane is intensified due to the contaminated stationary water during backwashing.

In the conventional membrane filtration process, the filtrate water side pressure is usually dependent on the supply side pressure and the inter-membrane pressure difference. That is, as the membrane filtration apparatus continues to operate, substances which can not pass through the separation membrane are accumulated on the surface of the separation membrane and the air gap, thereby acting as a resistance to the filtration process, and the transmembrane pressure continuously increases. There is a problem that the supply side pressure is increased in order to keep the flow rate of the filtered water produced in the membrane filtration apparatus constant.

Korean Patent No. 10-1235003 (Feb. 21, 2013)

SUMMARY OF THE INVENTION The present invention has been made in order to solve the above-mentioned problems of the prior art, and it is an object of the present invention to provide a membrane filtration apparatus which does not require a treated water storage tank, thereby improving space efficiency, And to provide a backwashing method therefor. BACKGROUND OF THE INVENTION

It is another object of the present invention to provide an immersion continuous flow membrane filtration apparatus and a backwashing method thereof, which can control the flow rate of influent water while controlling the flow rate of filtration water by pumping filtration water in an immersion membrane filtration unit.

It is another object of the present invention to provide an immersion continuous flow membrane filtration apparatus and a method of backwashing the same, which can supply reverse wastewater in various routes depending on whether pumping of reverse water is pumped.

It is another object of the present invention to provide an immersion continuous flow membrane filtration apparatus capable of selectively filtering filtered water by a pressure activated carbon filtration section and a pressure type ion exchange resin section, and a method of backwashing the same.

Another object of the present invention is to provide a submerged continuous flow membrane filtration apparatus and a method of backwashing the submerged membrane filtration apparatus capable of discharging filtered water at the same flow rate in a backward process even in the backwash of some submerged membrane filtration unit.

The present invention also provides an immersion continuous flow membrane filtration device capable of increasing the energy efficiency of the entire water treatment process by independently controlling the flow rate of the filtration water in the immersion membrane filtration process in accordance with the supply side pressure requirement of the downstream process, Another object of the present invention is to provide a backwashing method thereof.

According to an aspect of the present invention, there is provided a membrane filtration apparatus for separating and feeding supply water into a plurality of submerged separation membranes, comprising: a plurality of filtration supply units for supplying branched water to respective submerged separation membranes; A plurality of submerged membrane filtration units for filtering the feed water supplied by each of the filtration supply units by an immersion separation membrane; A plurality of filter discharge units for discharging filtered water treated in each of the submerged membrane filtration units; A backwash input unit connected to the downstream of the filtration discharge unit and backwashing a part of the filtered water to the submerged membrane filtration unit to backwash the submerged separation membrane; A backwash discharge unit connected to each of the submerged membrane filtration units to discharge the backwash water to the outside during backwashing of the submerged membrane filtration unit; And a flow rate controller for controlling the flow rate of the filtrate water discharged from each of the submerged membrane filtration sections downstream of the respective submerged membrane filtration sections and controlling the flow rate of the supply water flowing upstream of the respective submerged membrane filtration sections The filtration discharge unit includes a filtration discharge pump for pumping filtered water discharged from each of the submerged membrane filtration units and a first filtered water discharge valve provided downstream of the filtration discharge pump for opening and closing the filtered water, And a second filtered water discharge valve provided upstream of the filtration discharge pump for opening and closing the filtered water. The backwash input unit is branched between the filtration discharge pump and the first filtered water discharge valve to control the backflow of the filtered water A second reverse water supply valve, and a second reverse water supply branch which branches between the filtration discharge pump and the second filtrate discharge valve to control the reverse flow of the filtered water It characterized in that it comprises a probe.

The present invention also provides a membrane filtration apparatus for filtering supply water into a plurality of submerged separation membranes, comprising: a plurality of filtration supply units for supplying branching supply water to each submerged separation membrane; A plurality of submerged membrane filtration units for filtering the feed water supplied by each of the filtration supply units by an immersion separation membrane; A plurality of filter discharge units for discharging filtered water treated in each of the submerged membrane filtration units; A backwash input unit connected to the downstream of the filtration discharge unit and backwashing a part of the filtered water to the submerged membrane filtration unit to backwash the submerged separation membrane; A backwash discharge unit connected to each of the submerged membrane filtration units to discharge the backwash water to the outside during backwashing of the submerged membrane filtration unit; And a flow rate controller for controlling the flow rate of the filtrate water discharged from each of the submerged membrane filtration sections downstream of the respective submerged membrane filtration sections and controlling the flow rate of the supply water flowing upstream of the respective submerged membrane filtration sections The filtration discharge unit includes a filtration discharge pump for pumping filtered water discharged from each of the submerged membrane filtration units and a first filtered water discharge valve provided downstream of the filtration discharge pump for opening and closing the filtered water, And the backwash input unit includes a first reverse water supply valve branched downstream of the first filtered water discharge valve to control the reverse flow of the filtered water.

The present invention also provides a membrane filtration apparatus for filtering supply water into a plurality of submerged separation membranes, comprising: a plurality of filtration supply units for supplying branching supply water to each submerged separation membrane; A plurality of submerged membrane filtration units for filtering the feed water supplied by each of the filtration supply units by an immersion separation membrane; A plurality of filter discharge units for discharging filtered water treated in each of the submerged membrane filtration units; A backwash input unit connected to the downstream of the filtration discharge unit and backwashing a part of the filtered water to the submerged membrane filtration unit to backwash the submerged separation membrane; A backwash discharge unit connected to each of the submerged membrane filtration units to discharge the backwash water to the outside during backwashing of the submerged membrane filtration unit; And a flow rate controller for controlling the flow rate of the filtrate water discharged from each of the submerged membrane filtration sections downstream of the respective submerged membrane filtration sections and controlling the flow rate of the supply water flowing upstream of the respective submerged membrane filtration sections The filtration discharge unit includes a filtration discharge pump for pumping filtered water discharged from each of the submerged membrane filtration units and a first filtered water discharge valve provided downstream of the filtration discharge pump for opening and closing the filtered water, The backwash input unit includes a first reverse water wash water supply valve branched downstream of the first filtered water discharge valve to control the reverse flow of the filtered water, and a second reverse water wash water supply valve provided downstream of the first reverse water wash water supply valve, And a backwash water supply pump for circulating the water.

Further, the present invention provides a filtration apparatus for a filtration apparatus, comprising: a pressure activated carbon filter unit connected downstream of the filtration discharge unit to remove organic matter and residual chlorine contained in the filtrate; And a pressure type ion exchange resin part contacting downstream of the pressure activated carbon filter part to remove hardness components of calcium and magnesium contained in the filtered water; A bypass valve is installed upstream of the pressure activated carbon filtration section, between the pressure activated carbon filtration section and the pressure type ion exchange resin section, and downstream of the pressure type ion exchange resin section, .

The flow rate control unit of the present invention may further include a first flow rate measurement unit connected to the downstream of the submerged membrane filtration unit and measuring a flow rate of the filtration water discharged from each submerged membrane filtration unit; A second flow rate measuring means connected to the downstream of the filtration discharging portion to measure a flow rate of the total filtrate discharged from the entire submerged membrane filtration portion; A flow rate control signal of the filtrate water discharged from each of the submerged membrane filtration sections in accordance with the measurement results of the first flow rate measurement means and the second flow rate measurement means, connected to the first flow rate measurement means and the second flow rate measurement means, A flow rate control means for providing the flow rate control means; And flow rate regulating means connected to the filtration discharging portion and regulating a flow rate of filtrate discharged from each submerged membrane filtration portion on the basis of a flow rate control signal of the flow rate control means, And the other of the plurality of submerged membrane filtration units to backwash the submerged membrane filtration unit to keep the flow rate of the filtration water in the remaining submerged membrane filtration unit equal to the flow rate of the filtration water in the entire submerged membrane filtration unit, And the flow rate of the filtered water discharged from the knowledge membrane filtration unit is controlled.

Further, the present invention is a backwashing method of an immersion continuous flow membrane filtration apparatus for branching and filtering the feed water described above to a plurality of submerged membrane filtration units, wherein the submerged membrane filtration unit includes a plurality of submerged membrane filtration units Closing the filtration supply unit and the filtration discharge unit connected to the filtration unit; Opening the backwash input unit and backwash discharge unit connected to the filtration supply unit and a part of the submerged membrane filtration unit in which the filtration discharge unit is closed; A first flow rate control step of firstly controlling a flow rate of the feed water and the filtrate water by a flow rate control unit connected to the filtration discharge unit; Opening the chemical feed valve connected to the submerged membrane filtration part of the filtration supply part and the filtration discharge part, and activating the chemical pump; Closing the chemical supply valve and stopping the chemical pump after backwashing of the filtration supply unit and a part of the submerged membrane filtration unit in which the filtration discharge unit is closed; Closing the backwash input unit connected to the submerged membrane filtration unit and the backwash discharge unit; Opening the filtration supply portion and the filtrate discharge portion connected to the submerged membrane filtration portion; And a secondary flow rate control step of controlling the flow rate of the feed water and the filtrate water by a flow rate control unit connected to the filtration discharge unit.

The first flow rate control step of the present invention is characterized in that the flow rate of the filtrate of the remaining submerged membrane filtration part is partially regenerated during the backwashing of the submerged membrane filtration part of the plurality of submerged membrane filtration parts, The flow rate of the filtrate water discharged from the remaining submerged membrane filtration unit is measured so as to maintain the same flow rate and the flow rate of the feed water and the filtrate water of the remaining submerged membrane filtration unit is controlled.

As described above, according to the present invention, a part of the filtered water filtered in the submerged membrane filtration process is used as backwashed water and the flow rate of the influent water and the filtrate water is controlled, so that the treated water storage tank is unnecessary in the membrane filtration device, It is possible to increase the efficiency and to provide the effect of discharging the same filtrate flow rate in the back end process even when backing up some of the submerged membrane.

Further, by providing the filtration discharge pump and the filtration discharge valve as the filtration discharge portion, it is possible to control the flow rate of the influent water while controlling the flow rate of the filtration water by pumping the filtration water of the immersion membrane filtration portion.

In addition, as the backwash input unit, the first and second reverse water supply valves provided respectively in the downstream and upstream of the filtration discharge pump are provided, or the reverse water wash water supply pump is separately provided so that the reverse water wash .

In addition, by providing a bypass valve upstream and downstream of the pressure activated carbon filtration section and the pressure type ion exchange resin section, the filtered water can be selectively treated by the pressure activated carbon filtration section and the pressure type ion exchange resin section.

Also, by including the first to second flow rate measuring means, the flow rate control means, and the flow rate adjusting means as the flow rate control portion, it is possible to discharge the filtered water having the same flow rate to the downstream stage process even when backing up some of the submerged membrane filtration portion.

In addition, it is possible to control the flow rate of the filtered water in the submerged membrane filtration process independently and arbitrarily according to the supply side pressure requirement of the downstream process, by controlling the respective flow rates in the submerged membrane filtration process without using the pressure of the filtration water, Thereby providing an effect of increasing the energy efficiency of the entire water treatment process.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a block diagram showing a part of a submerged continuous flow membrane filtration apparatus according to an embodiment of the present invention; FIG.
BACKGROUND OF THE INVENTION 1. Field of the Invention [0001]
FIG. 3 is a schematic view showing a backwashing state of a submerged continuous flow membrane filtration apparatus according to an embodiment of the present invention; FIG.
4 is a configuration diagram showing a backwashing state of a modified example of the submerged continuous flow membrane filtration apparatus according to the embodiment of the present invention;
5 is a graph showing the driving pressure of a conventional membrane filtration device.
6 is a graph showing the driving pressure of the submerged continuous flow membrane filtration apparatus according to an embodiment of the present invention.
7 is a block diagram showing a filtration process of a submerged continuous flow membrane filtration apparatus according to an embodiment of the present invention;
FIG. 8 is a block diagram showing a backwash process of the submerged continuous flow membrane filtration apparatus according to an embodiment of the present invention; FIG.
9 is a graph showing a comparison between filtration flow rate and backwash flow rate in the submerged continuous flow membrane filtration apparatus according to an embodiment of the present invention.
10 is a view showing a filtration state of a submerged filtration membrane of a submerged continuous flow membrane filtration apparatus according to an embodiment of the present invention;
11 is a schematic view showing a backwashing state of a conventional submerged filtration membrane.
12 is a view showing a backwashing state of a submerged filtration membrane of a submerged continuous flow membrane filtration apparatus according to an embodiment of the present invention;
13 is a flow chart illustrating a backwashing method of a submerged continuous flow membrane filtration apparatus according to an embodiment of the present invention.

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

FIG. 1 is a configuration diagram showing a part of a submerged continuous flow membrane filtration apparatus according to an embodiment of the present invention, FIG. 2 is a view showing a submerged continuous flow membrane filtration apparatus according to an embodiment of the present invention, FIG. 3 is a configuration diagram showing a backwashing state of the submerged continuous flow membrane filtration apparatus according to an embodiment of the present invention, and FIG. 4 is a cross- Fig.

FIG. 5 is a graph showing a driving pressure of a conventional membrane filtration apparatus, FIG. 6 is a graph showing a driving pressure of a submerged continuous flow membrane filtration apparatus according to an embodiment of the present invention, and FIG. FIG. 8 is a block diagram showing a backwash process of the submerged continuous flow membrane filtration apparatus according to an embodiment of the present invention, and FIG. 9 is a block diagram showing the filtration process of the submerged continuous flow membrane filtration apparatus according to one embodiment of the present invention. FIG. 10 is a graph showing a comparison between filtration flow rate and backwash flow rate in the submerged continuous flow membrane filtration apparatus according to an embodiment of the present invention. FIG. 11 is a configuration diagram showing a backwashing state of a conventional submerged filtration membrane, and FIG. 12 is a view showing a submerged state of the submerged filtration membrane of the submerged filtration apparatus according to the embodiment of the present invention. FIG. 13 is a flowchart showing a backwashing method of the submerged continuous flow membrane filtration apparatus according to an embodiment of the present invention. FIG.

As shown in Figs. 1 and 2, the submerged continuous flow membrane filtration apparatus according to the present embodiment includes a filtration supply unit, a submerged membrane filtration unit, a filtration discharge unit, a backwash input unit, a backwash discharge unit, And separating the feed water into a plurality of submerged separation membranes and filtering them.

The filtration supply unit is provided as supply means provided respectively in the supply water distributing pipes 1A, 1B, 1C and 1D branched to supply the supply water to the immersion separation membranes of the respective submerged membrane filtration units, 11, 12, 13, 14).

The filtration supply valves 11, 12, 13, and 14 are respectively installed in the supply water distributing pipes 1A, 1B, 1C, and 1D for supplying the supply water to the respective submerged membrane filtration sections in the reservoir of the supply water , And the branched supply water is opened and closed, respectively, and supplied to the respective submerged membrane filtration sections.

The filtration supply valves 11, 12, 13 and 14 of the present embodiment are provided with a first filtration supply valve 11, a second filtration supply valve 12, a third filtration supply valve 13, a fourth filtration supply valve 14, but it is needless to say that it may be composed of two to three and more than five filter supply valves.

The submerged membrane filtration section is composed of a plurality of submerged membrane filters (31, 32, 33, 34) as filtration means for filtering the supply water supplied by each filtration supply section by an immersion separation membrane.

The submerged membrane filters 31, 32, 33 and 34 are installed in the inlet pipes downstream of the respective filtration feed valves 11, 12, 13 and 14, and the respective filtration feed valves 11, 12, 13 and 14 ) Is filtered by the submerged separation membrane to filter contaminants contained in the feed water, and the filtered water filtered by the contaminants is discharged downstream.

The submerged membrane filter 31, 32, 33 and 34 of the present embodiment includes a first submerged membrane filter 31, a second submerged membrane filter 32, a third submerged membrane filter 33, It is also possible to use two or three or more than five submerged membrane filtration units.

The filtration discharging portion is a discharging means for discharging the filtered water treated in each of the submerged membrane filtration portions and includes a plurality of filtration discharge pumps 61, 62, 63, 64 and a plurality of first filtered water discharge valves 111, 112, 113 And 114, and second filtered water discharge valves 121, 122, 123, and 124, respectively.

The filtration discharge pumps 61, 62, 63 and 64 are provided with filtration water discharge pipes 30A, 30B, 30C and 30D provided downstream of the submerged membrane filtration section for pumping out the filtration water treated in each submerged membrane filtration section, And the discharged filtered water is pumped and discharged from the submerged membrane filtration unit, respectively.

The filtration discharge pumps 61, 62, 63 and 64 of this embodiment are provided with a first filtration discharge pump 61, a second filtration discharge pump 62, a third filtration discharge pump 63, a fourth filtration discharge pump 64). However, it is also possible to use two or three or more than five filtration discharge pumps.

The first filtered water discharge valves 111, 112, 113 and 114 are connected to a filtered water discharge pipe 30A (hereinafter, referred to as " first filtered water discharge pipe ") provided downstream of each of the first and second filtered water discharge pumps for discharging filtered water, , 30B, 30C, and 30D, respectively. The filtered water thus discharged is opened and closed and discharged from the submerged membrane filtration unit.

The first filtrate discharge valves 111, 112, 113 and 114 of the present embodiment are provided with a first filtration discharge valve 111, a second filtration discharge valve 112, a third filtration discharge valve 113, The valve 114 is composed of four filtration discharge valves, but it goes without saying that it may be composed of two to three and more than five filtration discharge valves.

The second filtrate discharge valves 121, 122, 123 and 124 are respectively installed upstream of the respective filtration discharge pumps for discharging the filtrate water treated in the respective submerged membrane filtration sections by pumping the filtration discharge pumps. And the discharged filtered water is discharged from the submerged membrane filtration unit by opening and closing, respectively.

The second filtered water valve 122, the third filtered water valve 123, the fourth filtered water valve 124, and the second filtered water discharge valve 121, 122, 123, But it is needless to say that it may be composed of two to three or more than five filtrate valves.

The backwash input section is connected downstream of the filtration discharge section to return a part of the filtered water discharged from the plurality of submerged membrane filtration sections to the submerged membrane filtration section of the plurality of submerged membrane filtration sections to backwash the submerged separation membrane And a plurality of second reverse feedwater supply valves 131, 132, 133, and 134. The first reverse feedwater supply valves 91, 92, 93,

The first reverse water supply valve 91, 92, 93, 94 is connected to a filtration discharge pump (not shown) so as to return the filtrate water treated in each of the submerged membrane filtration sections to the submerged membrane filtration section of a plurality of submerged membrane filtration sections And a feeding means for branching between the first filtration discharge valve and controlling the backward flow of the filtrate water.

These first reverse water supply valves 91, 92, 93 and 94 are respectively installed in the filtered water discharge pipes 30A, 30B, 30C and 30D connected downstream of the respective submerged membrane filtration units, And are introduced into respective submerged membrane filtration sections.

The first reverse water supply valve 91, 92, 93, 94 of this embodiment is provided with the first backwash supply valve 91, the second backwash supply valve 92, the third backwash supply valve 93, And four backwash supply valves of the supply valve 94. It goes without saying that the backwash supply valves may be composed of two to three and five or more backwash supply valves.

The second reverse feedwater supply valves 131, 132, 133, and 134 are connected to a filtration drain pump and a second drainage pump so as to return the filtered water treated in each of the submerged membrane filtration sections to the submerged membrane filtration sections of the plurality of submerged membrane filtration sections. And is branched into the second filtration discharge valve to control the backflow of the filtered water.

These second countercleaning water supply valves 131, 132, 133 and 134 are respectively installed in the reverse septic water supply pipes 31A, 31B, 31C and 31D branching downstream of the respective filtration discharge units, Respectively, to be introduced into each submerged membrane filtration section.

The second reverse water supply valve 131, 132, 133, 134 of the present embodiment includes a first reverse water wash valve 131, a second reverse water wash valve 132, a third reverse water wash valve 133, But it is needless to say that it may be composed of two to three and more than five reverse water wash valves.

4, as a modification of the submerged continuous flow membrane filtration apparatus of the present invention, the filtration discharge unit includes a plurality of filtration discharge pumps 61, 62, 63, 64 and a plurality of first filtered water discharge valves 111 , 112, 113, and 114, and the backwash input unit may include only a plurality of first reverse water supply valves 91, 92, 93, and 94.

The first reverse water supply valves 91, 92, 93, and 94 of this modified example are provided so as to return the filtered water treated in each of the submerged membrane filtration units to the submerged membrane filtration units of a plurality of submerged membrane filtration units 1 downstream of the filtration discharge valve to control the backflow of the filtered water.

These first reverse water supply valves 91, 92, 93 and 94 are respectively installed in the reverse water wash water supply pipes 31A, 31B, 31C and 31D branching downstream of the respective filtration discharge portions, Respectively, to be introduced into each submerged membrane filtration section.

The first reverse water supply valve 91, 92, 93, 94 of this embodiment is provided with the first backwash supply valve 91, the second backwash supply valve 92, the third backwash supply valve 93, And four backwash supply valves of the supply valve 94. It goes without saying that the backwash supply valves may be composed of two to three and five or more backwash supply valves.

Therefore, the backwash input unit composed of only the plurality of first reverse osmosis water supply valves 91, 92, 93 and 94 completely stops the filtration discharge pumps of some series, and then only the adjustment of the first reverse osmosis water supply valve .

4, the filter discharge unit includes a plurality of filtration discharge pumps 61, 62, 63, 64 and a plurality of first filtered water discharge valves The backwash input unit includes a plurality of first reverse water supply valves 91, 92, 93 and 94 and a plurality of reverse water supply pumps 151, 152, 153 and 154 Of course it is possible.

The countercleaning water supply pumps 151, 152, 153, and 154 of the other modified example are arranged in such a manner that the circulating water treated by each of the submerged membrane filtration units is returned to the first submerged membrane filtration unit And is installed downstream of the reverse water wash water supply valve to control the input of the reverse water wash water.

These countercleaning water supply pumps 151, 152, 153 and 154 are respectively installed in the countercleaning water supply pipes 31A, 31B, 31C and 31D branched downstream of the respective filtrate discharging units, Respectively, to backwash each submerged membrane filtration section.

The reverse osmosis water supply pumps 151, 152, 153 and 154 of the present embodiment are provided with a first reverse osmosis water supply pump 151, a second reverse osmosis water supply pump 152, a third reverse osmosis water supply pump 153, And four reverse osmosis feed pumps of the reverse osmosis feed pump 154. However, it is needless to say that they may be composed of two to three and more than five reverse osmosis feed pumps.

Thus, the backwash input section composed of the plurality of first reverse osmosis water supply valves 91, 92, 93, 94 and the reverse osmosis water supply pumps 151, 152, 153, After the pump is stopped, the backwash water is pumped by the first reverse osmosis water supply valve and the reverse osmosis water supply pump to be introduced into each of the submerged membrane filtration sections.

The backwash discharge unit is connected to each of the submerged membrane filtration units and is discharge means for discharging backwash water discharged from the submerged membrane filtration unit in the backwashing of the submerged membrane filtration unit to the outside, 21, 22, 23, 24).

The backwash discharge valves 21, 22, 23 and 24 are connected to the backwash discharge pipes 2A, 2B, 2C, 2D connected to the respective submerged membrane filtration sections to discharge backwashed backwash water in each submerged membrane filtration section And the backwashed water thus discharged is opened and closed, respectively, and discharged from the submerged membrane filtration unit to the outside.

The backwash discharge valves 21, 22, 23 and 24 of the present embodiment are connected to the first backwash discharge valve 21, the second backwash discharge valve 22, the third backwash discharge valve 23, 24, but it is needless to say that it may be composed of two to three or more than five backwash discharge valves.

The flow rate control section is provided downstream of each submerged membrane filtration section and measures the flow rate of the filtration water discharged from each submerged membrane filtration section and controls the flow rate of the filtration water discharged downstream from each submerged membrane filtration section The flow rate control means includes a plurality of first flow rate measurement means 81, 82, 83 and 84, a second flow rate measurement means 600, a flow rate control means 610 and a plurality of flow rate control means 71, 72, 73, 74).

The first flow rate measuring means 81, 82, 83, 84 is a flow rate measuring means connected to the downstream of each submerged membrane filtration portion and measuring the flow rate of the filtration water discharged from the submerged membrane filtration portion.

The first flow rate measuring means 81, 82, 83 and 84 are connected downstream of the filtration discharge pumps 61, 62, 63 and 64 of the respective submerged membrane filtration sections and are connected to the filtration discharge pumps 61, 62, 30B, 30C, and 30D so as to measure the flow rate of the filtrate discharged from the filtrate discharge pipes 30A, 30B, 30C and 30D.

The first flow rate sensor 81, the second flow rate sensor 82, the third flow rate sensor 83, the fourth flow rate sensor 84, But it is needless to say that it is possible to use two to three and five or more flow sensors.

The second flow rate measuring means 600 is connected to the downstream of the filtration discharging portion and is a flow rate measuring means for measuring the total flow rate of the total filtrate discharged from the entire submerged membrane filtration portion, And a total amount flow sensor provided downstream of the merging pipe 30 in which the filtrate discharge pipes 30A, 30B, 30C and 30D are merged.

The flow rate control means 610 is connected to the first flow rate measurement means and the second flow rate measurement means 600 and is connected to the first flow rate measurement means and the second flow rate measurement means in accordance with the measurement results of the first flow rate measurement means and the second flow rate measurement means, And a flow rate control signal of the filtered water.

The flow rate control means 71, 72, 73 and 74 are connected to the filtration discharge pump of the filtration discharge portion to regulate the flow rate of the filtrate water discharged from each submerged membrane filtration portion on the basis of the flow rate control signal of the flow rate control means And a pump regulator for regulating the respective filtration discharge pumps 61, 62, 63 and 64 as flow regulators.

The flow rate regulating means 71, 72, 73 and 74 are connected to the respective filtration discharge pumps 61, 62, 63 and 64 provided in the respective filtration discharging portions to adjust the rotational speed of the pump, Thereby controlling the flow rate of the filtered water discharged from the membrane filtration unit.

The flow rate control means 71, 72, 73 and 74 of the present embodiment are provided with the first flow rate controller 71, the second flow rate controller 72, the third flow rate controller 73, the fourth flow rate controller 74, However, it is needless to say that it may be composed of two to three and more than five flow controllers.

Therefore, the flow rate control means controls the flow rate of the filtrate of the remaining submerged membrane filtration portion to be equal to the flow rate of the filtration water of the entire submerged membrane filtration portion during backwashing of the submerged membrane filtration portion, It is preferable to regulate the flow rate of the filtered water discharged from the part.

More specifically, as shown in Fig. 3, the flow rate adjusting means adjusts the flow rate of the filtered water in the remaining second to fourth submerged membrane filters (32, 33, 34) during backwashing of the first submerged membrane filter The flow rate of the filtered water discharged from the remaining second to fourth submerged membrane filter units 32, 33, and 34 is adjusted so as to maintain the same flow rate of the filtered water in the entire submerged membrane filtration unit.

The membrane filtration apparatus of the present embodiment further includes at least one of a pressure activated carbon filtration unit 900 and a pressure type ion exchange resin unit 910 connected downstream of the filtration discharge unit to remove foreign substances contained in the filtrate water Of course it is possible.

The activated carbon filtration unit 900 is connected to the downstream of the filtration discharge unit to remove organic matter and residual chlorine contained in the filtrate water. The activated carbon filtration unit 900 removes organic matter contained in the filtrate water and removes residual chlorine .

The pressure type ion exchange resin part 910 is a means for removing calcium and magnesium hardness components contained in the filtrate water by contacting the downstream side of the pressure activated carbon filter part 900. The pressure type ion exchange resin part 910 includes an ion exchange resin, Thereby removing hardness components of calcium and magnesium.

At the upstream side of the pressure activated carbon filter unit 900, between the pressure activated carbon filter unit 900 and the pressure type ion exchange resin unit 910 and downstream of the pressure type ion exchange resin unit 910, It is of course possible to provide pass valves 141, 142, 143, 144, and 145, respectively.

These bypass valves 141, 142, 143, 144 and 145 are connected to the first bypass valve 141, the second bypass valve 142, the third bypass valve 143, (144) and a fifth bypass valve (145).

The first bypass valve 141 is provided on the bypass pipe branched upstream of the pressure activated carbon filter unit 900 to control whether the filtered water is bypassed to the activated carbon filter unit 900.

The second bypass valve 142 is provided on the bypass pipe branched upstream of the pressure type ion exchange resin part 910 to control whether or not the filtered water is bypassed to the pressure type ion exchange resin part 910 .

The third bypass valve 143 is provided in a bypass pipe branched downstream of the pressure type ion exchange resin part 910 to control whether or not the filtered water is bypassed to the pressure type ion exchange resin part 910 .

The fourth bypass valve 144 is installed in a filtered water discharge pipe provided upstream of the pressure activated carbon filter unit 900 to control whether the filtered water flows into the activated carbon filter unit 900.

The fifth bypass valve 145 is installed in a filtered water discharge pipe provided upstream of the pressure type ion exchange resin part 910 to control whether the filtered water is introduced into the pressure type ion exchange resin part 910.

Therefore, the filtered water can be treated only by the pressure activated carbon filtration unit 900 or by only the pressure type ion exchange resin part 910 by operating the bypass valves 141, 142, 143, 144, and 145, The activated carbon filtration unit 900 and the pressure type ion exchange resin unit 910 can be treated together or bypassed without treatment of the pressure activated carbon filtration unit 900 and the pressure type ion exchange resin unit 910.

The membrane filtration apparatus of the present embodiment may further include a chemical injection unit connected between the submerged membrane filtration unit and the backwash input unit and injecting the chemical into the backwash water during backwashing of a part of the submerged membrane filtration unit Of course.

The medicament introducing portion is a medicament introducing means for introducing the medicines into the backwash water during the backwashing of the submerged membrane filtration portion and includes drug tanks 801 and 811, drug pumps 800 and 810, pump regulators 75 and 76, And drug supply valves (101, 102, 103, 104).

The chemical tanks 801 and 811 are provided with a first chemical tank 801 for storing two kinds of chemicals for reverse osmosis so as to improve the backwashing efficiency by inputting two kinds of chemicals for reverse osmosis into the backwash water, (811).

The chemical pumps 800 and 810 are provided downstream of the first chemical tank 801 and the second chemical tank 811 and are connected to the first chemical tank 801 and the second chemical tank 811, And a first medicine pump 800 and a second medicine pump 810 for pumping the medicine for reverse osmosis and inputting it to the reverse water washing water.

The pump regulators 75 and 76 are connected to the first medicine pump 800 and the second medicine pump 810 so that the first medicine pump 800 and the second medicine And a first pump regulator 75 and a second pump regulator 76 for adjusting the operation of the pump 810, respectively.

The medicine supply valves 101, 102, 103 and 104 are respectively installed in the medicine feed pipes 50A, 50B, 50C and 50D connected between the submerged membrane filtration part and the backwash input part, Supply control means for controlling the supply of the medicine.

The chemical supply valves 101, 102, 103 and 104 of the present embodiment are provided with a first chemical supply valve 101, a second chemical supply valve 102, a third chemical supply valve 103, 104, but it is needless to say that it may be composed of two to three or more than five drug supply valves.

Needless to say, the membrane filtration apparatus of the present embodiment may further include an air supply unit provided at a lower portion of the submerged membrane filtration unit to supply compressed air to clean the inside of the submerged membrane filtration unit.

The air supply unit is an air supply unit for supplying compressed air to each submerged membrane filtration unit to prevent the membrane contamination. The air supply unit is composed of a compressor 400 and a plurality of pressure control valves 41, 42, 43, and 44.

The compressor (400) is a supply source of compressed air for supplying compressed air. The compressor (400) compresses air by air compressing means such as a compressor to always supply compressed air to the supply pipe of the compressed air.

The pressure regulating valves 41, 42, 43, and 44 are pressure regulating means for regulating the supply pressure of the compressed air, which is installed in a supply pipe of compressed air connected between the compressor 400 and each submerged membrane filtration unit, Four pressure regulating valves, i.e., two pressure regulating valves 41, a second pressure regulating valve 42, a third pressure regulating valve 43 and a fourth pressure regulating valve 44, It goes without saying that the pressure regulating valve may be composed of five or more pressure regulating valves.

Therefore, as shown in the driving pressure graph of the conventional membrane filtration apparatus of FIG. 5, the immersion continuous flow membrane filtration apparatus of the present embodiment is provided with a separate feed pump for supplementing the loss of the driving pressure due to the filtration water storage tank As shown in the driving pressure graph of FIG. 6, the flow rate control by the flow rate control unit reduces the pressure loss and requires no separate rear-stage process transfer pump, so that the driving pressure of the filtered water can be directly fed to the driving pressure .

In addition, as shown in Figure 7, the filtering flow rate of the entire submerged membrane filter in the filtration of the entire immersion membrane filter is made of a total permeate flow rate (Q _t), filtered, flow rate of each submerged membrane filter (q _n ) is obtained by dividing the total filtration flow rate (Q _t ) by the number (n) of submerged membrane filters.

In addition, as shown in Figure 8, the filtration flow rate of the total in the backwash process of one membrane filter is made of a total permeate flow rate (Q _t) and the back washing flow rate (Q _b), for each of the remaining submerged membrane filter filtration flow rate (q _n ) is a value obtained by dividing the sum (Q _t + Q _b ) of the total filtration flow rate (Q _t ) and the backwash flow rate (Q _b ) by the number (n-1) have.

9, in the graph showing the backwash flow rate distribution ratio according to the number of series of the submerged membrane filtration device of the membrane filtration device, the backwash flow rate was set at (A value in Fig. 8) of the filtration flow rate q per series, and the membrane filtration apparatus is provided with two or more multi-system separation membranes so that the flow rate of the filtration water consumed in the backwashing can be additionally filtered. And a filter was installed.

That is, the ratio of the backwash flow rate to the total filtration flow rate of the membrane filtration device, that is, the backwash flow rate distribution ratio, is lower as the backwash flow rate multiplied by the filtration flow rate per sequence, This means that the filtration flow rate per unit area of the submerged membrane filtration device, that is, the permeation flux is low, permits stable long-term operation of the submerged membrane filtration device.

However, when the backwash flow rate is low, the performance of the submerged membrane deteriorates due to poor separation of the membrane contaminants during the backwash of the submerged membrane, and if the permeation flux is too low, a large number of membranes must be installed, which is uneconomical do.

9, according to the graph showing the distribution ratio of the backwash flow rate according to the number of series of the submerged membrane filter of the membrane filtration apparatus, the ratio of the backwash flow rate to the filtration flow rate per series with respect to the number of series of 4-10 membrane filter 40%. ≪ / RTI >

10 and 12 are diagrams showing the filtration state and backwashing state of the submerged filtration membrane of the submerged continuous flow membrane filtration apparatus according to the present embodiment. As shown in Fig. 10, in the filtration state, And the inflow water is filtered by the separation membrane. As shown in FIG. 12, in the backwashing state, the filtered water is formed as a downward flow to backwash the separation membrane.

FIG. 11 is a view showing a backwashing state of a conventional submerged filtration membrane, showing that secondary contamination generated in the storage tank after filtration can flow during backwashing and can not easily be recovered in the interior of the separation membrane.

Hereinafter, the backwashing method of the submerged continuous flow membrane filtration apparatus of the present embodiment will be described in detail with reference to FIG. 3 and FIG.

As shown in Figs. 3 and 13, the backwashing method of the submerged continuous flow membrane filtration apparatus of the present embodiment includes a step (S10) of closing a part of the filtration supply unit and the filtration discharge unit, A first flow rate control step S30 for firstly controlling the flow rates of the feed water and the filtrate water, a step S40 for opening some of the medicine supply valves and activating the medicine pump, Closing the supply valve and stopping the chemical pump (S50), closing some backwash input and backwash discharge units (S60), opening a portion of the filtration supply unit and the filtration discharge unit (S70) And a secondary flow rate control step (S80) for controlling the flow rate to a second order, wherein the feed water is branched into a plurality of submerged membrane filtration units to be filtered.

Particularly, the backwashing method of the submerged continuous flow membrane filtration apparatus of the present embodiment is characterized in that, in the filtration process of a plurality of submerged membrane filtration units having a plurality of filtration supply units and a filtration discharge unit, This is a concrete representation of the ongoing configuration.

The step S10 of closing the filtration supply part and the filtration discharge part is a step of closing the filtration supply part and the filtration discharge part connected to a part of the plurality of submerged membrane filtration parts and the first filtration supply valve 11 and the first The filtration discharge valve 111 is closed and the filtration process of the first submerged membrane filter 31 is stopped.

At this time, since the filtration supply portion and the filtrate discharge portion connected to the remaining immersion type filtration portion of the plurality of submerged membrane filtration portions are open, the second to fourth filtration supply valves (12, 13, 14) 4 filtration discharge valves 112, 113, 114 are opened, and the second through fourth submerged membrane filter units 32, 33, 34 proceed the filtration process.

The step S20 of opening the backwash input unit and the backwash discharge unit includes opening the backwash input unit and the backwash discharge unit connected to the filtration supply unit and a part of the submerged membrane filtration unit in which the filtration discharge unit is closed, The sewage valve 131, the first backwash supply valve 91 and the first backwash discharge valve 21 are opened to perform the backwashing process of the first immersion membrane filter 31.

At this time, since the backwash input section connected to the remaining immersion membrane filtration section of the plurality of submerged membrane filtration sections and the backwash discharge section are closed, the second to fourth reverse water storage valves 132, 133, The second to fourth backwash supply valves 92, 93 and 94 and the second to fourth backwash discharge valves 22, 23 and 24 are closed so that the second to fourth submerged membrane filters 32, 33, The process proceeds.

The first flow rate control step (S30) for firstly controlling the flow rate of the feed water and the filtrate water is a step of controlling the flow rate of the feed water and the filtrate water by the flow rate control unit connected to the filtrate discharge unit, The flow rate of the filtrate discharged from the remaining submerged membrane filtration section is measured so that the flow rate of the filtration water in the submerged membrane filtration section remains the same as the total flow rate of the filtration water in the entire submerged membrane filtration section, Thereby controlling the feed water of the membrane filtration unit and the flow rate of the filtrate.

The first flow rate control step S30 is a step of controlling the flow rate of the filtered water discharged from the remaining immersion membrane filtration section to the second to fourth flow rate sensors 82, 83, 84 and the second flow rate measurement means 600 And the flow rate control means 610 provides a control signal to control the flow rate of the filtrate water discharged from the remaining submerged membrane filtration portion.

Accordingly, the second to fourth pump rotation speed regulators 72, 73, and 74 adjust the second to fourth filtration discharge pumps 62, 63, and 64 by the control signal, The flow rate of the filtered water discharged from the filters 32, 33, and 34 is adjusted while the flow rate of the supplied water is adjusted.

In the first flow rate control step S30, the flow rate of backwash water supplied to a part of the submerged membrane filtration unit is measured by the first flow rate sensor 81, and the first pump rotation speed regulator 71 performs the first filtration It is also possible to control the discharge pump 61 to control the flow rate of backwash water supplied to the first submerged membrane filter 31.

The step S40 of opening the medicament supply valve and activating the medicament pump is a step of opening the medicament supply valve connected to a part of the plurality of submerged membrane filtration units and pumping the medicament supply valve into the medicinal water pump The first filtration discharge pump 61 provided between the first reverse water wash valve 131 and the first backwash supply valve 91 is operated to pump the reverse water wash water and the first medicine supply valve 101 is opened The second to fourth medicine supply valves 102, 103 and 104 are closed and the anticancer medicines stored in the medicine tanks 801 and 811 are put into the reverse water by the medicine pumps 800 and 801.

After completing backwashing, the step S50 of closing some of the medicine supply valves and stopping the medicine pump is performed by closing the first medicine supply valve 101 and stopping the medicine pumps 800 and 801 to the medicine tanks 801 and 811 And the input of the stored reverse medicine is blocked.

The step S60 of closing the backwash input part and the backwash discharge part closes the first backwash water valve 131 and the first backwash supply valve 91 and the first backwash discharge valve 21, The backwashing process of the membrane filter 31 is terminated.

The step S70 of opening the filtration supply part and the filtration discharge part is performed by opening the first filtration supply valve 11 and the first filtration discharge valve 111 and repeating the filtration process of the first impregnation separation membrane filter 31 again .

The second flow rate control step (S80) for controlling the flow rate of the feed water and the filtrate water is a step for controlling the flow rates of the feed water and the filtrate water by the flow rate control unit connected to the filtrate discharge unit, The flow rate of the filtrate discharged from the remaining submerged membrane filtration section is measured so that the flow rate of the filtration water in the filtration section is kept equal to the total flow rate of the filtration water in the entire submerged membrane filtration section, The flow rate of the fuel is controlled.

As described above, according to the present invention, a part of the filtered water filtered in the submerged membrane filtration process is used as backwash water and the flow rate of the influent water and the filtrate water is controlled so that the treated water storage tank is not required in the membrane filtration device, It is possible to increase the efficiency and to provide the effect of discharging the same filtrate flow rate in the back end process even when backing up some of the submerged membrane.

Further, by providing the filtration discharge pump and the filtration discharge valve as the filtration discharge portion, it is possible to control the flow rate of the influent water while controlling the flow rate of the filtration water by pumping the filtration water of the immersion membrane filtration portion.

In addition, as the backwash input unit, the first and second reverse water supply valves provided respectively in the downstream and upstream of the filtration discharge pump are provided, or the reverse water wash water supply pump is separately provided so that the reverse water wash .

In addition, by providing a bypass valve upstream and downstream of the pressure activated carbon filtration section and the pressure type ion exchange resin section, the filtered water can be selectively treated by the pressure activated carbon filtration section and the pressure type ion exchange resin section.

Also, by including the first to second flow rate measuring means, the flow rate control means, and the flow rate adjusting means as the flow rate control portion, it is possible to discharge the filtered water having the same flow rate to the downstream stage process even when backing up some of the submerged membrane filtration portion.

In addition, it is possible to control the flow rate of the filtered water in the submerged membrane filtration process independently and arbitrarily according to the supply side pressure requirement of the downstream process, by controlling the respective flow rates in the submerged membrane filtration process without using the pressure of the filtration water, Thereby providing an effect of increasing the energy efficiency of the entire water treatment process.

The present invention may be embodied in other specific forms without departing from the spirit or essential characteristics thereof. Therefore, the above embodiments are merely illustrative in all respects and should not be construed as limiting.

1A, 1B, 1C, 1D: Supply water distributor
2A, 2B, 2C, 2D: Backwater discharge pipe
30A, 30B, 30C and 30D:
31A, 31B, 31C and 31D:
50A, 50B, 50C, 50D: drug injection tube
11, 12, 13, 14: Filtration supply valve
21, 22, 23, 24: Backwash discharge valve
31, 32, 33, 34: immersion membrane filter
41, 42, 43, 44: pressure regulating valve
61, 62, 63, 64: Filtration discharge pump
71, 72, 73, 74: flow rate control means
75, 76: Pump regulator
81, 82, 83, 84: first flow measuring means
91, 92, 93, 94: the first reverse water supply valve
101, 102, 103, 104: chemical supply valve
111, 112, 113, 114: a first filtered water discharge valve
121, 122, 123, 124: the second filtered water discharge valve
131, 132, 133, 134: the second reverse water supply valve
141, 142, 143, 144, 145: Bypass valve
151, 152, 153, 154: Reverse osmosis water supply pump
400: Compressor
600: second flow measuring means
610: Flow control means
800, 810: Pharmaceutical pump
801, 811: chemical tank
900: pressure activated carbon filtration part
910: Pressure type ion exchange resin part

Claims (7)

1. A membrane filtration device for branching and filtering feed water into a plurality of submerged separation membranes,
A plurality of filtration supply units for supplying the branched supply water to each of the submerged separation membranes;
A plurality of submerged membrane filtration units for filtering the feed water supplied by each of the filtration supply units by an immersion separation membrane;
A plurality of filter discharge units for discharging filtered water treated in each of the submerged membrane filtration units;
A backwash input unit connected to the downstream of the filtration discharge unit and backwashing a part of the filtered water to the submerged membrane filtration unit to backwash the submerged separation membrane;
A backwash discharge unit connected to each of the submerged membrane filtration units to discharge the backwash water to the outside during backwashing of the submerged membrane filtration unit; And
And a flow rate control unit which is installed downstream of each of the submerged membrane filtration units to measure the flow rate of the filtration water discharged from each of the submerged membrane filtration units and controls the flow rate of the supply water flowing upstream of each of the submerged membrane filtration units And a control unit,
The filtration and discharge unit includes a filtration discharge pump for pumping filtered water discharged from each of the submerged membrane filtration units, a first filtered water discharge valve installed downstream of the filtration discharge pump for opening and closing the filtered water, And a second filtered water discharge valve which is installed upstream and opens and closes the filtered water,
The backwash input unit includes a first reverse water supply valve branched between the filtration discharge pump and the first filtration water discharge valve to control the backflow of the filtration water and a second reverse water supply valve branched between the filtration discharge pump and the second filtration water discharge valve, And a second reverse osmosis supply valve for controlling the backflow of the first reverse osmosis water. delete delete The method according to claim 1,
A pressure activated carbon filter connected downstream of the filtration discharge unit to remove organic matter and residual chlorine contained in the filtrate; And a pressure type ion exchange resin part contacting downstream of the pressure activated carbon filter part to remove hardness components of calcium and magnesium contained in the filtered water; Wherein the at least one continuous flow-through membrane filtration apparatus further comprises at least one of: The method according to claim 1,
Wherein the flow rate controller comprises:
First flow measurement means connected to the downstream of the submerged membrane filtration unit and measuring a flow rate of the filtration water discharged from each submerged membrane filtration unit;
A second flow rate measuring means connected to the downstream of the filtration discharging portion to measure a flow rate of the total filtrate discharged from the entire submerged membrane filtration portion;
A flow rate control signal of the filtrate water discharged from each of the submerged membrane filtration sections in accordance with the measurement results of the first flow rate measurement means and the second flow rate measurement means, connected to the first flow rate measurement means and the second flow rate measurement means, A flow rate control means for providing the flow rate control means; And
And flow rate control means connected to the filtration discharge portion and controlling the flow rate of the filtrate water discharged from each submerged membrane filtration portion on the basis of the flow rate control signal of the flow rate control means,
Wherein the flow rate control means controls the flow rate of the filtrate of the remaining submerged membrane filtration portion to be equal to the flow rate of the filtrate of the entire submerged membrane filtration portion during backwashing of the submerged membrane filtration portion of the plurality of submerged membrane filtration portions Wherein the flow rate of the filtrate discharged from the remaining submerged membrane filtration unit is regulated so that the flow rate of the filtration water discharged from the remaining submerged membrane filtration unit is adjusted. A backwashing method of an immersion continuous flow membrane filtration apparatus for branching and filtering the feed water according to claim 1 into a plurality of submerged membrane filtration units,
Closing the filtration supply portion and the filtrate discharge portion connected to the submerged membrane filtration portion of the plurality of submerged membrane filtration portions;
Opening the backwash input unit and backwash discharge unit connected to the filtration supply unit and a part of the submerged membrane filtration unit in which the filtration discharge unit is closed;
A first flow rate control step of firstly controlling a flow rate of the feed water and the filtrate water by a flow rate control unit connected to the filtration discharge unit;
Closing the backwash input unit connected to the submerged membrane filtration unit and the backwash discharge unit;
Opening the filtration supply portion and the filtrate discharge portion connected to the submerged membrane filtration portion; And
And a second flow rate control step of controlling a flow rate of the feed water and the filtrate water by a flow rate control unit connected to the filtrate discharge unit. The method according to claim 6,
Wherein the first flow rate control step includes the step of controlling the flow rate of the filtrate of the remaining submerged membrane filtration section during backwashing of the submerged membrane filtration section of the plurality of submerged membrane filtration sections to the same flow rate of the filtration water of the entire submerged membrane filtration section And the flow rate of filtrate discharged from the remaining submerged membrane filtration unit is measured to control the flow rate of the feed water and the filtrate water in the remaining submerged membrane filtration unit Cleaning method.

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