KR20190055428A - Membrane filtration system and controlling method thereof - Google Patents

Abstract

The present invention relates to a membrane filtration system, which comprises: a filtration tank including a filtration membrane and a mixed liquor suspended solid (MLSS) densitometer for measuring an MLSS concentration of inflow water; an aeration unit including an aeration pipe positioned at a lower portion of the filtration membrane, a blower for injecting air into the aeration pipe through an air injection pipe, and an insertion type electron flow rate (PIT) pressure gauge for measuring a discharge pressure of the blower; a sludge discharge pipe for communicating with the filtration tank and discharging sludge; a trans-membrane pressure (TMP) measuring unit for measuring a trans-membrane pressure of the filtration membrane; and a control unit for controlling a membrane filtration process by receiving information on the MLSS concentration, the TMP, and a blower pressure (BP) from the MLSS densitometer, the TMP measuring unit and the insertion type electron flow rate (PIT) pressure gauge.

Description

[0001] MEMBRANE FILTRATION SYSTEM AND CONTROLLING METHOD THEREOF [0002]

The present invention relates to a membrane filtration system and a membrane filtration control method.

With the development of the industry and population growth, interest in efficient water use and treatment technologies is increasing. In recent years, membrane technology has been increasingly applied to ensure water quality stability in water treatment, under-wastewater treatment, and seawater desalination.

Membrane technology is undergoing physical and chemical treatment to control the contamination of the membrane, and physical devices are used to produce the acid gas.

However, even if the causes of the degradation of the efficiency of the air-conditioning system are varied, it is impossible to accurately determine the cause of the deterioration of the air-conditioning efficiency, so that appropriate measures are not taken or wasted time and money due to wrong actions.

Therefore, there is a need for a membrane filtration system and a membrane filtration control method capable of precisely grasping the cause of the degradation of the acid period efficiency and performing appropriate measures accordingly.

Prior art related to this is disclosed in Korean Patent Publication No. 10-2001-0028598.

It is an object of the present invention to provide a membrane filtration system and a membrane filtration control method capable of improving the water treatment efficiency and the life of the membrane filtration apparatus by appropriate measures depending on the causes of degradation of the acid period efficiency.

It is another object of the present invention to provide a membrane filtration system and a membrane filtration control method which can accurately determine the cause of degradation of the acid value.

The above and other objects of the present invention can be achieved by the present invention described below.

One aspect of the present invention relates to a membrane filtration system.

According to one embodiment, the membrane filtration system includes a filtration tank having a filtration membrane therein and equipped with a mixed solution suspended solids (MLSS) concentration meter for measuring the MLSS concentration of the influent water; An acid part including an air diffuser positioned below the filtration membrane, a blower for injecting air into the air diffuser through an air inlet tube, and an insertion type electromagnetic flow rate (PIT) pressure gauge for measuring a discharge pressure (BP) of the blower; A sludge discharge pipe communicating with the filtration tank and discharging sludge; An inter-membrane pressure difference (TMP) measuring unit for measuring an inter-membrane pressure difference of the filtration membrane; (TMP) and the blower discharge pressure (BP) from the mixing liquid suspension solid solu- tion (MLSS) densitometer, the inter-membrane pressure difference (TMP) measuring unit and the insertion type electronic flow rate (PIT) And a controller.

In one embodiment, the control unit can maintain the operating state when the MLSS concentration and the inter-membrane pressure difference (TMP) satisfy the following equation (1).

[Formula 1]

(TMP × MLSS) / (TMP ₀ × MLSS ₀ ) ≦ 1.5

(TMP ₀ and MLSS ₀ in the above equation (1) are the intermembrane pressure difference and the MLSS concentration in the normal operation state, respectively, and TMP and MLSS are the intermembrane pressure difference and the MLSS concentration at the time of measurement, respectively).

In other embodiments, the control unit MLSS concentration and transmembrane pressure difference (TMP) when the following equation 2 increase the satisfaction and blower discharge pressure (BP) is a blower discharge pressure of the steady state more than 10% (BP ₀₎ aeration flushing Can be performed.

[Formula 2]

(TMP × MLSS) / (TMP ₀ × MLSS ₀ )> 1.5

(Where TMP ₀ and MLSS ₀ are the intermembrane pressure difference and MLSS concentration in the normal operation state, respectively, and TMP and MLSS are the inter-membrane pressure difference and the MLSS concentration at the time of measurement, respectively).

In yet another embodiment, the control unit MLSS concentration and transmembrane pressure difference (TMP) is the following formula 2, the satisfactory, and blower discharge pressure (BP) is a blower discharge pressure of the steady state (BP ₀₎ compared to an increase of less than 10% to 5% The discharge flow rate of the blower can be increased from 1.1 times to 1.5 times.

[Formula 2]

(TMP × MLSS) / (TMP ₀ × MLSS ₀ )> 1.5

(Where TMP ₀ and MLSS ₀ are the intermembrane pressure difference and MLSS concentration in the normal operation state, respectively, and TMP and MLSS are the inter-membrane pressure difference and the MLSS concentration at the time of measurement, respectively).

The membrane filtration system maintains the blower discharge flow rate until the blower discharge pressure (BP ₀ ) becomes a steady state when the discharge pressure (BP) of the blower decreases with time after increasing the discharge flow rate of the blower , The sludge can be discharged through the sludge discharge pipe if the discharge pressure BP of the blower does not change or increases with the lapse of time.

The filtration tank may further include a viscometer for measuring the viscosity of the influent water.

Another aspect of the present invention relates to a membrane filtration control method.

According to one embodiment, the membrane filtration control method sets the steady-state transmembrane pressure differential (TMP ₀ ), the MLSS concentration (MLSS ₀ ) and the blower discharge pressure (BP ₀ ) to a predetermined time between 10 seconds and 1 minute (TMP) and the MLSS concentration (MLSS) are measured at intervals of the inter-membrane pressure difference (TMP) and the MLSS concentration (MLSS) When the concentration MLSS satisfies the following formula 2, the blower discharge pressure BP is measured. When the blower discharge pressure BP is increased by 10% or more with respect to the normal blower discharge pressure BP ₀ , And when the inter-film pressure difference TMP and the MLSS concentration MLSS satisfy the following formula 2 and the blower discharge pressure BP is 5% or more and less than 10% of the normal state blower discharge pressure BP ₀ , Is increased from 1.1 times to 1.5 times, and then the blower discharge pressure (BP) The controller controls the sludge residence time (SRT) when the blower discharge pressure (BP) does not change or increases with time, while the discharge flow rate of the blower is maintained until the blower discharge pressure (BP ₀ ) Or the sludge can be discharged through the sludge discharge pipe.

[Formula 1]

(TMP × MLSS) / (TMP ₀ × MLSS ₀ ) ≦ 1.5

[Formula 2]

(TMP × MLSS) / (TMP ₀ × MLSS ₀ )> 1.5

(TMP ₀ and MLSS ₀ in the equations (1) and (2) are the intermembrane pressure difference and the MLSS concentration in the normal operation state, respectively.

The present invention has the effect of providing a membrane filtration system and a membrane filtration control method capable of accurately determining the cause of degradation of the acid period efficiency and improving the water treatment efficiency and the life of the membrane filtration apparatus by appropriate measures according to the cause.

1 schematically shows a membrane filtration system according to one embodiment of the present invention.
2 schematically shows a flow chart of a membrane filtration control method according to one embodiment of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Reference will now be made in detail to embodiments of the present application, examples of which are illustrated in the accompanying drawings. However, the techniques disclosed in this application are not limited to the embodiments described herein but may be embodied in other forms.

Rather, these embodiments are provided so that this disclosure will be thorough and complete, and will fully convey the concept of this invention to those skilled in the art. In the drawings, the width, thickness, and the like of the components are enlarged in order to clearly illustrate the components of each device. Also, while only a portion of the components is shown for convenience of explanation, those skilled in the art will readily recognize the remaining portions of the components.

When an element is described at the point of view of the general description of the drawings and an element is referred to as being located above or below another element, it is to be understood that the element may be located immediately above or below another element, Quot; can be intervened. Those skilled in the art will appreciate that various modifications, additions and substitutions are possible, without departing from the scope and spirit of the invention as disclosed in the accompanying claims. In the drawings, the same reference numerals denote substantially the same elements.

It should be understood, however, that the singular forms "a", "an", and "the" include plural referents unless the context clearly dictates otherwise, and the terms "comprise" Acts, components, parts, or combinations thereof, but does not preclude the presence or addition of one or more other features, numbers, steps, operations, components, parts, or combinations thereof It should be understood that it does not.

In the present specification, 'X to Y' representing the range means 'X or more and Y or less'.

In this specification, BP is the blower pressure of the blower, TMP is the trans-membrane pressure, MLSS is the mixed liquor suspended solid, PIT is the insertion type electromagnetic flowmeter, SRT is the sludge ) May be a solid retention time.

Membrane filtration  system

A membrane filtration system according to one aspect of the present invention will be described with reference to Fig. 1 schematically shows a membrane filtration system according to one embodiment of the present invention.

1, a membrane filtration system according to an embodiment of the present invention includes a filtration membrane 110 having a filtration membrane 110 therein, a filtration tank (not shown) provided with a mixed solution suspended solids (MLSS) concentration meter 520 for measuring the MLSS concentration of influent water 100); A blower 230 for injecting air into the air diffusing pipe 210 through an air diffuser 210 and an air injection pipe 250 positioned below the filtration membrane 110 and a blower 230 for measuring the blowing pressure of the blower 230 (200) comprising an insertion-type electronic flow (PIT) pressure gauge; A sludge discharge pipe (400) communicating with the filtration tank (100) and discharging sludge; An inter-membrane pressure difference (TMP) measuring unit 510 for measuring the inter-membrane pressure difference of the filtration membrane 110; The intermembrane pressure difference (TMP) and the blower discharge pressure (BP) from the mixture liquid suspensions (MLSS) densitometer 520, the TMP measuring unit 510 and the insertion type electromagnetic flow rate (PIT) And a control unit 500 for controlling the filtration process.

The membrane filtration system of the present invention is provided with a MLSS concentration meter, a TMP measurement unit, and an insertion type electronic flow rate (PIT) pressure gauge at the same time. The MLSS concentration, intermembrane pressure difference (TMP) It is possible to accurately determine the cause of the degradation of the acid efficiency by the pressure (BP), and to take appropriate measures promptly according to the cause, thereby improving the water treatment efficiency and the life of the membrane filtration device. Such measures include maintenance of the operating state, flue gas flushing, adjustment of the sludge residence time (SRT), sludge discharge and increase of the discharge flow rate of the blower by 1.1 to 1.5 times, which are automatically controlled through the control unit 500, When the degradation occurs, there is an advantage that it can actively cope without delay.

The filtration tank 100 is filled with influent water as raw water and the filtration membrane 110 included in the filtration tank 100 can filter the inflow water and discharge it to the process water discharge pipe 60. The raw water can be directly introduced into the filtration tank 100 from the inflow pipe or from the raw water storage tank 50. The inflow pipe is provided with a pump to smoothly supply raw water.

The filtration membrane 110 may include at least one of a PTFE membrane, a PVDF membrane, a PES membrane, a PSF membrane, a PE membrane, and a PP membrane. Specifically, the filtration membrane may be a PTFE membrane or a PVDF membrane in terms of chemical resistance and mechanical strength. 1, the filtration membrane 110 is illustrated as a hollow fiber membrane, but is not limited thereto.

The filtration tank 100 may include a mixed solution suspended solids (MLSS) densitometer 520 for measuring the MLSS concentration of the influent water and the measured value of the mixed solution suspended solids (MLSS) As shown in FIG.

The acid part 200 includes an air diffuser 210 for supplying air bubbles to the lower part of the filtration membrane 110, a blower 230 for injecting air into the air diffuser 210 through the air injection tube 250, (PIT) pressure gauge for measuring the discharge pressure (BP) of the blower (230).

The air diffuser 210 may have a pore shape along the longitudinal direction in a tubular shape, and may include a plurality of pipes, but is not limited thereto.

The blower 230 can supply air to the lower part of the filtration membrane 110 by injecting air into the air diffuser 210 through the air injection pipe 250 and adjust the flow rate If flushing is performed, the process may temporarily stop. The air discharge pressure BP of the blower 230 can be measured by an insertion type electromagnetic flow rate (PIT) pressure gauge and the measured discharge pressure BP of the blower 230 can be inputted to the control unit 500 have.

The sludge discharge pipe (400) communicates with the filtration tank (100) to discharge the sludge in the filtration tank (100). The sludge discharge pipe 400 may be formed at a lower portion of the filtration tank 100 (at a position less than 1/3 of the height of the filtration tank) to facilitate sludge discharge. The sludge discharge in the sludge discharge pipe 400 may temporarily stop the discharge of the sludge after a certain period of time, or may continuously discharge the sludge while adjusting the discharge amount of the sludge. The sludge discharge pipe 400 may include a pump and a valve to facilitate sludge discharge and discharge adjustment.

The inter-membrane pressure difference (TMP) measuring unit measures the inter-membrane pressure difference (TMP) of the filtration membrane, and the measured value can be input to the control unit 500 described later. Is not limited as long as it is capable of measuring the TMP, and may include a composition known to those skilled in the art.

The control unit 500 causes the MLSS concentration meter 520 and the inter-membrane pressure differential (TMP) measuring unit 510 to measure the MLSS concentration and the TMP at predetermined time intervals and receives the measured MLSS concentration and the TMP value The filtration membrane system can be monitored. When the MLSS concentration and the TMP value are in the relationship of the following equation (2), the insertion type electronic flow rate (PIT) pressure gauge measures the discharge pressure BP of the blower 230, It is possible to select a measure for eliminating the cause of the decrease in the efficiency of the acid. For example, the action may be one selected from maintenance of the operating state, flue gas flushing, adjustment of the sludge residence time (SRT), sludge discharge and increase of the discharge flow rate of the blower from 1.1 to 1.5 times. In this case, the control unit 500 measures the initial values MLSS ₀ , TMP ₀ and BP ₀ of the MLSS concentration, TMP, and the blower discharge pressure BP in the steady state (or the initial operating state) Can be compared with the changing MLSS concentration, TMP, and blower discharge pressure (BP). Here, the steady state (or the initial operating state) means a state in which the membrane filtration system is not in trouble, and it can determine whether the driver or the operator is in the steady state (or the initial operating state) according to the application environment and purpose.

The predetermined time interval may be several seconds to several minutes, specifically 10 seconds to 1 minute. In this time interval range, the filtration membrane device can be monitored in real time and power consumption can be reduced.

In one embodiment, the membrane filtration system determines that the MLSS concentration and the inter-membrane pressure (TMP) maintain normal operating conditions when the MLSS concentration and the inter-membrane pressure (TMP) satisfy the following equation The operation state can be maintained.

[Formula 1]

(TMP × MLSS) / (TMP ₀ × MLSS ₀ ) ≦ 1.5

(Where TMP ₀ and MLSS ₀ are the inter-membrane pressure difference and MLSS concentration in the normal operation state (or the initial operation state), respectively, and TMP and MLSS are the intermembrane pressure difference and the MLSS concentration at the time of measurement, respectively.

In another embodiment, the membrane filtration system is configured such that when the MLSS concentration and the transmembrane pressure differential (TMP) satisfy the following formula 2 and the blower discharge pressure BP is increased by 10% or more of the blower discharge pressure BP _{0 in the} steady state, Since it can be judged that the engine is seriously clogged by the sludge, flue-gas flushing can be performed. The flushing of the diffuser is to temporarily shut off the system including the blower, and then to instantaneously operate the blower at a high flow rate to physically clean the diffuser. For example, the diffuser flushing is to clean the diffuser by injecting a flow rate (e.g., 2 times) that is 1.5 times the flow rate of the steady-state or initial condition for 30 seconds to 90 seconds, for example 1 minute . Alternatively, after the system including the blower is temporarily stopped, raw water or treated water may be supplied to the acid engine from a separately provided flushing section (not shown) so that the sludge accumulated in the acid engine can be cleaned.

[Formula 2]

(TMP × MLSS) / (TMP ₀ × MLSS ₀ )> 1.5

(TMP ₀ and MLSS ₀ are the inter-membrane pressure difference and MLSS concentration in the normal operation state (or the initial operation state), respectively, and TMP and MLSS are the inter-membrane pressure difference and MLSS concentration at the time of measurement, respectively.

In yet another embodiment, the membrane filtration system MLSS concentration and transmembrane pressure difference (TMP) is the following formula 2, the satisfactory, and blower discharge pressure (BP) 5% 10% or more compared to the blower discharge pressure (BP ₀₎ in the normal state , It is judged that the degree of sludge clogging is serious. Therefore, it is possible to increase the discharge flow rate of the blower from 1.1 times to 1.5 times, specifically from 1.3 times to 1.5 times, and then perform additional judgment .

Specifically, when the discharge pressure BP of the blower decreases with time after the increase of the discharge flow rate of the blower, it can be judged that the decrease in the efficiency of the air-fuel ratio is recovered. Therefore, Can be maintained until the blower discharge pressure (BP ₀ ) is reached. If the discharge pressure BP of the blower does not change or increases with the lapse of time, it can be judged that the decrease in the efficiency of the acid gas is due to the increase of the concentration and the viscosity of the influent water. Therefore, the sludge residence time SRT can be controlled, The sludge can be discharged through the sludge discharge pipe. The adjustment of the sludge residence time (SRT) may be performed by methods known to those skilled in the art, for example by reducing the sludge residence time (SRT), thereby reducing the viscosity of the influent water, , And can be performed continuously by adjusting the amount of emissions.

[Formula 2]

(TMP × MLSS) / (TMP ₀ × MLSS ₀ )> 1.5

(TMP ₀ and MLSS ₀ are the inter-membrane pressure difference and MLSS concentration in the normal operation state (or the initial operation state), respectively, and TMP and MLSS are the inter-membrane pressure difference and MLSS concentration at the time of measurement, respectively.

In another embodiment, the membrane filtration system is judged to be in a normal state when the MLSS concentration and the transmembrane pressure difference (TMP) satisfy the following formula 2 and the blower discharge pressure BP increases or decreases or decreases to less than 5% So that the operating state can be maintained.

In an embodiment, the filtration tank 100 may further include a viscometer for measuring the viscosity of the influent water. The viscometer may measure the viscosity at a predetermined time interval, such as a mixed solution suspension solids (MLSS) densitometer and an inter-membrane pressure differential (TMP) measuring part, and the measured viscosity may be input to the controller 500. The measured viscosity can be used as a criterion for determining the viscosity of the influent water.

Membrane filtration  Control method

A membrane filtration control method according to another aspect of the present invention will be described with reference to FIG. 2 schematically shows a flow chart of a membrane filtration control method according to one embodiment of the present invention.

2, the membrane filtration control method according to one embodiment of the present invention sets the inter-membrane pressure difference (TMP ₀ ), MLSS concentration (MLSS ₀ ), and blower discharge pressure (BP ₀ ) The inter-film pressure difference (TMP) and the MLSS concentration (MLSS) are measured at predetermined time intervals, and when the inter-membrane pressure difference TMP and the MLSS concentration MLSS satisfy the following formula 1, ) And the MLSS concentration MLSS satisfy the following formula 2 and the blower discharge pressure BP is measured and when the blower discharge pressure BP is increased by 10% or more with respect to the blower discharge pressure BP _{0 in the} steady state, And the blower discharge pressure (BP) is 5% or more and less than 10% of the blower discharge pressure (BP ₀ ) in the steady state, The discharge flow rate of the blower is increased from 1.1 times to 1.5 times, Pressure sludge retention if (BP) In this case, to decrease with time, maintain the discharge flow rate of the blower until a blower discharge pressure (BP ₀₎ in the normal state, and blower discharge pressure (BP) is changed or increased with time It is possible to adjust the time (SRT), to discharge the sludge through the sludge discharge pipe, and to maintain the operating state when the blower discharge pressure (BP) decreases, changes or increases to less than 5%.

[Formula 1]

(TMP × MLSS) / (TMP ₀ × MLSS ₀ ) ≦ 1.5

[Formula 2]

(TMP × MLSS) / (TMP ₀ × MLSS ₀ )> 1.5

(TMP ₀ and MLSS ₀ in the above equations (1) and (2) are the intermembrane pressure difference and MLSS concentration in the normal operation state (or the initial operation state), and TMP and MLSS are the intermembrane pressure difference and MLSS concentration at the time of measurement respectively).

The predetermined time interval may be several seconds to several minutes, or 10 seconds to one minute.

While the present invention has been described with reference to exemplary embodiments, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, but, on the contrary, It will be understood that the invention may be embodied in other specific forms without departing from the spirit or essential characteristics thereof. It is to be understood, therefore, that the embodiments described above are intended to be illustrative in all respects and not restrictive.

50: raw water storage tank 60: treated water discharge pipe
100: Filtration tank 110: Filtration membrane
200: Acid base 210: Acid base
230: blower 250: air injection part
400: sludge discharge pipe 500:
510: Intermemory differential pressure (TMP) measuring part 520: Mixed liquid suspension solid (MLSS) concentration meter

Claims (7)

A filtration tank having a filtration membrane inside and equipped with a mixed solution suspended solids (MLSS) concentration meter for measuring the MLSS concentration of influent;
An acid part including an air diffuser positioned below the filtration membrane, a blower for injecting air into the air diffuser through an air inlet tube, and an insertion type electromagnetic flow rate (PIT) pressure gauge for measuring a discharge pressure (BP) of the blower;
A sludge discharge pipe communicating with the filtration tank and discharging sludge;
An inter-membrane pressure difference (TMP) measuring unit for measuring an inter-membrane pressure difference of the filtration membrane; And
The information on the MLSS concentration, the inter-membrane pressure difference (TMP), and the blower discharge pressure (BP) are received from the mixed liquid suspension solid matter (MLSS) densitometer, the intermechanic pressure (TMP) measuring unit and the insertion type electromagnetic flow rate (PIT) A control unit for controlling the control unit;
. ≪ / RTI >
The method according to claim 1,
Wherein the control unit maintains the operating state when the MLSS concentration and the inter-membrane pressure difference (TMP) satisfy the following equation (1): < EMI ID =
[Formula 1]
(TMP × MLSS) / (TMP ₀ × MLSS ₀ ) ≦ 1.5
(TMP ₀ and MLSS ₀ in the above equation (1) are the intermembrane pressure difference and the MLSS concentration in the normal operation state, respectively, and TMP and MLSS are the intermembrane pressure difference and the MLSS concentration at the time of measurement, respectively).
The method according to claim 1,
The control unit may membrane filtration satisfying to the MLSS concentration and transmembrane pressure difference (TMP) Equation 2, when the blower discharge pressure (BP) are increased by the normal state of the blower discharge pressure of more than 10% (BP _0), do the aeration flushing system:
[Formula 2]
(TMP × MLSS) / (TMP ₀ × MLSS ₀ )> 1.5
(Where TMP ₀ and MLSS ₀ are the intermembrane pressure difference and MLSS concentration in the normal operation state, respectively, and TMP and MLSS are the inter-membrane pressure difference and the MLSS concentration at the time of measurement, respectively).
The method according to claim 1,
When the MLSS concentration and the transmembrane pressure TMP satisfy the following formula 2 and the blower discharge pressure BP is increased by 5% or more but less than 10% of the blower discharge pressure BP _{0 in the} steady state, 1.1 to 1.5 times membrane filtration system:
[Formula 2]
(TMP × MLSS) / (TMP ₀ × MLSS ₀ )> 1.5
(Where TMP ₀ and MLSS ₀ are the intermembrane pressure difference and MLSS concentration in the normal operation state, respectively, and TMP and MLSS are the inter-membrane pressure difference and the MLSS concentration at the time of measurement, respectively).
5. The method according to claim 4, wherein after increasing the discharge flow rate of the blower,
When the discharge pressure BP of the blower decreases with time, the blower discharge flow rate is maintained until the blower discharge pressure BP ₀ becomes the steady state,
Wherein the sludge is discharged through the sludge discharge pipe when the discharge pressure (BP) of the blower does not change or increases with time.
The method according to claim 1,
Wherein the filtration tank further comprises a viscometer for measuring the viscosity of the influent water.
(TMP ₀ ), the MLSS concentration (MLSS ₀ ) and the blower discharge pressure (BP ₀ ) in the normal state are set,
(TMP) and MLSS concentration (MLSS) were measured at predetermined time intervals of 10 seconds to 1 minute,
When the inter-film pressure difference (TMP) and the MLSS concentration (MLSS) satisfy the following formula (1)
The blower discharge pressure BP is measured and the blower discharge pressure BP is set to 10% of the blower discharge pressure BP _{0 in the} steady state when the inter-film pressure difference TMP and the MLSS concentration MLSS satisfy the following expression (2) The flushing of the engine is performed,
When the inter-film pressure difference TMP and the MLSS concentration MLSS satisfy the following formula 2 and the blower discharge pressure BP is increased by 5% or more but less than 10% with respect to the normal blower discharge pressure BP ₀ , When the blower discharge pressure BP decreases with time after the flow rate is increased by 1.1 to 1.5 times, the discharge flow rate of the blower is maintained until the blower discharge pressure BP ₀ becomes the normal state, and the blower discharge pressure (SRT) in the case of no change or increase with time, or to control sludge discharge through the sludge discharge pipe:
[Formula 1]
(TMP × MLSS) / (TMP ₀ × MLSS ₀ ) ≦ 1.5
[Formula 2]
(TMP × MLSS) / (TMP ₀ × MLSS ₀ )> 1.5
(TMP ₀ and MLSS ₀ in the equations (1) and (2) are the intermembrane pressure difference and the MLSS concentration in the normal operation state, respectively.

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