KR101602929B1 - Controol system for air blowing - Google Patents

Abstract

The air supply control system of the present invention determines the amount of air to be supplied considering the water level inside an aeration tank and provides the appropriate amount of air to the aeration tank by controlling errors to be little regardless of the position inside the aeration tank to which the components of the system are installed. Further, the air supply control system of the present invention may comprise an air supply control unit which is connected to a pressure sensor and a water level sensor installed in the aeration tank and computes the amount of air supplied to the aeration tank by obtaining a pressure value and a water level value from the pressure sensor and the water level sensor, respectively, using an inverter which changes the frequency of the alternating current. Also, the air supply control unit determines the amount of air to be additionally supplied to the aeration tank based on the supplied amount of air and changes rotation speed of an air pump which supplies air to the aeration tank by changing output frequency of the inverter based on the amount of air to be additionally supplied.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001]

The present invention relates to a blowing control system, and more particularly, to a blowing control system that judges an amount of air to be introduced into an aeration tank with reference to a pressure and a water level in an aeration tank, controls an output frequency of the inverter, The present invention relates to an air flow control system for controlling the amount of air flowing into an aeration tank in an air pump and controlling the amount of air to be supplied to equalize the amount of air supplied to each aeration tank when there are a plurality of aeration tanks.

The activated sludge method used for wastewater treatment uses the principle of decomposing the substances contained in the wastewater by adding air to the wastewater and increasing the amount of dissolved oxygen while administering microorganisms. The facility that supplies air to the wastewater is called an aeration tank. The aeration tank has an open aeration tank and a closed aeration tank. The open type aeration tank means that the surface of the aeration tank is exposed to the atmosphere. In the process of purifying the wastewater, a large amount of odor and gas are generated, and the use of the closed type aeration tank is increasing.

Since the aeration tank cultivates aerobic nitrifying bacteria to purify the wastewater, it basically needs air to treat wastewater. The air is supplied by an electrically driven air pump. The air supplied from the air pump to the aeration tank is supplied through an air sprayer It is discharged in a crushed shape to increase air efficiency.

Since the aeration tank varies the efficiency of the wastewater treatment depending on the amount of air to be supplied, it is difficult to simply determine the supply amount of the air depending on the operator's neck. On the other hand, in the registered patent KR 10-0814523, the amount of dissolved oxygen in the aeration tank is obtained by using a DO sensor (dissolved oxygen sensor) provided in the aeration tank, and the amount of air supplied to the aeration tank is controlled on the basis of the obtained amount. Of the present invention. The patent document KR 10-0814523 discloses a method of immersing a DO sensor in an aeration tank and detecting the oxygen concentration in the aeration tank using the immersed DO sensor and then determining the rotational speed of the air pump And the oxygen concentration in the aeration tank is kept constant.

However, when the air supplied from the air pump is directed upward from the lower part of the aeration tank, the aeration tank supplies air to the wastewater by circulating the wastewater generated in the aeration tank,

1) When the water level of the aeration tank is low, obstacle occurs in the circulation of wastewater. At this time, it is difficult to trust the DO concentration because the wastewater does not mix well.

2) Depending on the position of the DO sensor, the oxygen concentration value can be discriminated.

Accordingly, even if an expensive DO sensor is applied, the patent application KR 10-0814523 can not grasp the proper amount of air to be supplied into the aeration tank.

It is an object of the present invention to provide an air flow control system which can determine an appropriate amount of air to be supplied to the aeration tank by referring to the water level of the wastewater and the pressure of the aeration tank.

It is another object of the present invention to provide a blowing control system for calculating a supply air amount for each aeration tank with reference to pressure values and water level values of a plurality of aeration tanks and to equalize supply air amount supplied to each aeration tank.

According to an aspect of the present invention, there is provided a method of controlling an aeration tank in which a pressure value and a water level value are respectively obtained from an inverter, a pressure measurement sensor, and a water level sensor connected to a pressure measurement sensor and a water level measurement sensor installed in an aeration tank, The air supply amount varying the rotation speed of the air pump for varying the output frequency of the inverter according to the amount of the additional air to supply the air to the aeration tank is determined based on the amount of air supplied to the aeration tank, Is achieved by the control unit.

According to an aspect of the present invention, there is provided an apparatus for measuring a pressure value and a water level value from an inverter, a pressure measuring sensor, and a water level measuring sensor connected to a pressure measuring sensor and a water level measuring sensor provided in each of a plurality of aeration tanks, And controlling the number of revolutions of the air pump for supplying air to each aeration tank by increasing or decreasing the output frequency of the inverter to obtain a supply air amount equalization to each aeration tank Lt; / RTI >

According to the present invention, it is possible to determine the supply air amount in consideration of the water level in the aeration tank, and to supply the appropriate air into the aeration tank without causing a large error according to the position to be mounted in the aeration tank.

In addition, according to the present invention, it is possible to determine the amount of supply air supplied to each aeration tank through a pressure measurement sensor and a water level sensor, which are provided non-contactly with each of a plurality of aeration tanks, and to equalize the amount of air supplied to each aeration tank based on this.

1 shows a flow chart of a method for removing activated sludge in a wastewater treatment plant using a DO sensor.
2 shows a conceptual diagram of a blowing control system according to an embodiment of the present invention.
Fig. 3 shows a conceptual diagram of an inverter control method of an air flow control system according to an embodiment.
Fig. 4 shows an example of the piping and the air injector installed in the aeration type aeration type enclosure and the reference to the drawing.
5 shows a conceptual diagram for explaining the circulation of wastewater generated in the aeration tank.
FIG. 6 shows a conceptual diagram of an engine blowing control system according to another embodiment of the present invention.
Fig. 7 shows a reference drawing according to another example of supplying air from the air pump to the aeration tank.
8 shows a reference drawing according to another example of supplying air from the air pump to the aeration tank.

The aeration tank referred to in this specification may mean a facility that increases the dissolved oxygen amount of the wastewater by aerating the wastewater. The aeration tank referred to in this specification is also referred to as an " aeration tank "or" aeration tank " In addition, the aeration tank referred to in the present specification may correspond to a closed aeration tank in which wastewater is not exposed to the outside.

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

FIG. 2 is a conceptual diagram of a blowing control system according to an embodiment of the present invention, and FIG. 3 is a conceptual diagram of a method of controlling an inverter of the blowing control system according to the embodiment.

Referring to FIGS. 2 and 3, the air flow control system 100 according to the embodiment may measure oxygen concentration or may be connected to a pair of sensors 131 and 132 that are not immersed in wastewater or water, , And calculates the difference between the reference air amount theoretically required in practice (or practically required) and the supply air amount in the present purification step as the additional air amount Can be calculated. The additional air amount may mean the amount of air to be supplied to the aeration tanks 11, 12. The reference air amount is determined according to the size of the aeration basins 11 and 12 and the treatment target (livestock manure, industrial water, domestic sewage and others) and throughput, It can be determined at the commissioning stage.

The air flow control system 100 calculates the additional air amount which is the difference between the reference air amount and the supply air amount and then calculates the additional air amount by referring to the air table defined for the number of revolutions of the air pumps 111, And provides the control signal ctrl to the inverters 121 and 122 connected to the air pumps 111 and 112 so as to determine the number of revolutions. Inverters 121 and 122 are devices for varying the frequency of AC, and perform power conversion in the order of AC-> DC-> AC. After converting AC-> DC, DC is switched to generate AC of desired frequency can do.

The inverters 121 and 122 change the frequency of the alternating current supplied to the air pumps 111 and 112 in the range of 0 to n so that the number of revolutions of the air pumps 111 and 112, can do. Preferably, the frequency of the alternating current output from the inverters 121 and 122 may be from 0 to 120, and the frequency range of the alternating current may range from 0 to 70, 0 to 200, and the like. However, it is not limited.

The air pumps 111 and 112 may be alternating current motors in which the drive shaft rotates in accordance with the frequency of the alternating current, that is, the pulse period, and the rotational speed may vary according to the frequency of the alternating current supplied from the inverters 121 and 122. Assuming that the air pumps 111 and 112 rotate at 100 RPM when the alternating current supplied to the air pumps 111 and 112 is 60 Hz, the air pumps 111 and 112 can rotate at 200 RPM when the AC frequency is 120 . Conversely, when the frequency of the alternating current supplied to the air pumps 111 and 112 is 30 Hz, the rotational speed of the air pumps 111 and 112 can be reduced to half, that is, 50 RPM at 60 Hz.

As described above, the air flow control system 100 according to the embodiment has an air table that defines the amount of air supplied to the aeration tanks 11, 12 in accordance with the number of revolutions of the air pumps 111, 112. The amount of air to be supplied to the aeration tanks 11 and 12 can be defined in accordance with the pressure measurement sensor 131 and the water level sensor 132 in the air table.

Sufficient air is supplied into the aeration tanks 11 and 12 when the pressure measured by the pressure measurement sensor 131 exceeds a preset reference value and conversely sufficient air is supplied into the aeration tanks 11 and 12 That is, the air shortage state.

When the water level measured by the water level sensor 132 does not reach the reference water level, the water level in the aeration tanks 11 and 12 is raised by the air pumps 111 and 112 irrespective of the pressure value measured by the pressure measurement sensor 131, It is necessary to increase the amount of air to be supplied to the air- That is, the air table corresponds to a data table in which the amount of air is defined according to two parameters.

That is, the air table is defined as "pressure value - water level value - air amount", and the amount of air can be increased or decreased according to each of the following numbers.

1) When the pressure value is low and the water level corresponds to the reference water level: the rotation speed of the air pumps 111 and 112 is increased so that the amount of air supplied from the air pumps 111 and 112 to the aeration tanks 11 and 12 is .

2) When the pressure value is high and the water level corresponds to the reference water level: The rotational speed of the air pumps 111 and 112 is reduced so that the amount of air supplied from the air pumps 111 and 112 to the aeration tanks 11 and 12 .

3) When the water level does not reach the reference water level: The rotational speed of the air pumps 111 and 112 can be increased in proportion to the reference water level and the deviation of the present water level in the aeration basins 11 and 12. If the deviation between the reference water level and the aeration basins 11 and 12 is small, the rotational speed of the air pumps 111 and 112 may increase slightly, and conversely, the rotational speed may greatly increase.

Here, the pressure measurement sensor 131 is located above the aeration basins 11 and 12 which are closed, and is installed so as not to be immersed in wastewater, so that the pressure inside the aeration basins 11 and 12 can be measured. The pressure inside the aeration tanks 11 and 12 increases according to the amount of air supplied to the aeration tanks 11 and 12 by the air pumps 111 and 112. [ The pressure measurement sensor 131 disposed inside the aeration tanks 11 and 12 does not directly contact the wastewater and the amount of air supplied into the aeration tanks 11 and 12 is set to a value It can be used to judge by the relation of quantity.

The water level measuring sensor 132 may measure the water level in the aeration basins 11 and 12 and provide the measured value to the airflow control system 100 in accordance with the ultrasonic wave detection system. The wastewater filled in the aeration tanks 11 and 12 may not be circulated when the water level in the aeration tanks 11 and 12 is low. When the air is injected from an air injector (not shown) disposed in the aeration tanks 11 and 12, the air can be mixed while the wastewater circulates from the lower portion to the upper portion of the aeration tanks 11 and 12 by the injected air . However, if the water level in the aeration basins 11 and 12 does not reach the appropriate water level, such circulation is limited and circulation of wastewater can not occur within the pomzes 11 and 12. This will be described with reference to FIG. 4 and FIG. 5 together.

Fig. 4 shows an example of the piping and the air injector installed in the aeration type aeration type enclosure and the reference to the drawing.

4, an air supply pipe 51 is extended and arranged in the aeration basins 11 and 12 and the air supplied from the air supply pipe 51 flows through each of the branches 51c, 51d and 51e And 51f. A plurality of air injectors 51g may be arranged in each of the branches 51c to 51f and air cut out from each air injector 51g may be supplied to the aeration bases 11 and 12, Air can be discharged from the lower part to the upper part. The discharged air is jetted from the air injector 51g and then directed to the water surfaces W1 and W2 as shown in Fig. 5, in which the air floats toward the water surfaces W1 and W2, The wastewater is attracted to the air discharge areas S1 and S2, and the attracted wastewater can be developed later on the water surface W1. Fig. 5A illustrates the case where the water level is proper, and the wastewater is drawn in the direction of d02 and d04 in the air injector 51g and developed in the d01 direction and the d03 direction.

As described above, when the water level in the aeration basins 11 and 12 is in the appropriate range (the reference water level REF or more), the wastewater circulates around the area S1 and air can be appropriately dissolved in the wastewater, The amount of dissolved oxygen in the wastewater can be uniform.

5 (b), when the water level in the aeration tanks 11 and 12 is lower than the reference water level REF, as the water surface W2 of the aeration tanks 11 and 12 becomes lower, 51g may not be properly circulated in the aeration tanks 11, 12. 5B shows an example in which the wastewater can not be developed in the d05 and d07 directions even if the wastewater is drawn in the d06 direction and the d08 direction when air is discharged from the air injector 51g. In this case, since the wastewater can not circulate in the aeration tanks 11 and 12 and the wastewater can not circulate in the aeration tanks 11 and 12, the dissolved oxygen amount of the wastewater stored in the aeration tanks 11 and 12 It is determined according to the amount of air injected from the air injector 51g.

If the measurement result of the ultrasonic level sensor 132 shows that the water level W2 does not reach the reference water level REF as shown in Fig. 5 (b) It is necessary to increase the amount of air significantly.

To this end, the airflow control system 100 may provide a control signal ctrl to the inverters 121 and 122 to significantly increase the AC frequency output from the inverters 121 and 122 (e.g., 70 Hz to 80 Hz) The amount of air discharged from the pumps 111 and 112 increases, and a large amount of air can be supplied into the aeration basins 11 and 12. [ At this time, the pressure value of the pressure measurement sensor 131 installed in the aeration tanks 11 and 12 can be greatly increased. However, when it is determined that the water level does not reach the reference water level REF, It is possible to ignore the measured value of the pressure measurement sensor 131 and to perform a large amount of aeration to the aeration basins 11 and 12. [

On the other hand, the pressure measurement sensor 131 and the water level sensor 132 may be provided for each aeration tank 11 or 12. A pressure measurement sensor 131 and a water level measurement sensor 132 are disposed in the aeration tank 11 and a pressure measurement sensor 133 and a water level measurement sensor 134 are arranged in a pair in the aeration tank 12 Can be seen. This is due to the increase in the number of aeration tanks 11, 12 included in the wastewater treatment system as a plurality of aeration tanks are connected in series or in parallel to increase the throughput of the wastewater. 2 illustrate that the pressure measurement sensors 131 and 132 and the level measurement sensors 133 and 134 are provided for each aeration tank 11 or 12 respectively. However, depending on the number of the aeration tanks, the pressure measurement sensors 131 and 132 And the level measuring sensors 133 and 134 can be arranged for each aeration tank. When the number of the aeration tanks is more than two, the air flow control system 100 according to the embodiment can control the amount of air for each aeration tank according to the measurement values of the pressure measurement sensor and the water level sensor disposed for each aeration tank. This is because the air flow control system 100 according to the embodiment of the air pump for supplying air to each aeration tank determines the amount of additional air and adjusts the number of rotations of the air pump allocated to each aeration tank according to the determined additional amount of air.

The amount of air supplied to the aeration tank can be adjusted by the electric valves 151 and 152 disposed between the air supply pipe 51 and the aeration tanks 11 and 12 in addition to the air pumps 111 and 112. The electric valves 151 and 152 are valves that determine the amount of opening and closing by the control signal ctrl2 (or control voltage) provided in the airflow control system 100 according to the embodiment. In the air pumps 111 and 112, It is possible to increase or decrease the amount of air directed toward the air cylinders 11 and 12 or block the air directed from the air pumps 111 and 112 to the aeration tanks 11 and 12. [

The amount of air directed from the air pumps 111 and 112 to the aeration tanks 11 and 12 is determined by the amount of rotation of the air pumps 111 and 112. However, the amount of air supplied to the aeration tanks 11, 12 through the air supply pipes 51, 52 in accordance with the length and condition of the air supply pipes 51, 52 and the water pressure of the aeration tanks 11, , 112 may not be exactly proportional to the amount of rotation. Accordingly, in the air flow control system 100 according to the embodiment, the flow rate measuring units 141 and 142 are disposed between the air supply pipes 51 and 52 and the aeration basins 11 and 12, The number of revolutions of the air pumps 111 and 112 can be corrected using the measured values.

When the air supply amounts detected by the flow rate measuring units 141 and 142 do not match the rotation amounts of the air pumps 111 and 112, the airflow control system 100 according to the embodiment is provided with the inverters 121 and 122 The frequency of the alternating current output from the inverters 121 and 122 can be increased by changing the control signal ctrl. The rotational speed of the air pumps 111 and 112 increases and the amount of air discharged from the air pumps 111 and 112 increases as the frequency of the AC output from the inverters 121 and 122 increases. The air flow control system 100 according to the embodiment controls the flow rate of the air to be supplied to the inverters 121 and 122 until the target air amount defined in the air table is measured by the flow rate measuring units 141 and 142 in accordance with a PLL (Phase Locked Loop) Can be increased.

As described above, the ventilation control system 100 according to the embodiment does not immerse the sensor in the wastewater. The sensors are a pressure measuring sensor 131 and a water level measuring sensor 132. These sensors are disposed in the upper part of the aeration tanks 11 and 12 which are not dipped in wastewater and are in a hermetically closed state to measure the pressure and the water level in a noncontact manner, To the airflow control system 100 according to the present invention. Therefore, it is not necessary to measure the oxygen concentration by directly immersing in the wastewater, and unlike the conventional air flow control system using the DO measurement value, the measurement deviation due to the position where the sensor is damaged in the wastewater or immersed in the wastewater is considered So that the ventilation system can be operated.

Considering the lifetime and stability of the DO sensor immersed in the livestock manure, assuming that the livestock manure is handled, considering the life span or the measurement accuracy of the expensive DO sensor in the livestock manure, It can be easily deduced that the measurement stability and the sensor life of the airflow control system 100 are superior to those of the conventional dipping method.

Also, assuming that the DO sensor is placed in a large amount of bubbles generated while purifying the wastewater, it may be difficult for the DO sensor to obtain an accurate measurement value in the foam of wastewater.

Even if the DO sensor is disposed at any position in the aeration basins 11 and 12, the degree of the measured value measured by the DO sensor is Can not be guaranteed.

As described above, the immersion method in which the sensor is directly immersed in wastewater can cause a large variation in the measurement accuracy depending on the measurement location or environment, and in some cases, the immersion method may not be reliable. On the other hand, the cost of the DO sensor may be small, as it costs several hundred thousand won for low cost and millions of won for expensive products.

The airflow control system 100 according to the embodiment uses the pressure measurement sensor 131 or the non-contact ultrasonic level measurement sensor 132 that is not directly immersed in wastewater, And indirectly obtains measurement values that can be measured in the wastewater treatment system and calculates the additional air amount to be supplied to the wastewater. That is, instead of using the DO sensor to supply oxygen in the aeration tanks 11 and 12, an indirect measurement method is used in which only the pressure and the water level are measured and the amount of air to be supplied into the aeration tanks 11 and 12 is calculated This is a feature of.

6 is a conceptual diagram of a blowing control system according to another embodiment of the present invention.

6, the air flow control system 100 according to the embodiment is connected to a pressure measurement sensor 131 and a water level measurement sensor 132 installed in a plurality of aeration tanks S1 to S4 and connected to each of the aeration tanks S1 to S4 ) Can be determined.

The blowing control system according to the embodiment of Fig. 6 is similar to the blowing control system according to the embodiment shown in Figs. 2 to 5 except that it is connected to a pair of sensors 131 and 132 which measure the oxygen concentration or are not directly immersed in the wastewater, S4, and determines the amount of supply air supplied to each of the aeration tanks S1 to S4 on the basis of the pressure value and the water level value. This is the same as that described with reference to Figs. 2 to 5.

However, the blowing control system 100 according to the embodiment is different from the embodiment of FIGS. 2 to 5 in that it corresponds to an equalizing function for the amount of supply air supplied to each of the aeration tanks S1 to S4.

Fig. 6 illustrates that the air pumps 111 and 112 operate the four aeration tanks S1 to S4. The air pump 111 supplies air to the aeration tanks S1 and S2 and the air pump 112 supplies air to the aeration tanks S3 and S4. Here, even if the characteristics of the air pumps 111 and 112 are the same and the capacity of each of the aeration tanks S1 to S4 is the same, the air supplied to each of the aeration tanks S1 to S4 may not be uniform. The amount of air supplied to each of the aeration tanks S1 to S4 is differentiated according to the arrangement method and the difference in state of the piping arranged for supplying air between the air pumps 111 and 112 and the aeration tanks S1 to S4. Accordingly, the treatment efficiency in which the wastewater is treated in each of the aeration tanks S1 to S4 can be discriminated, and the air supplied to each of the aeration tanks S1 to S4 needs to be equalized for uniform treatment of the wastewater.

To this end, the air flow control system 100 calculates the supply air amount supplied for each of the aeration tanks S1 to S4 through the pressure measurement sensor 131 and the water level sensor 132 installed for each of the aeration tanks S1 to S4 ,

The rotational speeds of the air pumps 111 and 112 for supplying air to the aeration tanks S1 to S4 can be increased or decreased to allow the deviation of the supply air amount calculated for each of the aeration tanks S1 to S4 to be zero , The amount of air discharged from the air pumps (11, 112) increases or decreases according to the rotational speed of the air pumps (111, 112).

For this purpose, the air flow control system 100 can increase and decrease the output frequency of the inverters 121 and 122 connected to the air pumps 111 and 112. When the output frequency of the inverter 121 connected to the air pump 111 increases from 60 Hz to 70 Hz, the rotational speed of the air pump 111 increases, which means that the amount of air discharged from the air pump 111 increases or decreases it means. This is the same as described above with reference to Figs.

However, since the air pump 111 supplies air to the two aeration tanks S1 and S2, the amount of air supplied to the two aeration tanks S1 and S2 may not be uniform. In order to solve this problem, the air flow control system 100 is connected to the two aeration tanks S1 and S2 via the pressure measurement sensor 131 and the water level sensor 132, which are respectively installed in the aeration tank S1 and the aeration tank S2 The supply valves 151a and 151b are controlled to supply the respective aeration tanks S1 and S2 to the aeration tanks S1 and S2 if one of the two aeration tanks S1 and S2 determines that the supply air amount is smaller than the other one It is possible to control the amount of air to be increased or decreased. Accordingly, the air supplied from the air pump 111 can be uniformly supplied to the two aeration tanks S1 and S2.

If the measured supply air amount (S1 supply air amount + S2 supply air amount) corresponding to the sum of the measured values of the pressure measurement sensor 131 and the water level measurement sensor 132 installed in the two aeration tanks S1 and S2 is smaller than the sum of the measured values of the two aeration tanks S1 S2, S23, S23, S23, S23, S23, S23, S23, S23, S23, S23, The output frequency can be decreased to control the amount of air supplied to the two aeration tanks S1 and S2 to decrease. It goes without saying that the amount of air supplied to the two aeration tanks S3 and S4 can be equalized in the same manner as the air discharged from the air pump 112. [

On the other hand, in the embodiment of FIG. 6, two air pumps 111 and 112 supply air to the four aeration tanks S1 to S4. However, when the air pump 111 is capable of discharging a large-capacity air, a single air pump 111 may supply air to the four aeration tanks S1 to S4, which can be implemented in the form shown in Fig. 7 have. 7 illustrates a method of driving the four aeration tanks with one air pump 111 and uses the electric valves 151a to 151d provided between the air pump 111 and each of the aeration tanks S1 to S4, The amount of air supplied to the aeration tanks S1 to S4 is finely adjusted.

On the other hand, as shown in Fig. 8, independent air pumps 111 to 114 may independently supply air to the aeration tanks S1 to S4.

8, the air pump 111 supplies air to the aeration tank S1, the air pump 112 supplies air to the aeration tank S2, and the air pump 113 supplies air to the aeration tank S3. And the air pump 114 can supply air to the aeration tank S4. In this case, since the air pump-aeration tank is matched 1: 1, the electric valves 151a to 151d provided between the aeration tanks S1 to S4 and the air pumps 111 to 114 can be omitted. This can be achieved by controlling the output frequency of the inverters 121 to 124 connected to the air pumps 111 to 114 to directly control the amount of air discharged from the air pumps 111 to 114.

11, 12: aeration tank 51, 52: air supply pipe
100: air flow control system 111, 112: air pump
121, 122: Inverter 131, 133: Pressure measuring sensor
132, 134: Level sensor 141, 142: Flow rate measuring unit
151, 152: Electric valve

Claims (5)

A plurality of aeration tanks;
A plurality of pressure measurement sensors provided in each of the plurality of aeration tanks;
A plurality of level measuring sensors provided in each of the plurality of aeration tanks;
A plurality of air supply pipes each having one end connected to each of the plurality of aeration tanks;
A plurality of air pumps for supplying air to the other end of each of the plurality of air supply pipes;
A plurality of inverters connected to each of the plurality of air pumps;
A plurality of flow measuring units installed in each of the plurality of air supply pipes to measure an amount of air supplied through each of the plurality of air supply pipes; And
And a plurality of electric valves provided in each of the plurality of air supply pipes for opening and closing each of the plurality of air supply pipes,
A plurality of pressure values measured by each of the plurality of pressure measuring sensors and a plurality of water level values measured by each of the plurality of level measuring sensors to calculate a plurality of supply air amounts supplied to each of the plurality of aeration tanks,
Wherein the control unit determines a plurality of additional air amounts to be supplied to the plurality of aeration tanks based on each of the plurality of supply air amounts and changes the output frequency of each of the plurality of inverters according to the plurality of additional air amounts, Wherein the air pump includes a plurality of air pumps,
And when the water level is lower than the reference water level among the plurality of water level values, the rotation speed of the air pump is increased in proportion to the magnitude of the deviation between the reference water level and the water level value,
Wherein each of the plurality of air supply pumps adjusts the rotation speed of each of the plurality of electric valves and the air pump by comparing each of the plurality of supply air amounts measured by the plurality of flow rate measuring units with the rotation amount of each of the plurality of air pumps. Ventilation control system. delete delete delete delete

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