KR102500373B1 - Off-Gas Measurement Device For Operates In Response To Level Of Wastewater In Aeration Tank - Google Patents

Abstract

The present invention relates to a sensor that detects the water level in an aeration tank and applies different default values to the sensor module according to the amount of wastewater filled in the aeration tank to increase the reliability of by-product gas measurement. It's about measuring devices. The off-gas measuring device that operates in response to the wastewater level of the aeration tank includes a diffuser installed at the lower end of the aeration tank to supply oxygen; A column part installed at a height higher than the height of the wastewater filled in the aeration tank; A water level sensor unit in which a plurality of water level sensors are installed at regular intervals on one side of the column, including a plurality of water level sensors capable of generating different signals depending on whether wastewater is detected and transmitting the generated signals through wired or wireless communication ; A collecting unit having an upper surface connected to a connection pipe that is a moving path of by-product gas, and a lower surface in contact with the waste water filled in the aeration tank and collecting by-product gas from the waste water; A first valve having one end connected to the first discharge pipe to control air discharged from the first discharge pipe, a second valve having one end connected to the by-product gas discharge pipe and controlling by-product gas discharged from the by-product gas discharge pipe, and one end connected to the by-product gas discharge pipe. A third valve connected to the gas discharge pipe to control the air discharged from the by-product gas discharge pipe and connected to the first valve and the second valve to generate suction power and to selectively transmit the suction force to the first valve or the second valve, A suction pump that allows air to be sucked through valve 1 and by-product gas to be sucked through valve 2, a default value set inside, and connected to the suction pump to detect atmospheric and by-product gases discharged from the suction pump A sensor module, a memory for storing the oxygen concentration and carbon dioxide concentration of the atmosphere measured by detecting the atmosphere by the sensor module as measurement default values, and when wastewater is detected by any one of the plurality of water level sensors, the first valve and the and a pump-type measuring unit equipped with an arithmetic module that opens the second valve, closes the third valve, and changes the default value set in the sensor module to the default measurement value stored in the memory.

Description

Off-Gas Measurement Device For Operates In Response To Level Of Wastewater In Aeration Tank}

The present invention relates to a device for measuring off-gas generated in sewage and wastewater treatment plants.

As the amount of sewage and wastewater discarded from households and industrial complexes increases, the amount of sewage/wastewater purified at wastewater treatment plants is increasing. The wastewater treatment plant is purifying a large amount of wastewater by constructing facilities such as a plurality of sedimentation facilities and a bioreactor. In addition, the wastewater treatment plant purifies a large amount of wastewater in various stages such as flow rate adjustment, PH adjustment, reduction, neutralization, reaction, coagulation, and treatment.

The wastewater treatment plant monitors the purification status of each stage and adjusts each stage using extracted data to manage the purification status of wastewater. For example, in a wastewater treatment plant, in a bioreactor treatment corresponding to a five-step treatment, an off-gas measuring device is installed inside the reactor to measure the purification state of wastewater. A by-product gas measuring device installed in the bioreactor measures oxygen and carbon dioxide in the treated water. In addition, the state of the treated water is grasped and the state data of the treated water filled in the reaction tank is extracted.

However, in the conventional by-product gas measuring device, although different by-product gases are generated according to the water level of sewage and wastewater treatment plants, the default value corresponding to the water level is not reflected in the sensor module, so the reliability of by-product gas measurement is not high. there is a problem.

Republic of Korea Patent No. 10-1503688 (2015.03.12)

According to the present invention, different default values are applied to the sensor module according to the amount of wastewater filled in the aeration tank in conjunction with a sensor for detecting the water level in the aeration tank, thereby increasing the reliability of by-product gas measurement.

The problem to be solved by the present invention is not limited to the problems mentioned above, and other technical problems not mentioned will be clearly understood by those skilled in the art from the following description.

The off-gas measuring device that operates in response to the wastewater level of the aeration tank of the present invention for achieving the above object is

A diffuser installed at the lower end of the aeration tank to supply oxygen;

A column part installed at a height higher than the height of the wastewater filled in the aeration tank;

A water level sensor unit including a plurality of water level sensors installed on one side of the pillar part at regular intervals to generate different signals depending on whether wastewater is detected and transmit the generated signals through wired or wireless communication;

A collection unit for collecting by-product gas generated from wastewater filled in an aeration tank with a lower surface connected to a connection pipe that is a moving path of by-product gas on an upper surface;

A first valve having one end connected to the first discharge pipe to control air discharged from the first discharge pipe;

A second valve having one end connected to the by-product gas discharge pipe to control the by-product gas discharged from the by-product gas discharge pipe;

One end is connected to the by-product gas discharge pipe to control the air discharged from the by-product gas discharge pipe, and the third valve is connected to the first and second valves to generate suction power and selectively transmit suction power to the first valve or the second valve. A suction pump for sucking air through the first valve and sucking by-product gas through the second valve;

A sensor module that has a default value set inside and is connected to the suction pump to detect atmospheric and by-product gases discharged from the suction pump;

A memory for detecting the atmosphere in the sensor module and storing the measured oxygen concentration and carbon dioxide concentration in the atmosphere as measurement default values;

Equipped with an operation module that opens the first and second valves and closes the third valve when one of the plurality of water level sensors detects wastewater, and changes the default value set in the sensor module to the default measurement value stored in the memory. It includes a pump-type measuring part.

water level sensor,

Including a first water level sensor and a second water level sensor,

The calculation module is

When wastewater is detected by the first water level sensor, a first measurement default value may be set in the sensor module, and when wastewater is detected by the second water level sensor, a second measurement default value may be set in the sensor module.

It is connected to the first suction pipe and the first discharge pipe to separate moisture in the air through the first suction pipe, and then to the first moisture separator that discharges air to the first discharge pipe, and is connected to the by-product gas transfer pipe and the by-product gas discharge pipe. After separating moisture from the by-product gas introduced through the gas pipe, a moisture separator including a second moisture separator configured to discharge the by-product gas through the by-product gas discharge pipe may be included.

The first valve is

It maintains the closed state, and when one of the plurality of water level sensors detects wastewater, it switches to the open state.

The second valve is

It maintains the closed state, and when one of the plurality of water level sensors detects wastewater, it switches to the open state.

The third valve is

While maintaining the open state, when any one of the plurality of water level sensors detects wastewater, it may be switched to the closed state.

An off-gas measuring device operating in response to the level of wastewater in an aeration tank according to the present invention is linked with a sensor that detects the level of wastewater in the aeration tank and applies different default values to the sensor module according to the amount of wastewater filled in the aeration tank to increase the reliability of by-product gas measurement. allow it to rise.

1 is a block diagram of an off-gas measuring device that operates in response to the level of wastewater in an aeration tank according to an embodiment of the present invention.
2 is a relationship diagram of an off-gas measuring device that operates in response to the level of wastewater in an aeration tank according to an embodiment of the present invention.
3 is a flow chart for the operation of an off-gas measuring device that operates in response to the level of wastewater in an aeration tank according to an embodiment of the present invention.
4 to 6 are operation diagrams of a pump type measuring unit when a water level sensor detects wastewater.
7 to 9 are operation diagrams of a pump type measuring unit when a water level sensor detects wastewater.

Advantages and features of the present invention and apparatuses for achieving them will become clear with reference to the embodiments described below in detail in conjunction with the accompanying drawings.

However, the present invention is not limited to the embodiments disclosed below. The present invention can be implemented in a variety of different forms, and only this embodiment is provided to complete the disclosure of the present invention and to fully inform those skilled in the art of the scope of the invention to which the present invention belongs will be. The claims of the present invention can be defined by the claims. In addition, the same reference numerals described throughout this specification refer to the same components.

Hereinafter, the components constituting the off-gas measuring device that operates in response to the wastewater level in the aeration tank of the present invention are briefly described with reference to FIG. 1 so that the description of the present invention can be concise and clear, and then the present invention Describe the installation conditions in sewage and wastewater treatment plants.

1 is a block diagram of an off-gas measuring device that operates in response to the wastewater level in an aeration tank according to an embodiment of the present invention, and FIG. 2 is an off-gas measuring device that operates in response to the wastewater level in an aeration tank according to an embodiment of the present invention. It is a relationship diagram of the device.

An off-gas measuring device (1, hereinafter, off-gas measuring device) operating in response to the level of wastewater in an aeration tank of the present invention is connected to a water level sensor unit 30 that detects the water level in the aeration tank (A). By-product gas is measured with high reliability by applying different default values to the sensor module 609 according to the amount of wastewater to be filled. For example, the off-gas measuring device 1 of the present invention opens the first valve 601 and closes the second valve 602 when the off-gas is to be measured when the water level rises through the water level sensor unit that senses the water level. In addition, atmospheric air is sucked in to set the basic measurement value of the sensor module so that the off-gas can be accurately measured at the time of measuring the off-gas in the sensor module.

That is, the off-gas measuring device 1 may accurately measure the off-gas based on the measurement environment by measuring the atmospheric environment at the time of measuring the off-gas. Furthermore, the off-gas measuring device 1 of the present invention purging the moving path of the off-gas before measuring the by-product gas, so that the off-gas moves to a clean path at the time of measurement, so that the off-gas generated in the aeration tank (A) Allows for more accurate measurement of off-gas.

The off-gas measuring device 1 having such characteristics includes a diffusion pipe 10, a column part 20, a water level sensor part 30, a collecting part 40, a water separator 50, a pump type measuring part ( 60), etc. are included as components.

Hereinafter, components constituting the off-gas measuring device 1 will be described in detail.

The diffuser pipe 10 becomes a pipe for supplying compressed air to the inside of the aeration tank A. In this diffuser pipe 10, compressed air is introduced through the flow pipe 110 installed on the lower surface of the aeration tank (A), the compressed air is discharged into the aeration tank (A), and microorganisms in the aeration tank (A) are discharged. allow it to oxidize. Here, the aeration tank may be a tank that is the center of purification by the activated sludge method.

The pillar portion 20 becomes a pillar installed in the aeration tank A. The column part 20 is installed at a height higher than the height of the wastewater filled in the aeration tank (A). A water level sensor unit 30 for detecting wastewater is installed on one side of the pillar unit 20.

The water level sensor unit 30 generates different signals depending on whether wastewater is detected or not. The generated signal may be transmitted in any one of wired communication and wireless communication. The water level sensor unit 30 includes a first water level sensor 301 installed at the lower end of the pillar unit 20, a second water level sensor 302 spaced upward from the first water level sensor 301, and a second water level sensor. A third water level sensor 303 spaced upward from 302 is included. The first water level sensor 301 to the third water level sensor 303 may be installed at regular intervals on one surface of the pillar part 20 . At this time, the first water level sensor 301 generates a first water level wastewater detection signal when wastewater is detected, and a first water level no detection signal when it does not detect wastewater, and the second water level sensor 302 generates a wastewater detection signal. When detected, a second water level wastewater detection signal is generated, and when wastewater is not detected, a second water level non-detected signal is generated. The third water level sensor 303 generates a third water level wastewater detection signal when wastewater is detected, and a third water level non-detection signal when wastewater is not sensed. The generated water level detection signal and the non-level detection signal may be transmitted to the pump type measurement unit 60 . The operation of the pump type measuring unit 60 through the plurality of water level sensors 301 to 303 will be described later.

The upper surface of the collecting unit 40 is connected to the connection pipe 410 serving as a moving path of by-product gas, and the lower surface is in contact with the wastewater filled in the aeration tank (A). The collecting unit 40 collects by-product gas generated by microorganisms in the wastewater and transfers it to the water separation unit 50. The shape of the collecting unit 40 as described above may be formed in a shape of a rhombus in a longitudinal section, that is, a lower side is longer than an upper side, and a side surface is inclined. The shape of the collecting unit 40 is not limited to a rhombic shape in longitudinal section, and may be modified according to the size and shape of the aeration tank.

The water separator 50 is a device for separating water floating in the gas. The water separator 50 includes a first water separator 510 for separating water floating in the air and a second water separator 520 for separating water floating in by-product gas. Here, the first moisture separator 510 is connected to the first suction pipe 511 on one side and the first discharge pipe 512 on the other side, and after separating moisture in the air through the first suction pipe 511, the first discharge pipe The air from which moisture has been removed in step 512 is discharged to the pump type measuring unit 60. The second water separator 520 is connected to a by-product gas pipe 521 on one side and a by-product gas discharge pipe 522 on the other side to separate moisture from the by-product gas flowing through the by-product gas pipe 521, and then to the by-product gas discharge pipe. In step 522, the by-product gas from which moisture has been removed is discharged to the pump-type measuring unit 60.

When it is time to measure the off-gas by detecting the wastewater in the water level sensor unit 60, the pump type measuring unit 60 opens the first valve 601 and turns the second valve 602 and the third valve 603 on. After closing, the atmospheric air is inhaled, and then the oxygen concentration and the carbon dioxide concentration analyzed by analyzing the components of the inhaled air are set as default values of the sensor module 609. In addition, the pump-type measurement unit 60 measures the by-product gas from which water is separated in the water separator 50 and prior to discharging it to the outside, through the air separated in the water separator 50, the by-product gas movement path to fuzz.

Such a pump-type measurement unit 60 includes a first valve 601, a second valve 602, a third valve 603, a flow control valve 604, a suction pump 605, and a water removal filter 606 , a flow meter 607, an arithmetic module 608, a memory 6081, a sensor module 609, an antenna 610, and an exhaust fan as components. Here, the first valve 601 controls air discharged from the first discharge pipe 512 .

The first valve 601 has one end connected to the first discharge pipe 512 and the other end connected to the flow control valve 604 to supply air moving from the first discharge pipe 512 to the flow control valve 604. can be controlled For example, the first valve 601 is connected to the calculation module 608, opens when a first valve opening signal is applied from the calculation module 608, and allows air to flow, and closes when a first valve closing signal is applied. Make sure the air doesn't flow.

The second valve 602 controls the by-product gas discharged from the by-product gas discharge pipe 522 at one end. The second valve 602 has one end connected to the by-product gas discharge pipe 522 and the other end connected to the flow control valve 604 so that the by-product gas moves from the by-product gas discharge pipe 522 to the flow control valve 604. can control. For example, the second valve 602 is connected to the arithmetic module 608 and opens when a second valve opening signal is applied from the arithmetic module 608 to allow by-product gas to flow and is closed when a second valve closing signal is applied. Prevent by-product gas from flowing.

The third valve 603 controls the flow of air introduced through the collecting unit 40 when the collecting unit 40 does not collect the by-product gas and air is sucked. One end of the third valve 603 may control air discharged from the by-product gas discharge pipe 522 . The third valve 603 has one end connected to the by-product gas discharge pipe 522 and the other end exposed to the outside, so that air moving from the by-product gas discharge pipe 522 to the outside can be controlled. For example, the third valve 603 is connected to the arithmetic module 608 and opens when a third valve opening signal is applied from the arithmetic module 608 to allow air to flow, and when a third valve closing signal is applied, it is closed to air do not flow

The flow control valve 604 has one end connected to the first valve 601 and the second valve 602, the other end connected to the suction pump 605, and the first valve through the suction force generated by the suction pump 605 Air and by-product gas introduced through the 601 and the second valve 602 are sucked.

Furthermore, the flow control valve 604 is a valve whose opening and closing amount is controlled, and different amounts of flow are moved to the suction pump 605 in response to the first to third opening and closing signals transmitted from the calculation module 608. make it possible

The suction pump 605 is a device that generates a suction force so that fluid can be moved in one direction. Such a suction pump 605 is connected to the calculation module 608 and can generate different suction forces according to an operation signal generated from the calculation module 608 . For example, when the operation module 608 receives a signal generated from the first water level sensor 301, the suction pump 605 operates to generate a first stage suction force through a first operation signal generated. do. And when the calculation module 608 receives the signal generated by the second water level sensor 302, it operates to generate a second stage suction force greater than the first stage suction force through the generated second operation signal. . And when the calculation module 608 receives the signal generated by the third water level sensor 303, it operates to generate a third stage suction force greater than the second stage suction force through the generated third operation signal. .

Such a suction pump 605 sucks inhaled air or by-product gas through suction power of different sizes and discharges it to the water removal filter 606.

The moisture removal filter 606 has one end connected to the suction pump 605 to remove moisture contained in the air or by-product gas passing through the suction pump 605. Such a moisture removal filter 606 may be a compressed air moisture removal device.

The flow meter 607 has one end connected to the other end of the water removal filter 606, and can measure the flow rate of air or by-product gas passing through the water removal filter 606. For example, the flow meter 607 is formed as a differential pressure type flow meter, and measures flow rate with a pressure difference between one side and the other side. The sensor module 609 may be connected to the suction pump 605 or the flow meter 607 to detect air and by-product gas discharged from the suction pump 605 or the flow meter 607 . At this time, the sensor module 609 has a default value set therein, and is connected to the suction pump 605 to detect air and by-product gas discharged from the suction pump 605. For example, oxygen in the air, carbon dioxide in the air, temperature at the time of measuring the by-product gas, humidity at the time of measuring the by-product gas, atmospheric pressure, flow rate, time, etc. are measured.

The calculation module 608 opens the first valve 601 and the second valve 602 and closes the third valve 603 when wastewater is detected by any one of the plurality of water level sensors, and the sensor module ( The default value set in 609) is changed to the default measurement value stored in the memory 6081. The calculation module 608 is connected to the antenna 610 capable of wireless communication with the water level sensor unit 30 to receive data transmitted from the water level sensor unit 30 .

In addition, data transmitted from the water level sensor unit 30 may be received wirelessly through the antenna 610 to a manager or control room. In addition, the memory 6081 included in the arithmetic module 608 may sense the air by the sensor module 609 and store the measured oxygen concentration and carbon dioxide concentration of the air as measurement basic values.

Such a calculation module 608 can control the operation of the first valve 601 to the third valve 603 and change the default value of the sensor module 609 to the default measurement value so as to correspond to the signal transmitted from the antenna 610. there is. That is, the calculation module 608 operates the first valve 601 to the third valve 603, the flow control valve 604 and the suction pump 605 when any one of the plurality of water level sensors 301 to 303 detects wastewater. ) and selectively applies an electrical signal to the first valve 601 to the third valve 603, the flow control valve 604 and the suction pump 605 to operate.

Through this, the default value set in the sensor module is changed to the default measurement value. Such an arithmetic module 608 may be, for example, a computer. Details of the signal output from the arithmetic module 608 and the valve and the pump operated according to the signal will be described later.

Hereinafter, with reference to FIGS. 3 to 9, the operation of the off-gas measuring device operating in response to the level of wastewater in the aeration tank will be described in detail.

First, with reference to FIGS. 3 to 6 , when the water level sensor detects wastewater, operations of the first to third valves and the flow control valve included in the pump type measurement unit will be described in detail.

However, the description of the operation will be based on the order shown in FIG. 3 so that the description of the operation can be concise and clear. Here, FIG. 3 is a flow chart for the operation of the off-gas measuring device that operates in response to the wastewater level in the aeration tank according to an embodiment of the present invention.

The off-gas measuring device 1 is initially set to a state where the first valve 601, the second valve 602, and the flow control valve 604 are closed, and the third valve 603 is open. The initial state of the off-gas measuring device 1 may be a state as shown in FIG. 4 .

In the initial state of the off-gas measuring device 1, when one of the plurality of water level sensors 301 to 303 detects wastewater, the first valve 601 is opened by an electrical signal generated by the calculation module 608. and the third valve 603 is switched to the closed state. At this time, the off-gas measuring device 1 opens the first valve 601 through the pump-type measuring unit 60 and the water level sensor 30 for detecting the water level, when the water level rises and it is time to measure the off-gas. The default value of the sensor module is changed to the default measurement value by sucking atmospheric air while closing the second valve 602 . For example, the off-gas measuring device 1 controls the operation of the first valve 601 and the second valve 602 through the arithmetic module 608 when the first water level sensor 301 detects wastewater, and turns off the gas. The gas path is purged for a first set time, and the oxygen concentration of 20.95% and the carbon dioxide concentration of 400 ppm of the atmosphere in the environment in which off-gas is generated may be changed to the default values of the sensor module as the first measurement default values. In addition, the off-gas measuring device 1 controls the operation of the first valve 601 and the second valve 602 through the arithmetic module 608 when the second water level sensor 302 detects wastewater, and controls the operation of the off-gas The route is purged for a second set time, and the oxygen concentration of 20.8% and the carbon dioxide concentration of 390 ppm of the atmosphere in the environment in which off-gas is generated may be changed to the default values of the sensor module as the second measurement default values.

Further, the off-gas measuring device 1 controls the operation of the first valve 601 and the second valve 602 through the calculation module 608 when the third water level sensor 303 detects wastewater, and the off-gas path is purged for a third set time, and oxygen concentration of 20.6% and carbon dioxide concentration of 380 ppm of the atmosphere in the environment where off-gas is generated may be set as default values of the sensor module.

The off-gas measuring device 1 measures the atmospheric environment at the time of off-gas measurement, uses the oxygen and carbon dioxide concentrations in the atmosphere as basic data, and can accurately measure the off-gas generated at the time of off-gas generation. can At this time, the by-product gas sucked through the second valve 602 is measured by the sensor module 609 after the moisture contained in the by-product gas is removed through the moisture removal filter 606.

Hereinafter, with reference to FIGS. 7 to 9, when the water level sensor detects wastewater, the operation of the pump-type measuring unit will be described.

7 to 9 are operation diagrams of a pump type measuring unit when a water level sensor detects wastewater.

The water level sensor unit 30 of the off-gas measuring device 1 may generate a wastewater detection signal when the first water level sensor 301 to the third water level sensor 303 detect wastewater in the aeration tank A.

At this time, the first water level sensor 301 generates a first water level wastewater detection signal, the second water level sensor 302 generates a second water level wastewater detection signal, and the third water level sensor 303 generates a third water level wastewater detection signal. generate a detection signal. Here, the first to third water level wastewater detection signals may be received through the antenna 610 and transmitted to the calculation module 608 . At this time, when the first level wastewater detection signal is applied to the flow control valve 604, the flow control valve 604 is opened to the first size, and when the second level wastewater detection signal is applied to the flow control valve 604, the flow rate is controlled. The valve 604 can be opened to a second size greater than the first size. And, when the third water level wastewater detection signal is applied to the flow control valve 604, the flow control valve 604 can be opened to a third size greater than the second size.

As described above, the off-gas measuring device 1 operating in response to the level of the wastewater in the aeration tank has a first valve 601 according to signals corresponding to the first water level sensor 301 to the third water level sensor 303. ) to the third valve 603, the flow control valve 604, and the suction pump 605 are operated and purging the off-gas movement path so that the off-gas moves to a clean path at the time of measurement, and the aeration tank (A) It is possible to accurately measure the amount of off-gas generated in

Although the embodiments of the present invention have been described with reference to the accompanying drawings, those skilled in the art to which the present invention pertains can be implemented in other specific forms without changing the technical spirit or essential features of the present invention. you will be able to understand Therefore, it should be understood that the embodiments described above are illustrative in all respects and not restrictive.

1: Off-gas measuring device that operates in response to the level of wastewater in the aeration tank
10: diffusion pipe 20: column part
30: water level sensor unit 301: first water level sensor
302: second water level sensor 303: third water level sensor
40: collection unit
410: connector 50: water separation unit
510: first water separator 511: first suction pipe
512: first discharge pipe
520: second water separator 521: by-product gas transfer pipe
522: by-product gas discharge pipe
60: pump type measurement unit
601: first valve 602: second valve
603: third valve 604: flow control valve
605: suction pump 606: water removal filter
607: flow meter 608: calculation module
609: sensor module 610: antenna
A: aeration tank B: wastewater

Claims (4)

a diffuser 10 installed at the lower end of the aeration tank A to supply oxygen;
A column part 20 installed at a height higher than the height of the wastewater filled in the aeration tank (A);
A water level sensor unit including a plurality of water level sensors installed on one side of the column part 20 at regular intervals to generate different signals depending on whether wastewater is detected and transmit the generated signals through wired or wireless communication. (30);
The upper surface is connected to the connection pipe 410, which is the movement path of by-product gas, and the lower surface collects the by-product gas generated from the wastewater filled in the aeration tank (A) (40);
A first valve 601 having one end connected to the first discharge pipe 512 to control air discharged from the first discharge pipe 512;
A second valve 602 having one end connected to the by-product gas discharge pipe 522 to control the by-product gas discharged from the by-product gas discharge pipe 522;
One end is connected to the by-product gas discharge pipe 522 to control the air discharged from the by-product gas discharge pipe 522, and is connected to the third valve 603 and the first valve 601 and the second valve 602 to generate suction power. and the suction power is selectively transmitted to the first valve 601 or the second valve 602 so that air is sucked through the first valve 601 and by-product gas is sucked through the second valve 602 A suction pump 605 to do,
A sensor module 609 having a default value set therein and being connected to the suction pump 605 to detect air and by-product gas discharged from the suction pump 605;
A memory 6081 for detecting the air in the sensor module 609 and storing the oxygen concentration and carbon dioxide concentration of the measured air as basic values for measurement;
When wastewater is detected by any one of the plurality of water level sensors, the first valve 601 and the second valve 602 are opened, the third valve 603 is closed, and the default value set in the sensor module 609 is set. An off-gas measuring device that operates in response to the wastewater level in an aeration tank, including a pump-type measuring unit 60 equipped with an arithmetic module 608 that changes to a basic measurement value stored in a memory 6081. According to claim 1,
The water level sensor unit 30,
It includes a first water level sensor 301 and a second water level sensor 302,
The calculation module 608,
When wastewater is detected by the first water level sensor 301, a first measurement basic value is set in the sensor module 609, and when wastewater is detected by the second water level sensor 302, a second measurement value is set in the sensor module 609. An off-gas measuring device that operates in response to the wastewater level in the aeration tank, setting the default measurement value. According to claim 1,
The first moisture separator 510 connected to the first suction pipe 511 and the first discharge pipe 512 to separate moisture in the air through the first suction pipe 511 and then discharge the air through the first discharge pipe 512. ), the by-product gas pipe 521, and the by-product gas discharge pipe 522, and after separating moisture from the by-product gas flowing through the by-product gas pipe 521, the by-product gas is discharged through the by-product gas discharge pipe 522. An off-gas measuring device that operates in response to the wastewater level in the aeration tank, including a water separator 50 including a second water separator 520. According to claim 1,
The first valve 601,
While maintaining the closed state, when one of the plurality of water level sensors (301 to 303) detects wastewater, it is switched to the open state,
The second valve 602,
It maintains the closed state, and when one of the plurality of water level sensors 301 to 303 detects wastewater, it is switched to the open state,
The third valve 603,
An off-gas measuring device that operates in response to the wastewater level in an aeration tank, which maintains an open state and switches to a closed state when one of the plurality of water level sensors 301 to 303 detects wastewater.

Images