KR20230015040A - Device for the Risk Management of Wastewater Treatment Plant and Method for the Risk Management of Wastewater Treatment Plant - Google Patents

Abstract

A crisis management system of a sewage and wastewater treatment facility according to the present invention is installed in the sewage and wastewater treatment facility, which treats sewage and wastewater through a biological nutrient removal (BNR) process to perform crisis management. The crisis management system comprises: a crisis management bioreactor equipped to accommodate detection water having the same properties as a reaction solution accommodated in a reaction tank provided in the sewage and wastewater treatment facility; a dissolved oxygen (DO) sensor provided in the crisis management bioreactor to detect the amount of dissolved oxygen (DO) in the detection water mixed with the reaction solution and sewage and wastewater in the crisis management bioreactor; a dissolved oxygen (DO) analysis unit converting the amount of dissolved oxygen (DO) in the detected water into data through a measured value of the dissolved oxygen (DO) sensor; and a control server receiving the data on the amount of dissolved oxygen (DO) converted into the data by the dissolved oxygen (DO) analysis unit to control the system. According to the present invention, it can be usefully utilized to minimize economic losses.

Description

Risk Management of Wastewater Treatment Plant and Method for the Risk Management of Wastewater Treatment Plant}

The present invention relates to a crisis management system for sewage and wastewater treatment facilities and a crisis management method for sewage and wastewater treatment facilities using the same, and more particularly, to a normal state due to the inflow of harmful substances into the sewage and wastewater treatment facilities or the continuous overload of organic matter. When operation is difficult, it is about a crisis management system for sewage and wastewater treatment facilities that detects it early and responds to the crisis, and a crisis management method for sewage and wastewater treatment facilities using it.

In general, sewage and wastewater discharged from households and various industrial facilities are moved to sewage and wastewater treatment facilities and undergo a series of treatment processes.

However, sewage and wastewater treatment facilities operated by Biological Nutrient Removal (BNR) can damage microorganisms in the bioreactor and cause abnormalities in the treatment process if the influent contains harmful substances. Driving becomes difficult, which can cause time and economic damage.

In addition, even in the case of an overload inflow in which influent flows in at a higher concentration than normal or exceeds the capacity of the sewage and wastewater treatment facility, the treatment efficiency of the reaction tank decreases, which can deteriorate the quality of effluent water and the economic cost to restore the system. this will happen

Conventional management of sewage and wastewater treatment facilities mainly relies on water quality analysis of influent and effluent, but the items that can be measured in real time in influent are simply temperature, pH, and DO (Dissolved Oxygen). ·When the condition of the wastewater treatment facility was identified, since the performance of the wastewater treatment facility has already deteriorated, considerable economic costs and time are required for its recovery.

In order to identify the cause of performance degradation in advance, it is necessary to measure whether or not harmful substances and toxic substances are contained in the influent. However, this requires expensive analysis equipment, and sample transfer even if equipment, analysis techniques and technology are equipped. When the results of the analysis come out, the performance of sewage and wastewater treatment facilities has already suffered damage.

In addition, when organic matter is overloaded in the influent for some reason, the point in time to identify and deal with it is after the performance of the sewage and wastewater treatment facilities has already deteriorated and the water quality standard of the effluent is exceeded, and this is also the current BOD ( This is because concentration analysis such as Biochemical Oxygendemand and COD (Chemical Oxygendemand) is difficult to perform in real time.

Therefore, as a prior art for the purpose of utilizing real-time measurement data of the amount of dissolved oxygen in order to solve this problem, 'DO real-time recording system and recording method' is disclosed in Korean Patent Publication No. 10-2007-0067443.

However, this technology simply relates to a real-time recording system for the amount of dissolved oxygen that can automatically record the concentration of the amount of dissolved oxygen in real time and its recording method. It has the disadvantage that it is difficult to know the exact value for a given sample because there is no injection of microorganisms.

Therefore, it is difficult to quickly cope with contamination in sewage and wastewater treatment facilities, and it can be used in a limited way to determine the existence of toxic substances.

As another prior art different from this, Korean Patent Registration No. 10-2199409 discloses a 'system and method for real-time monitoring of heavy metal concentration in water'. This technology monitors the concentration of heavy metals in water by measuring the degree of scattering when radiation emitted from a radiation source meets heavy metals in water and is scattered.

However, this technology can help determine the total amount of heavy metals in water, but has limitations in selectively identifying harmful heavy metals that affect the performance of sewage and wastewater treatment facilities.

As another prior art, Korean Patent Registration No. 10-1482624 discloses 'device and method for continuously monitoring target harmful substances in water'. It continuously measures the concentration of the target substance present in the water system by using a receptor that can selectively recognize the target substance, a porous membrane in which the receptor is fixed, and a sensing unit that continuously measures the fluorescence signal intensity of the target substance that reacts with the receptor. However, it is limited to the recognition of only the target substance, and the technology is complicated, so reproducibility is low, and it is difficult to apply in the field.

Therefore, a method for solving these problems is required.

Korean Patent Publication No. 10-2007-0067443 Korean Patent Registration No. 10-2199409 Korean Patent Registration No. 10-1482624

The present invention is an invention made to solve the problems of the prior art described above, and in sewage and wastewater treatment facilities including various types of wastewater treatment processes, unexpected harmful substances are introduced or high concentrations that exceed the design value excessively. Sewage and wastewater that can contribute to the smooth operation of all sewage and wastewater treatment facilities by early detection and blocking of accidents in which microorganisms in the aeration tank are shocked by the inflow of organic matter and function is lost or the performance of the treatment facility is deteriorated due to excessive function degradation It aims to provide a crisis management system for treatment facilities and a risk management method for sewage and wastewater treatment facilities using the same.

The tasks of the present invention are not limited to the tasks mentioned above, and other tasks not mentioned will be clearly understood by those skilled in the art from the following description.

The crisis management system of sewage and wastewater treatment facilities of the present invention for achieving the above object is installed in sewage and wastewater treatment facilities that treat sewage and wastewater through a biological advanced treatment process (BNR: Biological Nutrient Removal) for crisis management. As to perform, a crisis management bioreactor provided to accommodate sewage and wastewater having the same properties as the sewage and wastewater flowing into the reaction tank provided in the sewage and wastewater treatment facility, and the reaction liquid and Ha in the crisis management bioreactor Detection water mixed with wastewater, a DO sensor provided in the crisis management bioreactor to detect the amount of dissolved oxygen (DO, Dissolved Oxygen) in the detection water, and converting the amount of dissolved oxygen in the detection water into data through the measured value of the DO sensor It includes a dissolved oxygen amount analyzer and a control server that controls the system by receiving the dissolved oxygen amount data converted into data by the dissolved oxygen amount analyzer.

At this time, the crisis management bioreactor is formed to receive the sludge returned from the sedimentation tank provided in the sewage and wastewater treatment facility, and detects water having the same distribution of microorganisms as the reaction solution contained in the reaction tank provided in the wastewater treatment facility. It can be formed to maintain the properties of.

In addition, the crisis management bioreactor may be formed such that a part of the inflow water flowing into the sewage and wastewater treatment facility is selectively introduced.

In addition, the effluent discharged from the crisis management bioreactor may be formed to join an external return flow path returned from the settling tank to the anaerobic tank provided in the sewage and wastewater treatment facility.

In addition, the crisis management bioreactor may include an aeration unit for controlling a blower to maintain the amount of dissolved oxygen in the detection water.

On the other hand, the control server, when it is determined that the amount of dissolved oxygen in real time exceeds a preset upper limit reference value or is determined to be less than a preset lower limit reference value, blocks the inflow water flowing into the sewage and wastewater treatment facility, and can be controlled to stop the operation of

In addition, when the control server determines that the amount of dissolved oxygen exceeds a preset upper limit reference value or is determined to be less than a preset lower limit reference value in real time, a crisis management server provided to establish countermeasures and a mobile terminal owned by a manager It may include an alarm unit for performing an alarm on at least one of the above.

In addition, when the control server determines that the amount of dissolved oxygen in real time exceeds a preset upper limit reference value or is determined to be less than a preset lower limit reference value, the control server may control the detection water accommodated in the crisis management bioreactor to be replaced with a new one.

And the control server may control the crisis management bioreactor to be operated under the same conditions as the sewage and wastewater treatment facilities.

In addition, in the crisis management method of sewage and wastewater treatment facilities of the present invention for achieving the above object, the control server detects water having the same properties as the reaction liquid contained in the reaction tank provided in the sewage and wastewater treatment facilities. (a) step of introducing into the reactor, (b) detecting the amount of dissolved oxygen in the detection water in which the reaction liquid and sewage/wastewater are mixed in the crisis management bioreactor through the DO sensor provided in the crisis management bioreactor, Step (c) of converting the amount of dissolved oxygen in the detection water into data through the dissolved oxygen amount analysis unit through the measured value of the DO sensor, and the control server receiving the dissolved oxygen amount data converted into data by the dissolved oxygen amount analyzer and controlling the system ( d) step.

At this time, in the step (a), the control server controls the sludge returned from the settling tank provided in the wastewater treatment facility and a part of the inflow water flowing into the wastewater treatment facility to flow into the crisis management bioreactor. You can control it.

In addition, in the step (d), when the real-time dissolved oxygen content is determined to be greater than a preset upper limit reference value or less than a preset lower limit reference value by the control server, step (e) of the control server performing a follow-up action more can be done.

Here, in the step (e), the control server may control the inflow water flowing into the sewage/wastewater treatment facility to be blocked and the operation of the sewage/wastewater treatment facility to be stopped.

In the step (e), the control server may control the alarm unit to alarm at least one of the crisis management server and the mobile terminal owned by the manager, which are prepared to play a role of establishing countermeasures.

In addition, in the step (e), the control server may control the detection number accommodated in the crisis management bioreactor to be replaced with a new one.

The crisis management system for sewage and wastewater treatment facilities and the crisis management method for sewage and wastewater treatment facilities using the same of the present invention for solving the above problems are detected by the DO sensor provided in the crisis management bioreactor and analyze the amount of dissolved oxygen. Through this, the dissolved oxygen amount data converted into data can be monitored in real time on the control server, and in this process, when the real-time dissolved oxygen amount exceeds the preset upper limit value or does not reach the preset lower limit value, prompt action is possible automatically. In addition, it has the advantage of preventing in advance various damages such as the death of microorganisms and performance degradation of treatment facilities due to the inflow of harmful substances into sewage and wastewater treatment facilities or overload.

In addition, the present invention establishes countermeasures by recognizing in advance that harmful substances are unexpectedly introduced into the influent or overloaded in all biological sewage and wastewater treatment facilities using microorganisms such as sewage, manure, livestock wastewater, and industrial wastewater, resulting in damage. By doing so, it can be usefully used to minimize economic losses.

The effects of the present invention are not limited to the effects mentioned above, and other effects not mentioned will be clearly understood by those skilled in the art from the description of the claims.

1 is a diagram showing the configuration of a crisis management system for sewage and wastewater treatment facilities according to an embodiment of the present invention;
2 is a graph illustrating a state in which the amount of dissolved oxygen changes in real time over time in a crisis management system for a sewage and wastewater treatment facility according to an embodiment of the present invention; and
3 is a diagram showing each process of the risk management method of sewage and wastewater treatment facilities according to an embodiment of the present invention.

Hereinafter, a preferred embodiment of the present invention in which the object of the present invention can be realized in detail will be described with reference to the accompanying drawings. In describing the present embodiment, the same name and the same reference numeral are used for the same configuration, and additional description thereof will be omitted.

1 is a diagram showing the configuration of a crisis management system for sewage and wastewater treatment facilities according to an embodiment of the present invention.

As shown in FIG. 1, the crisis management system of a wastewater treatment facility according to an embodiment of the present invention is a wastewater treatment facility that treats wastewater through a biological advanced treatment process (BNR: Biological Nutrient Removal). It is installed in (10) and is equipped to perform crisis management, and is formed in the form of a small-scale model that maintains the same microbial composition and operating conditions as the reaction tank in order to prevent the inability to treat the wastewater treatment facility (10) from various threats. and enable an effective response to crises.

To this end, the crisis management system of sewage and wastewater treatment facilities according to an embodiment of the present invention includes a crisis management bioreactor 100, a DO sensor 110, a dissolved oxygen amount analyzer 120, and a control server 200. .

The crisis management bioreactor 100 is provided to receive detection water having the same properties as the reaction liquid contained in the reaction tank provided in the sewage and wastewater treatment facility 10, and the DO sensor 110 is such a crisis management bioreactor ( 100) and serves to detect the amount of dissolved oxygen (DO, Dissolved Oxygen) in the detection water in which the reaction liquid and sewage/wastewater are mixed in the crisis management bioreactor 100.

In addition, the dissolved oxygen amount analyzer 120 converts the amount of dissolved oxygen in the detected water into data through the measured value of the DO sensor 110, and the control server 200 transmits the dissolved oxygen amount data converted into data by the dissolved oxygen amount analyzer 120. and take control of the system.

In addition, the control server 200 may control the crisis management bioreactor 100 to be operated under the same conditions as the sewage and wastewater treatment facility 10. For example, the crisis management bioreactor 100 can be controlled under the same conditions as the hydraulic retention time (HRT), agitation speed, organic matter load, etc. of the wastewater treatment facility 10, and through this, the crisis management bioreactor 100 The volume of detection water in the reactor 100 may vary.

For example, the capacity of the crisis management bioreactor 100 is based on the range of 1 to 10 m ³ /d according to the capacity of the sewage and wastewater treatment facility 10, but in the case of a large-scale sewage and wastewater treatment facility, the capacity as needed can increase

And in this embodiment, the crisis management bioreactor 100 is formed to receive the returned sludge returned from the sedimentation tank 20 provided in the sewage and wastewater treatment facility 10, and has the same properties as the reaction solution contained in the reaction tank. It can be formed to hold. At this time, the same component means that the concentration of Mixed Liquer Suspended Solid (MLSS) and the composition of aerobic microorganisms are the same.

In addition, along with this, the crisis management bioreactor 100 may be formed so that a part of the inflow water flowing into the sewage and wastewater treatment facility 10 is selectively introduced.

In addition, the effluent discharged from the crisis management bioreactor 100 may be formed to join an external conveying passage that is returned from the sedimentation tank 20 to the anaerobic tank provided in the sewage and wastewater treatment facility 10.

Additionally, in the present embodiment, the crisis management bioreactor 100 may include an aeration unit (not shown) for controlling a blower to maintain the amount of dissolved oxygen in the detected water.

Meanwhile, the DO sensor 110 may be installed at a location capable of representing the DO value of the detected water stored in the crisis management bioreactor 100, and the dissolved oxygen amount data generated by the dissolved oxygen amount analyzer 120 is stored in the control server. It is transmitted to the (200) side and recorded, and real-time monitoring is performed.

The oxygen consumption of the aerobic microorganisms in the crisis management bioreactor 100 varies depending on the properties of the inflow water, and the activity of the aerobic microorganisms is confirmed by the amount of dissolved oxygen measured by the DO sensor 110. At this time, the properties of the influent mean the content of organic matter that can be utilized as nutrients by aerobic microorganisms and the type and content of harmful substances that can inhibit the activity of aerobic microorganisms.

When overload inflow occurs due to an increase in the organic matter content in the influent, the aerobic digestion process by aerobic microorganisms is promoted, the amount of dissolved oxygen in the crisis management bioreactor 100 is reduced, and the overload inflow due to the increase in the organic matter content in the influent continues. , the system treatment efficiency may be lowered, which may lead to deterioration of water quality.

In addition, when the influent contains more than a certain amount of harmful substances, aerobic microorganisms may die, and when the activity of aerobic microorganisms is weakened, oxygen consumption by aerobic microorganisms is lowered, and the amount of dissolved oxygen in the crisis management bioreactor 100 may increase. . At this time, harmful substances that weaken the activity of aerobic microorganisms include heavy metals such as arsenic (As), cadmium (Cd), lead (Pb), chromium (Cr), and mercury (Hg), excessive amounts of ammonia nitrogen, and phenolic compounds. applicable

Meanwhile, the control server 200 may perform various follow-up measures when it is determined that the real-time dissolved oxygen amount transmitted from the dissolved oxygen amount analyzer 120 is greater than a preset upper limit reference value or less than a preset lower limit reference value. .

As shown in FIG. 2, in the process of monitoring the amount of dissolved oxygen in the crisis management bioreactor 100 in real time, when toxic substances are introduced, the amount of dissolved oxygen gradually increases, and when high concentration organic matter is introduced, the amount of dissolved oxygen is increased. will gradually decrease.

Thereafter, when the real-time dissolved oxygen amount exceeds the preset upper limit reference value C1 at the first time point T1 or the real-time dissolved oxygen amount falls below the preset lower limit reference value C2 at the second time point T2, the control server ( 200) can perform various follow-up actions from that point.

First, when the control server 200 determines that the real-time dissolved oxygen amount transmitted from the dissolved oxygen amount analyzer 120 is greater than a preset upper limit reference value or less than a preset lower limit reference value, the sewage and wastewater treatment facility 10 It is possible to block the inflow water flowing into and stop the operation of the sewage and wastewater treatment facility 10.

In addition, the control server 200 may include an alarm unit 210, and therefore, when it is determined that the amount of dissolved oxygen in real time exceeds a preset upper limit reference value or is determined to be less than a preset lower limit reference value, it serves to establish countermeasures. An alert may be issued to at least one of the prepared crisis management server 300 and a mobile terminal (not shown) owned by the manager.

In addition, the control server 200, when it is determined that the amount of dissolved oxygen in real time exceeds a preset upper limit reference value or is determined to be less than a preset lower limit reference value, discharges the detected water accommodated in the crisis management bioreactor 100 and returns new sludge. It can be controlled so that it is filled and operated in a state in which the entire detection water is replaced. At this time, the discharged detection water may undergo a separate treatment process before being introduced into the sewage and wastewater treatment facility 10 .

Next, a risk management method for sewage and wastewater treatment facilities using the crisis management system for sewage and wastewater treatment facilities according to an embodiment of the present invention described above will be described.

3 is a diagram showing each process of the risk management method of sewage and wastewater treatment facilities according to an embodiment of the present invention.

As shown in FIG. 3, in the crisis management method for sewage and wastewater treatment facilities according to an embodiment of the present invention, the control server 200 controls the reaction liquid contained in the reaction tank provided in the sewage and wastewater treatment facility 10 and In the step (a) of introducing detection water having the same properties into the crisis management bioreactor 100, and in the crisis management bioreactor 100 through the DO sensor 110 provided in the crisis management bioreactor 100 Step (b) of detecting the amount of dissolved oxygen in the detection water in which the reaction solution and sewage/wastewater are mixed, and the dissolved oxygen amount analyzer 120 converting the amount of dissolved oxygen in the detection water into data through the measured value of the DO sensor 110 ( Step c) and step (d) in which the control server 200 controls the system by receiving the data of the amount of dissolved oxygen converted into data by the amount of dissolved oxygen analyzer 120 .

And when it is determined by the control server 200 in step (d) that the amount of dissolved oxygen in real time exceeds the preset upper limit reference value or is determined to be less than the preset lower limit reference value, the control server 200 performs follow-up actions ( Step e) may be further performed.

More specifically, in step (a), the control server 200 controls the sludge returned from the sedimentation tank provided in the wastewater treatment facility 10 and a portion of the inflow water flowing into the wastewater treatment facility 10 in a crisis. It may be made by controlling the flow into the management bioreactor 100.

At this time, as described above, the control server 200 may control the crisis management bioreactor 100 to be operated under the same conditions as the sewage and wastewater treatment facility 10.

For example, in this embodiment, the crisis management bioreactor 100 may be in the form of a reactor in which only an aeration tank exists in the standard activated sludge process, and in this case, the detection water in the crisis management bioreactor 100 has a residence time of 4-8 hours and a mixed solution suspension. The solid concentration can be maintained at 2,000-4,000 mg/L and the dissolved oxygen concentration at 2-3 mg/L.

On the other hand, in step (e) in which the control server 200 performs follow-up measures, the control server 200 blocks the inflow water flowing into the sewage and wastewater treatment facility 10, and operates the sewage and wastewater treatment facility 10. can be controlled to stop.

In addition, in step (e), the alarm unit 210 performs an alarm to at least one of the crisis management server 300 and the mobile terminal owned by the manager, which are prepared so that the control server 200 plays a role in establishing countermeasures. can control.

In addition, in step (e), the control server 200 may control the detection number accommodated in the crisis management bioreactor 100 to be replaced with a new one.

Here, the preset upper and lower limit reference values for step (e) may be based on when the concentration of dissolved oxygen in the general range of the crisis management bioreactor 100 exceeds ± 2 to 3 mg / L, but if necessary Considering the characteristics of the sewage and wastewater treatment facility 10, the limits of the upper and lower limits may be adjusted.

As described above, the preferred embodiments according to the present invention have been reviewed, and the fact that the present invention can be embodied in other specific forms without departing from the spirit or scope in addition to the above-described embodiments is a matter of ordinary knowledge in the art. It is self-evident to them. Therefore, the embodiments described above are to be regarded as illustrative rather than restrictive, and thus the present invention is not limited to the above description, but may vary within the scope of the appended claims and their equivalents.

10: Sewage and wastewater treatment facilities
20: sedimentation tank
100: crisis management bioreactor
110: DO sensor
120: dissolved oxygen amount analysis unit
200: control server
210: alarm unit
300: crisis management server

Claims (15)

In the crisis management system installed in a sewage and wastewater treatment facility that treats sewage and wastewater through a biological advanced treatment process (BNR: Biological Nutrient Removal) and performs crisis management,
Crisis management bioreactor provided to accommodate detection water having the same properties as the reaction liquid contained in the reaction tank provided in the sewage and wastewater treatment facility;
a DO sensor provided in the crisis management bioreactor and detecting dissolved oxygen (DO) in the detection water in which the reaction liquid and sewage/wastewater are mixed in the crisis management bioreactor;
a dissolved oxygen amount analyzer configured to form data on the amount of dissolved oxygen in the detection water through the measured value of the DO sensor; and
a control server that controls the system by receiving the dissolved oxygen amount data converted into data by the dissolved oxygen amount analyzer;
including,
Crisis management system for sewage and wastewater treatment facilities. According to claim 1,
The crisis management bioreactor,
It is formed to receive the returned sludge returned from the sedimentation tank provided in the sewage and wastewater treatment facility and is formed to maintain the properties of the detection water having the same microbial distribution as the reaction liquid contained in the reaction tank,
Crisis management system for sewage and wastewater treatment facilities. According to claim 1,
In the crisis management bioreactor,
Formed so that a part of the influent flowing into the sewage and wastewater treatment facility is selectively introduced,
Crisis management system for sewage and wastewater treatment facilities. According to claim 1,
The effluent from the crisis management bioreactor is formed to join the external conveying passage returned from the sedimentation tank provided in the wastewater treatment facility to the anaerobic tank provided in the wastewater treatment facility,
Crisis management system for sewage and wastewater treatment facilities. According to claim 1,
The crisis management bioreactor is provided with an aeration unit for controlling a blower to maintain the amount of dissolved oxygen in the detection water.
Crisis management system for sewage and wastewater treatment facilities. According to claim 1,
The control server,
When the amount of dissolved oxygen in real time is determined to be greater than the preset upper limit value or less than the preset lower limit value, the inflow water flowing into the sewage and wastewater treatment facility is blocked, and the operation of the sewage and wastewater treatment facility is stopped. doing,
Crisis management system for sewage and wastewater treatment facilities. According to claim 1,
The control server,
When it is determined that the amount of dissolved oxygen exceeds the preset upper limit reference value or is determined to be less than the preset lower limit reference value in real time, at least one of the crisis management server and the mobile terminal owned by the manager are provided to establish countermeasures. Including an alarm unit that performs an alarm,
Crisis management system for sewage and wastewater treatment facilities. According to claim 1,
The control server,
When the real-time dissolved oxygen amount is determined to be greater than a preset upper limit reference value or less than a preset lower limit reference value, controlling the detection water received in the crisis management bioreactor to be replaced with a new one,
Crisis management system for sewage and wastewater treatment facilities. According to claim 1,
The control server,
Controlling the crisis management bioreactor to be operated under the same conditions as the sewage and wastewater treatment facility,
Crisis management system for sewage and wastewater treatment facilities. In the risk management method of sewage and wastewater treatment facilities through a crisis management system that is installed in sewage and wastewater treatment facilities that treat sewage and wastewater through Biological Nutrient Removal (BNR) and performs risk management,
(a) step of allowing the control server to introduce detection water having the same properties as the reaction liquid contained in the reaction tank provided in the sewage and wastewater treatment facility into the crisis management bioreactor;
(b) detecting the amount of dissolved oxygen in the detection water in which the reaction liquid and sewage/wastewater are mixed in the crisis management bioreactor through a DO sensor provided in the crisis management bioreactor;
(c) converting the amount of dissolved oxygen in the detection water into data through a dissolved oxygen amount analyzer using the measured value of the DO sensor; and
(d) the control server controlling the system by receiving the data of the amount of dissolved oxygen converted into data by the amount of dissolved oxygen analyzer;
including,
Crisis management method of sewage and wastewater treatment facilities. According to claim 10,
In step (a),
The control server controls the sludge returned from the settling tank provided in the wastewater treatment facility and a part of the inflow water flowing into the wastewater treatment facility to flow into the crisis management bioreactor,
Crisis management method of sewage and wastewater treatment facilities. According to claim 10,
In the step (d), when it is determined by the control server that the amount of dissolved oxygen in real time exceeds a preset upper limit reference value or is determined to be less than a preset lower limit reference value,
The step (e) of performing the follow-up by the control server is further performed,
Crisis management method of sewage and wastewater treatment facilities. According to claim 12,
In step (e),
Controlling the control server to block inflow water flowing into the sewage and wastewater treatment facility and to stop the operation of the sewage and wastewater treatment facility,
Crisis management methods for sewage and wastewater treatment facilities. According to claim 12,
In step (e),
Controlling the alarm unit to alert at least one of the crisis management server and the mobile terminal owned by the manager, which is provided so that the control server plays a role in establishing countermeasures.
Crisis management methods for sewage and wastewater treatment facilities. According to claim 12,
In step (e),
The control server controls the detection water accommodated in the crisis management bioreactor to be replaced with a new one.
Crisis management methods for sewage and wastewater treatment facilities.

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