CN115108594A - Sewage automatic detection management system based on high in clouds remote control - Google Patents

Abstract

The invention discloses a sewage automatic detection management system based on cloud remote control, which comprises a cloud service module, a client, a detection module, a meteorological module, a prediction module, an adjustment module and an anomaly detection module. The invention can judge whether sewage can be discharged into nearby rivers through simulation calculation, avoids polluting the environment of the nearby rivers, can prejudge weather through the meteorological module, and reasonably regulate the discharge pipeline of the sewage through the prejudging result, can maximize the use of the discharge pipeline of the sewage, and prolong the service life of the discharge pipeline of the sewage.

Description

Sewage automatic detection management system based on high in clouds remote control

Technical Field

The invention relates to the technical field of sewage, in particular to a sewage automatic detection management system based on cloud remote control.

Background

With the rapid development of urban economy, the material life of common people is improved, but adverse effects are brought, wherein the most affected is the increase of sewage. The sewage is the effluent water from life and production which is polluted to a certain extent, and the water which loses the original use function is simply called the sewage. Mainly used water in life, which contains more organic matters and is easy to treat. Generally, the sewage is collected by urban canals and is discharged into water after being treated by an urban sewage treatment plant. At present, the sewage can be discharged into nearby water bodies only when the discharge of the sewage reaches the national discharge standard, otherwise, the living environment is influenced.

In the prior art, the content in sewage is measured, if the content in the sewage reaches the discharge standard, the sewage is discharged into a nearby water body, but the self-purification capacity of the nearby water body is different along with the change of seasons, temperature, water flow velocity and the like, and if the self-purification capacity of the nearby water body is not monitored, the environment of the water body is greatly influenced.

Disclosure of Invention

The invention aims to provide a cloud remote control-based automatic sewage detection and management system to solve the problems in the background technology.

In order to solve the technical problems, the invention provides the following technical scheme: a sewage automatic detection management system based on cloud remote control comprises a cloud service module, a client, a component detection module, a meteorological module, a prediction module, an adjustment module and an anomaly detection module, wherein the cloud service module is used for carrying out platform type management on the system, the client is used for carrying out manual control on the system, the component detection module is used for detecting urban sewage, the meteorological module is used for detecting weather, the prediction module is used for judging the flow of the urban sewage according to the weather, the adjustment module is used for adjusting the flow and treatment of the urban sewage, the anomaly detection module is used for checking the system when the urban sewage is treated, the output end of the cloud service module is electrically connected with the input ends of the client, the component detection module, the meteorological module, the prediction module, the adjustment module and the anomaly detection module, the input end of the cloud service module is electrically connected with the output ends of the client, the component detection module, the meteorological module, the prediction module, the regulation module and the abnormality detection module, and the output end of the prediction module is electrically connected with the input ends of the meteorological module and the regulation module.

Further, the cloud service module includes an information transceiver unit and a storage unit, the information transceiver unit is configured to perform transceiver processing on data, and the storage unit is configured to store the data.

Further, the client includes a display unit and a control unit, the display unit is used for searching data, and the control unit is used for modifying data.

Further, the component detection module comprises a heavy metal detection unit, a data collection unit, a data analysis unit and a sewage discharge simulation unit, wherein the heavy metal detection unit is used for detecting heavy metals in sewage to be discharged, the data collection unit is used for collecting relevant data of a river, the data analysis unit is used for analyzing the detected and collected data, and the data analysis process is as follows:

the method comprises the following steps that X tons of sewage to be discharged exist, the content of heavy metal in each ton of sewage to be discharged is Y, and the total content N of heavy metal in X tons of sewage is N = XY;

s is the flow velocity of the sewage discharge river, M is the flow distance, T is the flow time, and the water flow velocity of the river can be obtained according to the formula S =;

and R is the current water body temperature, M is the current month, and the water body temperature R and the month M of the river at the moment are measured and recorded.

Further, the sewage discharge simulation unit simulates the heavy metal content N in X tons of sewage purified by the current river according to the obtained data, and records the time T required for purifying each ton of sewage _X And calculating the moving distance H when each ton of sewage is purified by the formula H = T _X S can obtain the moving distance of the sewage, and compares the moving distance with the time length for purifying the heavy metal content in the same sewage in the historical data under the same flow speed, temperature, month and distance, if T is T _X 1 is the current time length for sewage purification, T _X 2 is the historical sewage purification time, when T _X 1>T _X 2, it indicates that the sewage can be discharged into the river, when T is _X 1<T _X 2, it means that the sewage cannot be discharged into the river, otherwise the environment of the river is polluted.

Further, the weather module includes real-time detection unit and data transmission unit, real-time detection unit is used for carrying out real-time supervision to weather, data transmission unit is used for transmitting the weather data that detect.

Further, the prediction module includes a first comparison unit, a first database and a judgment unit, the first database is used for storing the received weather data, the first comparison unit is used for comparing the received weather data with historical weather data in the first database, and the judgment unit is used for judging whether rainy season occurs in the current weather.

Further, the flow regulating unit comprises a valve controller, a first flow sensor and a first central processing unit, and the data analysis process is as follows:

the valve controller comprises a valve A, a valve B and a valve C;

if the rainy season is predicted, the central processing unit enables the valve controller to open the valve A and the valve B;

if no rainy season is predicted, the central processing unit enables the valve controller to open the valve A;

the flow sensor is used for calculating the real-time flow of the sewage;

q is sewage flow, Q ₁ 、Q ₂ 、Q ₃ Rated value for sewer pipe flow, and Q ₁ <Q ₂ <Q ₃ S is the cross-sectional area of the pipeline, and v is the flow velocity of the sewage;

calculating the real-time sewage flow by the formula Q = Sv;

a) when Q is ₂ ≧Q≧Q ₁ At the moment, the central processing unit enables the valve controller to open the valve A;

b) when Q is ₃ >Q>Q ₂ At the moment, the central processing unit enables the valve controller to open the valve A and the valve B;

c) when Q ≧ Q ₃ At this time, the central processing unit makes the valve controller open the valve A, the valve B and the valve C.

Further, the zone adjusting unit comprises a pipeline controller, a second flow sensor and a second central processing unit, and the data analysis is as follows:

the pipeline controller comprises a pipeline D, a pipeline E and a pipeline F, the second flow sensor monitors the flow in each pipeline in real time, and the sewage flow in the pipeline D is Q _D And the sewage flow inside the E pipeline is Q _E The sewage flow in the F pipeline isQ _F And transmitting the information to a second central processing unit in real time, the second central processing unit monitoring the flow in the D pipeline, the E pipeline and the F pipeline,

if Q _D >Q _E >Q _F Communicating the D pipeline with the F pipeline by using the pipeline controller, draining sewage in the D pipeline, and reducing the sewage flow in the D pipeline;

②Q _D >Q _F >Q _E communicating the D pipeline with the E pipeline by using the pipeline controller, draining sewage in the D pipeline, and reducing the sewage flow in the D pipeline;

③Q _E >Q _D >Q _F communicating the pipeline E with the pipeline F by using the pipeline controller, draining sewage in the pipeline E, and reducing the sewage flow in the pipeline E;

④Q _E >Q _F >Q _D communicating the pipeline E with the pipeline D by using the pipeline controller, draining sewage in the pipeline E, and reducing the sewage flow in the pipeline E;

⑤Q _F >Q _E >Q _D communicating the F pipeline with the D pipeline by using the pipeline controller, draining sewage in the F pipeline, and reducing the sewage flow in the F pipeline;

⑥Q _F >Q _D >Q _E and then the pipeline controller is used for communicating the F pipeline with the E pipeline, draining sewage in the F pipeline and reducing sewage flow in the F pipeline.

Further, the abnormity detection module comprises a detection unit, an alarm unit and an emergency processing unit, wherein the detection unit is used for detecting each pipeline, the alarm unit is used for warning under the abnormal condition, the emergency processing unit is used for taking emergency processing measures under the abnormal condition, and when the detection unit detects that the pipeline is in a problem and cannot drain, the alarm unit is started to warn relevant workers, the emergency processing unit is used for closing the valve of the pipeline, stopping the operation of the pipeline, opening the pipeline and the drainage valve of other pipelines, and draining the sewage in the pipeline.

Compared with the prior art, the invention has the following beneficial effects:

1. according to the invention, by arranging the cloud service module, the client, the component detection module, the meteorological module, the prediction module and the regulation module, whether sewage can be discharged into a nearby river can be judged through simulation calculation, so that the pollution to the environment of the nearby river is avoided, the weather can be pre-judged through the meteorological module, the discharge pipeline of the sewage is reasonably regulated through the pre-judgment result, the discharge pipeline of the sewage can be maximally used, the service life of the discharge pipeline of the sewage is prolonged, and the discharge flow direction of the sewage in the discharge pipeline can be regulated according to the flow in each discharge pipeline through the regulation module, so that the discharge rate of the sewage is increased.

2. According to the invention, by arranging the abnormality detection module, each sewage pipeline in the system can be detected, and a corresponding processing mode is made when an accident occurs, so that the safety of the system in use is improved.

Drawings

The accompanying drawings, which are included to provide a further understanding of the invention and are incorporated in and constitute a part of this specification, illustrate embodiments of the invention and together with the description serve to explain the principles of the invention and not to limit the invention. In the drawings:

FIG. 1 is a block diagram of the invention as a whole;

in the figure: 1. a cloud service module; 2. a client; 3. a component detection module; 4. a weather module; 5. a prediction module; 6. an adjustment module; 7. an anomaly detection module; 8. an information transmitting/receiving unit; 9. a storage unit; 10. a display unit; 11. a control unit; 12. a heavy metal detection unit; 13. a data collection unit; 14. a data analysis unit; 15. a sewage discharge simulation unit; 16. a real-time detection unit; 17. a data transmission unit; 18. a first comparison unit; 19. a first database; 20. a judgment unit; 21. a flow rate adjusting unit; 22. a zone adjusting unit; 23. a detection unit; 24. an alarm unit; 25. an emergency processing unit.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Referring to fig. 1, the present invention provides a technical solution: a cloud remote control-based automatic sewage detection and management system comprises a cloud service module 1, a client 2, a component detection module 3, a meteorological module 4, a prediction module 5, an adjustment module 6 and an anomaly detection module 7, wherein the cloud service module 1 is used for performing platform management on the system, the client 2 is used for performing manual control on the system, the component detection module 3 is used for detecting urban sewage, the meteorological module 4 is used for detecting weather, the prediction module 5 is used for judging the flow of the urban sewage according to the weather, the adjustment module 6 is used for adjusting the flow and treatment of the urban sewage, the anomaly detection module 7 is used for checking the system during treatment of the urban sewage, and the output end of the cloud service module 1, the client 2, the component detection module 3, the meteorological module 4, the anomaly detection module 7, The input terminals of the prediction module 5, the adjustment module 6 and the anomaly detection module 7 are electrically connected, the input terminal of the cloud service module 1 is electrically connected with the output terminals of the client terminal 2, the composition detection module 3, the weather module 4, the prediction module 5, the adjustment module 6 and the anomaly detection module 7, and the output terminal of the prediction module 5 is electrically connected with the input terminals of the weather module 4 and the adjustment module 6.

The cloud service module comprises an information receiving and sending unit and a storage unit, the information receiving and sending unit is used for receiving and sending data, and the storage unit is used for storing the data.

The client comprises a display unit and a control unit, wherein the display unit is used for searching data, and the control unit is used for modifying the data.

The component detection module 3 comprises a heavy metal detection unit 12, a data collection unit 13, a data analysis unit 14 and a sewage discharge simulation unit 15, wherein the heavy metal detection unit 12 is used for detecting heavy metals in sewage to be discharged, the data collection unit 13 is used for collecting relevant data of a river, the data analysis unit 14 is used for analyzing the detected and collected data, and the data analysis process is as follows:

the method comprises the following steps of (1) enabling the sewage to be discharged to be X tons, enabling the heavy metal content in each ton of sewage to be Y, and enabling the total content N of the heavy metals in X tons of sewage to be N = XY;

s is the flow velocity of the sewage discharge river, M is the flow distance, T is the flow time, and the water flow velocity of the river can be obtained according to a formula S =;

and R is the current water body temperature, M is the current month, and the water body temperature R and the month M of the river at the moment are measured and recorded.

The sewage discharge simulation unit 15 simulates the heavy metal content N in the current X tons of sewage purified by the river according to the obtained data, and records the time T required for purifying each ton of sewage _X And calculating the moving distance H when each ton of sewage is purified by the formula H = T _X S can obtain the moving distance of the sewage, and compares the moving distance with the time length for purifying the heavy metal content in the same sewage in the historical data under the same flow speed, temperature, month and distance, if T is T _X 1 is the current time length for sewage purification, T _X 2 is the historical sewage purification time, when T _X 1>T _X 2, it indicates that the sewage can be discharged into the river, when T is _X 1<T _X 2, it means that the sewage cannot be discharged into the river, otherwise the environment of the river is polluted.

The prediction module 5 includes a first comparing unit 18, a first database 19 and a judging unit 20, where the first database 19 is configured to store the received weather data, the first comparing unit 18 is configured to compare the received weather data with historical weather data in the first database 19, and the judging unit 20 is configured to judge whether a rainy season occurs in the current weather.

The adjusting module 6 comprises a flow adjusting unit 21 and a zone adjusting unit 22, wherein the flow adjusting unit 21 is used for controlling the flow of sewage, and the zone adjusting unit 22 is used for adjusting the flow of sewage in each zone.

The flow regulating unit 21 comprises a valve controller, a first flow sensor and a first central processing unit, and the data analysis process is as follows:

the valve controller comprises a valve A, a valve B and a valve C;

if the rainy season is predicted, the central processing unit enables the valve controller to open the valve A and the valve B;

if no rainy season is predicted, the central processing unit enables the valve controller to open the valve A;

the flow sensor is used for calculating the real-time flow of the sewage;

q is sewage flow, Q ₁ 、Q ₂ 、Q ₃ Rated value for sewer pipe flow, and Q ₁ <Q ₂ <Q ₃ S is the cross-sectional area of the pipeline, and v is the flow velocity of the sewage;

calculating the real-time sewage flow by a formula Q = Sv;

a) when Q is ₂ ≧Q≧Q ₁ At the moment, the central processing unit enables the valve controller to open the valve A;

b) when Q is ₃ >Q>Q ₂ At the moment, the central processing unit enables the valve controller to open the valve A and the valve B;

c) when Q ≧ Q ₃ At this time, the central processing unit makes the valve controller open the valve A, the valve B and the valve C.

The zone regulating unit 22 comprises a pipeline controller, a second flow sensor and a second central processing unit, and the data analysis thereof is as follows:

the pipeline controller comprises a D pipeline, an E pipeline and an F pipeline, and the second flow sensor is used for each pipelineThe flow in each pipeline is monitored in real time, and the sewage flow in the D pipeline is Q _D And the sewage flow inside the E pipeline is Q _E And the sewage flow inside the F pipeline is Q _F And transmits the information to a second central processing unit in real time, the second central processing unit monitors the flow in the D pipeline, the E pipeline and the F pipeline,

if Q _D >Q _E >Q _F Communicating the D pipeline with the F pipeline by using the pipeline controller, draining sewage in the D pipeline, and reducing the sewage flow in the D pipeline;

②Q _D >Q _F >Q _E communicating the D pipeline with the E pipeline by using the pipeline controller, draining sewage in the D pipeline, and reducing the sewage flow in the D pipeline;

③Q _E >Q _D >Q _F communicating the pipeline E with the pipeline F by using the pipeline controller, draining sewage in the pipeline E, and reducing the sewage flow in the pipeline E;

④Q _E >Q _F >Q _D communicating the pipeline E with the pipeline D by using the pipeline controller, draining sewage in the pipeline E, and reducing the sewage flow in the pipeline E;

⑤Q _F >Q _E >Q _D communicating the F pipeline with the D pipeline by using the pipeline controller, draining sewage in the F pipeline, and reducing the sewage flow in the F pipeline;

⑥Q _F >Q _D >Q _E and then the pipeline controller is used for communicating the F pipeline with the E pipeline, draining sewage in the F pipeline and reducing sewage flow in the F pipeline.

The abnormity detection module 7 comprises a detection unit 23, an alarm unit 24 and an emergency processing unit 25, wherein the detection unit 23 is used for detecting each pipeline, the alarm unit 24 is used for warning under the abnormal condition, the emergency processing unit 25 is used for taking emergency processing measures under the abnormal condition, when the detection unit 23 detects that the pipeline is in a problem and cannot drain, the alarm unit 24 is started to warn relevant workers, and the emergency processing unit 25 is used for closing the valve of the pipeline, stopping the work of the pipeline, opening the pipeline and the drainage valve of other pipelines and draining the sewage in the pipeline.

The specific implementation mode is as follows: when the device is used, the heavy metal content in the sewage to be discharged and purified is detected through the component detection module, whether the sewage can be discharged into a nearby river for automatic purification is judged through simulation and calculation, the environment of the river is prevented from being influenced, the current weather is monitored in real time through the meteorological module, the monitored weather data is conveyed to the prediction module, the prediction module judges whether the current weather is in rainy season or not and conveys the judgment result to the adjustment module, the adjustment module controls the valves of all the pipelines according to the judgment result, if the current weather is in rainy season, a plurality of valves are opened, if the current weather is not in rainy season, the valves are kept unchanged, the adjustment module also detects the sewage flow in all the pipelines, and if the sewage flow difference between the pipelines is large, the two sewage pipelines with large difference are identical, the system has the advantages that sewage in the pipeline is shunted, the flow of the sewage in the pipeline is reduced, the service life of the sewage pipeline is prolonged, simultaneously the detection module carries out real-time detection on the discharged sewage components, and carries out rationalization arrangement on a physical decontamination method, a chemical decontamination method and a biological decontamination method according to the sewage component regulation decontamination mode, so that the sewage treatment effect is maximized, meanwhile, an operator can use a client to remotely control the system through a cloud service module, the anomaly detection module can carry out anomaly detection on the system and make emergency treatment measures when the anomaly occurs, weather can be prejudged through the cloud service module 1, the client 2, the component detection module 3, the meteorological module 4, the prediction module 5 and the regulation module 6, the sewage discharge pipeline can be reasonably regulated according to the prejudged result, and the sewage discharge pipeline can be maximally used, the service life of sewage discharge pipeline is prolonged, the discharge flow direction of sewage inside the sewage discharge pipeline can be regulated according to the flow inside each discharge pipeline through the regulating module, the sewage discharge speed is increased, each sewage pipeline inside the system can be detected through the abnormity detecting module 7, corresponding treatment modes are made when accidents happen, and the safety of the system during use is improved.

The working principle of the invention is as follows:

referring to the attached figure 1 of the specification, the invention can judge whether sewage can be discharged into nearby rivers through analog calculation by arranging a cloud service module 1, a client 2, a component detection module 3, a meteorological module 4, a prediction module 5 and an adjustment module 6, so as to avoid pollution to the environment of the nearby rivers, can prejudge weather through the meteorological module 4, and reasonably adjust the discharge pipeline of the sewage through a prejudgment result, so that the discharge pipeline of the sewage can be maximally used, the service life of the discharge pipeline of the sewage is prolonged, the adjustment module 6 can adjust the discharge flow direction of the sewage in each discharge pipeline according to the flow in the discharge pipeline, so as to improve the discharge rate of the sewage, and the abnormality detection module 7 can detect each sewage pipeline in the system and make a corresponding treatment mode when an accident occurs, the safety of the system in use is improved.

It is noted that, herein, relational terms such as first and second, and the like may be used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Also, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus.

Finally, it should be noted that: although the present invention has been described in detail with reference to the foregoing embodiments, it will be apparent to those skilled in the art that changes may be made in the embodiments and/or equivalents thereof without departing from the spirit and scope of the invention. Any modification, equivalent replacement, or improvement made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims (10)

1. Sewage automated inspection management system based on high in clouds remote control, including cloud service module (1), customer end (2), composition detection module (3), meteorological module (4), prediction module (5), adjusting module (6), unusual detection module (7), its characterized in that: the cloud service module (1) is used for performing platform type management on the system, the client (2) is used for manually controlling the system, the component detection module (3) is used for detecting urban sewage, the weather module (4) is used for detecting weather, the prediction module (5) is used for judging the flow of the urban sewage according to the weather, the regulation module (6) is used for regulating the flow and the treatment of the urban sewage, the abnormality detection module (7) is used for checking the system during treatment of the urban sewage, the output end of the cloud service module (1) is electrically connected with the input ends of the client (2), the component detection module (3), the weather module (4), the prediction module (5), the regulation module (6) and the abnormality detection module (7), and the input end of the cloud service module (1) is electrically connected with the client (2), The output ends of the composition detection module (3), the meteorological module (4), the prediction module (5), the regulation module (6) and the abnormality detection module (7) are electrically connected, and the output end of the prediction module (5) is electrically connected with the input ends of the meteorological module (4) and the regulation module (6).

2. The automatic sewage detection and management system based on cloud remote control as claimed in claim 1, wherein: the cloud service module (1) comprises an information transceiving unit (8) and a storage unit (9), wherein the information transceiving unit (8) is used for transceiving data, and the storage unit (9) is used for storing the data.

3. The automatic sewage detection and management system based on cloud remote control as claimed in claim 1, wherein: the client (2) comprises a display unit (10) and a control unit (11), wherein the display unit (10) is used for searching data, and the control unit (11) is used for modifying the data.

4. The automatic sewage detection and management system based on cloud remote control as claimed in claim 1, wherein: the component detection module (3) comprises a heavy metal detection unit (12), a data collection unit (13), a data analysis unit (14) and a sewage discharge simulation unit (15), wherein the heavy metal detection unit (12) is used for detecting heavy metals in sewage to be discharged, the data collection unit (13) is used for collecting relevant data of a river, the data analysis unit (14) is used for analyzing the data obtained by detection and collection, and the data analysis process is as follows:

the method comprises the following steps that X tons of sewage to be discharged exist, the content of heavy metal in each ton of sewage to be discharged is Y, and the total content N of heavy metal in X tons of sewage is N = XY;

s is the flow velocity of the sewage discharge river, M is the flow distance, T is the flow time, and the water flow velocity of the river can be obtained according to the formula S =;

and R is the current water body temperature, M is the current month, and the water body temperature R and the month M of the river at the moment are measured and recorded.

5. The automatic sewage detection and management system based on cloud remote control as claimed in claim 4, wherein: the sewage discharge simulation unit (15) simulates the heavy metal content N in X tons of sewage purified by the current river according to the obtained data, and records the time T required for purifying each ton of sewage _X And calculate the displacement of each ton of sewage when purifiedDistance of movement H, by the formula H = T _X S can obtain the moving distance of the sewage, and the moving distance is compared with the time length used for purifying the heavy metal content in the same sewage in the historical data under the same flow speed, temperature, month and distance of the river, if T is _X 1 is the current time length for sewage purification, T _X 2 is the historical sewage purification time, when T _X 1>T _X 2, it indicates that the sewage can be discharged into the river, when T is _X 1<T _X 2, it means that the sewage cannot be discharged into the river, otherwise the environment of the river is polluted.

6. The automatic sewage detection and management system based on cloud remote control as claimed in claim 1, wherein: the weather module (4) comprises a real-time detection unit (16) and a data transmission unit (17), wherein the real-time detection unit (16) is used for monitoring weather in real time, and the data transmission unit (17) is used for transmitting detected weather data.

7. The automatic sewage detection and management system based on cloud remote control as claimed in claim 1, wherein: the prediction module (5) comprises a first comparison unit (18), a first database (19) and a judgment unit (20), wherein the first database (19) is used for storing received weather data, the first comparison unit (18) is used for comparing the received weather data with historical weather data in the first database (19), and the judgment unit (20) is used for judging whether rainy seasons occur in the current weather.

8. The automatic sewage detection and management system based on cloud remote control as claimed in claim 1, wherein: the adjusting module (6) comprises a flow adjusting unit (21) and a zone adjusting unit (22), wherein the flow adjusting unit (21) is used for controlling the flow of sewage, the zone adjusting unit (22) is used for adjusting the flow of sewage in each zone, and the data analysis process is as follows:

the flow regulating unit (21) comprises a valve controller, a first flow sensor and a first central processing unit, wherein the valve controller comprises an A valve, a B valve and a C valve;

if the rainy season is predicted, the central processing unit enables the valve controller to open the valve A and the valve B;

if no rainy season is predicted, the central processing unit enables the valve controller to open the valve A;

the flow sensor is used for calculating the real-time flow of the sewage;

q is sewage flow, Q ₁ 、Q ₂ 、Q ₃ Rated value for sewer pipe flow, and Q ₁ <Q ₂ <Q ₃ S is the cross-sectional area of the pipeline, and v is the flow velocity of the sewage;

calculating the real-time sewage flow by the formula Q = Sv;

a) when Q is ₂ ≧Q≧Q ₁ At the moment, the central processing unit enables the valve controller to open the valve A;

b) when Q is ₃ >Q>Q ₂ At the moment, the central processing unit enables the valve controller to open the valve A and the valve B;

c) when Q ≧ Q ₃ At this time, the central processing unit makes the valve controller open the valve A, the valve B and the valve C.

9. The automatic sewage detection and management system based on cloud remote control as claimed in claim 8, wherein: the regional adjusting unit (22) comprises a pipeline controller, a second flow sensor and a second central processing unit, the pipeline controller comprises a D pipeline, an E pipeline and an F pipeline, the second flow sensor monitors the flow in each pipeline in real time, and the sewage flow in the D pipeline is Q _D And the sewage flow inside the E pipeline is Q _E And the sewage flow inside the F pipeline is Q _F And transmitting information to a second central processing unit in real time, wherein the second central processing unit monitors the flow in the D pipeline, the E pipeline and the F pipeline:

if Q _D >Q _E >Q _F Communicating the D pipeline with the F pipeline by using the pipeline controller, draining sewage in the D pipeline, and reducing the sewage flow in the D pipeline;

②Q _D >Q _F >Q _E communicating the D pipeline with the E pipeline by using the pipeline controller, draining sewage in the D pipeline, and reducing the sewage flow in the D pipeline;

③Q _E >Q _D >Q _F communicating the pipeline E with the pipeline F by using the pipeline controller, draining sewage in the pipeline E, and reducing the sewage flow in the pipeline E;

④Q _E >Q _F >Q _D communicating the pipeline E with the pipeline D by using the pipeline controller, draining sewage in the pipeline E and reducing the sewage flow in the pipeline E;

⑤Q _F >Q _E >Q _D communicating the F pipeline with the D pipeline by using the pipeline controller, draining sewage in the F pipeline, and reducing the sewage flow in the F pipeline;

⑥Q _F >Q _D >Q _E and then the pipeline controller is used for communicating the F pipeline with the E pipeline, draining sewage in the F pipeline and reducing sewage flow in the F pipeline.

10. The automatic sewage detection and management system based on cloud remote control as claimed in claim 2, wherein: abnormity detection module (7) includes detecting element (23), alarm unit (24) and emergency processing unit (25), detecting element (23) are used for detecting each pipeline, alarm unit (24) are used for warning under the unusual condition, emergency processing unit (25) are used for the emergency treatment measure to adopting under the unusual condition, work as detecting element (23) detect the inside problem that appears of pipeline, when unable drainage, start alarm unit (24), warn for relevant staff to use emergency processing unit (25) to close the valve of its pipeline, stop the work of this pipeline, and open the drainage valve of this pipeline and other pipelines, carry out the drainage with the inside sewage of this pipeline.

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