CN116282277B - Multi-membrane sewage treatment system and method - Google Patents

Abstract

The invention relates to the technical field of sewage treatment, and particularly discloses a multi-membrane sewage treatment system and a multi-membrane sewage treatment method. The invention processes the site by confirming a plurality of processes; determining a processing monitoring period, generating and sending monitoring feedback signals to a plurality of flow processing stations; marking unknown processing sites; selecting and marking a co-processing site; and acquiring the cooperative feedback data, performing data comprehensive analysis, generating a processing adjustment instruction, and sending the processing adjustment instruction to a plurality of flow processing stations. The method can determine a plurality of flow processing stations, periodically receive a plurality of monitoring feedback data, acquire the cooperative feedback data corresponding to the unknown processing stations through the cooperative processing stations, further perform data comprehensive analysis, generate a processing adjustment instruction, and send the processing adjustment instruction to the plurality of flow processing stations to perform cooperative processing adjustment, so that the integral comprehensive analysis and adjustment of the multi-membrane sewage treatment are realized, the integral coordination consistency of the multi-membrane sewage treatment process is ensured, and efficient and high-quality sewage treatment is performed.

Description

Multi-membrane sewage treatment system and method

Technical Field

The invention belongs to the technical field of sewage treatment, and particularly relates to a multi-membrane sewage treatment system and a multi-membrane sewage treatment method.

Background

Sewage treatment is a process for purifying sewage to meet the water quality requirement of being discharged into a certain water body or reused. The sewage treatment is widely applied to various fields of buildings, agriculture, traffic, energy sources, petrifaction, environmental protection, urban landscapes, medical treatment, catering and the like, and the sewage treatment is increasingly carried into the daily life of common people. Sewage treatment is generally divided into three stages: the first-stage treatment is to remove insoluble pollutants and parasitic ova in the sewage by using a physical treatment method; the secondary treatment is to apply biological treatment method to oxidize and degrade various complex organic matters in the sewage into simple matters; the third-stage treatment is to use chemical precipitation, biochemical and physicochemical methods to remove phosphorus, nitrogen, refractory organic matter and inorganic salt in the sewage.

In the prior art, each process of the multi-membrane sewage treatment is generally monitored, analyzed and treated independently, but not integrally comprehensively analyzed and regulated, so that the integral coordination and consistency of the multi-membrane sewage treatment process cannot be ensured, and the efficient and high-quality sewage treatment cannot be realized.

Disclosure of Invention

The invention aims to provide a multi-membrane sewage treatment system and a multi-membrane sewage treatment method, and aims to solve the problems in the background technology.

In order to achieve the above purpose, the present invention provides the following technical solutions:

a multi-membrane sewage treatment method specifically comprises the following steps:

acquiring flow setting data of multi-membrane sewage treatment, and determining a plurality of flow treatment sites;

determining a processing monitoring period according to the flow setting data, and generating and sending monitoring feedback signals to a plurality of flow processing stations;

periodically receiving and sorting a plurality of monitoring feedback data according to the processing monitoring period, and marking unknown processing stations;

selecting and marking a cooperative processing site corresponding to the unknown processing site according to the flow setting data;

and acquiring cooperative feedback data through the cooperative processing stations, performing data comprehensive analysis, generating a processing adjustment instruction, and sending the processing adjustment instruction to a plurality of flow processing stations.

As a further limitation of the technical scheme of the present invention, the process setting data of the multi-membrane sewage treatment is obtained, and the determining of the plurality of process treatment sites specifically includes the following steps:

acquiring flow setting data of multi-membrane sewage treatment;

processing flow analysis is carried out on the flow setting data, and a plurality of target processing flows are determined;

and determining a plurality of corresponding flow processing stations according to the target processing flows.

As a further limitation of the technical solution of the present invention, the determining a processing monitoring period according to the flow setting data, generating and sending monitoring feedback signals to a plurality of flow processing stations specifically includes the following steps:

extracting period setting data in the flow setting data;

determining a processing monitoring period according to the period setting data;

generating a monitoring feedback signal;

and periodically transmitting the monitoring feedback signals to a plurality of flow processing stations according to the processing monitoring period.

As a further limitation of the technical scheme of the present invention, the step of periodically receiving and sorting a plurality of monitoring feedback data according to the processing monitoring period, and marking an unknown processing site specifically includes the following steps:

periodically receiving a plurality of monitoring feedback data;

performing feedback address recording on the plurality of monitoring feedback data to obtain address recording data;

acquiring site address data corresponding to a plurality of flow processing sites;

and comparing the address record data with the site address data, and marking unknown processing sites from a plurality of flow processing sites according to comparison results.

As a further limitation of the technical solution of the present invention, the selecting and marking the co-processing site corresponding to the unknown processing site according to the flow setting data specifically includes the following steps:

marking a plurality of associated processing stations corresponding to the unknown processing station from a plurality of flow processing stations according to the flow setting data;

acquiring communication relations between a plurality of associated processing stations and the unknown processing stations through the station address data;

according to the communication relations, direct communication screening is carried out in the plurality of associated processing stations, and a communication screening result is generated;

and screening and marking the cooperative processing stations from a plurality of the associated processing stations according to the communication screening result.

As a further limitation of the technical scheme of the present invention, the steps of obtaining cooperative feedback data through the cooperative processing station, performing data comprehensive analysis, generating a processing adjustment instruction, and sending the processing adjustment instruction to a plurality of flow processing stations specifically include the following steps:

sending a cooperative feedback instruction to the cooperative processing station;

acquiring cooperative feedback data sent by the unknown processing station through the cooperative processing station;

comprehensively analyzing the cooperative feedback data and the monitoring feedback data to judge whether processing adjustment is needed;

when the processing adjustment is needed, corresponding processing adjustment instructions are generated, and the processing adjustment instructions are sent to a plurality of flow processing stations.

The system comprises a set data processing unit, a periodic processing monitoring unit, a feedback receiving and sorting unit, a site analysis marking unit and a collaborative comprehensive analysis unit, wherein:

the setting data processing unit is used for acquiring flow setting data of multi-membrane sewage treatment and determining a plurality of flow treatment sites;

the period processing monitoring unit is used for determining a processing monitoring period according to the flow setting data, generating and sending monitoring feedback signals to a plurality of flow processing stations;

the feedback receiving and sorting unit is used for periodically receiving and sorting a plurality of monitoring feedback data according to the processing monitoring period and marking unknown processing stations;

the site analysis marking unit is used for selecting and marking the cooperative processing site corresponding to the unknown processing site according to the flow setting data;

and the collaborative comprehensive analysis unit is used for acquiring collaborative feedback data through the collaborative processing stations, performing data comprehensive analysis, generating a processing adjustment instruction, and sending the processing adjustment instruction to a plurality of flow processing stations.

As a further limitation of the technical solution of the present invention, the setting data processing unit specifically includes:

the setting acquisition module is used for acquiring flow setting data of multi-membrane sewage treatment;

the flow analysis module is used for carrying out processing flow analysis on the flow setting data and determining a plurality of target processing flows;

and the site determining module is used for determining a plurality of corresponding flow processing sites according to a plurality of target processing flows.

As a further limitation of the technical solution of the present invention, the cycle processing monitoring unit specifically includes:

the data extraction module is used for extracting period setting data in the flow setting data;

the period determining module is used for determining a processing monitoring period according to the period setting data;

the signal generation module is used for generating a monitoring feedback signal;

and the period sending module is used for periodically sending the monitoring feedback signals to a plurality of flow processing stations according to the processing monitoring period.

As a further limitation of the technical scheme of the present invention, the feedback receiving and sorting unit specifically includes:

the feedback receiving module is used for periodically receiving a plurality of monitoring feedback data;

the address recording module is used for carrying out feedback address recording on the plurality of monitoring feedback data to obtain address recording data;

the address acquisition module is used for acquiring site address data corresponding to a plurality of flow processing sites;

and the address comparison module is used for comparing the address record data with the site address data, and marking unknown processing sites from a plurality of flow processing sites according to comparison results.

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

the invention processes the site by confirming a plurality of processes; determining a processing monitoring period, generating and sending monitoring feedback signals to a plurality of flow processing stations; marking unknown processing sites; selecting and marking a co-processing site; and acquiring the cooperative feedback data, performing data comprehensive analysis, generating a processing adjustment instruction, and sending the processing adjustment instruction to a plurality of flow processing stations. The method can determine a plurality of flow processing stations, periodically receive a plurality of monitoring feedback data, acquire the cooperative feedback data corresponding to the unknown processing stations through the cooperative processing stations, further perform data comprehensive analysis, generate a processing adjustment instruction, and send the processing adjustment instruction to the plurality of flow processing stations to perform cooperative processing adjustment, so that the integral comprehensive analysis and adjustment of the multi-membrane sewage treatment are realized, the integral coordination consistency of the multi-membrane sewage treatment process is ensured, and efficient and high-quality sewage treatment is performed.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the following description will briefly introduce the drawings that are needed in the embodiments or the description of the prior art, and it is obvious that the drawings in the following description are only some embodiments of the present invention.

Fig. 1 shows a flowchart of a method provided by an embodiment of the present invention.

Fig. 2 shows a flowchart of determining a flow processing station in the method according to the embodiment of the present invention.

Fig. 3 shows a flowchart of a method for transmitting a monitoring feedback signal according to an embodiment of the present invention.

FIG. 4 shows a flow chart of a method for tagging unknown processing sites in a method provided by an embodiment of the present invention.

FIG. 5 shows a flow chart of marking co-processing sites in a method provided by an embodiment of the invention.

Fig. 6 shows a flowchart of data analysis in a method according to an embodiment of the present invention.

Fig. 7 shows an application architecture diagram of a system provided by an embodiment of the present invention.

Fig. 8 is a block diagram of a configuration of a data processing unit in the system according to the embodiment of the present invention.

Fig. 9 shows a block diagram of a cycle processing monitoring unit in the system according to an embodiment of the present invention.

Fig. 10 shows a block diagram of a feedback receiving and sorting unit in the system according to the embodiment of the present invention.

Detailed Description

The present invention will be described in further detail with reference to the drawings and examples, in order to make the objects, technical solutions and advantages of the present invention more apparent. It should be understood that the specific embodiments described herein are for purposes of illustration only and are not intended to limit the scope of the invention.

It can be understood that multi-membrane sewage treatment is one of sewage treatment methods, in multi-membrane sewage treatment, a plurality of different sewage treatment processes need to be monitored, and according to the monitoring result, multi-membrane sewage treatment is regulated, in the prior art, each process of multi-membrane sewage treatment is generally monitored, analyzed and treated independently, rather than being subjected to integral comprehensive analysis and regulation, so that the integral coordination and consistency of the multi-membrane sewage treatment process cannot be ensured, and high-efficiency and high-quality sewage treatment cannot be realized.

In order to solve the problems, the embodiment of the invention determines a plurality of flow treatment sites by acquiring flow setting data of multi-membrane sewage treatment; determining a processing monitoring period, generating and sending monitoring feedback signals to a plurality of flow processing stations; marking unknown processing sites; selecting and marking a co-processing site; and acquiring the cooperative feedback data, performing data comprehensive analysis, generating a processing adjustment instruction, and sending the processing adjustment instruction to a plurality of flow processing stations.

The method can determine a plurality of flow processing stations, periodically receive a plurality of monitoring feedback data, acquire the cooperative feedback data corresponding to the unknown processing stations through the cooperative processing stations, further perform data comprehensive analysis, generate a processing adjustment instruction, and send the processing adjustment instruction to the plurality of flow processing stations to perform cooperative processing adjustment, so that the integral comprehensive analysis and adjustment of the multi-membrane sewage treatment are realized, the integral coordination consistency of the multi-membrane sewage treatment process is ensured, and efficient and high-quality sewage treatment is performed.

Fig. 1 shows a flowchart of a method provided by an embodiment of the present invention.

In particular, in a preferred embodiment of the present invention, a multi-membrane sewage treatment method, the method comprising the steps of:

step S100, flow setting data of multi-membrane sewage treatment are acquired, and a plurality of flow treatment sites are determined.

In the embodiment of the invention, flow setting data of multi-membrane sewage treatment is obtained, a plurality of target treatment flows for multi-membrane sewage treatment are determined by carrying out treatment flow analysis on the flow setting data, and then flow treatment stations corresponding to the plurality of treatment positions are matched from prestored station backup information according to the treatment positions corresponding to the plurality of target treatment flows, and specifically, the plurality of target treatment flows can comprise: precipitation, RO membrane filtration, SIC membrane filtration, conditioning, softening, chlorination, etc.

Specifically, fig. 2 shows a flowchart of determining a flow processing site in the method provided by the embodiment of the present invention.

In the preferred embodiment of the present invention, the process setting data of the multi-membrane sewage treatment is obtained, and the determining of the plurality of process treatment sites specifically includes the following steps:

step S101, acquiring flow setting data of multi-membrane sewage treatment.

Step S102, processing flow analysis is carried out on the flow setting data, and a plurality of target processing flows are determined.

Step S103, determining a plurality of corresponding process processing sites according to a plurality of the target process flows.

Further, the multi-membrane sewage treatment method further comprises the following steps:

step 200, determining a processing monitoring period according to the flow setting data, generating and sending monitoring feedback signals to a plurality of flow processing stations.

In the embodiment of the invention, a manager can perform periodic setting according to the strict or not of management, generate flow setting data, acquire the periodic setting data by analyzing the flow setting data, determine the processing and monitoring period for monitoring and feeding back a plurality of target processing flows according to the periodic setting data, further generate a monitoring and feedback signal, and periodically send the monitoring and feedback signal to a plurality of flow processing stations according to the processing and monitoring period, thereby performing more frequent monitoring and feedback signal sending when strict management is needed; when strict management is not needed, low-frequency monitoring feedback signal transmission is performed.

Specifically, fig. 3 shows a flowchart of sending a monitoring feedback signal in the method provided by the embodiment of the present invention.

In a preferred embodiment of the present invention, the determining a process monitoring period according to the flow setting data, generating and sending monitoring feedback signals to a plurality of flow processing stations specifically includes the following steps:

step S201, extracting period setting data in the flow setting data.

Step S202, determining a processing monitoring period according to the period setting data.

In step S203, a monitoring feedback signal is generated.

Step S204, periodically sending the monitoring feedback signal to a plurality of process processing stations according to the processing monitoring period.

Further, the multi-membrane sewage treatment method further comprises the following steps:

and step S300, periodically receiving and sorting a plurality of monitoring feedback data according to the processing monitoring period, and marking an unknown processing station.

In the embodiment of the invention, after the monitoring feedback signal transmission of one processing monitoring period is completed, the flow processing stations receiving the monitoring feedback signal need to monitor and feed back, a plurality of monitoring feedback data are periodically received, address analysis is carried out on the plurality of monitoring feedback data, address analysis results are recorded to obtain address record data, station address data corresponding to the plurality of flow processing stations are obtained from a preset address backup library, the address record data are compared with the station address data to generate a comparison result, and the flow processing stations which do not feed back are determined from the plurality of flow processing stations according to the comparison result and are marked as unknown processing stations.

Specifically, fig. 4 shows a flowchart of a method for marking an unknown processing site according to an embodiment of the present invention.

In a preferred embodiment of the present invention, the step of periodically receiving and sorting a plurality of monitoring feedback data according to the processing monitoring period, and marking the unknown processing site specifically includes the following steps:

in step S301, a plurality of monitoring feedback data are periodically received.

And step S302, carrying out feedback address recording on the plurality of monitoring feedback data to obtain address recording data.

Step S303, acquiring site address data corresponding to a plurality of the flow processing sites.

And step S304, comparing the address record data with the site address data, and marking unknown processing sites from a plurality of flow processing sites according to comparison results.

Further, the multi-membrane sewage treatment method further comprises the following steps:

and step S400, selecting and marking the cooperative processing sites corresponding to the unknown processing sites according to the flow setting data.

In the embodiment of the invention, according to the flow setting data, a plurality of associated processing stations with direct relation with an unknown processing station are determined according to the sequence processing relation corresponding to the plurality of flow processing stations, then according to the station address data, the communication relation between the plurality of associated processing stations and the unknown processing station is obtained, then according to the plurality of communication relations, whether the direct communication relation exists or not is judged, according to the judging result, the associated processing station with the direct communication with the unknown processing station is selected from the plurality of associated processing stations, and is marked as a cooperative processing station, and the cooperative processing station and the unknown processing station can be directly connected in a wired communication way.

Specifically, fig. 5 shows a flowchart of marking a co-processing site in the method provided by the embodiment of the present invention.

In a preferred embodiment of the present invention, selecting and marking a co-processing site corresponding to the unknown processing site according to the flow setting data specifically includes the following steps:

and step S401, marking a plurality of associated processing stations corresponding to the unknown processing station from a plurality of flow processing stations according to the flow setting data.

Step S402, obtaining communication relations between the plurality of associated processing stations and the unknown processing station through the station address data.

And S403, performing direct communication screening in a plurality of associated processing sites according to a plurality of communication relations to generate a communication screening result.

And step S404, screening and marking the cooperative processing stations from a plurality of the associated processing stations according to the communication screening result.

Further, the multi-membrane sewage treatment method further comprises the following steps:

and S500, acquiring cooperative feedback data through the cooperative processing stations, performing data comprehensive analysis, generating a processing adjustment instruction, and transmitting the processing adjustment instruction to a plurality of flow processing stations.

In the embodiment of the invention, the cooperative feedback instruction is generated and sent to the cooperative processing station, the cooperative processing station performs communication attempt with the unknown processing station after receiving the cooperative feedback instruction, after the communication attempt is successful, the cooperative processing station acquires the cooperative feedback data sent by the unknown processing station, and determines whether the process of the multi-membrane sewage treatment (comprising water quantity, processing time in different processes and the like) needs to be regulated by comprehensively analyzing the cooperative feedback data and the plurality of monitoring feedback data, and when the process regulation is needed, the corresponding process regulation instruction is generated, and then the process regulation instruction is sent to the plurality of process processing stations (comprising the cooperative processing station and the unknown processing station), so that the integral comprehensive analysis and regulation of the multi-membrane sewage treatment are realized, the integral coordination and the consistency of the multi-membrane sewage treatment process are ensured, and the high-efficiency and high-quality sewage treatment is performed.

Specifically, fig. 6 shows a flowchart of data analysis in the method according to the embodiment of the present invention.

In a preferred embodiment of the present invention, the method for acquiring cooperative feedback data through the cooperative processing station, performing data comprehensive analysis, generating a processing adjustment instruction, and sending the processing adjustment instruction to a plurality of flow processing stations specifically includes the following steps:

step S501, sending a cooperative feedback instruction to the cooperative processing station.

Step S502, obtaining, by the cooperative processing station, cooperative feedback data sent by the unknown processing station.

Step S503, performing comprehensive analysis on the cooperative feedback data and the plurality of monitoring feedback data, to determine whether processing adjustment is required.

Step S504, when the process adjustment is needed, generating a corresponding process adjustment instruction, and sending the process adjustment instruction to a plurality of flow process stations.

Further, fig. 7 shows an application architecture diagram of the system provided by the embodiment of the present invention.

In another preferred embodiment, the present invention provides a multi-membrane sewage treatment system, comprising:

a data processing unit 10 is configured to acquire flow setting data of the multi-membrane sewage treatment and determine a plurality of flow treatment sites.

In the embodiment of the present invention, the setting data processing unit 10 obtains flow setting data of the multi-membrane sewage treatment, determines a plurality of target treatment flows of the multi-membrane sewage treatment by performing treatment flow analysis on the flow setting data, and matches flow treatment sites corresponding to the plurality of treatment positions from pre-stored site backup information according to treatment positions corresponding to the plurality of target treatment flows, where the plurality of target treatment flows may specifically include: precipitation, RO membrane filtration, SIC membrane filtration, conditioning, softening, chlorination, etc.

Specifically, fig. 8 shows a block diagram of a configuration of the data processing unit 10 in the system according to the embodiment of the present invention.

In a preferred embodiment of the present invention, the setting data processing unit 10 specifically includes:

and the setting acquisition module 11 is used for acquiring flow setting data of the multi-membrane sewage treatment.

The process analysis module 12 is configured to perform process flow analysis on the process setting data, and determine a plurality of target process flows.

The site determining module 13 is configured to determine a plurality of corresponding process processing sites according to a plurality of the target processing flows.

Further, the multi-membrane sewage treatment system further comprises:

and the period processing monitoring unit 20 is configured to determine a processing monitoring period according to the flow setting data, generate and send monitoring feedback signals to a plurality of flow processing sites.

In the embodiment of the invention, a manager can perform periodic setting according to the strict or not of management, the periodic processing monitoring unit 20 generates corresponding flow setting data according to the periodic setting, analyzes the flow setting data to obtain the periodic setting data, determines a processing monitoring period for monitoring feedback on a plurality of target processing flows according to the periodic setting data, generates a monitoring feedback signal, and periodically transmits the monitoring feedback signal to a plurality of flow processing stations according to the processing monitoring period, so that more frequent monitoring feedback signal transmission is performed when strict management is required; when strict management is not needed, low-frequency monitoring feedback signal transmission is performed.

Specifically, fig. 9 shows a block diagram of the cycle processing monitoring unit 20 in the system according to the embodiment of the present invention.

In a preferred embodiment of the present invention, the cycle processing monitoring unit 20 specifically includes:

a data extraction module 21, configured to extract the period setting data in the flow setting data.

The period determining module 22 is configured to determine a process monitoring period according to the period setting data.

The signal generating module 23 is configured to generate a monitoring feedback signal.

And the period sending module 24 is configured to send the monitoring feedback signal to a plurality of process processing stations periodically according to the processing monitoring period.

Further, the multi-membrane sewage treatment system further comprises:

the feedback receiving and sorting unit 30 is configured to periodically receive and sort a plurality of monitoring feedback data according to the processing monitoring period, and mark an unknown processing station.

In the embodiment of the present invention, after the monitoring feedback signal transmission of one processing monitoring period is completed, the process processing stations that receive the monitoring feedback signal need to monitor and feedback, the feedback receiving and sorting unit 30 periodically receives a plurality of monitoring feedback data, performs address analysis on the plurality of monitoring feedback data, records the address analysis result to obtain address record data, obtains station address data corresponding to the plurality of process processing stations from a preset address backup library, compares the address record data with the station address data to generate a comparison result, and determines a process processing station that does not perform feedback from the plurality of process processing stations according to the comparison result, and marks the process processing station as an unknown processing station.

Specifically, fig. 10 shows a block diagram of the feedback receiving and sorting unit 30 in the system according to the embodiment of the present invention.

In a preferred embodiment provided by the present invention, the feedback receiving and sorting unit 30 specifically includes:

the feedback receiving module 31 is configured to periodically receive a plurality of monitoring feedback data.

The address recording module 32 is configured to perform feedback address recording on the plurality of monitoring feedback data, so as to obtain address recording data.

And the address acquisition module 33 is configured to acquire site address data corresponding to a plurality of the flow processing sites.

And the address comparison module 34 is configured to compare the address record data with the site address data, and mark an unknown processing site from a plurality of flow processing sites according to the comparison result.

Further, the multi-membrane sewage treatment system further comprises:

and a site analysis marking unit 40, configured to select and mark a co-processing site corresponding to the unknown processing site according to the flow setting data.

In the embodiment of the present invention, the site analysis marking unit 40 determines a plurality of associated processing sites having a direct relationship with the unknown processing site according to the sequence processing relationship corresponding to the plurality of process processing sites according to the process setting data, obtains the communication relationship between the plurality of associated processing sites and the unknown processing site according to the site address data, determines whether the communication relationship has the direct communication relationship according to the plurality of communication relationships, screens out the associated processing sites directly communicating with the unknown processing site from the plurality of associated processing sites according to the determination result, and marks the associated processing sites as cooperative processing sites, wherein the cooperative processing sites and the unknown processing sites may be directly connected through wired communication.

And the collaborative comprehensive analysis unit 50 is configured to obtain collaborative feedback data through the collaborative processing station, perform data comprehensive analysis, generate a processing adjustment instruction, and send the processing adjustment instruction to a plurality of flow processing stations.

In the embodiment of the invention, the collaborative comprehensive analysis unit 50 generates the collaborative feedback instruction and sends the collaborative feedback instruction to the collaborative processing site, the collaborative processing site performs communication attempt with the unknown processing site after receiving the collaborative feedback instruction, after the communication attempt is successful, the collaborative processing site acquires collaborative feedback data sent by the unknown processing site, and determines whether the process of the multi-membrane sewage treatment (including water quantity, treatment time in different processes and the like) needs to be regulated by comprehensively analyzing the collaborative feedback data and a plurality of monitoring feedback data, and when the process needs to be regulated, generates corresponding treatment regulation instructions, and sends the treatment regulation instructions to a plurality of process processing sites (including the collaborative processing site and the unknown processing site), so that the integral comprehensive analysis and regulation of the multi-membrane sewage treatment are realized, the integral coordination of the multi-membrane sewage treatment process is ensured, and the high-efficiency and high-quality sewage treatment is performed.

It should be understood that, although the steps in the flowcharts of the embodiments of the present invention are shown in order as indicated by the arrows, these steps are not necessarily performed in order as indicated by the arrows. The steps are not strictly limited to the order of execution unless explicitly recited herein, and the steps may be executed in other orders. Moreover, at least some of the steps in various embodiments may include multiple sub-steps or stages that are not necessarily performed at the same time, but may be performed at different times, nor do the order in which the sub-steps or stages are performed necessarily performed in sequence, but may be performed alternately or alternately with at least a portion of the sub-steps or stages of other steps or other steps.

The technical features of the above-described embodiments may be arbitrarily combined, and all possible combinations of the technical features in the above-described embodiments are not described for brevity of description, however, as long as there is no contradiction between the combinations of the technical features, they should be considered as the scope of the description.

The foregoing examples illustrate only a few embodiments of the invention and are described in detail herein without thereby limiting the scope of the invention. It should be noted that it will be apparent to those skilled in the art that several variations and modifications can be made without departing from the spirit of the invention, which are all within the scope of the invention. Accordingly, the scope of protection of the present invention is to be determined by the appended claims.

The foregoing description of the preferred embodiments of the invention is not intended to be limiting, but rather is intended to cover all modifications, equivalents, and alternatives falling within the spirit and principles of the invention.

Claims (2)

1. The multi-membrane sewage treatment method is characterized by comprising the following steps of:

acquiring flow setting data of multi-membrane sewage treatment, and determining a plurality of flow treatment sites;

determining a processing monitoring period according to the flow setting data, and generating and sending monitoring feedback signals to a plurality of flow processing stations;

periodically receiving and sorting a plurality of monitoring feedback data according to the processing monitoring period, and marking unknown processing stations;

selecting and marking a cooperative processing site corresponding to the unknown processing site according to the flow setting data;

acquiring cooperative feedback data through the cooperative processing stations, performing data comprehensive analysis, generating processing adjustment instructions, and sending the processing adjustment instructions to a plurality of flow processing stations;

the process setting data of the multi-membrane sewage treatment are obtained, and the determination of the plurality of process treatment sites specifically comprises the following steps:

acquiring flow setting data of multi-membrane sewage treatment;

processing flow analysis is performed on the flow setting data, and a plurality of target processing flows are determined, wherein the plurality of target processing flows comprise: precipitation, RO membrane filtration, SIC membrane filtration, conditioning, softening and chlorination;

determining a plurality of corresponding flow processing sites according to a plurality of target processing flows;

the step of determining a processing monitoring period according to the flow setting data, and generating and sending monitoring feedback signals to a plurality of flow processing stations specifically comprises the following steps:

extracting period setting data in the flow setting data;

determining a processing monitoring period according to the period setting data;

generating a monitoring feedback signal;

periodically transmitting the monitoring feedback signals to a plurality of flow processing stations according to the processing monitoring period;

the method comprises the steps of periodically receiving and sorting a plurality of monitoring feedback data according to the processing monitoring period, and marking an unknown processing site specifically comprises the following steps:

periodically receiving a plurality of monitoring feedback data;

performing feedback address recording on the plurality of monitoring feedback data to obtain address recording data;

acquiring site address data corresponding to a plurality of flow processing sites;

comparing the address record data with the site address data, and marking unknown processing sites from a plurality of flow processing sites according to comparison results;

the selecting and marking the cooperative processing site corresponding to the unknown processing site according to the flow setting data specifically comprises the following steps:

marking a plurality of associated processing stations corresponding to the unknown processing station from a plurality of flow processing stations according to the flow setting data;

acquiring communication relations between a plurality of associated processing stations and the unknown processing stations through the station address data;

according to the communication relations, direct communication screening is carried out in the plurality of associated processing stations, and a communication screening result is generated;

screening and marking cooperative processing stations from a plurality of related processing stations according to the communication screening result;

the collaborative feedback data is obtained through the collaborative processing station, the data is comprehensively analyzed, a processing adjustment instruction is generated, and the processing adjustment instruction is sent to a plurality of flow processing stations, wherein the processing adjustment instruction specifically comprises the following steps:

sending a cooperative feedback instruction to the cooperative processing station;

acquiring cooperative feedback data sent by the unknown processing station through the cooperative processing station;

comprehensively analyzing the cooperative feedback data and the monitoring feedback data to judge whether processing adjustment is needed;

when processing adjustment is needed, corresponding processing adjustment instructions are generated, and the processing adjustment instructions are sent to a plurality of flow processing stations, including a cooperative processing station and an unknown processing station.

2. The utility model provides a many membrane sewage treatment system which characterized in that, the system includes setting up data processing unit, periodic processing monitoring unit, feedback receipt arrangement unit, website analysis marking unit and cooperation comprehensive analysis unit, wherein:

the setting data processing unit is used for acquiring flow setting data of multi-membrane sewage treatment and determining a plurality of flow treatment sites;

the period processing monitoring unit is used for determining a processing monitoring period according to the flow setting data, generating and sending monitoring feedback signals to a plurality of flow processing stations;

the feedback receiving and sorting unit is used for periodically receiving and sorting a plurality of monitoring feedback data according to the processing monitoring period and marking unknown processing stations;

the site analysis marking unit is used for selecting and marking the cooperative processing site corresponding to the unknown processing site according to the flow setting data; the station analysis marking unit determines a plurality of associated processing stations with direct relation with the unknown processing stations according to the sequence processing relation corresponding to the plurality of flow processing stations and the flow setting data, acquires the communication relation between the plurality of associated processing stations and the unknown processing stations according to the station address data, judges whether the communication relation exists or not according to the plurality of communication relation, screens out the associated processing stations with the direct communication with the unknown processing stations according to the judgment result, and marks the associated processing stations as cooperative processing stations;

the collaborative comprehensive analysis unit is used for acquiring collaborative feedback data through the collaborative processing stations, performing data comprehensive analysis, generating processing adjustment instructions, and sending the processing adjustment instructions to a plurality of flow processing stations; the collaborative comprehensive analysis unit generates a collaborative feedback instruction and sends the collaborative feedback instruction to a collaborative processing station, the collaborative processing station performs communication attempt with an unknown processing station after receiving the collaborative feedback instruction, acquires collaborative feedback data sent by the unknown processing station through the collaborative processing station after the communication attempt is successful, and judges whether the process of multi-membrane sewage treatment is required to be regulated by comprehensively analyzing the collaborative feedback data and a plurality of monitoring feedback data, and generates a corresponding treatment regulation instruction when the treatment regulation is required, and then sends the treatment regulation instruction to a plurality of flow processing stations including the collaborative processing station and the unknown processing station;

the setting data processing unit specifically includes:

the setting acquisition module is used for acquiring flow setting data of multi-membrane sewage treatment;

the flow analysis module is used for carrying out processing flow analysis on the flow setting data and determining a plurality of target processing flows, wherein the plurality of target processing flows comprise: precipitation, RO membrane filtration, SIC membrane filtration, conditioning, softening and chlorination;

the site determining module is used for determining a plurality of corresponding flow processing sites according to a plurality of target processing flows;

the periodic processing monitoring unit specifically comprises:

the data extraction module is used for extracting period setting data in the flow setting data;

the period determining module is used for determining a processing monitoring period according to the period setting data;

the signal generation module is used for generating a monitoring feedback signal;

the period sending module is used for periodically sending the monitoring feedback signals to a plurality of flow processing stations according to the processing monitoring period;

the feedback receiving and sorting unit specifically comprises:

the feedback receiving module is used for periodically receiving a plurality of monitoring feedback data;

the address recording module is used for carrying out feedback address recording on the plurality of monitoring feedback data to obtain address recording data;

the address acquisition module is used for acquiring site address data corresponding to a plurality of flow processing sites;

and the address comparison module is used for comparing the address record data with the site address data, and marking unknown processing sites from a plurality of flow processing sites according to comparison results.