CN117130314A - Water affair intelligent monitoring system based on Internet of things - Google Patents

Abstract

The invention relates to the technical field of water affair monitoring, and provides a water affair intelligent monitoring system based on the Internet of things, which comprises the following components: the system comprises a data acquisition module, an Internet of things cloud platform, a data analysis module, a wireless communication module and a server, wherein the data acquisition module is used for acquiring pollutants in urban river channels, the Internet of things cloud platform is used for receiving and storing acquired data, the data analysis module integrates and calculates the received data, and the server displays the received calculation result to monitoring staff. The data acquisition module of the intelligent water service monitoring system based on the Internet of things comprises more elements of river water pollution, so that river pollution can be monitored more comprehensively; in addition, when river water pollution exceeds standard, the warning light is on, and simultaneously a warning message is sent to the mobile phone of the monitoring personnel to remind the monitoring personnel to timely process, the monitoring personnel carries out targeted processing according to the data stored and recorded in the data analysis module, and the processing efficiency is improved.

Description

Water affair intelligent monitoring system based on Internet of things

Technical Field

The invention relates to the technical field of water affair monitoring, in particular to an intelligent water affair monitoring system based on the Internet of things.

Background

The water affair mainly relates to various aspects of urban water supply and drainage engineering, environmental engineering, hydrologic and water resource engineering, urban hydraulic engineering and the like. For example: taking and purifying urban water supply, treating and discharging sewage, controlling urban flood and river channel, developing and utilizing water resources, saving water resources and the like. In the operation of water engineering, the method is mostly applied to the Internet of things.

The internet of things is a network which is used for connecting any article with the internet through information sensing equipment according to a contracted protocol and carrying out information exchange and communication so as to realize intelligent identification, positioning, tracking, monitoring and management. In popular terms, the internet of things is the internet of things, and comprises two layers of meanings: firstly, the Internet of things is an extension and expansion of the Internet, and the core and the foundation of the Internet are still the Internet; secondly, the user side of the Internet of things not only comprises people, but also comprises articles, and the Internet of things realizes the exchange and communication of information among people, articles and articles.

At present, although water affair monitoring systems are built in most cities in China, most monitoring systems are not comprehensive in monitoring pollution elements of urban river channels, so that the treatment effect on river channel pollution is poor, cleaning is not comprehensive enough, and urban development is affected.

Disclosure of Invention

The invention provides a water affair intelligent monitoring system based on the Internet of things, and aims to solve the existing problems.

The invention is realized in such a way that a water affair intelligent monitoring system based on the Internet of things comprises: the system comprises a data acquisition module, an Internet of things cloud platform, a data analysis module, a wireless communication module and a server side;

the data acquisition module is used for acquiring pollutants in the urban river and comprises a camera, a radioactive substance detector, a water quality tester, a microorganism sensor and an algae sensor, wherein the camera is used for capturing white garbage in the river, the radioactive substance detector is used for detecting the content of radioactive substances in the river, the water quality tester is used for detecting various components in the river, mainly comprises ammonia nitrogen, total phosphorus, total nitrogen and turbidity of heavy metals (total chromium, hexavalent chromium, copper, nickel, iron and zinc), and the microorganism sensor and the algae sensor are used for respectively detecting microorganisms and algae in the river;

the Internet of things cloud platform is used for receiving and storing acquired data and transmitting the data to the data analysis module;

the data analysis module integrates and calculates the received data to obtain the total river water pollution M _i Comparing the result with a river pollution standard value M standard, and then transmitting the result to a server through a wireless communication module;

and the server displays the received calculation result to a monitor, and reminds the monitor to process according to the result.

Preferably, the data acquisition module specifically comprises the following acquisition processes:

s1: the camera is a waterproof camera and is arranged below the water surface of the river channel, captures the quantity of white garbage in one cubic meter of the river channel, and transmits the quantity to the data analysis module;

s2: the radioactive substance detector is used for collecting the content of radioactive substances in one cubic meter of a river channel and transmitting the content to the data analysis module;

s3: the water quality tester is used for collecting chemical substances in a river channel, detecting the contents of ammonia nitrogen, total phosphorus, total nitrogen and heavy metals in one cubic meter, and transmitting the contents to the data analysis module;

s4: the microbial sensor is used for collecting the content of microorganisms in one cubic meter of a river channel and transmitting the content to the data analysis module;

s5: the algae sensor is used for collecting the content of cubic meter algae in the river channel and transmitting the content to the data analysis module;

preferably, the data analysis module performs the integrated calculation on the received data specifically as follows:

step 1: the quantity of white garbage in one cubic meter of the received river channel is recorded as B _i The radioactive substance content in one cubic meter of river channel is marked as F _i The contents of ammonia nitrogen, total phosphorus, total nitrogen and heavy metal in one cubic meter of river channel are respectively A _i 、P _i 、N _i And J _i The microorganism content in one cubic meter of the river channel is marked as C _i The content of one cubic meter of algae in the river channel is recorded as Z _i 。

Step 2: to be received in river courseQuantity B of white refuse in square meter _i Dividing the standard quantity B of white garbage in one cubic meter to obtainIf->Quantity B of the acquisition _i Storing the record;

step 3: the radioactive substance content in one cubic meter of the received river channel is recorded as F _i Dividing by standard quantity F of radioactive substance in cubic meter to obtainIf->The content F of the collection is then _i Storing the record;

step 4: the ammonia nitrogen, the total phosphorus, the total nitrogen and the heavy metal content A in one cubic meter of the received river channel _i 、P _i 、N _i And J _i Dividing the standard contents of ammonia nitrogen, total phosphorus, total nitrogen and heavy metal in one cubic meter by the standard contents of A, P, N and J to obtainAnd->If->Or->One of them is greater than 1, the content A collected this time is _i 、P _i 、N _i Or J _i Storing the record;

step 5: the microorganism content in one cubic meter of the received river channel is recorded as C _i Dividing the standard quantity of microorganisms in one cubic meter by the standard quantity C of microorganisms to obtainIf->The content C of the collection is then _i Storing the record;

step 6: the quantity Z of algae in one cubic meter of the received river channel _i Dividing by standard quantity Z of algae in cubic meter to obtainIf->The number Z of the collection _i Storing the record;

step 7: calculating the total pollution amount of river water:

wherein omega _{White color} Omega is the percentage of white refuse in total pollutants _{Put and put} Omega is the percentage of radioactive material in the total contaminants _Ammonia Omega is the percentage of ammonia nitrogen in total pollutants _{Phosphorus (P)} Omega as a percentage of total phosphorus in total contaminants _{Nitrogen and nitrogen} Omega is the percentage of total nitrogen in total contaminants _{Gold alloy} Omega is the percentage of heavy metals in the total contaminants _Micro-scale Omega is the percentage of microorganisms in total contaminants _{Algae (algae)} Is the percentage of algae in the total pollutants.

Step 8: total pollution m of river course _i Dividing the standard river pollution amount by M standard to obtainAnd will->Transmitting to the server through the wireless communication module, and simultaneously transmitting +.>And->The ratio of (2) is sent to a server;

preferably, the server side comprises a reminding module, and the server side receives the dataThe reminding module comprises a reminding lamp and a short message sending mode, if +.>The total pollution amount M of the time is reduced _i The storage record, start and remind the module, the warning lamp lights, send the cell-phone of warning SMS to monitoring personnel simultaneously, remind monitoring personnel to handle in time, arrange the ratio of each pollutant to standard value according to big to little order simultaneously.

Preferably, the server is a computer, a mobile phone or a PAD.

Preferably, the intelligent water monitoring system based on the internet of things further comprises a PH value sensor, the PH value sensor is connected to the cloud platform of the internet of things, the PH value sensor is used for collecting the PH value of river water in a river, and if the detected PH value is higher or lower than a standard value, the detected PH value is transmitted to a server through a wireless communication module, and monitoring staff is reminded of timely processing.

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

1. the data acquisition module of the intelligent water service monitoring system based on the Internet of things is convenient for more comprehensively monitoring river pollution through contents of white garbage, radioactive substances, chemical substances, microorganisms and algae, including elements of more river water pollution.

2. When river water pollution exceeds standard, the reminding module is started, the reminding lamp is turned on, meanwhile, a reminding short message is sent to a mobile phone of a monitoring person, the monitoring person is reminded of timely treatment, the monitoring person can inquire specific reasons of the river water pollution in the data analysis module, targeted treatment is carried out according to data stored and recorded in the data analysis module, and treatment efficiency is improved.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings that are needed in the embodiments will be briefly described below, it being understood that the following drawings only illustrate some embodiments of the present invention and therefore should not be considered as limiting the scope, and other related drawings may be obtained according to these drawings without inventive effort for a person skilled in the art.

FIG. 1 is an overall block diagram of embodiment 1 of the present invention;

FIG. 2 is a partial block diagram of embodiment 2 of the present invention;

Detailed Description

In order to more fully understand the technical content of the present invention, the following technical solutions of the present invention will be further described and illustrated with reference to specific embodiments, but are not limited thereto. The following description of the embodiments of the present invention will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present invention, but not all embodiments. All other embodiments, which can be made by a person skilled in the art without making any inventive effort, are based on embodiments of the present invention, which are intended to be within the scope of the present invention.

Example 1

Referring to fig. 1 to 2, the intelligent water service monitoring system based on the internet of things includes: the system comprises a data acquisition module, an Internet of things cloud platform, a data analysis module, a wireless communication module and a server side; the data acquisition module is used for acquiring pollutants in the urban river and comprises a camera, a radioactive substance detector, a water quality tester, a microorganism sensor and an algae sensor;

the pollutants mainly comprise white garbage, radioactive substances, chemical substances, microorganisms and algae; white garbage refers to plastic garbage which is difficult to degrade, and is difficult to degrade and treat due to random and messy throwing, so that urban environment is seriously polluted, and a camera is used for capturing the white garbage in a river channel; under the irradiation of large dose, the radioactive substance has certain damage effect on human body and animals, and the radioactive substance detector is used for detecting the content of the radioactive substance in the river channel; the chemical substances mainly comprise ammonia nitrogen, total phosphorus, total nitrogen and heavy metals (total chromium, hexavalent chromium, copper, nickel, iron and zinc), the water quality is influenced by excessive content, and the water quality tester is used for detecting the chemical components in the river channel; the microorganism is a large group of organisms including bacteria, viruses, fungi, some small protozoa, microalgae and the like, the aquatic environment is easily destroyed by excessive microorganisms in water, and the microorganism sensor and the algae sensor collect the microorganisms and the algae in the river channel respectively; algae are eukaryotes in the kingdom of protists, and excessive algae can cause turbid water quality and hypoxia death of fish organisms.

The acquisition process of the data acquisition module specifically comprises the following steps:

s1: the camera is a waterproof camera and is arranged below the water surface of the river channel, captures the quantity of white garbage in one cubic meter of the river channel, and transmits the quantity to the data analysis module;

s2: the radioactive substance detector collects the content of radioactive substances in one cubic meter of river channel and transmits the content to the data analysis module;

s3: the water quality tester collects chemical substances in a river channel, detects the contents of ammonia nitrogen, total phosphorus, total nitrogen and heavy metals in one cubic meter, and transmits the contents to the data analysis module;

s4: the microbial sensor collects the content of microorganisms in a cubic meter of a river channel and transmits the content to the data analysis module;

s5: the algae sensor collects the content of cubic meter algae in the river channel and transmits the content to the data analysis module;

the cloud platform of the Internet of things receives and stores the data acquired by the data acquisition module, transmits the data to the data analysis module, and the data analysis module integrates and calculates the received dataObtaining the total amount M of river water pollution _i And comparing with a standard m of a river pollution standard value, wherein the specific process is as follows:

step 1: the quantity of white garbage in one cubic meter of the received river channel is recorded as B _i The radioactive substance content in one cubic meter of river channel is marked as F _i The contents of ammonia nitrogen, total phosphorus, total nitrogen and heavy metal in one cubic meter of river channel are respectively A _i 、P _i 、N _i And J _i The microorganism content in one cubic meter of the river channel is marked as C _i The content of one cubic meter of algae in the river channel is recorded as Z _i 。

Step 2: the quantity B of white garbage in one cubic meter of the received river channel _i Dividing the standard quantity B of white garbage in one cubic meter to obtainIf->Quantity B of the acquisition _i Storing the record;

step 3: the radioactive substance content in one cubic meter of the received river channel is recorded as F _i Dividing by standard quantity F of radioactive substance in cubic meter to obtainIf->The content F of the collection is then _i Storing the record;

step 4: the ammonia nitrogen, the total phosphorus, the total nitrogen and the heavy metal content A in one cubic meter of the received river channel _i 、P _i 、N _i And J _i Dividing the standard contents of ammonia nitrogen, total phosphorus, total nitrogen and heavy metal in one cubic meter by the standard contents of A, P, N and J to obtainAnd->If->Or->One of them is greater than 1, the content A collected this time is _i 、P _i 、N _i Or J _i Storing the record;

step 5: the microorganism content in one cubic meter of the received river channel is recorded as C _i Dividing the standard quantity of microorganisms in one cubic meter by the standard quantity C of microorganisms to obtainIf->The content C of the collection is then _i Storing the record;

step 6: the quantity Z of algae in one cubic meter of the received river channel _i Dividing by standard quantity Z of algae in cubic meter to obtainIf->The number Z of the collection _i Storing the record;

step 7: calculating the total pollution amount of river water:

wherein omega _{White color} Omega is the percentage of white refuse in total pollutants _{Put and put} Omega is the percentage of radioactive material in the total contaminants _Ammonia Omega is the percentage of ammonia nitrogen in total pollutants _{Phosphorus (P)} As a percentage of total phosphorus in total contaminants，ω _{Nitrogen and nitrogen} Omega is the percentage of total nitrogen in total contaminants _{Gold alloy} Omega is the percentage of heavy metals in the total contaminants _Micro-scale Omega is the percentage of microorganisms in total contaminants _{Algae (algae)} Is the percentage of algae in the total pollutants.

Step 8: total pollution M of river course _i Dividing the standard river pollution amount by M standard to obtainAnd will->Transmitting to the server through the wireless communication module, and simultaneously transmitting +.>And->The ratio of (2) is sent to a server;

the method comprises the steps that a calculation integrated result is transmitted to a server through a wireless communication module, the server can be a computer, a mobile phone or a PAD, the server displays the received calculation result to a monitoring person, the monitoring person is reminded to process according to the result, the server comprises a reminding module, and the server receives the calculation resultThe reminding module comprises a reminding lamp and a short message sending mode, ifThen the water pollution of the river channel exceeds the standard, and the total pollution amount M of the river channel is calculated _i Storing records, starting a reminding module, lighting a reminding lamp, sending reminding short messages to a mobile phone of a monitoring person, reminding the monitoring person to process in time, inquiring specific reasons of river pollution in a data analysis module by the monitoring person, and storing recorded B in the data analysis module _i 、F _i 、A _i 、P _i 、N _i 、J _i 、C _i Or Z is _i The values of (2) are processed pertinently, the processing efficiency is improved, meanwhile, the ratios of the pollutants to the standard values are arranged in order from large to small, and the workers can start to process the pollutants with the most serious pollution conveniently.

Example 2

The difference with embodiment 1 is that, this water affair intelligent monitoring system based on thing networking, its characterized in that, water affair intelligent monitoring system based on thing networking still includes PH value sensor, and PH value sensor inserts thing networking cloud platform, and PH value sensor is used for gathering the PH value of river course river, if the PH value that detects is higher than or is less than the standard value, transmits the PH value that detects to the server through wireless communication module, and the server starts the warning module, reminds monitoring personnel to handle in time.

The above embodiments are only some embodiments of the present invention, but the protection scope of the present invention is not limited thereto, and any person skilled in the art should be able to apply equivalents and modifications according to the technical solution and the inventive concept thereof within the scope of the present invention.

Claims (6)

1. The utility model provides a water affair intelligent monitoring system based on thing networking which characterized in that, this water affair intelligent monitoring system based on thing networking includes: the system comprises a data acquisition module, an Internet of things cloud platform, a data analysis module, a wireless communication module and a server side;

the data acquisition module is used for acquiring pollutants in the urban river channel and comprises a camera, a radioactive substance detector, a water quality detector, a microorganism sensor and an algae sensor, wherein the camera is used for capturing white garbage in the river channel, the radioactive substance detector is used for detecting the content of radioactive substances in the river channel, the water quality detector is used for detecting various components in the river channel, and the microorganism sensor and the algae sensor are used for respectively detecting microorganisms and algae in the river channel;

the Internet of things cloud platform is used for receiving and storing acquired data and transmitting the data to the data analysis module;

the data analysis module performs integration calculation on the received data, and then transmits the result to the server through the wireless communication module;

and the server displays the received calculation result to a monitor, and reminds the monitor to process according to the result.

2. The intelligent monitoring system of water affairs based on thing networking of claim 1, wherein, the data acquisition module's collection process specifically is:

s1: capturing the quantity of white garbage in a cubic meter of a river channel by a camera, and transmitting the quantity to a data analysis module;

s2: the radioactive substance detector collects the content of radioactive substances in one cubic meter of river channel and transmits the content to the data analysis module;

s3: the water quality tester collects chemical substances in a river channel, detects the contents of ammonia nitrogen, total phosphorus, total nitrogen and heavy metals in one cubic meter, and transmits the contents to the data analysis module;

s4: the microbial sensor collects the content of microorganisms in a cubic meter of a river channel and transmits the content to the data analysis module;

s5: the algae sensor collects the content of cubic meter algae in the river channel and transmits the content to the data analysis module.

3. The intelligent monitoring system of water affairs based on thing networking of claim 1, wherein the integration calculation of data analysis module to received data specifically is:

step 1: the quantity of white garbage in one cubic meter of the received river channel is recorded as B _i The radioactive substance content in one cubic meter of river channel is marked as F _i The contents of ammonia nitrogen, total phosphorus, total nitrogen and heavy metal in one cubic meter of river channel are respectively A _i 、P _i 、N _i And J _i The microorganism content in one cubic meter of the river channel is marked as C _i The content of one cubic meter of algae in the river channel is recorded as Z _i 。

Step 2: the quantity B of white garbage in one cubic meter of the received river channel _i Dividing by standard quantity B of white refuse in cubic meter _{Label (C)} ObtainingIf->Quantity B of the acquisition _i Storing the record;

step 3: the radioactive substance content in one cubic meter of the received river channel is recorded as F _i Divided by the standard quantity F of radioactive material in one cubic meter _{Label (C)} ObtainingIf->The content F of the collection is then _i Storing the record;

step 4: the ammonia nitrogen, the total phosphorus, the total nitrogen and the heavy metal content A in one cubic meter of the received river channel _i 、P _i 、N _i And J _i Dividing the standard contents A of ammonia nitrogen, total phosphorus, total nitrogen and heavy metal in one cubic meter respectively _{Label (C)} 、P _{Label (C)} 、N _{Label (C)} And J _{Label (C)} ObtainingAnd->If->Or->One of them is greater than 1, the content A collected this time is _i 、P _i 、N _i Or J _i Storing the record;

step 5: the microorganism content in one cubic meter of the received river channel is recorded as C _i Dividing the standard quantity of microorganisms in one cubic meter by the standard quantity C of microorganisms to obtainIf->The content C of the collection is then _i Storing the record;

step 6: the quantity Z of algae in one cubic meter of the received river channel _i Dividing by standard quantity Z of algae in cubic meter to obtainIf->The number Z of the collection _i Storing the record;

step 7: calculating the total pollution amount of river water:

wherein omega _{White color} Omega is the percentage of white refuse in total pollutants _{Put and put} Omega is the percentage of radioactive material in the total contaminants _Ammonia Omega is the percentage of ammonia nitrogen in total pollutants _{Phosphorus (P)} Omega as a percentage of total phosphorus in total contaminants _{Nitrogen and nitrogen} Omega is the percentage of total nitrogen in total contaminants _{Gold alloy} Omega is the percentage of heavy metals in the total contaminants _Micro-scale Omega is the percentage of microorganisms in total contaminants _{Algae (algae)} Is the percentage of algae in the total pollutants.

Step 8: total pollution M of river course _i Dividing the standard river pollution amount by M standard to obtainAnd will->Transmitting to the server through the wireless communication module, and simultaneously transmitting +.>And->The ratio of (2) is sent to the server.

4. The intelligent monitoring system of water affairs based on thing networking of claim 1, wherein, the server side includes a warning module, and the server side receivesAnd the ratio of each pollutant to the standard value, the reminding module comprises a reminding lamp and a short message sending mode, if>1, the total pollution M _i The storage record, start and remind the module, the warning lamp lights, send the warning SMS simultaneously and remind the cell-phone of monitoring personnel, remind monitoring personnel to handle in time, arrange each pollutant and standard value's ratio according to big to little order simultaneously, the staff of being convenient for begins to handle from the most serious pollutant of pollution.

5. The intelligent monitoring system of water affairs based on thing networking of claim 1, wherein, the server is computer, cell-phone or PAD.

6. The intelligent monitoring system for water service based on the internet of things according to claim 1, further comprising a PH value sensor, wherein the PH value sensor is connected to the cloud platform of the internet of things and is used for collecting the PH value of river water in a river channel, and if the detected PH value is higher or lower than a standard value, the detected PH value is transmitted to a server through a wireless communication module to remind monitoring staff of timely treatment.