CN118054975A - Intelligent management system for river sewage outlet - Google Patents

Abstract

The invention discloses an intelligent management system for a river inlet drain outlet, which relates to the technical field of drain outlet management.

Description

Intelligent management system for river sewage outlet

Technical Field

The invention relates to the technical field of drain outlet management, in particular to an intelligent management system for a river-entering drain outlet.

Background

With the rapid development of industrialization and urbanization, the protection and treatment of water resources are becoming increasingly a focus of social concern. The sewage outlet is used as a main channel for discharging industrial wastewater and domestic sewage, and the water quality condition directly influences the health of water bodies such as rivers, lakes and the like. Therefore, the establishment of an effective sewage outlet water quality monitoring system has important significance for protecting water environment and promoting sustainable development;

In the prior art, the method for monitoring the water quality of the river inlet drain outlet in real time monitors the water quality of the river inlet drain outlet by means of various high-precision sensors, the high-precision sensors have high-performance detection functions, and a small amount of analysis functions can be provided, so that whether the water quality exceeds a standard or not can be found, and the reasons for exceeding the standard, the exceeding degree and the pollution sources are required to be traced for the exceeding water quality are analyzed, and the analysis capability with high-strength performance is required, so that the water quality data acquired by real-time monitoring are synchronously uploaded to a cloud server by using a secret key at present, however, the risk of data loss exists in the transmission process, the data needs to be retransmitted once being lost, and business secrets of enterprises are possibly involved in the water quality data acquired by monitoring the river inlet drain outlet of enterprises, the data are retransmitted for many times, the water quality data encrypted by using the secret key are unsafe, and the possibility of secret key leakage is easy to be increased;

in order to solve the problems, the invention provides an intelligent management system for a river sewage outlet.

Disclosure of Invention

The invention aims to provide an intelligent management system for a river sewage outlet, which aims to solve the problems that in the prior art, a secret key is used for synchronously uploading collected water quality data to a cloud end, the risk of secret key leakage is increased in the repeated retransmission process based on data loss, and further, the business secret code of an enterprise possibly related to the water quality data is leaked;

The aim of the invention can be achieved by the following technical scheme:

an intelligent management system for a river sewage outlet, comprising:

The sewage outlet monitoring unit monitors the water quality parameter of one river sewage outlet in the target area in real time to obtain real-time water quality monitoring data of the river sewage outlet;

Based on the number of characters forming the water quality monitoring data of the river sewage outlet at the current moment after binary conversion, constructing the water quality monitoring data of the river sewage outlet at the previous moment by a processing transmission unit to obtain water quality comparison data at the previous moment, and recalibrating the water quality monitoring data of the river sewage outlet at the current moment after binary conversion into water quality system data at the current moment;

From left to right, respectively comparing the characters of the water quality system data forming the current moment with the characters of the water quality ratio data forming the previous moment one by one according to the number of bits, sequentially obtaining the equipotential characters of each character in the water quality system data forming the previous moment, and splicing all the equipotential characters according to the obtained sequence to obtain the water quality equipotential data of the current moment;

From left to right, the characters forming the water quality equipotential data at the current moment and the water quality comparison data at the previous moment are respectively compared one by one according to the digits to obtain a plurality of screening character strings and the corresponding screening digits, and water quality conversion data and water quality screening digits data of the sewage outlet entering the river at the current moment are respectively generated according to the screening character strings and the corresponding screening digits.

Further, the water quality parameters include pH value, temperature value, conductivity, turbidity value, dissolved oxygen value, permanganate index value, ammonia nitrogen concentration value, total phosphorus concentration value, heavy metal concentration value and flow.

Further, all water quality monitoring data of the river sewage outlet in the time period from the current moment to the past backtracking P1 are prestored in the processing and transmitting unit, and the P1 is a preset backtracking storage time threshold value.

Further, the step of obtaining the water quality comparison data at the previous moment comprises the following steps:

S11: acquiring water quality data of the river sewage outlet at the previous moment, performing binary conversion on the water quality data, recalibrating the converted binary number into water quality data at the previous moment, and simultaneously acquiring the number A1 of characters forming the water quality data at the previous moment;

S12: binary conversion is carried out on the received water quality data of the river sewage outlet at the current moment, the binary number after conversion is recalibrated into the water quality data at the current moment, and meanwhile, character data B1 forming the water quality data at the current moment is obtained;

s13: if A1 is more than or equal to B1, assigning 0 to C1, wherein C1 is the number of characters to be filled at the current moment, otherwise, calculating and obtaining the number of characters to be filled at the current moment by using a formula C1=B1-A1;

s14: c1 characters are sequentially cut from the water quality system data at the previous moment according to the sequence from left to right, and the C1 characters are spliced into the water quality system data at the previous moment before cutting according to the sequence of cutting, so that the water quality comparison data at the current moment is obtained.

The invention has the beneficial effects that:

(1) According to the invention, the water quality monitoring data of a river sewage outlet at the current moment is obtained by setting the sewage outlet monitoring unit to monitor the water quality parameter of the river sewage outlet at the target area in real time, the processing transmission unit is arranged to compare the water quality monitoring data at the current moment according to the number of bits one by one, the characters are replaced based on the comparison result to obtain water quality equipotential data at the current moment, the water quality equipotential data at the current moment contains the characteristics of the water quality monitoring data transmitted at the last moment, then the water quality equipotential data at the current moment and the water quality monitoring data after binary conversion at the last moment are compared to obtain a plurality of screening character strings and screening bits, the water quality conversion data at the current moment is obtained based on the plurality of screening character strings, the screening bits are converted into derivative data at the last moment, the water quality conversion data is separated into the conversion data and the screening bits in a mode of encrypting the transmission data by using a key, and the water quality conversion data are transmitted on the basis of the data, and the quality conversion data is not decrypted by a third party even if the lost data are not transmitted at the third moment, and the water quality conversion data cannot be further decrypted and the other data cannot be transmitted on the basis of the quality monitoring data at the third moment is ensured;

(2) The screening character strings obtained by the invention satisfy the following characteristics: the method is characterized in that the method is used for extracting water quality equipotential data at the current moment, all characters positioned between every two screening character strings in the water quality equipotential data at the current moment are identical to water quality monitoring data after being subjected to system conversion at the last moment, by adopting the method, based on the past water quality monitoring data at the last moment, only different data from the water quality monitoring data at the last moment are required to be transmitted at the current moment, the data quantity transmitted at the current moment is relatively reduced, the time of transmitting the data in a network is reduced, and the safety of transmitting the data is further ensured.

Drawings

The invention is further described below with reference to the accompanying drawings.

Fig. 1 is a system block diagram of the present invention.

Detailed Description

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 those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

As shown in fig. 1, the intelligent management system for the river sewage outlet comprises a sewage outlet monitoring terminal and a cloud analysis platform;

the sewage outlet monitoring terminal is used for monitoring the water quality of all the river inlet sewage outlets in the target area in real time, and comprises a plurality of sewage outlet monitoring modules, one sewage outlet monitoring module corresponds to one river inlet sewage outlet in the target area;

The sewage outlet monitoring module is used for monitoring water quality parameters corresponding to the sewage outlet of the river in the current area, and in the embodiment, the water quality parameters comprise a pH value, a temperature value, conductivity, a turbidity value, a dissolved oxygen value, a permanganate index value, an ammonia nitrogen concentration value, a total phosphorus concentration value, a heavy metal concentration value and a flow;

The sewage outlet monitoring module comprises a sewage outlet monitoring unit and a processing and transmitting unit, wherein the sewage outlet monitoring unit monitors water quality parameters corresponding to the sewage outlet of the river in real time to obtain water quality monitoring data of the sewage outlet of the river at the current moment, and transmits the water quality monitoring data to the processing and transmitting unit;

All water quality monitoring data of the river sewage inlet and outlet are pre-stored in the processing and transmitting unit, wherein the time of the water quality monitoring data starts from the current moment to the past time of P1, the P1 is a preset backtracking storage time threshold value, and the numerical value of the P1 is set based on the storage capacity of equipment for monitoring water quality parameters;

the processing and transmitting unit processes the water quality monitoring data of the river sewage outlet according to a preset processing rule after receiving the water quality monitoring data transmitted at the current moment, and the processing and transmitting unit is specifically as follows:

S11: acquiring water quality data of the river sewage outlet at the previous moment, performing binary conversion on the water quality data, recalibrating the converted binary number into water quality data at the previous moment, and simultaneously acquiring the number A1 of characters forming the water quality data at the previous moment;

S12: binary conversion is carried out on the received water quality data of the river sewage outlet at the current moment, the binary number after conversion is recalibrated into the water quality data at the current moment, and meanwhile, character data B1 forming the water quality data at the current moment is obtained;

s13: if A1 is more than or equal to B1, assigning 0 to C1, wherein C1 is the number of characters to be filled at the current moment, otherwise, calculating and obtaining the number of characters to be filled at the current moment by using a formula C1=B1-A1;

S14: c1 characters are sequentially cut from water quality system data at the previous moment according to the sequence from left to right, and the C1 characters are spliced into water quality system data at the previous moment before cutting according to the sequence of cutting, so that water quality comparison data at the current moment is obtained;

s15: the water quality equipotential data at the current moment is generated by comparison according to a preset bit comparison rule, and the specific steps are as follows:

S151: according to the sequence from left to right, respectively acquiring the first character in the water quality system data at the current moment and the water quality comparison data at the current moment, wherein the first character is correspondingly marked as D1 and E1;

If the character D1 is the same as the character E1, taking the number 1 as a substitute character of the character D1, otherwise, taking the number 0 as an equipotential character of the character D1;

S152: according to S151, comparing the water quality system data at the current moment with characters in the water quality ratio data at the current moment one by one according to the number of bits to obtain equipotential characters of all the characters in the water quality system data at the current moment;

s153: according to the position of each character in the water quality system data at the current moment, splicing the equipotential characters of all the characters in sequence from left to right to obtain the water quality equipotential data at the current moment;

S16: screening and extracting a plurality of screening character strings from the current time water quality equipotential data according to a preset screening rule, wherein the specific screening rule is as follows:

s161: comparing the water quality equipotential data at the current moment with the water quality comparison data at the current moment one by one according to the bit number in sequence from left to right;

in the comparison process, when a character with different characters in the same position in the water quality equipotential data at the current moment and the water quality comparison data at the current moment appears, calibrating the character as a screening character, and simultaneously recording the number of bits of the screening character, wherein the number of bits of the screening character represents the position of the screening character in the water quality equipotential data at the current moment from left to right;

after the recording is completed, continuing the comparison process until all characters in the water quality equipotential data at the current moment are compared;

S162: acquiring all the screening characters and the corresponding digits thereof after comparison, traversing the digits of all the screening characters, and splicing the screening characters with continuous digits according to the order from small digits to large digits to obtain a plurality of screening character strings, wherein for the screening characters with no continuous digits, the screening characters are also used as one screening character string;

meanwhile, the number of bits of the first screening character from left to right in each screening character string is calibrated as the screening number of bits of the corresponding screening character string;

S17: the method comprises the steps of performing duplicate removal on a plurality of screening character strings taken out of water quality equipotential data at the current moment, and establishing an association between the number of screening bits of the duplicate screening character strings and the screening character strings which are consistent with the duplicate screening character strings and are retained after duplicate removal, wherein at least one screening bit is at least one corresponding to each screening character string which is retained after duplicate removal;

For example, if there are 2 screening strings, which are identical to the screening string A1, in the plurality of screening strings extracted from the current time water quality allele data and are one screening string A1, one of the three screening strings is arbitrarily reserved, and an association relationship is established between the remaining two duplicate removal screening strings and the reserved one screening string;

S18: aiming at all the screening character strings which are remained after the duplication removal, respectively obtaining all screening digits corresponding to each screening character string, and selecting the screening digits with the smallest numerical value from the screening digits as the reference digits of the screening digits;

simultaneously splicing all screening digits corresponding to each screening character string according to the sequence from small to large to obtain a screening digit sequence of each screening character string;

According to the sequence from small to large of the parameter bit number of each screening character string, all the screening character strings which are kept after the duplication removal are spliced to obtain water quality conversion data at the current moment, and the screening bit sequences of all the screening character strings which are kept after the duplication removal are spliced to obtain the screening bit data at the current moment;

the processing and transmitting unit transmits the water quality conversion data and the screening bit data of the river sewage outlet at the current moment to the cloud analysis platform;

the cloud analysis platform is used for analyzing water quality monitoring data of all river sewage inlets and outlets in a target area at the cloud, and comprises a butt joint reduction unit and an analysis early warning unit;

the cloud analysis platform receives the water quality conversion data and the screening bit data of the river entering sewage outlet at the current time of transmission and then transmits the water quality conversion data and the screening bit data to the docking and restoring unit, and the docking and restoring unit stores water quality monitoring data of all the river entering sewage outlets in the target area at all times;

The butt joint reduction unit receives the transmitted water quality conversion data and screening bit data of the river inlet drain outlet at the current moment, firstly obtains water quality system data at the previous moment according to the same step as S11, then obtains water quality monitoring data corresponding to the river inlet drain outlet at the current moment by referring to the obtained water quality system data at the previous moment according to the received water quality conversion data and screening bit data of the river inlet drain outlet at the current moment, and transmits the water quality monitoring data to the analysis and early warning unit;

The analysis and early warning unit is used for inputting the water quality monitoring data of the river inlet drain outlet at the current moment obtained by reduction into the water quality analysis model, judging whether the water quality of the river inlet drain outlet at the current moment exceeds the standard or not by the water quality analysis model and outputting the water quality analysis data of the river inlet drain outlet at the current moment;

The water quality analysis data of the river sewage outlet at the current moment comprises water quality signal quantity;

The water quality signal quantity is 1 or 0, the water quality signal quantity is 1, the water quality of the river inlet drain outlet at the current moment exceeds the standard, the water quality signal quantity is 0, and the water quality of the river inlet drain outlet at the current moment is normal;

when the water quality signal quantity is 1, the water quality analysis data of the river sewage outlet at the current moment also comprises out-of-standard water quality parameters, possible reasons for out-of-standard water quality and the like;

In the description of the present specification, the descriptions of the terms "one embodiment," "example," "specific example," and the like, mean that a particular feature, structure, material, or characteristic described in connection with the embodiment or example is included in at least one embodiment or example of the present invention. In this specification, schematic representations of the above terms do not necessarily refer to the same embodiments or examples. Furthermore, the particular features, structures, materials, or characteristics described may be combined in any suitable manner in any one or more embodiments or examples.

The foregoing is merely illustrative and explanatory of the invention, as various modifications and additions may be made to the particular embodiments described, or in a similar manner, by those skilled in the art, without departing from the scope of the invention or exceeding the scope of the invention as defined in the claims.

The foregoing describes one embodiment of the present invention in detail, but the description is only a preferred embodiment of the present invention and should not be construed as limiting the scope of the invention. All equivalent changes and modifications within the scope of the present invention are intended to be covered by the present invention.

Claims (8)

1. An intelligent management system for a river sewage outlet, which is characterized by comprising:

The sewage outlet monitoring unit monitors the water quality parameter of one river sewage outlet in the target area in real time to obtain real-time water quality monitoring data of the river sewage outlet;

Based on the number of characters forming the water quality monitoring data of the river sewage outlet at the current moment after binary conversion, constructing the water quality monitoring data of the river sewage outlet at the previous moment by a processing transmission unit to obtain water quality comparison data at the previous moment, and recalibrating the water quality monitoring data of the river sewage outlet at the current moment after binary conversion into water quality system data at the current moment;

From left to right, respectively comparing the characters of the water quality system data forming the current moment with the characters of the water quality ratio data forming the previous moment one by one according to the number of bits, sequentially obtaining the equipotential characters of each character in the water quality system data forming the previous moment, and splicing all the equipotential characters according to the obtained sequence to obtain the water quality equipotential data of the current moment;

From left to right, the characters forming the water quality equipotential data at the current moment and the water quality comparison data at the previous moment are respectively compared one by one according to the digits to obtain a plurality of screening character strings and the corresponding screening digits, and water quality conversion data and water quality screening digits data of the sewage outlet entering the river at the current moment are respectively generated according to the screening character strings and the corresponding screening digits.

2. The intelligent management system of a river sewage outlet according to claim 1, wherein the water quality parameters comprise pH, temperature, conductivity, turbidity, dissolved oxygen, permanganate index, ammonia nitrogen concentration, total phosphorus concentration, heavy metal concentration and flow.

3. The intelligent management system for a river sewage outlet according to claim 1, wherein all water quality monitoring data of the river sewage outlet in a time period of backtracking P1 from the current moment to the past is prestored in the processing and transmitting unit, and P1 is a preset backtracking storage time threshold.

4. The intelligent management system for a river sewage outlet according to claim 1, wherein the step of obtaining the water quality comparison data at the previous moment is as follows:

S11: acquiring water quality data of the river sewage outlet at the previous moment, performing binary conversion on the water quality data, recalibrating the converted binary number into water quality data at the previous moment, and simultaneously acquiring the number A1 of characters forming the water quality data at the previous moment;

S12: binary conversion is carried out on the received water quality data of the river sewage outlet at the current moment, the binary number after conversion is recalibrated into the water quality data at the current moment, and meanwhile, character data B1 forming the water quality data at the current moment is obtained;

s13: if A1 is more than or equal to B1, assigning 0 to C1, wherein C1 is the number of characters to be filled at the current moment, otherwise, calculating and obtaining the number of characters to be filled at the current moment by using a formula C1=B1-A1;

s14: c1 characters are sequentially cut from the water quality system data at the previous moment according to the sequence from left to right, and the C1 characters are spliced into the water quality system data at the previous moment before cutting according to the sequence of cutting, so that the water quality comparison data at the current moment is obtained.

5. The intelligent management system for a river sewage outlet according to claim 1, wherein the step of obtaining the water quality equipotential data at the current moment is as follows:

S151: according to the sequence from left to right, respectively acquiring the first character in the water quality system data at the current moment and the water quality comparison data at the current moment, wherein the first character is correspondingly marked as D1 and E1;

If the character D1 is the same as the character E1, taking the number 1 as a substitute character of the character D1, otherwise, taking the number 0 as an equipotential character of the character D1;

S152: according to S151, comparing the water quality system data at the current moment with characters in the water quality ratio data at the current moment one by one according to the number of bits to obtain equipotential characters of all the characters in the water quality system data at the current moment;

S153: and splicing the equipotential characters of all the characters in sequence from left to right according to the position of each character in the water quality data at the current moment to obtain the water quality equipotential data at the current moment.

6. The intelligent management system for a river sewage outlet according to claim 1, wherein the specific steps of obtaining a plurality of screening character strings and the corresponding screening digits thereof are as follows:

s161: comparing the water quality equipotential data at the current moment with the water quality comparison data at the current moment one by one according to the bit number in sequence from left to right;

In the comparison process, when a character with different characters at the same position in the water quality comparison data at the current moment appears in the water quality equipotential data at the current moment, calibrating the character as a screening character, and simultaneously recording the bit number of the screening character;

after the recording is completed, continuing the comparison process until all characters in the water quality equipotential data at the current moment are compared;

S162: acquiring all the screening characters and the digits thereof after comparison, traversing the digits of all the screening characters, and splicing the screening characters with continuous digits according to the order from small digits to large digits to obtain a plurality of screening character strings, wherein for the screening characters with no continuous digits, the screening characters are also used as one screening character string;

And meanwhile, the number of bits of the first screening character from left to right in each screening character string is calibrated as the screening number of bits of the corresponding screening character string.

7. The intelligent management system for a river sewage outlet according to claim 1, wherein the specific steps of generating the current moment according to the obtained plurality of screening character strings and the corresponding screening digits respectively are as follows:

S17: the method comprises the steps of performing duplicate removal on a plurality of screening character strings taken out of water quality equipotential data at the current moment, and establishing an association between the number of screening bits of the duplicate screening character strings and the screening character strings which are consistent with the duplicate screening character strings and are retained after duplicate removal, wherein at least one screening bit is at least one corresponding to each screening character string which is retained after duplicate removal;

S18: for all the screening character strings which are remained after the duplication removal, respectively obtaining all the screening digits corresponding to each screening character string, and selecting the screening digit with the smallest value from the screening digits as the reference digit of the screening digits;

simultaneously splicing all screening digits corresponding to each screening character string according to the sequence from small to large to obtain a screening digit sequence of each screening character string;

And according to the sequence of the parameter bit number of each screening character string from small to large, splicing all the screening character strings which are reserved after the duplication removal to obtain water quality conversion data of the river sewage outlet at the current moment, and splicing the screening bit sequences of all the screening character strings which are reserved after the duplication removal to obtain the screening bit data of the river sewage outlet at the current moment.

8. The intelligent management system of a river sewage outlet according to claim 1, further comprising a cloud analysis platform, wherein the cloud analysis platform is used for analyzing and early warning water quality monitoring data of the river sewage outlet at the cloud.