CN115950066A - Distributed cooling control system and method based on water resource collection and processing - Google Patents

Abstract

The invention discloses a distributed cooling control system and method based on water resource collection and processing, belonging to the technical field of water resource utilization cooling control; the method comprises the steps of obtaining ring mobility by simultaneously integrating real-time temperature, real-time humidity and real-time air pressure of each subregion in a target region and corresponding environment coefficients, integrally evaluating whether the temperature reduction of each subregion in the target region needs to be regulated according to the ring mobility, analyzing according to an integer part and a decimal part of the ring mobility to generate different temperature reduction instructions, implementing corresponding temperature reduction schemes according to different temperature reduction instructions, realizing dynamic temperature reduction of different subregions, improving the overall effect of temperature reduction of different subregions, and improving the utilization effect of water resources; the distributed cooling control method and the distributed cooling control system are used for solving the technical problem that the overall effect of distributed cooling control in the existing scheme is poor.

Description

Distributed cooling control system and method based on water resource collection and treatment

Technical Field

The invention relates to the technical field of water resource utilization and cooling control, in particular to a distributed cooling control system and method based on water resource collection and processing.

Background

In most cases, the outdoor temperature cannot be controlled, and people often have to stay in hot and clunky places for hours or more, such as open squares, sports venues, amusement parks and the like; in these outdoor large environments, air conditioners cannot be used, people must endure ubiquitous intense heat, and with a spray cooling system, the temperature of the large environment can be controlled locally.

When the existing spray cooling control scheme is implemented, most of the existing spray cooling control schemes only control the spraying equipment to perform intermittent spraying or continuous spraying through a preset program, and the existing spray cooling control schemes cannot perform self-adaptive dynamic spraying according to surrounding areas and environments and do not monitor and evaluate the running state of the spraying equipment, so that the abnormal spraying equipment has poor spraying effect, the overall water resource utilization effect is poor, and the overall distributed cooling control effect is poor.

Disclosure of Invention

The invention aims to provide a distributed cooling control system and method based on water resource collection and processing, which are used for solving the technical problem of poor overall effect of distributed cooling control in the existing scheme.

The purpose of the invention can be realized by the following technical scheme:

distributed cooling control system based on water resource collection handles includes:

the environment monitoring module is used for monitoring the environment of different subregions in the target region and analyzing data, and acquiring the real-time temperature, the real-time humidity and the real-time air pressure of each subregion in the target region by using the acquisition sensor at preset interval time;

respectively marking the real-time temperature, the real-time humidity and the real-time air pressure which are monitored each time as SWi, SSi and SQi; extracting the numerical values of the three data, and connecting in parallel to obtain the ring mobility HQ;

matching the ring mobility with a preset ring mobility threshold, if the ring mobility is greater than the ring mobility threshold, generating a regulation signal, and regulating and controlling the temperature reduction of each sub-region in the target region according to the regulation signal;

the environment analysis module is used for acquiring an integer part and a decimal part of the ring mobility, setting the integer part and the decimal part as a first numerical value H1 and a second numerical value H2 respectively, and matching the first numerical value H1 and the second numerical value H2 with a corresponding first threshold value H10 and a corresponding second threshold value H20 respectively to obtain different cooling instructions and corresponding cooling schemes;

when a cooling scheme is implemented according to different cooling instructions, setting the starting time point as a first time stamp, setting the time point when the corresponding cooling instruction disappears as a second time stamp, and counting the cooling duration of the corresponding cooling instruction according to the first time stamp and the second time stamp;

the ring mobility, the plurality of corresponding cooling instructions and the cooling duration form an environment analysis set;

the monitoring and evaluating module is used for analyzing and evaluating the cooling behaviors of different cooling schemes according to the environment analysis set to obtain a monitoring and evaluating set;

and the abnormal checking module is used for performing tracing checking on the subsequent cooling behavior of the selected sub-region to obtain an abnormal checking set containing the first tracing signal, the second tracing signal and the third tracing signal, and generating a corresponding alarm prompt according to different tracing signals in the abnormal checking set.

Preferably, the calculation formula of the ring mobility HQ is:

；

in the formula, h1, h2 and h3 are preset proportionality coefficients which are all larger than zero, and the value ranges are (0,5), and HX is an environment coefficient corresponding to each sub-region.

Preferably, the different cooling instructions include a first cooling instruction, a second cooling instruction, a third cooling instruction and a fourth cooling instruction, and the cooling schemes of low water volume low distribution, low water volume high distribution, high water volume low distribution and high water volume high distribution are respectively and correspondingly implemented.

Preferably, the specific steps of monitoring the acquisition of the evaluation set include:

obtaining cooling time lengths corresponding to the cooling instructions in the environment analysis set, and respectively marking the cooling time lengths corresponding to the cooling instructions as JSk, and k =1,2,3,4; combining the cooling duration corresponding to the plurality of cooling instructions with the corresponding standard cooling duration JSk0, and obtaining a cooling evaluation value JP through calculation; the calculation formula of the reduced evaluation value JP is as follows: JP = JSk/JSk;

acquiring an integer part of the degradation value, marking the integer part as J1, and matching the integer part with a preset degradation threshold value J0;

if J1 is less than or equal to J0, judging that the cooling subarea corresponding to the cooling scheme is normal and generating a positive-falling signal;

if J1 is larger than J0, judging that the cooling sub-region corresponding to the cooling scheme is abnormal and generating a reducing signal, and marking the cooling sub-region as a selected sub-region according to the reducing signal;

the degraded value and the corresponding degraded positive signal and degraded signal form a monitoring evaluation set.

Preferably, the specific steps of acquiring the abnormal verification set include:

counting the analysis and evaluation results of m subsequent cooling behaviors of the selected sub-region, and if m cooling behavior analysis and evaluation results have m different signals, judging that the operation of the spraying equipment in the selected sub-region is abnormal and generating a first tracing signal;

if v reducing signals exist in the analysis and evaluation results of the m reducing behaviors, judging that the operation of the spraying equipment in the selected sub-area is abnormal and generating a second tracing signal; wherein v is more than 0 and less than m, and m and v are positive integers;

if the m cooling behaviors have less than v reducing signals or positive reducing signals, judging that the spraying equipment in the selected sub-area operates normally and generating a third tracing signal;

the first tracing signal, the second tracing signal and the third tracing signal form an abnormal verification set.

Preferably, still include water resource monitoring module for monitor statistics to the water resource of collecting to whether qualified the aassessment is carried out for providing the water resource that each subregion implemented spray cooling in the target area, include:

acquiring the total amount of the collected water resources, marking the total amount as a first total amount, marking the time point when the collected water resources start to be processed as a third timestamp, marking the total amount of the processed water resources as a second total amount, and marking the time point for evaluating the second total amount as a fourth timestamp;

counting the time length between the fourth time stamp and the third time stamp, acquiring the ratio between the second total amount and the time length, marking the ratio as a first ratio, and analyzing the first ratio;

if the first ratio is smaller than the filtering threshold value, generating a first processing signal;

if the first ratio is not smaller than the filtering threshold, generating a second processing signal; the first processed signal and the second processed signal constitute filter processed data.

Preferably, the impurity proportion in the treated water resource is obtained, and the impurity proportion is matched with a preset proportion threshold;

if the impurity ratio is smaller than the ratio threshold, generating a first filtering signal;

if the impurity proportion is not less than the proportion threshold value, generating a second filtering signal;

the first filtered signal and the second filtered signal form filtered analysis data;

and evaluating the processing condition of the water resource according to the filtering processing data and the filtering analysis data by using a water resource prompting module and carrying out self-adaptive alarm prompting.

Preferably, the working steps of the water resource prompting module include:

and performing simultaneous evaluation on the filtering signals in the filtering analysis data and the processing signals in the filtering processing data to obtain a first alarm instruction, a second alarm instruction, a third alarm instruction and a fourth alarm instruction, and prompting an administrator to immediately perform processing check, filtering check and replacement check alarm prompting according to the second alarm instruction, the third alarm instruction and the fourth alarm instruction.

In order to solve the problem, the invention also discloses a distributed cooling control method based on water resource collection and treatment, which comprises the following steps:

monitoring and data analysis are carried out on the environment of different sub-areas in a target area, real-time temperature, real-time humidity and real-time air pressure of each sub-area in the target area are obtained at preset interval time periods, and ring mobility is immediately obtained in parallel, and whether the corresponding sub-area needs to be cooled and regulated is judged according to the ring mobility;

generating different cooling instructions according to the integer part and the decimal part of the ring mobility, implementing corresponding cooling schemes, and meanwhile counting the cooling time length for executing the cooling schemes;

and evaluating the cooling state of the corresponding sub-region according to the cooling time to obtain the selected sub-region, tracing and checking the subsequent cooling behavior of the selected sub-region, and carrying out self-adaptive alarm prompt according to the checking result.

Preferably, the method further comprises the following steps:

monitoring and counting the collected water resources, acquiring a first ratio for analysis according to the total amount of the processed water resources and the corresponding processing time, and analyzing the first ratio to obtain filtering processing data containing a first processing signal and a second processing signal;

acquiring the impurity ratio in the processed water resource and matching the impurity ratio with a preset ratio threshold value to obtain filtering analysis data containing a first filtering signal and a second filtering signal;

and evaluating the processing condition of the water resource according to the filtering processing data and the filtering analysis data and carrying out self-adaptive alarm prompt.

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

according to the invention, on one hand, the ring mobility is obtained by simultaneously integrating the real-time temperature, the real-time humidity and the real-time air pressure of each subregion in the target region and the corresponding environment coefficient, the integral evaluation is carried out on whether the temperature reduction of each subregion in the target region needs to be regulated according to the ring mobility, different temperature reduction instructions are generated by analyzing the integral part and the fractional part of the ring mobility, and the corresponding temperature reduction scheme is implemented according to the different temperature reduction instructions, so that the dynamic temperature reduction of different subregions is realized, the integral effect of the temperature reduction of different subregions is improved, and the utilization effect of water resources is improved.

On the other hand, the invention monitors and evaluates the spray cooling condition of each subregion, judges whether the spray cooling implementation state is normal, performs traceback check on the selected subregion in the abnormal state and automatically generates a corresponding alarm prompt, so that the abnormal spray cooling of the selected subregion can be checked in time, and the overall effect of cooling control is ensured in the aspect of spray operation.

According to the other aspects disclosed by the invention, the collected water resource is monitored and evaluated, whether the water resource is qualified or not is analyzed from the aspect of the water resource processing time and the aspect of impurity content, and different types of alarm prompts are generated in a self-adaptive manner, so that a manager can check abnormal water resource processing in time, and the influence of the processed unqualified water resource on the operation of spraying equipment in spraying cooling is avoided.

Drawings

The invention will be further described with reference to the accompanying drawings.

FIG. 1 is a block diagram of a distributed cooling control system based on water resource collection processing according to the present invention.

FIG. 2 is a block flow diagram of an embodiment of a distributed cooling control method based on a water resource collection process.

FIG. 3 is a block diagram of a distributed cooling control method based on a water resource collection process according to another embodiment of the present invention.

Detailed Description

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

In the first embodiment, as shown in fig. 1, the invention provides a distributed cooling control system based on water resource collection and processing, which comprises an environment monitoring module, a monitoring and evaluation module, an abnormal verification module, a water resource monitoring module and a water resource prompt module;

the artificial fog space environment cooling principle is an aerial fog double-flow and evaporation heat absorption principle, fog particles with the particle diameter of 1-10 microns are diffused to a cooling target area at a cooling terminal, are continuously evaporated in the diffusion process, and absorb a large amount of heat energy of the target area, the cooling effect of 6-10 ℃ can be generally achieved, and the cooling amplitude is 14 ℃ under extreme conditions;

in addition, the effect of spray cooling is greatly influenced by the air humidity, and the higher the relative humidity is, the worse the effect is; therefore, the effect of spray cooling on indoor is poor, and particularly the effect of spray cooling on indoor with poor ventilation is limited;

the application scene in the embodiment of the invention can be an outdoor place needing cooling, the overall effect of spray cooling is improved by implementing dynamic cooling in a self-adaptive manner according to the environmental conditions of different sub-areas in a target area, the state of implementing spray cooling of each sub-area is monitored and analyzed, the treatment of recovered water resources is monitored and analyzed, and the dynamic maintenance is carried out on the spraying equipment and the water resource treatment equipment of each sub-area in a self-adaptive manner, so that the overall effect of implementing spray cooling can be further improved.

The environment monitoring module is used for monitoring and analyzing data of environments of different sub-areas in the target area to obtain an environment analysis set; the method comprises the following steps:

in a preset interval time period, the unit of the interval time period is minute, a specific numerical value can be obtained based on the existing spraying interval time period, a real-time temperature, a real-time humidity and a real-time air pressure of each sub-region in a target region are obtained by using an acquisition sensor, and the monitoring behaviors in each time are numbered and marked as i, i = {1,2,3,. Once, n }; n is a positive integer; the acquisition sensor can be a temperature sensor, a humidity sensor and an air pressure sensor; the target area comprises a plurality of sub-areas distributed at different positions;

respectively marking the real-time temperature, the real-time humidity and the real-time air pressure which are monitored each time as SWi, SSi and SQi; extracting the numerical values of the three data, and obtaining the ring mobility HQ through calculation; the calculation formula of the ring mobility HQ is as follows:

；

in the formula, h1, h2 and h3 are preset proportionality coefficients which are all larger than zero, and the value ranges are (0,5), HX is an environment coefficient corresponding to each sub-region, h1 can be 1.863, h2 can be 0.554, and h3 can be 1.217;

it should be noted that the ring mobility is a numerical value used for performing overall evaluation on whether the temperature reduction of each sub-region in the target region needs to be regulated and controlled; the areas of the sub-regions can be the same or different, and can be set according to the actual scene, and in addition, the environment coefficients corresponding to the sub-regions can be obtained through two schemes;

scheme one)

In a preset monitoring time period, calculating and obtaining the number of the total people in each sub-area and the average number of people in all the sub-areas by counting the ratio;

scheme two)

Counting the total number ZR of people appearing in each subarea, the total area ZM occupied by each subarea and the greening area LM in a preset monitoring period, and acquiring the average number PR of people appearing in all the subareas; extracting numerical values of all data, connecting the numerical values, and calculating to obtain an environment coefficient HX corresponding to each subregion; the calculation formula of the environmental coefficient HX is as follows:

；

in the formula, g1 and g2 are preset proportionality coefficients, and g2 is more than 0 and less than g1; g1 can take the value of 1.567, g2 can take the value of 0.683; the larger the greening area is, the larger the positive influence on the sub-area cooling is;

realizing differential dynamic spray cooling of different sub-areas based on the environment coefficient;

matching the ring mobility with a preset ring mobility threshold;

if the ring mobility is not greater than the ring mobility threshold, generating a monitoring signal;

if the ring mobility is larger than the ring mobility threshold, generating a regulation signal, and regulating and controlling the cooling of each subarea in the target area according to the regulation signal;

in the embodiment of the invention, because the number of the persons staying in different sub-areas is different, whether the spray cooling needs to be implemented or not is judged through the ring mobility corresponding to each sub-area, so that the differential dynamic spray cooling is implemented on different sub-areas, the utilization effect of the collected water resource is maximized, and compared with the prior scheme in which the spray cooling is triggered by a single item of temperature, the embodiment of the invention can realize a more timely and efficient spray cooling regulation and control effect.

The environment analysis module is used for acquiring an integer part and a decimal part of the ring mobility, setting the integer part and the decimal part as a first numerical value H1 and a second numerical value H2 respectively, and matching the first numerical value H1 and the second numerical value H2 with a corresponding first threshold value H10 and a corresponding second threshold value H20 respectively;

if the first numerical value H1 is smaller than the first threshold value H10 and the second numerical value H2 is smaller than the second threshold value H20, generating a first cooling instruction and implementing a low-water-volume low-distribution cooling scheme;

if the first value H1 is smaller than the first threshold value H10 and the second value H2 is not smaller than the second threshold value H20, generating a second cooling instruction and implementing a low-water-volume high-distribution cooling scheme;

if the first numerical value H1 is not less than the first threshold value H10 and the second numerical value H2 is less than the second threshold value H20, generating a third cooling instruction and implementing a high-water-volume low-distribution cooling scheme;

if the first value H1 is not less than the first threshold value H10 and the second value H2 is not less than the second threshold value H20, generating a fourth cooling instruction and implementing a high-water-content high-distribution cooling scheme;

when a cooling scheme is implemented according to different cooling instructions, setting a starting time point as a first time stamp, setting a time point at which the corresponding cooling instruction disappears as a second time stamp, and counting the cooling duration of the corresponding cooling instruction according to the first time stamp and the second time stamp;

the ring mobility, the plurality of corresponding cooling instructions and the cooling duration form an environment analysis set;

in the embodiment of the invention, dynamic spray cooling can be implemented based on the ring mobility while judging whether spray cooling needs to be started or not through the ring mobility, wherein low water volume and high water volume refer to delivered water flow, and low distribution and high distribution refer to a space formed by water mist transmission in a spraying process; compared with the spray cooling in a fixed mode in the existing scheme, the dynamic cooling scheme of different sub-areas in the embodiment of the invention can more efficiently utilize water resources while implementing dynamic spray cooling.

The monitoring evaluation module is used for analyzing and evaluating the cooling behaviors of different cooling schemes according to the environment analysis set, and comprises:

obtaining a cooling time length corresponding to each cooling instruction in the environment analysis set, and respectively marking the cooling time lengths corresponding to a plurality of cooling instructions as JSk, and k =1,2,3,4; the cooling schemes can be expressed as corresponding to a first cooling instruction, a second cooling instruction, a third cooling instruction and a fourth cooling instruction; the duration may be in units of minutes;

combining the cooling duration corresponding to the cooling instructions with the standard cooling duration JSk, and calculating to obtain a cooling evaluation value JP; the calculation formula of the evaluation value JP is as follows: JP = JSk/JSk;

acquiring an integer part of the degradation value, marking the integer part as J1, and matching the integer part with a preset degradation threshold value J0;

if J1 is less than or equal to J0, judging that the cooling subarea corresponding to the cooling scheme is normal and generating a positive-falling signal;

if J1 is larger than J0, judging that the cooling sub-region corresponding to the cooling scheme is abnormal and generating a reducing signal, and marking the cooling sub-region as a selected sub-region according to the reducing signal;

the evaluation value reduction and the corresponding positive signal reduction and the corresponding abnormal signal reduction form a monitoring evaluation set;

in the embodiment of the invention, whether the spray cooling implementation state is normal is judged by monitoring and evaluating the spray cooling condition of each subarea so as to find and process the abnormity in time and ensure the stability of the spray cooling implementation.

The abnormal checking module is used for tracing and checking the subsequent cooling behavior of the selected sub-region, and comprises:

counting the analysis and evaluation results of m subsequent cooling behaviors of the selected sub-region, and if m cooling behavior analysis and evaluation results have m different signals, judging that the operation of the spraying equipment in the selected sub-region is abnormal and generating a first tracing signal; an exception is here understood to be a constant exception;

if v reducing signals exist in the analysis and evaluation results of the m reducing behaviors, judging that the operation of the spraying equipment in the selected sub-area is abnormal and generating a second tracing signal; wherein v is more than 0 and less than m, and m and v are positive integers; the presence of an exception here may be understood as a good-time-bad exception;

if the m cooling behaviors have less than v reducing signals or positive reducing signals, judging that the spraying equipment in the selected sub-area operates normally and generating a third tracing signal;

the first tracing signal, the second tracing signal and the third tracing signal form an abnormal verification set, and corresponding alarm prompts are generated according to different tracing signals in the abnormal verification set;

in the embodiment of the invention, the abnormity existing in the evaluation result is traced and checked, and the corresponding alarm prompt is automatically generated, so that the abnormal spray cooling of the sub-area can be checked in time, and the overall effect of cooling control is ensured in the aspect of spray operation.

Water resource monitoring module for monitor the water resource of collection and count to whether qualified aassessment is carried out for the water resource that provides each subregion implementation spray cooling in the target area, include:

acquiring the total amount of the collected water resources, marking the total amount as a first total amount, marking the time point when the collected water resources start to be processed as a third time stamp, marking the total amount of the processed water resources as a second total amount, and marking the time point when the second total amount is evaluated as a fourth time stamp;

counting the time length between the fourth time stamp and the third time stamp, acquiring the ratio of the second total amount to the time length, marking the ratio as a first ratio, and analyzing the first ratio;

if the first ratio is smaller than the filtering threshold value, generating a first processing signal;

if the first ratio is not smaller than the filtering threshold, generating a second processing signal; the first processing signal and the second processing signal form filtering processing data;

acquiring the impurity proportion in the treated water resource, and matching the impurity proportion with a preset proportion threshold; the acquisition of the impurity proportion in the water resource is the conventional technical means, and the specific steps are not described herein;

if the impurity ratio is smaller than the ratio threshold, generating a first filtering signal;

if the impurity proportion is not less than the proportion threshold, generating a second filtering signal;

the first filtering signal and the second filtering signal form filtering analysis data; the priority of the filtering analysis data is greater than that of the filtering processing data;

the water resource prompting module is used for evaluating the processing condition of the water resource according to the filtering processing data and the filtering analysis data and carrying out self-adaptive alarm prompting; the method comprises the following steps:

acquiring filtering processing data and filtering analysis data and evaluating;

if the filtering analysis data contains the first filtering signal and the filtering processing data contains the first processing signal, judging that the processing state of the water resource is normal and generating a first alarm instruction;

if the filtering analysis data contains a first filtering signal and the filtering processing data contains a second processing signal, judging that the processing condition of the water resource has processing abnormity and generating a second alarm instruction;

if the filtering analysis data contains the second filtering signal and the filtering processing data contains the first processing signal, judging that the processing condition of the water resource has filtering abnormity and generating a third alarm instruction;

if the filtered and analyzed data contains the second filtering signal and the filtered and processed data contains the second processing signal, judging that the processing condition of the water resource is abnormal and generating a fourth alarm instruction;

and prompting an administrator to immediately perform processing verification, filtering verification and replacement verification according to the second alarm instruction, the third alarm instruction and the fourth alarm instruction.

In the embodiment of the invention, the collected water resource is monitored and evaluated, whether the water resource is qualified or not is analyzed from the aspect of the water resource treatment duration and the aspect of impurity content, and different types of alarm prompts are generated in a self-adaptive manner, so that a manager can check abnormal water resource treatment in time, the influence of the treated unqualified water resource on the operation of spraying equipment in spraying cooling is avoided, and the influence is mainly to prevent the spraying equipment from being blocked;

it should be noted that the formulas mentioned above are all calculated by removing dimensions and taking values thereof, and are one formula that is obtained by collecting a large amount of data and performing software simulation to obtain the closest real situation, and the proportionality coefficient in the formula and each preset threshold in the analysis process are set by those skilled in the art according to the actual situation or obtained by simulating a large amount of data.

In a second embodiment, as shown in fig. 2, the present invention is a distributed cooling control method based on water resource collection processing, including:

monitoring and data analysis are carried out on the environment of different sub-areas in a target area, real-time temperature, real-time humidity and real-time air pressure of each sub-area in the target area are obtained at preset interval time periods and are connected in parallel to obtain ring mobility, and whether the corresponding sub-area needs to be cooled and regulated is judged according to the ring mobility;

generating different cooling instructions according to the integer part and the decimal part of the ring mobility, implementing corresponding cooling schemes, and meanwhile counting the cooling time length for executing the cooling schemes;

evaluating the cooling state of the corresponding sub-region according to the cooling time length to obtain the selected sub-region, tracing and checking the subsequent cooling behavior of the selected sub-region, and carrying out self-adaptive alarm prompt according to the checking result.

In a third embodiment, as shown in fig. 3, the present invention is a distributed cooling control method based on water resource collection and processing, further including:

monitoring and counting the collected water resources, acquiring a first ratio for analysis according to the total amount of the processed water resources and the corresponding processing time, and analyzing the first ratio to obtain filtering processing data containing a first processing signal and a second processing signal;

acquiring the impurity ratio of the processed water resource and matching the impurity ratio with a preset ratio threshold value to obtain filtering analysis data containing a first filtering signal and a second filtering signal;

and evaluating the processing condition of the water resource according to the filtering processing data and the filtering analysis data and carrying out self-adaptive alarm prompt.

In the embodiments provided in the present invention, it should be understood that the disclosed system may be implemented in other ways. For example, the above-described embodiments of the present invention are merely illustrative, and for example, the division of modules is only one logical function division, and there may be other division ways in actual implementation.

Modules described as separate parts may or may not be physically separate, and parts displayed as modules may or may not be physical modules, may be located in one place, or may be distributed on a plurality of network modules. Some or all of the modules may be selected according to actual needs to achieve the purpose of the solution of this embodiment.

In addition, functional modules in the embodiments of the present invention may be integrated into one processing module, or each of the modules may exist alone physically, or two or more modules are integrated into one module. The integrated module can be realized in a hardware mode, and can also be realized in a mode of hardware and a software functional module.

It is obvious to a person skilled in the art that the invention is not restricted to details of the above-described exemplary embodiments, but that it can be implemented in other specific forms without departing from the essential characteristics of the invention.

Finally, it should be noted that the above embodiments are only for illustrating the technical solutions of the present invention and not for limiting, and although the present invention is described in detail with reference to the preferred embodiments, it should be understood by those skilled in the art that modifications or equivalent substitutions may be made on the technical solutions of the present invention without departing from the spirit and scope of the technical solutions of the present invention.

Claims (10)

1. Distributed cooling control system based on water resource collection handles, its characterized in that includes:

the environment monitoring module is used for monitoring the environment of different subregions in the target region and analyzing data, and acquiring the real-time temperature, the real-time humidity and the real-time air pressure of each subregion in the target region by using the acquisition sensor at preset interval time;

respectively marking the real-time temperature, the real-time humidity and the real-time air pressure which are monitored each time as SWi, SSi and SQi; extracting the numerical values of the three data, and connecting in parallel to obtain the ring mobility HQ;

matching the ring mobility with a preset ring mobility threshold, if the ring mobility is greater than the ring mobility threshold, generating a regulation signal, and regulating and controlling the temperature reduction of each sub-region in the target region according to the regulation signal;

the environment analysis module is used for acquiring an integer part and a decimal part of the ring mobility, setting the integer part and the decimal part as a first numerical value H1 and a second numerical value H2 respectively, and matching the first numerical value H1 and the second numerical value H2 with a corresponding first threshold value H10 and a corresponding second threshold value H20 respectively to obtain different cooling instructions and corresponding cooling schemes;

when a cooling scheme is implemented according to different cooling instructions, setting the starting time point as a first time stamp, setting the time point when the corresponding cooling instruction disappears as a second time stamp, and counting the cooling duration of the corresponding cooling instruction according to the first time stamp and the second time stamp;

the ring mobility, the plurality of corresponding cooling instructions and the cooling duration form an environment analysis set;

the monitoring and evaluating module is used for analyzing and evaluating the cooling behaviors of different cooling schemes according to the environment analysis set to obtain a monitoring and evaluating set;

and the abnormal checking module is used for performing tracing checking on the subsequent cooling behavior of the selected sub-region to obtain an abnormal checking set containing the first tracing signal, the second tracing signal and the third tracing signal, and generating a corresponding alarm prompt according to different tracing signals in the abnormal checking set.

2. The distributed cooling control system based on water resource collection and processing of claim 1, wherein the calculation formula of the ring mobility HQ is as follows:

；

in the formula, h1, h2 and h3 are preset proportionality coefficients which are all larger than zero, and the value ranges are (0,5), and HX is an environment coefficient corresponding to each sub-region.

3. The distributed cooling control system based on water resource collection and processing of claim 1, wherein the different cooling commands comprise a first cooling command, a second cooling command, a third cooling command and a fourth cooling command, and the cooling schemes of low water volume low distribution, low water volume high distribution, high water volume low distribution and high water volume high distribution are implemented correspondingly.

4. The distributed cooling control system based on water resource collection processing according to claim 1, wherein the specific steps of monitoring and evaluating set acquisition include:

obtaining cooling time lengths corresponding to the cooling instructions in the environment analysis set, and respectively marking the cooling time lengths corresponding to the cooling instructions as JSk, and k =1,2,3,4; combining the cooling duration corresponding to the plurality of cooling instructions with the corresponding standard cooling duration JSk0, and obtaining a cooling evaluation value JP through calculation; the calculation formula of the evaluation value JP is as follows: JP = JSk/JSk;

acquiring an integer part of the degradation value, marking the integer part as J1, and matching the integer part with a preset degradation threshold value J0; if J1 is less than or equal to J0, judging that the cooling subarea corresponding to the cooling scheme is normal and generating a positive-falling signal; if J1 is larger than J0, judging that the cooling sub-region corresponding to the cooling scheme is abnormal and generating a reducing signal, and marking the cooling sub-region as a selected sub-region according to the reducing signal;

the degraded value and the corresponding degraded positive signal and degraded abnormal signal form a monitoring evaluation set.

5. The distributed cooling control system based on water resource collection and processing according to claim 1, wherein the specific steps of obtaining the abnormal verification set include:

counting the analysis and evaluation results of m subsequent cooling behaviors of the selected sub-region, and if m cooling behavior analysis and evaluation results have m different signals, judging that the operation of the spraying equipment in the selected sub-region is abnormal and generating a first tracing signal;

if v reducing signals exist in the analysis and evaluation results of the m reducing behaviors, judging that the operation of the spraying equipment in the selected sub-area is abnormal and generating a second tracing signal; wherein v is more than 0 and less than m, and m and v are positive integers;

if the m cooling behavior analysis and evaluation results comprise less than v reducing signals or positive reducing signals, judging that the spraying equipment in the selected sub-area normally operates and generating a third tracing signal;

the first tracing signal, the second tracing signal and the third tracing signal form an abnormal verification set.

6. The distributed cooling control system based on water resource collection processing according to claim 1, further comprising a water resource monitoring module for performing monitoring statistics on the collected water resources and evaluating whether the water resources provided for each sub-area in the target area to perform spray cooling are qualified, comprising:

acquiring the total amount of the collected water resources, marking the total amount as a first total amount, marking the time point when the collected water resources start to be processed as a third time stamp, marking the total amount of the processed water resources as a second total amount, and marking the time point when the second total amount is evaluated as a fourth time stamp;

counting the time length between the fourth time stamp and the third time stamp, acquiring the ratio of the second total amount to the time length, marking the ratio as a first ratio, and analyzing the first ratio;

if the first ratio is smaller than the filtering threshold value, generating a first processing signal;

if the first ratio is not smaller than the filtering threshold, generating a second processing signal; the first processed signal and the second processed signal constitute filter processed data.

7. The distributed cooling control system based on water resource collection and processing according to claim 6, wherein the impurity proportion in the processed water resource is obtained, and the impurity proportion is matched with a preset proportion threshold; if the impurity ratio is smaller than the ratio threshold, generating a first filtering signal;

if the impurity proportion is not less than the proportion threshold, generating a second filtering signal;

the first filtering signal and the second filtering signal form filtering analysis data;

and evaluating the processing condition of the water resource according to the filtering processing data and the filtering analysis data by using a water resource prompting module and carrying out self-adaptive alarm prompting.

8. The distributed cooling control system based on water resource collection processing according to claim 7, wherein the working steps of the water resource prompting module include:

and performing simultaneous evaluation on the filtering signals in the filtering analysis data and the processing signals in the filtering processing data to obtain a first alarm instruction, a second alarm instruction, a third alarm instruction and a fourth alarm instruction, and prompting an administrator to immediately perform processing check, filtering check and replacement check alarm prompts according to the second alarm instruction, the third alarm instruction and the fourth alarm instruction.

9. A distributed cooling control method based on water resource collection processing is applied to the distributed cooling control system based on water resource collection processing of any one of claims 1 to 8, and is characterized by comprising the following steps:

monitoring and data analysis are carried out on the environment of different sub-areas in a target area, real-time temperature, real-time humidity and real-time air pressure of each sub-area in the target area are obtained at preset interval time periods and are connected in parallel to obtain ring mobility, and whether the corresponding sub-area needs to be cooled and regulated is judged according to the ring mobility;

generating different cooling instructions according to the integer part and the decimal part of the ring mobility, implementing corresponding cooling schemes, and meanwhile counting the cooling time length for executing the cooling schemes;

evaluating the cooling state of the corresponding sub-region according to the cooling time length to obtain the selected sub-region, tracing and checking the subsequent cooling behavior of the selected sub-region, and carrying out self-adaptive alarm prompt according to the checking result.

10. The distributed cooling control method based on water resource collection processing according to claim 9, further comprising:

monitoring and counting the collected water resources, acquiring a first ratio for analysis according to the total amount of the processed water resources and the corresponding processing time, and analyzing the first ratio to obtain filtering processing data containing a first processing signal and a second processing signal;

acquiring the impurity ratio in the processed water resource and matching the impurity ratio with a preset ratio threshold value to obtain filtering analysis data containing a first filtering signal and a second filtering signal;

and evaluating the processing condition of the water resource according to the filtering processing data and the filtering analysis data and carrying out self-adaptive alarm prompt.

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