CN115307678A - Intelligent monitoring method and device for ecological sponge system, terminal and storage medium - Google Patents

Abstract

The application relates to an intelligent monitoring method, an intelligent monitoring device, a terminal and a storage medium for an ecological sponge system, which belong to the technical field of urban rainfall flood management, wherein the method comprises the following steps: acquiring and recording temperature and humidity data of the ecological sponge module according to the acquisition time interval, and determining the real-time running state of the ecological sponge module according to the change trend between two adjacent temperature and humidity data; determining a long-term operation state of the ecological sponge module according to the maximum difference value between the temperature and humidity data in the verification time interval; and sending an alarm when the long-term running state is abnormal. This application is through effective record and the real-time analysis to ecological sponge system use moderate temperature humidity data, quantifies ecological sponge system's operational effect, has not only ensured ecological sponge system's continuous steady operation, but also provides data support for the subsequent popularization and application of ecological sponge system.

Description

Intelligent monitoring method and device for ecological sponge system, terminal and storage medium

Technical Field

The application relates to the technical field of urban rainfall flood management, in particular to an intelligent monitoring method, device, terminal and storage medium for an ecological sponge system.

Background

With the advance of urbanization, the concept of ecological sponge cities is popularized and applied in large scale in China, and the concept advocates that the cities can have good elasticity in the aspects of adapting to environmental changes, coping with natural disasters and the like sponges, absorb, store, seep and purify water during raining, release and utilize the stored water when needed, and gradually improve and restore the natural ecological balance of the cities.

In the current stage of ecological sponge city construction, ecological sponge systems with various forms and structures are arranged in cities to play respective functions. These ecological sponge systems bury underground in urban road below and be linked together through overflow drain pipe and municipal pipe network, and under the influence of osmosis, ecological sponge system can regulate and control the moisture in its peripheral soil, and then improves the utilization ratio of rainwater.

Although the above related schemes can exert beneficial effects after implementation, through long-term practical summary, technicians find that in the use process of the existing ecological sponge system, necessary data recording and data analysis are lacked, and the operation state and the operation effect of the system are difficult to be intuitively quantized.

Therefore, how to provide a technical solution capable of overcoming the above-mentioned drawbacks becomes a problem to be solved by those skilled in the art.

Disclosure of Invention

In order to realize visual quantification of the running state and the running effect of the ecological sponge system, the application provides an intelligent monitoring method, device, terminal and storage medium of the ecological sponge system.

In a first aspect, the application provides an intelligent monitoring method for an ecological sponge system, which adopts the following technical scheme:

an ecological sponge system intelligent monitoring method is matched with an ecological sponge system, wherein the ecological sponge system comprises an ecological sponge module which is buried underground and used for realizing a rainfall flood regulation function, and the method comprises the following steps:

acquiring and recording temperature and humidity data of the ecological sponge module according to a preset acquisition time interval, and determining a real-time operation state of the corresponding ecological sponge module according to a data change trend between the temperature and humidity data acquired twice;

determining a long-term running state of the corresponding ecological sponge module according to a maximum difference value between the temperature and humidity data within a preset check time interval;

and when the long-term running state is abnormal, generating corresponding replacement prompt information of the ecological sponge module and giving an alarm.

By adopting the technical scheme, the temperature and humidity data in the use process of the ecological sponge system can be effectively recorded and analyzed, the running state of the ecological sponge module in the ecological sponge system can be intuitively known, and real-time hidden danger informing and reminding can be realized.

In a specific implementation scheme, the acquiring and recording temperature and humidity data of the ecological sponge module according to a preset acquisition time interval, and determining a real-time operation state of the corresponding ecological sponge module according to a data change trend between the temperature and humidity data acquired twice, specifically includes the following steps:

setting an acquisition time interval corresponding to the ecological sponge module;

acquiring and recording temperature data and humidity data of the ecological sponge module according to the acquisition time interval;

comparing data change trends between the humidity data acquired in two adjacent times, when the humidity data before the two adjacent times is lower than the humidity data after the two adjacent times, marking the corresponding real-time running state of the ecological sponge module as a water storage state, when the humidity data before the two adjacent times is higher than the humidity data after the two adjacent times, marking the corresponding real-time running state of the ecological sponge module as a water supply state, and when the humidity data before the two adjacent times is equal to the humidity data after the two adjacent times, marking the corresponding real-time running state of the ecological sponge module as a balance state.

By adopting the technical scheme, the real-time running state of the ecological sponge module can be accurately known by system management personnel and the moisture content of the soil around the ecological sponge module can be further deduced, so that complete data support is provided for the popularization and application of a subsequent ecological sponge system.

In a specific implementation, the determining the long-term operation state of the corresponding ecological sponge module according to the maximum difference between the temperature and humidity data within a preset check time interval specifically includes the following steps:

setting a calibration time interval corresponding to the ecological sponge module;

determining a long-term operation state of the ecological sponge module in a verification time interval, wherein the long-term operation state comprises a maximum temperature change value and a maximum humidity change value, the maximum temperature change value is a difference value between a maximum value and a minimum value of the temperature data acquired in the verification time interval, and the maximum humidity change value is a difference value between the maximum value and the minimum value of the humidity data acquired in the verification time interval.

By adopting the technical scheme, the long-term running state of the ecological sponge module can be accurately known by system management personnel, and the evaluation on the water storage capacity of the ecological sponge module can be visually reflected through numerical calculation, so that the running of the whole ecological sponge module is no longer in a black box state.

In a specific implementation, when the long-term operation state is abnormal, generating a replacement prompt message of the corresponding ecological sponge module and giving an alarm specifically includes the following steps:

when the maximum temperature change value exceeds a preset temperature change threshold value, marking the corresponding ecological sponge module as an abnormal module;

when the maximum humidity change value is lower than a preset humidity change threshold value and the corresponding ecological sponge module is not marked as an abnormal module, generating inspection prompt information of the corresponding ecological sponge module and giving an alarm;

and when the maximum humidity change value is lower than a preset humidity change threshold value and the corresponding ecological sponge module is marked as an abnormal module, generating corresponding replacement prompt information of the ecological sponge module and giving an alarm, wherein the alarm priority of the replacement prompt information is higher than that of the inspection prompt information.

Through adopting above-mentioned technical scheme, only can judge whether ecological sponge module is in abnormal condition, whether need change according to the humiture data of ecological sponge module, also reduced the degree of difficulty of ecological sponge system operation maintenance when having improved the monitoring result accuracy by a wide margin, promoted the efficiency of operation maintenance.

In a specific possible embodiment, the intelligent monitoring method for the ecological sponge system further comprises the following steps:

setting a depth change threshold corresponding to the ecological sponge module;

acquiring and recording burial depth data of the ecological sponge module according to the acquisition time interval;

calculating the difference value of the burying depth data obtained in two adjacent times to obtain a single burying depth change value, comparing the burying depth change value with the depth change threshold value, and generating first-level maintenance prompt information of the corresponding ecological sponge module and giving an alarm when the single burying depth change value exceeds the depth change threshold value;

and calculating the difference value between the maximum value and the minimum value of the burial depth data acquired in the verification time interval to obtain a long-term burial depth change value, generating corresponding secondary maintenance prompt information of the ecological sponge module and giving an alarm when the long-term burial depth change value exceeds the depth change threshold, wherein the alarm priority of the secondary maintenance prompt information is lower than that of the primary maintenance prompt information.

Through adopting above-mentioned technical scheme, supplementary ground settlement monitoring to ecological sponge system setting area has been realized, has reduced the ground settlement risk that leads to because of ecological sponge system sets up. For areas with potential sedimentation hazards, system operation and maintenance personnel should excavate and find the cause in time.

In a specific possible embodiment, the intelligent monitoring method for the ecological sponge system further comprises the following steps:

setting a water quality normal interval corresponding to the ecological sponge module;

acquiring and recording water quality data of the ecological sponge module according to the acquisition time interval;

and comparing all the water quality data acquired in the verification time interval with the water quality normal interval one by one, and generating corresponding replacement prompt information of the ecological sponge module and giving an alarm when any one of the water quality data exceeds the water quality normal interval.

Through adopting above-mentioned technical scheme, supplementary having realized setting up regional quality of water condition monitoring to ecological sponge system, consider that current ecological sponge system disposes the purification filter core mostly, the result of quality of water condition monitoring will direct prompt system operation maintenance personnel change the purification filter core that does not reach standard.

The second aspect, this application provides an ecological sponge system intelligent monitoring device, adopts following technical scheme:

the utility model provides an ecological sponge system intelligent monitoring device, with ecological sponge system looks adaptation, contain in the ecological sponge system and bury underground in the underground, be used for realizing the ecological sponge module of rainfall flood regulatory function, the device includes following module:

the real-time running state determining module is configured to acquire and record temperature and humidity data of the ecological sponge module according to a preset acquisition time interval, and determine a corresponding real-time running state of the ecological sponge module according to a data change trend between the temperature and humidity data acquired twice;

the long-time running state determining module is configured to determine a corresponding long-time running state of the ecological sponge module according to a maximum difference value between the temperature and humidity data within a preset checking time interval;

and the abnormal operation state alarm module is configured to generate corresponding replacement prompt information of the ecological sponge module and send out an alarm when the long-term operation state is abnormal.

Through adopting above-mentioned technical scheme, set up one set of complete intelligent monitoring system, for current ecological sponge system provides necessary software technology and supports, and then make different ecological sponge modules in different ecological sponge systems in the city, same ecological sponge system all obtain effectively integrating, the intelligent monitoring system that system management personnel utilized this application to provide can realize the management of unification, science.

In a third aspect, the present application provides an intelligent terminal, which adopts the following technical scheme:

an intelligent terminal comprises a memory and a processor, wherein at least one instruction, at least one program, a code set or an instruction set is stored in the memory, and the at least one instruction, at least one program, the code set or the instruction set is loaded and executed by the processor to realize the intelligent monitoring method for the ecological sponge system.

In a fourth aspect, the present application provides a computer-readable storage medium, which adopts the following technical solutions:

a computer readable storage medium having stored therein at least one instruction, at least one program, a set of codes, or a set of instructions, which is loaded and executed by a processor to implement the ecological sponge system intelligent monitoring method as described above.

In summary, the present application includes at least one of the following beneficial technical effects:

1. this application is through effective record and the real-time analysis to each item application data in the ecological sponge system use, quantifies the operational effect of ecological sponge system, and concrete parameters such as the moisture content of ecological sponge module and peripheral soil, ecological sponge system's running state, water storage efficiency, water purification efficiency can all directly acquire and demonstrate, have not only ensured ecological sponge system's continuous steady operation, but also provide data support for its subsequent popularization and application.

2. This application provides necessary software technology for current ecological sponge system through the one set of complete intelligent monitoring system of putting up and supports, and then makes different ecological sponge modules in different ecological sponge systems in the city, same ecological sponge system all obtain effectively integrating, and the system administrator utilizes the intelligent monitoring system that this application provided can realize the management of unification, science.

3. This application is through combining together data analysis technique and threshold value alarm technology, has realized that real-time hidden danger informs to remind, in case unusual data has appeared in certain ecological sponge module among the ecological sponge system, can combine the data analysis result in time to make hidden danger and inform and remind, also reduced the degree of difficulty of ecological sponge system operation and maintenance, promoted the efficiency of operation and maintenance when having improved the monitoring result accuracy by a wide margin.

Drawings

Fig. 1 is a schematic flow chart of an intelligent monitoring method for an ecological sponge system in an embodiment of the present application.

Fig. 2 is a schematic structural diagram of an ecological sponge system intelligent monitoring device in the embodiment of the present application.

Detailed Description

The application provides an intelligent monitoring method, an intelligent monitoring device, an intelligent monitoring terminal and a storage medium for an ecological sponge system, and in order to make the purposes, technical schemes and advantages of the application clearer, the following will further explain the implementation mode of the application in detail.

The following describes in detail an embodiment of an intelligent monitoring method for an ecological sponge system according to the present application with reference to the drawings of the specification.

An intelligent monitoring method of an ecological sponge system, which is matched with the ecological sponge system. The ecological sponge system comprises an ecological sponge module which is buried underground and used for achieving a rainfall flood adjusting function, the ecological sponge module can be further embodied as an ecological sponge EAU carbon fiber module, the ecological sponge EAU carbon fiber module is provided with a corresponding sensor assembly used for acquiring various application data in the operation process of the ecological sponge EAU carbon fiber module, the sensor assembly at least comprises a temperature and humidity sensor, and a probe of the temperature and humidity sensor is inserted into the ecological sponge module or the peripheral soil of the ecological sponge module. When acquiring data and performing subsequent monitoring processes, the ecological sponge modules, individually or in groups, should be taken as basic operation units.

The intelligent monitoring method for the ecological sponge system comprises the following steps of:

s1, acquiring and recording temperature and humidity data of the ecological sponge module according to a preset acquisition time interval, and determining a real-time operation state of the corresponding ecological sponge module according to a data change trend between the temperature and humidity data acquired twice. This step can be embodied as the following flow.

S11, setting a collection time interval corresponding to the ecological sponge module; the acquisition time interval can be determined according to the actual application requirements, and can be generally set to 6 to 12 hours.

And S12, acquiring and recording the temperature data and the humidity data of the ecological sponge module according to the acquisition time interval.

S13, comparing data change trends between the humidity data acquired at two adjacent times;

when the humidity data before two adjacent times is lower than the humidity data after the two adjacent times, marking the real-time running state of the corresponding ecological sponge module as a water storage state;

when the humidity data before two adjacent times is higher than the humidity data after the two adjacent times, marking the real-time running state of the corresponding ecological sponge module as a water supply state;

when the humidity data before two adjacent times is equal to the humidity data after the two adjacent times, marking the real-time running state of the corresponding ecological sponge module as an equilibrium state.

It should be noted here that, in consideration of the accuracy of the temperature and humidity sensor and the actual system application environment, the humidity data obtained in two adjacent times are hardly completely the same, so in the actual method application process, a very small comparison threshold may also be considered to be set, and if the difference between the humidity data obtained in two times is greater than the comparison threshold, the data change trend is further compared, otherwise, it is directly regarded that the humidity data obtained in two adjacent times are the same.

In the actual use process, after the water content of the ecological sponge module is accurately known by system management personnel, the water content of the soil around the ecological sponge module can be deduced according to the water content, so that the popularization and the application of the subsequent ecological sponge system have complete data support.

S2, determining a long-term running state of the corresponding ecological sponge module according to the maximum difference value between the temperature and humidity data in a preset check time interval. This step can be embodied as the following flow.

S21, setting a check time interval corresponding to the ecological sponge module; the verification time interval can also be determined according to the actual application requirements, but the verification time interval needs to be larger than the acquisition time interval, and can be generally considered to be set to 3~6 months.

S22, determining a long-term operation state of the ecological sponge module in a verification time interval, wherein the long-term operation state comprises a maximum temperature change value and a maximum humidity change value, the maximum temperature change value is a difference value between a maximum value and a minimum value of the temperature data acquired in the verification time interval, and the maximum humidity change value is a difference value between the maximum value and the minimum value of the humidity data acquired in the verification time interval.

After the long-term running state of the ecological sponge module is accurately known by system management personnel, the evaluation on the water storage capacity of the ecological sponge module can be visually completed through the extreme value, and further a basis is provided for the subsequent early warning process of the method.

And S3, when the long-term running state is abnormal, generating corresponding replacement prompt information of the ecological sponge module and giving an alarm. This step can be embodied as the following flow.

And S31, if the maximum temperature change value exceeds a preset temperature change threshold value, marking the corresponding ecological sponge module as an abnormal module.

Because the service life of the ecological sponge module is generally 10 to 20 years, the material aging phenomenon is slow, but the abnormal temperature change can seriously accelerate the process, once the maximum temperature change value exceeds a preset temperature change threshold value, whether the material aging phenomenon of the ecological sponge module occurs needs to be considered. In the actual method application process, the ecological sponge module marked as an abnormal module needs to be subjected to important monitoring.

And S32, if the maximum humidity change value is lower than a preset humidity change threshold value and the corresponding ecological sponge module is not marked as an abnormal module, generating corresponding inspection prompt information of the ecological sponge module and giving an alarm.

The maximum humidity change value can visually reflect the maximum water storage capacity of the ecological sponge module, the humidity change threshold value is generally 20% -30% of the initial maximum water storage capacity of the corresponding ecological sponge module, and if the maximum humidity change value is lower than the humidity change threshold value, the water storage capacity of the ecological sponge module is seriously reduced and further inspection or replacement is required.

And S33, if the maximum humidity change value is lower than a preset humidity change threshold value and the corresponding ecological sponge module is marked as an abnormal module, generating corresponding replacement prompt information of the ecological sponge module and giving an alarm.

In the method, whether the ecological sponge module is in an abnormal state or not and needs to be replaced or not can be judged through temperature and humidity data of the ecological sponge module, the method is convenient and fast in implementation process, basic monitoring needs are met, the difficulty of operation and maintenance of the ecological sponge system is reduced, and the efficiency of operation and maintenance is improved.

In addition to the above technical solution, in a specific practical implementation, the intelligent monitoring method for an ecological sponge system further includes the following steps:

s41, setting a depth change threshold corresponding to the ecological sponge module; the value of the depth change threshold value can be set according to a system to set a locally issued ground settlement rate standard.

S42, acquiring and recording the burial depth data of the ecological sponge module according to the acquisition time interval; the buried depth data can be obtained by means of a depth sensor arranged in the ecological sponge module, and corresponding numerical values can be obtained by observation according to the existing settlement observation method.

S43, calculating a difference value of the burial depth data obtained in two adjacent times to obtain a single burial depth change value, comparing the burial depth change value with the depth change threshold, if the single burial depth change value exceeds the depth change threshold, generating first-level maintenance prompt information of the corresponding ecological sponge module, giving an alarm, and ending the process immediately, otherwise, entering the step S44 in sequence;

s44, calculating a difference value between the maximum value and the minimum value of the burial depth data acquired in the checking time interval to obtain a long-term burial depth change value, if the long-term burial depth change value exceeds the depth change threshold value, generating corresponding secondary maintenance prompt information of the ecological sponge module and giving an alarm, wherein the alarm priority of the secondary maintenance prompt information is lower than that of the primary maintenance prompt information.

The above-mentioned step is supplementary to have realized setting up regional ground settlement monitoring to ecological sponge system, has reduced the ground settlement risk that leads to because of ecological sponge system sets up by a wide margin. For areas with potential sedimentation hazards, system operation and maintenance personnel should excavate and find the cause in time.

In addition to the above technical solution, in a specific practical implementation, the intelligent monitoring method for an ecological sponge system further includes the following steps:

s51, setting a water quality normal interval corresponding to the ecological sponge module;

s52, acquiring and recording water quality data of the ecological sponge module according to the acquisition time interval;

s53, all the water quality data acquired in the verification time interval are compared with the water quality normal interval one by one, and when any one of the water quality data exceeds the water quality normal interval, corresponding replacement prompt information of the ecological sponge module is generated and an alarm is given.

The above-mentioned step is supplementary to have realized setting up regional quality of water condition monitoring to ecological sponge system, considers that current ecological sponge system disposes the purification filter core mostly, can realize the getting rid of pollutants such as suspended solid SS, phosphorus, nitrogen, so the result of quality of water condition monitoring will direct suggestion system operation maintenance personnel change the purification filter core that does not reach standard.

It should be further noted that, in the present application, for the acquisition of various sensor data, various related technologies in the prior art may be selected, and it is considered that conventional implementation means of the sensor communication technology are numerous, and both the wired form and the wireless form may be used, and therefore, details are not described herein.

According to the intelligent monitoring method for the ecological sponge system, the data analysis technology and the threshold value alarm technology are combined, real-time hidden danger informing and reminding is achieved, once abnormal data occur in a certain ecological sponge module in the ecological sponge system, hidden danger informing and reminding can be timely made by combining a data analysis result, the accuracy of the monitoring result is greatly improved, the difficulty of operation, maintenance and maintenance of the ecological sponge system is reduced, and the efficiency of operation, maintenance and maintenance is improved.

Based on the same inventive concept, the embodiment of the application also discloses an intelligent monitoring device of an ecological sponge system, the device is matched with the ecological sponge system, the ecological sponge system comprises an ecological sponge module which is buried underground and used for realizing a rainfall flood regulation function, and referring to fig. 2, the device comprises the following modules:

the real-time running state determining module is configured to acquire and record temperature and humidity data of the ecological sponge module according to a preset acquisition time interval, and determine a corresponding real-time running state of the ecological sponge module according to a data change trend between the temperature and humidity data acquired twice;

the long-time running state determining module is configured to determine a corresponding long-time running state of the ecological sponge module according to a maximum difference value between the temperature and humidity data within a preset checking time interval;

and the abnormal operation state alarm module is configured to generate corresponding replacement prompt information of the ecological sponge module and send out an alarm when the long-term operation state is abnormal.

In a specific possible embodiment, the real-time operation state determination module includes:

the acquisition time interval setting unit is configured to set an acquisition time interval corresponding to the ecological sponge module;

the temperature and humidity data acquisition unit is configured to acquire and record temperature data and humidity data of the ecological sponge module according to the acquisition time interval;

the real-time operation state determining unit is configured to compare data change trends between the humidity data acquired in two adjacent times, mark the corresponding real-time operation state of the ecological sponge module as a water storage state when the humidity data before the two adjacent times is lower than the humidity data after the two adjacent times, mark the corresponding real-time operation state of the ecological sponge module as a water supply state when the humidity data before the two adjacent times is higher than the humidity data after the two adjacent times, and mark the corresponding real-time operation state of the ecological sponge module as an equilibrium state when the humidity data before the two adjacent times is equal to the humidity data after the two adjacent times.

In a specific embodiment, the long-time operation status determining module includes:

the checking time interval setting unit is configured to set a checking time interval corresponding to the ecological sponge module;

the long-term operation state determining unit is configured to determine a long-term operation state of the ecological sponge module in a verification time interval, wherein the long-term operation state comprises a maximum temperature change value and a maximum humidity change value, the maximum temperature change value is a difference value between a maximum value and a minimum value of the temperature data acquired in the verification time interval, and the maximum humidity change value is a difference value between the maximum value and the minimum value of the humidity data acquired in the verification time interval.

In a specific possible embodiment, the abnormal operation state alarm module includes:

an abnormal module marking unit configured to mark the corresponding ecological sponge module as an abnormal module when the maximum temperature change value exceeds a preset temperature change threshold;

and the inspection prompt alarm unit is configured to generate inspection prompt information of the corresponding ecological sponge module and send an alarm when the maximum humidity change value is lower than a preset humidity change threshold value and the corresponding ecological sponge module is not marked as an abnormal module.

And the first replacement prompt alarm unit is configured to generate corresponding replacement prompt information of the ecological sponge module and send an alarm when the maximum humidity change value is lower than a preset humidity change threshold value and the corresponding ecological sponge module is marked as an abnormal module, wherein the alarm priority of the replacement prompt information is higher than that of the inspection prompt information.

In a specific possible embodiment, the intelligent monitoring device for the ecological sponge system further comprises the following units:

the depth change threshold setting unit is configured to set a depth change threshold corresponding to the ecological sponge module;

the buried depth acquisition unit is configured to acquire and record buried depth data of the ecological sponge module according to the acquisition time interval;

the first-level maintenance prompting alarm unit is configured to calculate a difference value of the burial depth data acquired twice in a neighboring mode to obtain a single burial depth change value, compare the burial depth change value with the depth change threshold, and generate first-level maintenance prompting information of the corresponding ecological sponge module and send an alarm when the single burial depth change value exceeds the depth change threshold;

and the secondary maintenance prompting alarm unit is configured to calculate a difference value between the maximum value and the minimum value of the burial depth data acquired in the verification time interval to obtain a long-term burial depth change value, when the long-term burial depth change value exceeds the depth change threshold, secondary maintenance prompting information of the corresponding ecological sponge module is generated and an alarm is given, and the alarm priority of the secondary maintenance prompting information is lower than that of the primary maintenance prompting information.

In a specific possible embodiment, the intelligent monitoring device for the ecological sponge system further comprises the following units:

the water quality normal interval setting unit is configured to set a water quality normal interval corresponding to the ecological sponge module;

the water quality data acquisition unit is configured to acquire and record water quality data of the ecological sponge module according to the acquisition time interval;

and the second replacement prompt alarm unit is configured to compare all the water quality data acquired in the verification time interval with the water quality normal interval one by one, and when any one of the water quality data exceeds the water quality normal interval, generate corresponding replacement prompt information of the ecological sponge module and send an alarm.

An ecological sponge system intelligent monitoring device in this application has set up one set of complete intelligent monitoring system, provides necessary software technology for current ecological sponge system and supports, and then makes different ecological sponge modules in different ecological sponge systems in the city, same ecological sponge system all obtain effectively integrating, and the system administrator utilizes the intelligent monitoring system that this application provided can realize the management of unification, science.

Based on the same inventive concept, an embodiment of the present application further discloses a computer-readable storage medium, where at least one instruction, at least one program, a code set, or an instruction set is stored in the storage medium, and the at least one instruction, the at least one program, the code set, or the instruction set can be loaded and executed by a processor to implement the intelligent monitoring method for an ecological sponge system provided by the embodiment of the method.

It should be understood that reference to "a plurality" herein means two or more. "and/or" describes the association relationship of the associated objects, meaning that there may be three relationships, e.g., a and/or B, which may mean: a exists alone, A and B exist simultaneously, and B exists alone. The character "/" generally indicates that the former and latter associated objects are in an "or" relationship.

Those skilled in the art will appreciate that all or part of the steps of implementing the above embodiments may be implemented by hardware, or may be implemented by a program instructing associated hardware, where the program may be stored in a computer-readable storage medium, where the above-mentioned storage medium includes, for example: various media capable of storing program codes, such as a usb disk, a removable hard disk, a Read-Only Memory (ROM), a Random Access Memory (RAM), a magnetic disk, or an optical disk.

The above description is only exemplary of the present application and should not be taken as limiting, as any modification, equivalent replacement, or improvement made within the spirit and principle of the present application should be included in the protection scope of the present application.

Claims (9)

1. The intelligent monitoring method of the ecological sponge system is matched with the ecological sponge system, and the ecological sponge system comprises an ecological sponge module which is buried underground and used for realizing a rainfall flood regulation function, and is characterized by comprising the following steps:

acquiring and recording temperature and humidity data of the ecological sponge module according to a preset acquisition time interval, and determining a real-time operation state of the corresponding ecological sponge module according to a data change trend between the temperature and humidity data acquired twice;

determining a long-term operation state of the corresponding ecological sponge module according to a maximum difference value between the temperature and humidity data within a preset check time interval;

and when the long-term running state is abnormal, generating corresponding replacement prompt information of the ecological sponge module and giving an alarm.

2. The intelligent monitoring method for the ecological sponge system according to claim 1, wherein the temperature and humidity data of the ecological sponge module are acquired and recorded according to a preset acquisition time interval, and the real-time operation state of the corresponding ecological sponge module is determined according to a data change trend between the temperature and humidity data acquired twice, specifically comprising the following steps:

setting an acquisition time interval corresponding to the ecological sponge module;

acquiring and recording temperature data and humidity data of the ecological sponge module according to the acquisition time interval;

comparing data change trends between the humidity data acquired in two adjacent times, when the humidity data before the two adjacent times is lower than the humidity data after the two adjacent times, marking the corresponding real-time running state of the ecological sponge module as a water storage state, when the humidity data before the two adjacent times is higher than the humidity data after the two adjacent times, marking the corresponding real-time running state of the ecological sponge module as a water supply state, and when the humidity data before the two adjacent times is equal to the humidity data after the two adjacent times, marking the corresponding real-time running state of the ecological sponge module as a balance state.

3. The ecological sponge system intelligent monitoring method according to claim 2, wherein the long-term operation state of the ecological sponge module is determined according to the maximum difference between the temperature and humidity data within a preset check time interval, and the method specifically comprises the following steps:

setting a calibration time interval corresponding to the ecological sponge module;

and determining a long-term running state of the ecological sponge module in a checking time interval, wherein the long-term running state comprises a maximum temperature change value and a maximum humidity change value, the maximum temperature change value is a difference value between the maximum value and the minimum value of the temperature data acquired in the checking time interval, and the maximum humidity change value is a difference value between the maximum value and the minimum value of the humidity data acquired in the checking time interval.

4. The ecological sponge system intelligent monitoring method according to claim 3, wherein when the long-term operation state is abnormal, the method generates corresponding replacement prompt information of the ecological sponge module and gives an alarm, and specifically comprises the following steps:

when the maximum temperature change value exceeds a preset temperature change threshold value, marking the corresponding ecological sponge module as an abnormal module;

when the maximum humidity change value is lower than a preset humidity change threshold value and the corresponding ecological sponge module is not marked as an abnormal module, generating inspection prompt information of the corresponding ecological sponge module and giving an alarm;

and when the maximum humidity change value is lower than a preset humidity change threshold value and the corresponding ecological sponge module is marked as an abnormal module, generating corresponding replacement prompt information of the ecological sponge module and giving an alarm, wherein the alarm priority of the replacement prompt information is higher than that of the inspection prompt information.

5. The ecological sponge system intelligent monitoring method according to claim 3, characterized in that the method further comprises the following steps:

setting a depth change threshold corresponding to the ecological sponge module;

acquiring and recording burial depth data of the ecological sponge module according to the acquisition time interval;

calculating the difference value of the burying depth data obtained in two adjacent times to obtain a single burying depth change value, comparing the burying depth change value with the depth change threshold value, and generating first-level maintenance prompt information of the corresponding ecological sponge module and giving an alarm when the single burying depth change value exceeds the depth change threshold value;

and calculating the difference value between the maximum value and the minimum value of the burial depth data acquired in the verification time interval to obtain a long-term burial depth change value, generating corresponding secondary maintenance prompt information of the ecological sponge module and giving an alarm when the long-term burial depth change value exceeds the depth change threshold, wherein the alarm priority of the secondary maintenance prompt information is lower than that of the primary maintenance prompt information.

6. The intelligent monitoring method for ecological sponge system according to claim 3, further comprising the steps of:

setting a water quality normal interval corresponding to the ecological sponge module;

acquiring and recording water quality data of the ecological sponge module according to the acquisition time interval;

and comparing all the water quality data acquired in the verification time interval with the water quality normal interval one by one, and generating corresponding replacement prompt information of the ecological sponge module and giving an alarm when any water quality data exceeds the water quality normal interval.

7. The utility model provides an ecological sponge system intelligent monitoring device, with ecological sponge system looks adaptation, contain in the ecological sponge system and bury underground in, be used for realizing the ecological sponge module of rainfall flood regulatory function, its characterized in that, the device includes following module:

the real-time running state determining module is configured to acquire and record temperature and humidity data of the ecological sponge module according to a preset acquisition time interval, and determine a corresponding real-time running state of the ecological sponge module according to a data change trend between the temperature and humidity data acquired twice;

the long-time running state determining module is configured to determine a corresponding long-time running state of the ecological sponge module according to a maximum difference value between the temperature and humidity data within a preset checking time interval;

and the abnormal operation state alarm module is configured to generate corresponding replacement prompt information of the ecological sponge module and send out an alarm when the long-term operation state is abnormal.

8. An intelligent terminal, comprising a memory and a processor, wherein the memory stores at least one instruction, at least one program, a code set or an instruction set, and the at least one instruction, at least one program, a code set or an instruction set is loaded and executed by the processor to implement the intelligent monitoring method for ecological sponge system according to any one of claims 1 to 6.

9. A computer-readable storage medium, wherein at least one instruction, at least one program, a set of codes, or a set of instructions is stored in the computer-readable storage medium, and the at least one instruction, at least one program, a set of codes, or a set of instructions is loaded and executed by a processor to implement the ecological sponge system intelligent monitoring method as claimed in any one of claims 1 to 6.

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