CN114867087A - Intelligent solar equipment supports uses governing system - Google Patents

Abstract

The invention discloses an intelligent regulating system for supporting solar equipment, which comprises an information monitoring and acquiring module, a data calculation and analysis module and a control management module, wherein the information monitoring and acquiring module is electrically connected with the data calculation and analysis module, the data calculation and analysis module is connected with the control management module through a network, the information monitoring and acquiring module is used for monitoring and acquiring base station information, the data calculation and analysis module is used for calculating and analyzing energy information, the control management module is used for controlling and managing the base station and the solar equipment, the information monitoring and acquiring module comprises a monitoring module, a weather information unit and a segmentation matching module, the monitoring module is electrically connected with the weather information unit, the weather information unit is connected with the segmentation matching module through a network, the monitoring module is used for monitoring energy supply information, the monitoring module comprises a first monitoring submodule and a second monitoring submodule.

Description

Intelligent solar equipment supports uses governing system

Technical Field

The invention relates to the technical field of adjustment, in particular to an intelligent adjusting system for supporting solar equipment.

Background

With the development of modern industry, the global energy crisis and the atmospheric pollution problem are increasingly highlighted, and solar energy, a clean renewable energy source, has received high attention and utilization from many countries. The application of solar energy technology in China is also greatly developed.

The base station is an interface device for the mobile device to access the internet, is a mobile communication switching center, and is a radio transceiver station for information transmission with the mobile phone terminal. Since users communicate a lot of information through the base station every day, and it costs huge energy to maintain normal communication operation of the base station, the solar technology is also applied to normal operation of the base station. However, when the stored solar energy is exhausted and the normal operation of the base station needs to be maintained by adjusting the electric energy, the adjustment process can seriously affect the normal communication of users in the base station area. Therefore, it is necessary to design an intelligent solar plant support regulating system that intelligently regulates the energy supply.

Disclosure of Invention

The present invention is directed to an intelligent solar device supporting adjustment system, so as to solve the problems of the background art.

In order to solve the technical problems, the invention provides the following technical scheme: the utility model provides an intelligent solar equipment supports uses governing system, includes information monitoring acquisition module, data calculation analysis module and control management module, information monitoring acquisition module is connected with data calculation analysis module electricity, data calculation analysis module and control management module network connection, information monitoring acquisition module is used for monitoring the collection to basic station information, data calculation analysis module is used for carrying out the analysis of calculation to energy information, control management module is used for carrying out control management to basic station and solar equipment.

According to the technical scheme, the information monitoring and acquiring module comprises a monitoring module, a weather information unit and a segmentation matching module, the monitoring module is electrically connected with the weather information unit, the weather information unit is in network connection with the segmentation matching module, the monitoring module is used for monitoring energy supply information, the monitoring module comprises a monitoring submodule I and a monitoring submodule II, the monitoring submodule I is electrically connected with the monitoring submodule II, the monitoring submodule I and the monitoring submodule II are respectively used for monitoring different energy supply information, the weather information unit is used for acquiring weather information, and the segmentation matching module is used for segmenting and matching communication data information.

According to the technical scheme, the data calculation and analysis module comprises a consumption analysis module, a pre-estimation judgment module and an input energy calculation module, the consumption analysis module is electrically connected with the pre-estimation judgment module, the input energy calculation module is electrically connected with the consumption analysis module, the consumption analysis module is used for analyzing and acquiring energy information consumed by the base station, the pre-estimation judgment module is used for pre-estimating and judging the acquisition of solar energy, and the input energy calculation module is used for calculating and analyzing electric energy required to be input by the base station.

According to the technical scheme, the control management module comprises an under-voltage value adjusting module, an energy supply conversion module and a recovery processing module, the under-voltage value adjusting module is electrically connected with the energy supply conversion module, the energy supply conversion module is electrically connected with the recovery processing module, the under-voltage value adjusting module is used for adjusting the under-voltage value of the solar storage battery, the energy supply conversion module is used for performing conversion control on energy supply of a base station, and the recovery processing module is used for recovering communication processing of the base station.

According to the technical scheme, the operation method of the intelligent solar equipment supporting adjusting system mainly comprises the following steps:

step S1: when the electric quantity of a storage battery powered by solar energy of the base station is insufficient, preparing for further processing;

step S2: monitoring the power supply condition of the solar power supply equipment to the base station through weather information and base station power consumption information;

step S3: calculating and analyzing the electric energy supply quantity required to maintain the normal operation of the base station according to the monitoring result;

step S4: and controlling and adjusting the power supply of the solar power supply equipment and the base station according to the calculation and analysis result.

According to the above technical solution, the step S2 further includes the following steps:

step S21: when the monitoring submodule I monitors that the residual electric quantity of a solar storage battery supplying power to the base station reaches a battery electric quantity minimum threshold value L, starting a weather information unit through an electric signal to acquire weather information in an area where the base station is located within one hour;

step S22: estimating and judging the average electric energy supplement amount of the illumination intensity to the solar storage battery within one hour to be N by the weather information estimation and judgment module, and further analyzing by the consumption analysis module to obtain the average electric energy consumption amount of the base station within one hour to be X ₁ ；

Step S23: further comparing the two groups of data, when N is<X ₁ When N is more than or equal to X, the communication information of the base station is processed ₁ Then no further processing is performed on the base station.

According to the above technical solution, the step S3 further includes the following steps:

step S31: to obtain N<X ₁ When the comparison result is obtained, the segmentation matching module segments each frame of communication information data on the broadband data carrier of the base station into J time slots, and each time slot is used as a communication channel and is distributed to users needing to communicate through the base station at the same time;

step S32: further controlling the mobile station to send communication signals to the base station in a specified time slot within each frame time, and simultaneously transmitting the signals to each mobile station by the base station in the time slot sequence matched with the division to finish the sending and receiving of the communication information of the base station;

step S33: after the communication information is processed and controlled by the base station, the monitoring submodule II is further started through an electric signal to monitor the average electric energy consumed by the base station in one hour to be X, the input energy calculating module is further started to calculate the electric energy which needs to be provided by the power grid to maintain the normal operation of the base station to be Q, namely Q is X-N, wherein Q is the electric energy value which needs to be provided by the power grid, X is the average electric energy value consumed by the base station in one hour in operation, and N is the average electric energy supplement amount of the illumination intensity to the solar storage battery in one hour.

According to the above technical solution, the step S4 further includes the following steps:

step S41: when the monitoring submodule I monitors that the residual electric quantity of the solar storage battery for supplying power to the base station reaches a battery electric quantity threshold value L, the undervoltage value adjusting module adjusts the undervoltage value of the solar storage battery and controls the undervoltage value of the solar storage battery to be adjusted to be two thirds of the original value;

step S42: according to the calculation result of the step S33, the energy supply conversion module controls the power supply mode of the base station to be converted from the power supply mode of the solar storage battery into the parallel power supply mode of the solar storage battery and the power supply mode of the power grid, and the electric energy provided by the power grid is the calculation result Q;

step S43: after the power supply mode conversion is completed, the electric energy of the power grid for supplying power to the base station is further gradually increased, the electric energy of the solar storage battery for supplying power to the base station is reduced, and the power supply conversion is stopped until the power supply of the base station is completely supplied by the power grid;

step S44: and after the power supply conversion is finished, the recovery processing module controls the power supply energy of the power grid to the base station to gradually increase, and stops the processing mode of the base station to the communication signals in the step S32 and the step S33, and recovers the mode of the base station to normally process the communication signals.

Compared with the prior art, the invention has the following beneficial effects: according to the invention, through arranging the information monitoring acquisition module, the data calculation analysis module and the control management module, the communication information processing mode of the base station can be temporarily adjusted, the electric energy consumption is reduced under the condition of reducing the influence on the user communication to the maximum extent, the anti-interference capability of a communication signal is enhanced, the frequency utilization rate is high, and the system capacity is large; the discontinuous transmission of communication data is further controlled, the energy consumption of the base station is favorably reduced, namely, the mobile phone end of the user is controlled to queue in sequence to wait for transmitting communication information to the base station, and meanwhile, the perception of the waiting time of the user is reduced through the signal processing of the mobile phone end; further, the under-voltage value can be properly reduced to ensure the normal operation of the base station, and the subsequent conversion of the electric energy supply of the base station is immediately carried out through the energy supply conversion module; through the conversion of the electric energy supply mode of the base station, the normal operation of the base station can be maintained, and the electric energy supply to the base station is performed by the power grid independently in a step-by-step quasi-switching mode, so that the base station can be ensured to have sufficient electric energy supply, and the influence on the normal operation of the base station caused by the sudden stop of the electric energy supply to the base station due to the electric energy exhaustion of the solar storage battery is prevented.

Drawings

The accompanying drawings, which are included to provide a further understanding of the invention and are incorporated in and constitute a part of this specification, illustrate embodiments of the invention and together with the description serve to explain the principles of the invention and not to limit the invention. In the drawings:

fig. 1 is a schematic diagram of the system module composition 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.

Referring to fig. 1, the present invention provides a technical solution: the intelligent solar equipment supporting adjusting system comprises an information monitoring and acquiring module, a data calculating and analyzing module and a control management module, wherein the information monitoring and acquiring module is electrically connected with the data calculating and analyzing module, the data calculating and analyzing module is in network connection with the control management module, the information monitoring and acquiring module is used for monitoring and acquiring base station information, the data calculating and analyzing module is used for calculating and analyzing energy information, and the control management module is used for controlling and managing the base station and solar equipment.

The information monitoring and acquiring module comprises a monitoring module, a weather information unit and a segmentation matching module, the monitoring module is electrically connected with the weather information unit, the weather information unit is in network connection with the segmentation matching module, the monitoring module is used for monitoring energy supply information, the monitoring module comprises a first monitoring submodule and a second monitoring submodule, the first monitoring submodule is electrically connected with the second monitoring submodule, the first monitoring submodule and the second monitoring submodule are respectively used for monitoring different energy supply information, the weather information unit is used for acquiring weather information, and the segmentation matching module is used for segmenting and matching communication data information.

The data calculation and analysis module comprises a consumption analysis module, a prediction judgment module and an input energy calculation module, the consumption analysis module is electrically connected with the prediction judgment module, the input energy calculation module is electrically connected with the consumption analysis module, the consumption analysis module is used for analyzing and acquiring energy information consumed by the base station, the prediction judgment module is used for performing prediction judgment on the acquisition of solar energy, and the input energy calculation module is used for calculating and analyzing electric energy required to be input by the base station.

The control management module comprises an undervoltage value adjusting module, an energy supply conversion module and a recovery processing module, the undervoltage value adjusting module is electrically connected with the energy supply conversion module, the energy supply conversion module is electrically connected with the recovery processing module, the undervoltage value adjusting module is used for adjusting the undervoltage value of the solar storage battery, the energy supply conversion module is used for performing conversion control on energy supply of a base station, and the recovery processing module is used for recovering communication processing of the base station.

An operation method of an intelligent solar equipment supporting adjusting system mainly comprises the following steps:

step S1: when the electric quantity of a storage battery powered by solar energy of the base station is insufficient, preparing for further processing;

step S2: monitoring the power supply condition of the solar power supply equipment to the base station through weather information and base station power consumption information;

step S3: calculating and analyzing the electric energy supply quantity required to maintain the normal operation of the base station according to the monitoring result;

step S4: and controlling and adjusting the electric energy supply of the solar power supply equipment and the base station according to the calculation and analysis result.

Step S2 further includes the steps of:

step S21: when the monitoring submodule I monitors that the residual electric quantity of a solar storage battery supplying power to the base station reaches a battery electric quantity minimum threshold value L, starting a weather information unit through an electric signal to acquire weather information in an area where the base station is located within one hour;

step S22: the average electric energy supplement amount of the illumination intensity to the solar storage battery within one hour is estimated and judged to be N by the weather information estimation and judgment module, and further the average electric energy supplement amount is consumedThe analysis module analyzes to obtain the average power consumption of the base station within one hour as X ₁ ；

Step S23: further comparing the two groups of data, when N is<X ₁ When N is more than or equal to X, the communication information of the base station is processed ₁ Then the base station is not further processed; through the comparison of two groups of data information, the power consumption condition of the base station, N, can be visually expressed<X ₁ The solar energy supplement of the solar storage battery is influenced due to insufficient illumination conditions caused by weather reasons, or the work load of the base station is too high due to the fact that the number of users communicating through the base station is large, the electric energy consumption is too high to exceed the electric energy supply quantity of the solar storage battery, so that the communication information processing mode of the base station needs to be adjusted temporarily, the electric energy consumption is reduced under the condition that the influence on the communication of the users is reduced to the maximum extent, and a cushion is laid for further processing.

Step S3 further includes the steps of:

step S31: to obtain N<X ₁ When the comparison result is obtained, the segmentation matching module segments each frame of communication information data on the broadband data carrier of the base station into J time slots, and each time slot is used as a communication channel to be allocated to a user needing to communicate through the base station at the same time;

step S32: further controlling the mobile station to send communication signals to the base station in a specified time slot within each frame time, and simultaneously transmitting the signals to each mobile station by the base station in the time slot sequence matched with the division to finish the sending and receiving of the communication information of the base station; through the steps S31 and S32, a plurality of time slots share one carrier, intermodulation interference is reduced, meanwhile, the anti-interference capability of communication signals is enhanced, the frequency utilization rate is high, and the system capacity is large; the discontinuous transmission of communication data is further controlled, the energy consumption of the base station is favorably reduced, namely, the mobile phone end of the user is controlled to queue in sequence to wait for transmitting communication information to the base station, and meanwhile, the perception of the waiting time of the user is reduced through the signal processing of the mobile phone end;

step S33: after the communication information is processed and controlled by the base station, the monitoring submodule II is further started through an electric signal to monitor the average electric energy consumed by the base station in one hour to be X, the input energy calculating module is further started to calculate the electric energy which needs to be provided by the power grid to maintain the normal operation of the base station to be Q, namely Q is X-N, wherein Q is the electric energy value which needs to be provided by the power grid, X is the average electric energy value consumed by the base station in one hour in operation, and N is the average electric energy supplement amount of the illumination intensity to the solar storage battery in one hour.

Step S4 further includes the steps of:

step S41: when the monitoring submodule I monitors that the residual electric quantity of the solar storage battery for supplying power to the base station reaches a battery electric quantity threshold value L, the undervoltage value adjusting module adjusts the undervoltage value of the solar storage battery and controls the undervoltage value of the solar storage battery to be adjusted to be two thirds of the original value; when the electric quantity of the solar storage battery is insufficient, the electric energy supply of the base station is unstable, the line voltage of the base station is easy to reach a preset undervoltage value, the action of a protective electric appliance stops the electric energy supply, the base station stops running and the user communication of the area where the base station is located is seriously influenced, so the undervoltage value is properly reduced to ensure the normal running of the base station, and the subsequent conversion of the electric energy supply of the base station is immediately carried out through the energy supply conversion module;

step S42: according to the calculation result of the step S33, the energy supply conversion module controls the power supply mode of the base station to be converted from the power supply mode of the solar storage battery into the parallel power supply mode of the solar storage battery and the power supply mode of the power grid, and the electric energy provided by the power grid is the calculation result Q;

step S43: after the power supply mode conversion is completed, the electric energy of the power grid for supplying power to the base station is further gradually increased, the electric energy of the solar storage battery for supplying power to the base station is reduced, and the power supply conversion is stopped until the power supply of the base station is completely supplied by the power grid; the normal operation of the base station can be maintained by converting the electric energy supply mode of the base station, and the electric energy supply to the base station is performed by the power grid independently step by step, so that the sufficient electric energy supply of the base station can be ensured, and the influence on the normal operation of the base station caused by the sudden stop of the electric energy supply to the base station due to the electric energy exhaustion of the solar storage battery is prevented;

step S44: and after the power supply conversion is finished, the recovery processing module controls the power supply energy of the power grid to the base station to gradually increase, and stops the processing mode of the base station to the communication signals in the step S32 and the step S33, and recovers the mode of the base station to normally process the communication signals.

It is noted that, herein, relational terms such as first and second, and the like may be used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Also, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus.

Finally, it should be noted that: although the present invention has been described in detail with reference to the foregoing embodiments, it will be apparent to those skilled in the art that modifications may be made to the embodiments described above, or equivalents may be substituted for elements thereof. Any modification, equivalent replacement, or improvement made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims (8)

1. The utility model provides an intelligent solar equipment supports uses governing system, includes information monitoring acquisition module, data calculation analysis module and control management module, its characterized in that: the information monitoring and acquiring module is electrically connected with the data calculating and analyzing module, the data calculating and analyzing module is connected with the control management module through a network, the information monitoring and acquiring module is used for monitoring and acquiring information of the base station, the data calculating and analyzing module is used for calculating and analyzing energy information, and the control management module is used for controlling and managing the base station and the solar equipment.

2. The intelligent solar plant support conditioning system of claim 1, wherein: the information monitoring and acquiring module comprises a monitoring module, a weather information unit and a segmentation matching module, the monitoring module is electrically connected with the weather information unit, the weather information unit is in network connection with the segmentation matching module, the monitoring module is used for monitoring energy supply information, the monitoring module comprises a monitoring submodule I and a monitoring submodule II, the monitoring submodule I is electrically connected with the monitoring submodule II, the monitoring submodule I and the monitoring submodule II are respectively used for monitoring different energy supply information, the weather information unit is used for acquiring weather information, and the segmentation matching module is used for segmenting and matching communication data information.

3. The intelligent solar plant support conditioning system of claim 2, wherein: the data calculation and analysis module comprises a consumption analysis module, a pre-estimation judgment module and an input energy calculation module, the consumption analysis module is electrically connected with the pre-estimation judgment module, the input energy calculation module is electrically connected with the consumption analysis module, the consumption analysis module is used for analyzing and acquiring energy information consumed by the base station, the pre-estimation judgment module is used for pre-estimating and judging the acquisition of solar energy, and the input energy calculation module is used for calculating and analyzing electric energy required to be input by the base station.

4. The intelligent solar plant support conditioning system of claim 3, wherein: the control management module comprises an undervoltage value adjusting module, an energy supply conversion module and a recovery processing module, the undervoltage value adjusting module is electrically connected with the energy supply conversion module, the energy supply conversion module is electrically connected with the recovery processing module, the undervoltage value adjusting module is used for adjusting the undervoltage value of the solar storage battery, the energy supply conversion module is used for carrying out conversion control on energy supply of a base station, and the recovery processing module is used for recovering communication processing of the base station.

5. The intelligent solar plant support conditioning system of claim 4, wherein: the operation method of the intelligent solar equipment supporting adjusting system mainly comprises the following steps:

step S1: when the electric quantity of a storage battery powered by solar energy of the base station is insufficient, preparing for further processing;

step S2: monitoring the power supply condition of the solar power supply equipment to the base station through weather information and base station power consumption information;

step S3: calculating and analyzing the electric energy supply quantity required to maintain the normal operation of the base station according to the monitoring result;

step S4: and controlling and adjusting the power supply of the solar power supply equipment and the base station according to the calculation and analysis result.

6. The intelligent solar plant support conditioning system of claim 5, wherein: the step S2 further includes the steps of:

step S21: when the monitoring submodule I monitors that the residual electric quantity of a solar storage battery supplying power to the base station reaches a battery electric quantity minimum threshold value L, starting a weather information unit through an electric signal to acquire weather information in an area where the base station is located within one hour;

step S22: estimating and judging the average electric energy supplement amount of the illumination intensity to the solar storage battery within one hour to be N by the weather information estimation and judgment module, and further analyzing by the consumption analysis module to obtain the average electric energy consumption amount of the base station within one hour to be X ₁ ；

Step S23: further comparing the two groups of data, when N is<X ₁ When N is more than or equal to X, the communication information of the base station is processed ₁ Then no further processing is performed on the base station.

7. The intelligent solar plant support conditioning system of claim 6, wherein: the step S3 further includes the steps of:

step S31: to obtain N<X ₁ When the comparison result is obtained, the segmentation matching module divides the base station into a plurality of base stationsEach frame of communication information data on the data-carrying carrier wave is divided into J time slots, and each time slot is used as a communication channel to be distributed to users needing to communicate through a base station at the same time;

step S32: further controlling the mobile station to send communication signals to the base station in a specified time slot within each frame time, and simultaneously transmitting the signals to each mobile station by the base station in the time slot sequence matched with the division to finish the sending and receiving of the communication information of the base station;

step S33: after the communication information is processed and controlled by the base station, the monitoring submodule II is further started through an electric signal to monitor the average electric energy consumed by the base station in one hour to be X, the input energy calculating module is further started to calculate the electric energy which needs to be provided by the power grid to maintain the normal operation of the base station to be Q, namely Q is X-N, wherein Q is the electric energy value which needs to be provided by the power grid, X is the average electric energy value consumed by the base station in one hour in operation, and N is the average electric energy supplement amount of the illumination intensity to the solar storage battery in one hour.

8. The intelligent solar plant support conditioning system of claim 7, wherein: the step S4 further includes the steps of:

step S41: when the monitoring submodule I monitors that the residual electric quantity of the solar storage battery for supplying power to the base station reaches a battery electric quantity threshold value L, the undervoltage value adjusting module adjusts the undervoltage value of the solar storage battery and controls the undervoltage value of the solar storage battery to be adjusted to be two thirds of the original value;

step S42: according to the calculation result of the step S33, the energy supply conversion module controls the power supply mode of the base station to be converted from the power supply mode of the solar storage battery into the parallel power supply mode of the solar storage battery and the power supply mode of the power grid, and the electric energy provided by the power grid is the calculation result Q;

step S43: after the power supply mode conversion is completed, the electric energy of the power grid for supplying power to the base station is further gradually increased, the electric energy of the solar storage battery for supplying power to the base station is reduced, and the power supply conversion is stopped until the power supply of the base station is completely supplied by the power grid;

step S44: and after the power supply conversion is finished, the recovery processing module controls the power supply energy of the power grid to the base station to gradually increase, and stops the processing mode of the base station to the communication signals in the step S32 and the step S33, and recovers the mode of the base station to normally process the communication signals.

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