CN113178935A

CN113178935A - Solar outdoor power system

Info

Publication number: CN113178935A
Application number: CN202110439803.7A
Authority: CN
Inventors: 罗磊; 朱祥明; 冯少君
Original assignee: Shenzhen Hengtai Energy Technology Co ltd
Current assignee: Shenzhen Hengtai Energy Technology Co ltd
Priority date: 2021-04-23
Filing date: 2021-04-23
Publication date: 2021-07-27
Anticipated expiration: 2041-04-23
Also published as: CN113178935B

Abstract

The invention provides a solar outdoor power system, comprising: the connecting module is used for establishing communication connection between the outdoor power supply and the mobile equipment and acquiring the operating parameters of the solar panel; the data analysis module is used for determining the state information of the current outdoor power supply; the electric quantity obtaining module is used for obtaining the current total electric quantity of the outdoor power supply based on the working state of the outdoor power supply; the power supply capacity acquisition module is used for detecting the outdoor sunlight intensity and acquiring the power supply capacity of the current solar panel; the control module is used for displaying the power supply capacity of the solar panel and the current total electric quantity of the outdoor power supply and controlling the power supply mode of the outdoor power supply through the mobile equipment; the communication connection with the mobile device is established, so that the state information of the outdoor power supply can be acquired accurately, a proper power supply mode is selected to supply power for the outdoor power supply in combination with the solar power supply capacity, and the intelligence and the convenience of solar outdoor power supply are greatly improved.

Description

Solar outdoor power system

Technical Field

The invention relates to the technical field of solar power supply, in particular to a solar outdoor power system.

Background

At present, with the development of science and technology and the international limit on carbon emission, solar energy is gradually a new star in the energy market as an inexhaustible and pollution-free energy, the utilization degree of solar energy by people is higher and higher, and an outdoor power supply of solar energy is supplied more and more;

however, the outdoor power supply by solar energy is simply powered by a simple machine, so that the electric quantity of the outdoor power supply cannot be acquired, the power supply information of the outdoor power supply cannot be acquired by mobile devices such as a mobile phone, and the outdoor power supply cannot be controlled.

Disclosure of Invention

The invention provides a solar outdoor power system which is used for acquiring the operating parameters of a solar panel at any time by establishing connection between an outdoor power supply and mobile equipment, determining the electric quantity of the current outdoor power supply and supplying power to the outdoor power supply by selecting a power supply mode, so that the intelligence and convenience of supplying power to the outdoor power supply by solar energy are improved.

A solar outdoor power system comprising:

the connecting module is used for establishing communication connection between the outdoor power supply and the mobile equipment and acquiring the operating parameters of the solar panel based on the communication connection;

the data analysis module is used for analyzing the operating parameters of the solar panel and determining the current state information of the outdoor power supply based on the analysis result;

the electric quantity obtaining module is used for obtaining the current total electric quantity of the outdoor power supply based on the working state of the outdoor power supply;

the power supply capacity acquisition module is used for detecting the outdoor sunlight intensity and acquiring the current power supply capacity of the solar panel;

a control module: and uploading the power supply capacity of the solar panel and the current total electric quantity of the outdoor power supply to the mobile equipment for displaying, and controlling the power supply mode of the outdoor power supply through the mobile equipment.

Preferably, the solar outdoor power system, the connection module, includes:

the mobile equipment processing unit is used for acquiring a communication address of the mobile equipment and acquiring a first identifier of the mobile equipment based on the communication address of the mobile equipment;

the identification unit is used for acquiring a signal connecting end of the outdoor power supply, acquiring a second identifier of the outdoor power supply through the signal connecting end, identifying the first identifier and the second identifier, and acquiring an identification result;

the communication protocol construction unit is used for constructing a communication protocol between the outdoor power supply and the mobile equipment based on the identification result;

the verification unit is used for sending a connection request to the mobile equipment by the outdoor power supply according to the communication protocol, and meanwhile, the mobile equipment carries out validity verification on the connection request according to a preset method;

when the connection request passes the validity verification, establishing communication connection between the outdoor power supply and the mobile equipment;

and meanwhile, acquiring the operating parameters of the solar panel in real time through the monitoring end of the outdoor power supply, and transmitting the operating parameters of the solar panel to the mobile equipment for display based on the communication connection.

Preferably, the solar outdoor power system, the data analysis module, includes:

the operation parameter acquisition unit is used for preprocessing the operation parameters of the solar panel, acquiring target operation parameters, extracting identifiers of the target operation parameters, inputting the target operation parameters into a preset data classification training model, performing classification training according to the identifiers of the target operation parameters, and acquiring sub-target operation parameters;

the first data comparison unit is used for analyzing the sub-target operation data, constructing a sub-target operation data model based on an analysis result, acquiring the data dimension of the sub-target operation data model, constructing a data table based on the data dimension, comparing the sub-target operation data in the data table with the data in a preset data table, and acquiring the data with the data deviation larger than the preset deviation;

a result determining unit, configured to perform data processing on the data with the data deviation greater than a preset deviation, and determine current state information of the outdoor power supply based on a processing result, where the state information of the outdoor power supply includes: a charged state, a discharged state.

Preferably, the solar outdoor power system, the power acquiring module, includes:

the first data acquisition unit is used for acquiring the state information of the outdoor power supply, and acquiring the power of the outdoor power supply during normal operation and the working time of the outdoor power supply;

the relation construction unit is used for establishing an incidence relation with the current total electric quantity of the outdoor power supply according to the power of the outdoor power supply during normal work and the working time of the outdoor power supply;

and the electric quantity determining unit is used for acquiring the current working performance of the outdoor power supply, determining the current aging factor of the outdoor power supply based on the working performance, and calculating and acquiring the current total electric quantity of the outdoor power supply based on the current aging factor of the outdoor power supply and the incidence relation.

Preferably, the solar outdoor power system includes a power supply capacity acquisition module, which includes:

the monitoring preparation unit is used for arranging a measurement dot matrix on the solar panel and arranging a photosensitive sensor in each measurement point, wherein the measurement dot matrix is a discrete dot matrix which is uniformly distributed;

the data processing unit is used for acquiring an external illumination intensity value based on the photosensitive sensor, converting the external illumination intensity value into external illumination intensity data in a digital-to-analog conversion mode, and generating an illumination intensity matrix from the external illumination intensity data acquired by the photosensitive sensor according to the measurement dot matrix;

the first calculation unit is used for acquiring a solar exposure value based on the measurement lattice of the solar panel and calculating an exposure weight corresponding to the exposure value;

the data analysis unit is used for correcting the measurement dot matrix according to the exposure weight, analyzing the corrected illumination intensity matrix, acquiring an analysis result, acquiring the current outdoor illumination intensity based on the analysis result, and grading the current outdoor illumination intensity according to a preset method;

when the current outdoor illumination intensity is at a first level, judging that the current power supply capacity of the solar panel is strong;

when the current outdoor illumination intensity is at a second level, judging that the current power supply capacity of the solar panel is medium;

when the outdoor illumination intensity is at the third level, the power supply capacity of the solar panel is judged to be weak.

Preferably, the solar outdoor power system, the control module includes:

the second data acquisition unit is used for digitizing the power supply capacity of the solar panel, acquiring a power supply capacity data index, combining the power supply capacity data index with the current total electric quantity data of the outdoor power supply and acquiring data to be uploaded;

the data segmentation unit is used for carrying out data binarization on the data to be uploaded, segmenting the data to be uploaded after the data to be uploaded is subjected to the data binarization, and acquiring sub data segments to be uploaded;

the data encapsulation unit is used for encapsulating the first data segment of the sub data segment to be uploaded, acquiring a data address of the data to be uploaded as a data signal port of the data to be uploaded, acquiring data bit information of the data to be uploaded at the same time, and generating a data transmission signal according to the data signal port of the data to be uploaded, the data address of the data to be uploaded and the data bit information of the data to be uploaded;

a data uploading unit, configured to upload the data to be uploaded to the mobile device based on the data transmission signal;

the data updating unit is used for updating the data to be uploaded in a preset database by the mobile equipment and displaying the updated data to be uploaded in a target application program;

the selection unit is used for selecting the outdoor power supply mode as a target power supply mode based on the target application program and according to the power supply capacity data index and the current total electric quantity of the outdoor power supply;

wherein, the outdoor power supply mode includes: a solar power supply mode and an alternating current power supply mode;

and the power supply unit is used for supplying power to the outdoor power supply through the mobile equipment based on the target power supply mode.

Preferably, the solar outdoor power system, the selection unit includes:

the second data comparison unit is used for comparing the current total electric quantity of the outdoor power supply with a preset electric quantity threshold value;

the first execution unit is used for judging that the outdoor power supply needs to obtain electric energy currently if the current total electric quantity of the outdoor power supply is smaller than or equal to the preset electric quantity threshold value;

the power supply capacity determining unit is used for determining the current power supply capacity of the solar panel according to the current power supply capacity data index of the solar panel;

the second execution unit is used for taking the solar power supply mode as a target power supply mode when the power supply capacity of the solar panel is strong or medium;

the third execution unit is used for taking the alternating current power supply mode as a target power supply mode when the power supply capacity of the solar panel is weak;

and the power supply mode determining unit is used for finishing the selection of the power supply mode of the outdoor power supply based on the target power supply mode.

Preferably, the solar outdoor power system, the power supply capability obtaining module further includes:

the third data acquisition unit is used for acquiring an external illumination coefficient, calculating the current outdoor solar light intensity through the illumination coefficient, and calculating the power supply efficiency of the solar panel based on the outdoor light intensity;

the fourth data acquisition unit is used for acquiring the current external illumination coefficient and acquiring the current exposure of the external illumination based on the current external illumination coefficient;

the second calculation unit is used for calculating the intensity of the solar rays currently irradiated on the solar panel based on the current external illumination coefficient and the current exposure of the external illumination;

wherein Q represents the intensity of the solar rays currently irradiated on the solar panel; delta represents an external illumination coefficient, and the value range is (0.3, 0.6); g represents the luminous flux of the solar panel; s represents the area of the solar panel; b represents the sensitivity of the photosensitive sensor; m represents the average light sensitivity of the photosensitive sensors of all the measuring points to external illumination;

a third calculation unit: calculating the power supply efficiency of the solar panel according to the intensity of sunlight currently irradiating the solar panel;

wherein η represents a power supply efficiency of the solar panel; q represents the intensity of the solar rays currently irradiating the solar panel; q_maxRepresents the maximum light intensity that the solar panel can absorb; f represents the current operating power of the solar panel; f represents the rated power of the solar panel; w represents the work done by the solar panel during working time; u represents the voltage when the solar panel supplies power to the outdoor power supply; i represents the time when the solar panel supplies power to the outdoor power supply; t represents the working time of the solar panel;

the third comparison unit is used for determining the reference power supply efficiency of the solar panel according to the current outdoor sunlight intensity and comparing the power supply efficiency of the solar panel with the reference power supply efficiency of the solar panel;

when the power supply efficiency of the solar panel is equal to or greater than the reference power supply efficiency of the solar panel, judging that the current working performance of the solar panel is good;

a fourth calculating unit, configured to calculate a difference efficiency between a reference power supply efficiency of the solar panel and a power supply efficiency of the solar panel, determine an aging coefficient of the solar panel from an aging database according to the difference efficiency, and calculate an aging value of the solar panel according to the aging coefficient;

and the optimization unit is used for acquiring an efficiency optimization model of the solar panel according to the aging value of the solar panel and based on the aging degree, and performing efficiency optimization on the solar panel according to the efficiency optimization model.

Additional features and advantages of the invention will be set forth in the description which follows, and in part will be obvious from the description, or may be learned by practice of the invention. The objectives and other advantages of the invention will be realized and attained by the structure particularly pointed out in the written description and claims hereof as well as the appended drawings.

The technical solution of the present invention is further described in detail by the accompanying drawings and embodiments.

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 structural diagram of a solar outdoor power system according to an embodiment of the present invention;

FIG. 2 is a schematic diagram of an internal structure of a connection module in a solar outdoor power system according to an embodiment of the present invention;

FIG. 3 is a system diagram of an internal structure of a data analysis module in a solar outdoor power system according to an embodiment of the present invention;

fig. 4 is a system diagram of an internal structure of an electric quantity obtaining module in a solar outdoor power system according to an embodiment of the present invention.

Detailed Description

The preferred embodiments of the present invention will be described in conjunction with the accompanying drawings, and it will be understood that they are described herein for the purpose of illustration and explanation and not limitation.

Example 1:

the present embodiment provides a solar outdoor power system, as shown in fig. 1, including:

and the control module is used for uploading the power supply capacity of the solar panel and the current total electric quantity of the outdoor power supply to the mobile equipment for displaying, and controlling the power supply mode of the outdoor power supply through the mobile equipment.

In this embodiment, the mobile device may be a cell phone, tablet, or the like.

In this embodiment, the operating parameter of the solar panel may be the operating time of the solar panel, the current operating power of the solar panel, the storage capacity of the solar panel, and the like.

In this embodiment, the status information of the outdoor power supply may be a charging status or a discharging status.

In this embodiment, the power supply capability of the solar panel may be determined based on the ambient light intensity, for example, when the ambient light intensity is strong, the power supply capability of the solar panel is strong, and the like.

In this embodiment, the outdoor power supply mode may be a solar power supply mode or an ac power supply mode.

The beneficial effects of the above technical scheme are: the communication connection with the mobile device is established, so that the state information of the outdoor power supply can be acquired accurately, a proper power supply mode is selected to supply power for the outdoor power supply in combination with the solar power supply capacity, and the intelligence and the convenience of solar outdoor power supply are greatly improved.

Example 2:

on the basis of embodiment 1, this embodiment provides a solar outdoor power system, as shown in fig. 2, in the connection module, including:

In this embodiment, the first identifier is determined based on the communication address of the mobile device, which is used to identify the mobile device.

In this embodiment, the second identifier is obtained through the signal connection of the outdoor power source and identifies the outdoor power source.

In this embodiment, the communication protocol is a protocol that facilitates the establishment of contact between the outdoor power source and the mobile device.

In this embodiment, the preset method may be a method for detecting security of a communication protocol, and when the communication protocol does not conform to the preset method, it is determined that the communication protocol is illegal.

The beneficial effects of the above technical scheme are: the communication connection between the mobile equipment and the outdoor power supply is favorably established by acquiring the communication protocol, and the connection legality and safety are improved by detecting the safety of the communication protocol.

Example 3:

on the basis of embodiment 1, this embodiment provides a solar outdoor power system, as shown in fig. 3, the data analysis module includes:

an operation parameter acquisition unit: the system comprises a pre-processing module, a data classification training module and a data analysis module, wherein the pre-processing module is used for pre-processing the operating parameters of the solar panel, acquiring target operating parameters, extracting identifiers of the target operating parameters, inputting the target operating parameters into a preset data classification training model for classification training according to the identifiers of the target operating parameters and acquiring sub-target operating parameters;

a first data comparison unit: the data dimension of the sub-target operation data model is obtained, a data table is built based on the data dimension, the sub-target operation data in the data table is compared with the data in a preset data table, and the data with the data deviation larger than the preset deviation is obtained;

a result determination unit: the data processing unit is used for processing the data with the data deviation larger than the preset deviation, and meanwhile, determining the current state information of the outdoor power supply based on the processing result, wherein the state information of the outdoor power supply comprises: a charged state, a discharged state.

In this embodiment, the preprocessing of the operation parameters may be to delete data, error data, repeated data, and the like that are irrelevant to the operation parameters of the solar panel.

In this embodiment, the identifier of the operating parameter may be a different kind of identifier, for example: among the operation parameters, an identifier of the operation time of the solar panel is time-related, an identifier of the current operation power of the solar panel is power-related, an identifier of the storage capacity of the solar panel is capacity-related, and the like.

In this embodiment, the sub-target operation data model may be based on a sub-target operation data model, which is established by classifying the target operation parameters, and the model established by each class is the sub-target operation data model, such as a time operation data model, a power operation data model, and the like.

In this embodiment, when the data deviation is greater than the preset deviation, it is to determine the current working condition of the solar panel, for example: when solar panel's operating power equals or is greater than the settlement power, can judge that current solar panel is charging to outdoor power source, when solar panel's operating power is less than the settlement power, can judge that solar panel is carrying out daily operation, does not have extra power at the output, can judge outdoor power source this moment and discharge.

The beneficial effects of the above technical scheme are: the operation parameters of the solar panel are classified and the table is established, so that the operation parameters of the solar panel can be managed, and the current state information of the outdoor power supply can be judged.

Example 4:

on the basis of embodiment 1, this embodiment provides a solar outdoor power system, as shown in fig. 4, the power acquiring module includes:

the first data acquisition unit is used for acquiring the power of the outdoor power supply during normal work and the working time of the outdoor power supply based on the state information of the outdoor power supply;

In this embodiment, the association relationship with the current total power of the outdoor power supply may be based on W_{Electric quantity}＝p_{Power of}T is obtained.

In this embodiment, the operation performance may be the ability of the outdoor power supply to operate, such as the effective power output by the current outdoor power supply, the sensitivity of the current outdoor power supply when supplying power, and the like.

In this embodiment, the aging factor is used to measure an aging parameter of the outdoor power supply, and is related to the current working performance of the outdoor power supply, for example, if the effective power output by the outdoor power supply is a, and the effective power output by the outdoor power supply when the outdoor power supply is in use is b, the aging factor of the current outdoor power supply is a/b.

The beneficial effects of the above technical scheme are: the incidence relation between the outdoor power supply and the current total electric quantity of the outdoor power supply is established through the power of the outdoor power supply in normal working and the working time of the outdoor power supply, the total electric quantity can be rapidly acquired, and the current total electric quantity of the outdoor power supply can be accurately acquired by considering the aging factor and the incidence relation.

Example 5:

on the basis of embodiment 1, this embodiment provides a solar outdoor power system, where the power supply capability obtaining module includes:

In this embodiment, the measurement dot matrix is for dividing solar panel, is convenient for carry out accurate measurement to each position on the solar panel.

In this embodiment, the illumination intensity matrix refers to that the illumination intensity data corresponding to the illumination intensity value is placed in the matrix, and the placement position of the illumination intensity data is related to the setting position of the photosensitive sensor, so that the illumination intensity data can be conveniently processed or calculated correspondingly.

In this embodiment, the solar exposure value refers to the value of solar illumination intensity that the photosensitive sensor can receive.

In this embodiment, the exposure weight refers to the intensity of light received by different photosensors on the solar panel, and is an importance value of all the photosensors.

In this embodiment, the preset method is set in advance and is used for grading the illumination intensity, for example, when the illumination intensity is greater than 50, the illumination intensity is a first grade, less than 50 and greater than 30, the illumination intensity is a second grade, and the like.

The beneficial effects of the above technical scheme are: through the photosensitive sensor who sets up on solar panel, detect solar panel received illumination intensity data to handle illumination intensity data and accomplish the level and divide, this scheme has ensured to carry out accurate grade division to the illumination intensity of difference, thereby the corresponding power supply ability of accurate judgement has improved the accurate judgement to solar panel power supply ability.

Example 6:

on the basis of embodiment 1, this embodiment provides a solar outdoor power system, where the control module includes:

In this embodiment, the encapsulation of the first data segment of the sub data segment to be uploaded is to accurately obtain a data port for accurately obtaining the data to be uploaded, which is beneficial to uploading and identifying the data.

In this embodiment, the data transfer signal is determined by the data bit information, the data address, and the data signal port.

In this embodiment, the target power supply system is one of a solar power supply system and an ac power supply system.

In this embodiment, the target application program may be a program APP for displaying the operating state of the solar panel in the mobile device, or may be a wechat applet or the like.

In this embodiment, the power supply capability data index may be an index for measuring the power supply capability of the solar panel, that is, the higher the power supply capability data index is, the stronger the power supply capability of the solar panel is.

The beneficial effects of the above technical scheme are: the method has the advantages that the data signal port which is beneficial to accurately acquiring the data to be uploaded is formed by segmenting the data to be uploaded, the data transmission to the mobile equipment is completely and accurately facilitated by generating the data transmission signal, the new data are accurately acquired and displayed by updating the data of the preset database in the mobile equipment, so that the convenience of information acquisition is improved, the target power supply mode is favorably selected according to the current total electric quantity of the outdoor power supply, and the convenience of the device is greatly improved.

Example 7:

on the basis of embodiment 6, this embodiment provides a solar outdoor power system, where the selection unit includes:

In this embodiment, the preset electric quantity threshold is set in advance, and is used for measuring the electric quantity degree of the outdoor power supply.

In this embodiment, the power supply capacity data index is used to describe the power supply capacity of the solar panel, and the larger the index is, the stronger the power supply capacity of the solar panel is.

In this embodiment, the ac power supply mode refers to supplying power by 220V ac power in daily life.

The beneficial effects of the above technical scheme are: through confirming outdoor power supply's current total electric quantity to when outdoor power supply needs the power supply, judge current solar panel's power supply capacity, accomplish the affirmation to outdoor power supply mode, ensured to carry out timely charging to outdoor power supply.

Example 8:

on the basis of embodiment 1, the power supply capability obtaining module further includes:

the third calculation unit is used for calculating the power supply efficiency of the solar panel according to the intensity of the sunlight irradiating the solar panel at present;

and the optimization unit is used for acquiring an efficiency optimization model of the solar panel based on the aging degree according to the aging value of the solar panel and carrying out efficiency optimization on the solar panel according to the efficiency optimization model.

In this embodiment, the aging value of the solar panel is calculated according to the aging coefficient, which may be calculated by multiplying the aging coefficient by the power supply efficiency of the solar panel before aging.

In this embodiment, the ambient light coefficient is used to indicate that the degree of ambient light intensity is worth a parameter, and a larger coefficient indicates a stronger light intensity.

In this embodiment, the reference power supply efficiency refers to the optimal power supply efficiency of the solar panel, and is obtained through multiple training.

The beneficial effects of the above technical scheme are: through acquireing external illumination coefficient, be favorable to accurately calculating current outdoor sunlight intensity through illumination coefficient to based on outdoor light intensity accurate calculation solar panel's power supply efficiency is through carrying out the ageing degree of analysis reasonable analysis department solar panel to power supply efficiency, and confirm efficiency optimization model to ageing degree, optimize solar panel, improved solar panel's practicality greatly.

It will be apparent to those skilled in the art that various changes and modifications may be made in the present invention without departing from the spirit and scope of the invention. Thus, if such modifications and variations of the present invention fall within the scope of the claims of the present invention and their equivalents, the present invention is also intended to include such modifications and variations.

Claims

1. A solar outdoor power system, comprising:

2. A solar outdoor power system according to claim 1, wherein said connection module includes:

3. A solar outdoor power system according to claim 1, wherein said data analysis module includes:

4. The solar outdoor power system of claim 1, wherein the power harvesting module comprises:

5. A solar outdoor power system according to claim 1, wherein said power supply capability obtaining module includes:

6. A solar outdoor power system according to claim 1, wherein said control module includes:

7. A solar outdoor power system according to claim 6, wherein said selection unit includes:

8. The solar outdoor power system of claim 1, wherein the power capability obtaining module further comprises: