CN110829524A

CN110829524A - Adaptive charging control method and device, electronic equipment and storage medium

Info

Publication number: CN110829524A
Application number: CN201911056346.2A
Authority: CN
Inventors: 郑犁; 黄金林
Original assignee: Password Wizard Co Ltd
Current assignee: Password Wizard Co Ltd
Priority date: 2019-10-31
Filing date: 2019-10-31
Publication date: 2020-02-21
Anticipated expiration: 2039-10-31
Also published as: CN110829524B

Abstract

The application relates to the technical field of photovoltaic charging, in particular to a control method and device for self-adaptive charging, electronic equipment and a storage medium, wherein charging information of a rechargeable battery in an energy storage unit is acquired, if the charging information is lower than a preset charging threshold value, a camera associated with the energy storage unit is started, illumination brightness information in the environment is acquired through the camera, and the illumination brightness information is compared with a color gradation map stored in a database; determining color block information corresponding to the illumination brightness information in the color level diagram according to the comparison result, and acquiring power supply information associated with the color block information; controlling a power supply device to charge a rechargeable battery according to the power supply information; the scheme can not only avoid the power supply equipment from being influenced by illumination intensity, so that the phenomenon of unstable power supply is caused, but also can ensure the service life and the service performance of the rechargeable battery.

Description

Adaptive charging control method and device, electronic equipment and storage medium

Technical Field

The present application relates to the field of photovoltaic charging technologies, and in particular, to a method and an apparatus for controlling adaptive charging, an electronic device, and a storage medium.

Background

With the continuous development of science and technology, photovoltaic charging is more and more favored by people to replace traditional charging mode gradually. In the prior art, the photovoltaic module is exposed in an illumination environment, so that the photovoltaic module can continuously receive illumination, and light energy is converted into electric energy and then is transmitted to the electric storage device for storage, so that power is supplied to a load at any time.

For example, currently, an intelligent door lock with wide application can be automatically unlocked according to identified correct unlocking information, and the unlocking process needs to supply electric energy to an unlocking mechanism by depending on an internal power supply; at present, most photovoltaic charging equipment is used for supplying power for the intelligent door lock, and the intensity of illumination of the photovoltaic charging equipment is identified by utilizing a photosensitive resistor, so that a power supply circuit inside the intelligent door lock is adjusted.

However, the photovoltaic charging equipment is greatly influenced by the illumination intensity, and the service life and the performance of the power storage power supply in the intelligent door lock are influenced due to the instability of the photovoltaic charging equipment; in addition, the photoresistor is greatly influenced by the ambient temperature, so that the light sensing precision is reduced and the response time is reduced after long-term use.

Disclosure of Invention

The present application aims to solve at least one of the above technical drawbacks, in particular, the technical drawback of the prior art that the photovoltaic charging device is greatly affected by the intensity of illumination, and the instability of the photovoltaic charging device itself causes the reduction of the service life and performance of the storage power supply in the electronic device.

The application provides a control method of self-adaptive charging, which comprises the following steps:

the method comprises the steps of obtaining charging information of a rechargeable battery in an energy storage unit, and if the charging information is lower than a preset charging threshold value, starting a camera related to the energy storage unit;

acquiring illumination brightness information in an environment, and comparing the illumination brightness information with a color level map stored in a database;

determining color block information corresponding to the illumination brightness information in the color level diagram according to a comparison result, and acquiring power supply information associated with the color block information; the power supply information is an information set which is set according to different color block information and used for controlling a light source to provide different illumination brightness for power supply equipment;

and controlling the power supply equipment to charge the rechargeable battery according to the power supply information.

In one embodiment, the step of comparing the illumination brightness information with the color level map stored in the database further includes:

and setting each color block information in the color level diagram, and determining power supply information associated with each color block information.

In one embodiment, the color patch information includes at least one of a preparation phase color patch, a light-on charging color patch, a strong light charging color patch, and a weak light charging color patch.

In one embodiment, the patch information is a preparation phase patch;

determining power supply information associated with the preparation phase color block;

and controlling and detecting the state of a power supply circuit between the power supply equipment and the rechargeable battery according to the power supply information associated with the color blocks in the preparation stage.

In one embodiment, the color block information is a light-on charging color block;

determining power supply information associated with the light-on charging color block;

and controlling to start the spotlight according to the power supply information associated with the lighting and charging color block, and switching on a power supply circuit between the power supply equipment associated with the spotlight and the rechargeable battery.

In one embodiment, the color block information is a highlight charging color block;

determining power supply information associated with the highlight charging color block;

and controlling and communicating a power supply circuit between a strong light power supply module in the power supply equipment and the rechargeable battery according to the power supply information associated with the strong light charging color block.

In one embodiment, the color block information is a weak light charging color block;

determining power supply information associated with the low-light charging color block;

and controlling and communicating a power supply circuit between a weak light power supply module in the power supply equipment and the rechargeable battery according to the power supply information associated with the weak light charging color block.

In one embodiment, after the step of determining the power supply information associated with each color block information, the method further includes:

and determining a brightness threshold value corresponding to the color block depth according to the color block depth of each color block information.

In one embodiment, after the step of determining the luminance threshold corresponding to the color block depth according to the color block depth of each color block information, the method further includes:

acquiring an illumination brightness value in the illumination brightness information;

and comparing the illumination brightness value with the brightness threshold value.

In one embodiment, the step of determining color block information corresponding to the illumination brightness information in the color level map according to the comparison result includes:

obtaining a comparison result between the illumination brightness value and the brightness threshold value, and determining the brightness threshold value corresponding to the illumination brightness value;

and determining the corresponding color block depth according to the brightness threshold, and searching color block information corresponding to the color block depth.

In one embodiment, the energy storage unit further comprises a backup battery;

and if the charging information of the rechargeable battery is lower than a preset charging threshold value and no comparison result exists between the illumination brightness information and the color gradation graph, supplying power to a load through the standby battery.

The application also provides a self-adaptive charging control device, which includes:

the charging monitoring module is used for acquiring charging information of a rechargeable battery in the energy storage unit, and if the charging information is lower than a preset charging threshold value, a camera related to the energy storage unit is started;

the brightness comparison module is used for acquiring illumination brightness information in the environment and comparing the illumination brightness information with a color gradation map stored in a database;

the information acquisition module is used for determining color block information corresponding to the illumination brightness information in the color gradation graph according to a comparison result and acquiring power supply information related to the color block information; the power supply information is an information set which is set according to different color block information and used for controlling a light source to provide different illumination brightness for power supply equipment;

and the charging control module is used for controlling the power supply equipment to charge the rechargeable battery according to the power supply information.

The present application further provides an electronic device comprising a memory and a processor, wherein the memory stores computer readable instructions, and the computer readable instructions, when executed by the processor, cause the processor to execute the steps of the control method of adaptive charging as described in any one of the above embodiments.

The present application further provides a storage medium having stored therein computer readable instructions, which, when executed by one or more processors, cause the one or more processors to perform the steps of the method of controlling adaptive charging as described in any one of the above embodiments.

According to the control method and device for the self-adaptive charging, the electronic equipment and the storage medium, the charging information of the rechargeable battery in the energy storage unit is acquired and monitored in real time, if the charging information is lower than a preset charging threshold value, a camera associated with the energy storage unit is started, the illumination brightness information in the environment is acquired through the camera, and the illumination brightness information is compared with a color gradation map stored in a database; determining color block information corresponding to the illumination brightness information in the color level diagram according to the comparison result, and acquiring power supply information associated with the color block information; and controlling the power supply equipment to charge the rechargeable battery according to the power supply information.

In this scheme, real-time supervision rechargeable battery's charging information to when it is less than predetermineeing the threshold value of charging, open the illumination luminance information in the camera collection environment, so that take different power supply modes to supply power for rechargeable battery according to this illumination luminance information, the power supply unit that not only can avoid using the photovoltaic conversion mode to acquire the electric energy receives illumination intensity's influence, leads to the unstable phenomenon of power supply to take place, can also guarantee rechargeable battery's life and performance.

And the color block information in the color level diagram of the application comprises at least one of a preparation stage color block, a lighting charging color block, a strong light charging color block and a weak light charging color block, wherein each color block information corresponds to different power supply information, and after the power supply information associated with different color block information is obtained, the power supply circuit between the photovoltaic conversion power supply equipment and the rechargeable battery can be correspondingly adjusted according to the power supply information, so that the photoelectric conversion efficiency is further improved.

In addition, the energy storage unit still includes the backup battery in this application, and when rechargeable battery's charging information was less than predetermineeing the threshold value of charging, and when there was not the comparison result between the illumination luminance information that detects and the color gradation graph, can supply power for the load through the backup battery, guarantees electronic equipment's normal use, also avoids the excessive consumption to rechargeable battery simultaneously.

Additional aspects and advantages of the present application will be set forth in part in the description which follows and, in part, will be obvious from the description, or may be learned by practice of the present application.

Drawings

The foregoing and/or additional aspects and advantages of the present application will become apparent and readily appreciated from the following description of the embodiments, taken in conjunction with the accompanying drawings of which:

FIG. 1 is a flow diagram of a control method of adaptive charging according to an embodiment;

FIG. 2 is a schematic diagram of an internal power supply and charging structure of an electronic device according to an embodiment;

FIG. 3 is a diagram illustrating a structure of information of color patches in a color level diagram according to an embodiment;

FIG. 4 is a schematic diagram of an internal power supply and charging structure of an electronic device according to another embodiment;

FIG. 5 is a schematic structural diagram of a control device for adaptive charging according to an embodiment;

fig. 6 is a schematic internal structure diagram of an electronic device according to an embodiment.

Detailed Description

Reference will now be made in detail to embodiments of the present application, examples of which are illustrated in the accompanying drawings, wherein like or similar reference numerals refer to the same or similar elements or elements having the same or similar function throughout. The embodiments described below with reference to the drawings are exemplary only for the purpose of explaining the present application and are not to be construed as limiting the present application.

As used herein, the singular forms "a", "an", "the" and "the" are intended to include the plural forms as well, unless the context clearly indicates otherwise. It will be further understood that the terms "comprises" and/or "comprising," when used in this specification, specify the presence of stated features, integers, steps, operations, elements, and/or components, but do not preclude the presence or addition of one or more other features, integers, steps, operations, elements, components, and/or groups thereof.

It will be understood by those within the art that, unless otherwise defined, all terms (including technical and scientific terms) used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this application belongs. It will be further understood that terms, such as those defined in commonly used dictionaries, should be interpreted as having a meaning that is consistent with their meaning in the context of the prior art and will not be interpreted in an idealized or overly formal sense unless expressly so defined herein.

At present, the conventional charging mode is gradually replaced by photovoltaic charging, and photovoltaic conversion equipment becomes power supply equipment with wider application. In the prior art, the photovoltaic module is exposed in an illumination environment, so that the photovoltaic module can continuously receive illumination, and light energy is converted into electric energy and then is transmitted to the electric storage device for storage, so that power is supplied to a load at any time.

Due to the wide application of the photovoltaic conversion equipment, the generated electric energy can supply power for various electric equipment, for example, in the existing intelligent door lock with wide application, the unlocking process needs to supply electric energy for the unlocking mechanism by depending on an internal power supply; after using photovoltaic conversion equipment to supply power for intelligent lock, usable photo resistance discerns photovoltaic charging equipment receives irradiant intensity to this adjusts the inside power supply circuit of intelligent lock.

However, the photovoltaic conversion equipment is greatly influenced by the illumination intensity, and the instability of the photovoltaic conversion equipment causes the influence on the service life and the performance of an electric power storage source in the intelligent door lock; in addition, the photoresistor is greatly influenced by the ambient temperature, so that the light sensing precision is reduced and the response time is reduced after long-term use.

Therefore, in order to solve the technical problem that the photovoltaic conversion equipment is greatly influenced by the illumination intensity and the instability of the photovoltaic conversion equipment causes the reduction of the service life and the performance of the power storage power supply in the electronic equipment, the application provides a solution, which specifically comprises the following steps:

in one embodiment, fig. 1 and 2 are schematic diagrams of two embodiments of the present application, respectively; as shown in fig. 1, fig. 1 is a flowchart of a control method of adaptive charging according to an embodiment, where the present embodiment provides a control method of adaptive charging, which may specifically include the following steps:

s110: the method comprises the steps of obtaining charging information of a rechargeable battery in an energy storage unit, and if the charging information is lower than a preset charging threshold value, starting a camera related to the energy storage unit.

In this step, since the energy storage unit 102 in the electronic device 100 generally supplies power to the load 103, such as an intelligent door lock, a rechargeable battery is installed in the energy storage unit, and the rechargeable battery supplies power to the load in the intelligent door lock, such as an unlocking mechanism, so that the unlocking mechanism can open and close the door lock according to the control instruction.

Wherein, rechargeable battery 201 among the energy storage unit 102 passes through power supply unit 101 for its power supply for intelligent lock can circulate to open and close, avoids using dry battery etc. to supply power, needs often to carry out the loaded down with trivial details operation of changing.

As shown in fig. 2, fig. 2 is a schematic diagram of an internal power supply and charging structure of an electronic device according to an embodiment; the electronic device 100 includes a power supply device 101 for providing photovoltaic conversion, an energy storage unit 102 for storing electric energy converted in the power supply device, and a load 103 for supplying power through the energy storage unit, where the energy storage unit 102 includes at least one set of rechargeable battery 201, and the rechargeable battery 201 can store electric energy converted in the power supply device 101 and provide the electric energy to the load 103, so that the load 103 provides normal operation.

It can be understood that the power supply device 101 herein refers to a photovoltaic charging assembly, which may be formed by connecting a plurality of single cells in series and in parallel, and tightly packaging the connected single cells, so as to form a photovoltaic assembly, an inverter used in cooperation with the photovoltaic assembly may directly convert a current source of the photovoltaic assembly into a voltage source of about 40V, and may further include a voltage boost circuit and a voltage buck circuit, and may boost or buck a voltage of the voltage source so as to supply power to the energy storage unit 102.

When the rechargeable battery 201 in the energy storage unit 102 is fully charged, the circuit connection with the power supply device 101 is disconnected, and the power supply circuit with the load 103 is connected, so as to supply power to the load 103.

Therefore, the charging information of the rechargeable battery 201 needs to be acquired and monitored in real time, so that when the charging information of the rechargeable battery 201 is lower than the preset charging threshold, the power supply device 101 is turned on to charge the rechargeable battery 201, and the service life and the service performance of the rechargeable battery 201 are ensured.

Certainly, before the connection circuit between the power supply device 101 and the rechargeable battery 201 is connected, the camera associated with the energy storage unit 102 needs to be turned on, and after relevant illumination information is collected by the camera, the rechargeable battery 201 is further charged in different ways according to the collected information, so that the service life of the rechargeable battery 201 is better prolonged, and the use performance of the rechargeable battery 201 is ensured to be stably exerted.

It can be understood that the preset charging threshold refers to a lowest remaining power amount that is set according to the battery performance of the rechargeable battery 201 and guarantees that the battery performance is not changed, the charging information of the rechargeable battery 201 includes the current remaining power amount of the rechargeable battery 201, and when the remaining power amount is lower than the preset charging threshold, the power supply circuit between the rechargeable battery 201 and the load 103 needs to be disconnected, and the connection circuit between the power supply device 101 and the rechargeable battery 201 needs to be connected, so as to avoid affecting the usability and the service life of the rechargeable battery 201.

S120: and acquiring illumination brightness information in the environment, and comparing the illumination brightness information with a color level map stored in a database.

In this step, after the camera associated with the energy storage unit 102 is turned on in step S110, the illumination brightness information in the environment is collected by the camera, and it can be understood that the camera here refers to a camera assembly that is installed on an installation panel corresponding to the intelligent door lock and can be automatically turned on according to the charging information of the rechargeable battery 201 in the energy storage unit 102 and shoot the illumination information received by the photovoltaic charging assembly, and the camera assembly has higher shooting pixels and can automatically focus and shoot; in addition, the camera can also have other functions, such as face recognition of people who go forward when the intelligent door lock is opened, a visual doorbell and the like; this photovoltaic module of charging sets up near intelligent lock.

As a preferable mode, the camera may be further installed near the smart door lock on an installation plane that receives the same illumination as the photovoltaic charging module, and the camera is adjusted to focus on the white wall, and after the shooting pixel is determined, images of the white wall under different illumination intensities are shot according to the shooting pixel, where multiple sets of illumination intensities may be set, for example, the illumination intensities of 1Lux to 10Lux, 10Lux to 20Lux, and 20Lux to 30Lux … … are respectively shot with the illumination intensity of 10Lux as a unit.

After a plurality of groups of pictures corresponding to the illumination brightness are shot, the pictures are arranged according to the ascending order or the descending order of the illumination to manufacture a color gradation graph, and the color gradation graph is stored in a database. After the illumination brightness information in the environment is acquired through the camera, the illumination brightness information can be compared with the color gradation map stored in the database to confirm the illumination brightness information corresponding to the color gradation map.

S130: determining color block information corresponding to the illumination brightness information in the color level diagram according to a comparison result, and acquiring power supply information associated with the color block information; the power supply information is an information set for providing different illumination brightness for the power supply device 101 by the control light source set according to different color block information.

In this step, after the illumination brightness information in the environment is obtained in step S120 and the illumination brightness information is compared with the color gradation map stored in the database, color block information corresponding to the illumination brightness information in the color gradation map may be determined according to the comparison result, where the color block information includes illumination information, that is, an illumination interval corresponding to the illumination brightness in the illumination brightness information.

It can be understood that the color block information herein refers to block regions corresponding to different color depths in the color level map, where each group of block regions in the color level map has the same size, and the corresponding colors have different shades.

Each color block information in the color gradation diagram is associated with corresponding power supply information, and the power supply information refers to an information set for controlling a light source to provide different illumination brightnesses to the power supply device 101 according to different color block information.

For example, when the illuminance in the color block information corresponding to the color block map is 10Lux to 20Lux, the color block information may be set as a preparation stage color block because the illuminance range represents a weak illuminance, and the power supply information associated with the preparation stage color block may be set to check and detect the state of the power supply circuit between the power supply apparatus 101 and the rechargeable battery 201, so as to prepare the power supply information corresponding to the color block information of the next stage.

It should be noted that the color block information herein may be set according to the efficiency of converting light energy corresponding to the photovoltaic charging assemblies installed in different regions under different illumination intensities into electric energy, for example, the illumination intensity of the illumination intensity is between 10Lux and 20Lux, the photoelectric conversion rate is low, and at this time, the photovoltaic charging assemblies may be used as a preparation stage without switching on a power supply circuit between the power supply device 101 and the rechargeable battery 201.

The setting of the color block information may be adjusted according to actual conditions, and the method in the present application may be implemented, which is not limited herein.

S140: and controlling the power supply equipment 101 to charge the rechargeable battery 201 according to the power supply information.

In this step, after the color block information corresponding to the illumination brightness information is acquired in step S130 and the power supply information associated with the color block information is determined, the power supply device 101 may be controlled to charge the rechargeable battery 201 according to the power supply information.

Next, as an example in the step S130, when the illuminance in the color block information corresponding to the color block map is 10Lux to 20Lux, the color block information may be set as a preparation stage color block because the illuminance range represents weaker illuminance, and the power supply information associated with the color block in the preparation stage may be set to check and detect the state of the power supply circuit between the power supply apparatus 101 and the rechargeable battery 201, so as to prepare the power supply information corresponding to the color block information in the next stage.

When the illuminance in the color block information corresponding to the color level map is 30Lux to 40Lux, the color block information can be set as a highlight charging color block because the illuminance represented by the illuminance range is stronger, and the power supply information associated with the highlight charging color block can be set as a power supply circuit communicated between a highlight power supply module in the power supply device 101 and the rechargeable battery 201, so that the rechargeable battery 201 is charged through the highlight power supply module.

The self-adaptive charging control method comprises the steps of acquiring and monitoring charging information of a rechargeable battery 201 in the energy storage unit 102 in real time, if the charging information is lower than a preset charging threshold value, starting a camera associated with the energy storage unit 102, acquiring illumination brightness information in the environment through the camera, and comparing the illumination brightness information with a color gradation map stored in a database; determining color block information corresponding to the illumination brightness information in the color level diagram according to the comparison result, and acquiring power supply information associated with the color block information; and controlling the power supply equipment 101 to charge the rechargeable battery 201 according to the power supply information.

In this scheme, the charging information of rechargeable battery 201 is monitored in real time, and when it is less than and predetermines the threshold value of charging, open the illumination luminance information in the camera collection environment, so that take different power supply modes to supply power for rechargeable battery 201 according to this illumination luminance information, power supply unit 101 that not only can avoid using the photovoltaic conversion mode to acquire the electric energy receives the influence of illumination intensity, leads to the unstable phenomenon of power supply to take place, can also guarantee rechargeable battery 201's life and performance.

In an embodiment, before the step of comparing the illumination brightness information with the color level map stored in the database in step S120, the method may further include:

s200: setting the information of each color block in the color level diagram;

s300: and determining power supply information associated with each color block information.

In this embodiment, before comparing the illumination brightness information collected by the camera with the color gradation map stored in the database, corresponding setting may be performed on each piece of color block information in the color gradation map, and the setting may be based on the illuminance corresponding to different pieces of color block information.

If the illuminance corresponding to the color block information is 1Lux to 10Lux, the photovoltaic charging assembly cannot perform photoelectric conversion under the illuminance, so that the color block information can be set as a charging color block when the lamp is turned on, and the photovoltaic charging assembly can be assisted to perform photoelectric conversion only by means of light irradiation of a spotlight.

After the color block information is set, different power supply information can be associated according to different color block information. For example, when the color block information indicates a color block to be charged by turning on a light, that is, the current illumination brightness information is in the condition of the color block information, the photovoltaic conversion of the photovoltaic charging assembly needs to be completed by means of light assistance.

At this moment, the power supply information related to the color block information can be set to be a spotlight which is used for providing illumination for the photovoltaic charging assembly.

Further, after the spotlight is used to illuminate the photovoltaic charging module, the voltage generated by the photovoltaic charging module is equivalent to the voltage generated when the spotlight is illuminated, so that the power supply circuit between the strong light power supply module in the power supply device 101 and the rechargeable battery 201 can be switched on after the spotlight is turned on, thereby ensuring that the power supply device 101 can maximally provide the electric energy for the rechargeable battery 201.

In the above embodiment, the color block information includes at least one of a preparation-stage color block, a lighting charging color block, a strong-light charging color block, and a weak-light charging color block, as shown in fig. 3, fig. 3 is a schematic diagram of a color block information structure in a color gradation diagram according to an embodiment; the color level map 30 at least includes four color blocks with different color depths, where color block 31 represents a color block at a preparation stage, color block 32 represents a color block charged by turning on a light, color block 33 represents a color block charged by strong light, and color block 34 represents a color block charged by weak light.

When the stages corresponding to different color block information are set, and the power supply information associated with the color block information is determined, the corresponding power supply information can be called according to the illumination intensity information collected by the camera to charge the rechargeable battery 201.

In one embodiment, the patch information is a preparation phase patch;

s211: determining power supply information associated with the preparation phase color block;

s212: and controlling and detecting the state of a power supply circuit between the power supply device 101 and the rechargeable battery 201 according to the power supply information associated with the color blocks in the preparation stage.

In this embodiment, after comparing the current illumination brightness information with the color block information in the color gradation map, the obtained color block information corresponding to the illumination brightness information is a preparation stage color block, which indicates that the photoelectric conversion rate is low at this time, and therefore, the power supply information associated with the preparation stage color block may be set to detect the state of the power supply circuit between the power supply device 101 and the rechargeable battery 201, so as to prepare for the next stage.

Furthermore, the current illumination brightness information can be continuously monitored, if the illumination brightness information changes, and the change is compared by a color gradation map and corresponds to different color block information of color blocks in the preparation stage, the power supply information corresponding to the color block information can be correspondingly adjusted.

Further, when the illumination intensity information is continuously monitored without change, the rechargeable battery 201 may be powered in other manners. If the illumination brightness information is not changed within ten minutes, the power supply information can be automatically adjusted, the photovoltaic charging assembly is illuminated by means of a spotlight, the photoelectric conversion rate of the photovoltaic charging assembly is improved, and the phenomenon that the rechargeable battery 201 is seriously fed to influence the service life and the service performance due to the fact that the rechargeable battery 201 is not supplied with power for a long time is avoided.

s221: determining power supply information associated with the light-on charging color block;

s222: and controlling to start the spotlight according to the power supply information associated with the lighting charging color block, and switching on a power supply circuit between the power supply equipment 101 associated with the spotlight and the rechargeable battery 201.

In this embodiment, after comparing the current illumination brightness information with the color block information in the color gradation diagram, the obtained color block information corresponding to the illumination brightness information is a light-on charging color block, that is, it indicates that the current illumination brightness information is in the color block information condition, and the photoelectric conversion of the photovoltaic charging assembly needs to be completed with the assistance of light.

At this moment, the power supply information related to the color block information can be set to be a spotlight which provides illumination for the photovoltaic charging assembly for emergency.

It can be understood that the selection of the spotlight may include the requirement of spotlight within 10 ° and the power of at least 20W to achieve the requirements of lighting for 15min and emergency use for 3-4 times; and the positional setting for the spotlight may include directing a beam of the spotlight at the photovoltaic charging assembly, and the beam of the spotlight is at an angle of no less than 75 ° to the photovoltaic charging assembly.

When the photoelectric conversion of the photovoltaic charging assembly needs to be completed by light assistance, the spotlight is started to irradiate for emergency use, and the spotlight can be unlocked for more than 3 times after being irradiated for 15-30 min each time.

Further, after the spotlight is started, the camera can be used again to collect the current illumination brightness information, and the color block information corresponding to the current illumination brightness information is determined, so that the power supply circuit between the strong light power supply module or the weak light power supply module in the power supply device 101 and the rechargeable battery 201 is determined to be switched on, and therefore the power supply device 101 can be guaranteed to supply electric energy to the rechargeable battery 201 to the maximum extent.

It should be noted that the power supply device 101 in the present application includes a strong light power supply module and a weak light power supply module, where the strong light power supply module is correspondingly provided with a strong light photovoltaic panel and a voltage reduction circuit electrically connected to the strong light photovoltaic panel; the weak light power supply module is correspondingly provided with a weak light photovoltaic panel and a booster circuit electrically connected with the weak light photovoltaic panel.

s231: determining power supply information associated with the highlight charging color block;

s232: and controlling and communicating a power supply circuit between a strong light power supply module in the power supply equipment 101 and the rechargeable battery 201 according to the power supply information associated with the strong light charging color block.

In this embodiment, after comparing the current illumination brightness information with the color block information in the color gradation diagram, the obtained color block information corresponding to the illumination brightness information is an highlight charging color block, that is, it indicates that the illumination intensity received by the photovoltaic charging assembly is stronger at this time, an highlight photovoltaic panel needs to be used to receive illumination, and after converting light energy into electric energy, the circuit connection is performed between the voltage reduction circuit and the rechargeable battery 201, so as to provide relatively stable electric energy for the rechargeable battery 201, and avoid the occurrence of a conflict with the voltage of the rechargeable battery 201, which may cause a circuit break or a circuit fault.

s241: determining power supply information associated with the low-light charging color block;

s242: and controlling a power supply circuit communicated between a weak light power supply module in the power supply device 101 and the rechargeable battery 201 according to the power supply information associated with the weak light charging color block.

In this embodiment, after comparing the current illumination brightness information with the color block information in the color gradation diagram, the color block information corresponding to the illumination brightness information is obtained as a weak light charging color block, that is, it indicates that the illumination intensity received by the photovoltaic charging assembly is weak at this time, a weak light photovoltaic panel needs to be used to receive illumination, and after converting light energy into electric energy, the circuit connection is performed between the booster circuit and the rechargeable battery 201, so as to provide relatively stable electric energy for the rechargeable battery 201, and avoid the occurrence of a conflict with the voltage of the rechargeable battery 201, which may cause a circuit break or a circuit fault.

In one embodiment, after the step of determining the power supply information associated with each color block information in step S300, the method may further include:

s310: determining a brightness threshold corresponding to the color block depth according to the color block depth of each color block information;

s320: acquiring an illumination brightness value in the illumination brightness information;

s330: and comparing the illumination brightness value with the brightness threshold value.

In this embodiment, after determining the power supply information associated with each color block information, a corresponding luminance threshold may be determined according to the color block depth of each color block information, where the luminance threshold may be an illumination range, such as 1Lux to 10Lux, 10Lux to 20Lux, and 20Lux to 30Lux … ….

Specifically, comparing an illumination brightness value in the acquired illumination brightness information with a brightness threshold value, and determining a brightness threshold value corresponding to the illumination brightness value; if the illumination brightness value is 25Lux, the illumination brightness value is corresponding to the brightness threshold value of 20 Lux-30 Lux.

In an embodiment, the step of determining, according to the comparison result, color block information in the color level map corresponding to the illumination brightness information in step S130 may include:

s131: obtaining a comparison result between the illumination brightness value and the brightness threshold value, and determining the brightness threshold value corresponding to the illumination brightness value;

s132: and determining the corresponding color block depth according to the brightness threshold, and searching color block information corresponding to the color block depth.

In this embodiment, after the illumination brightness value in the illumination brightness information is obtained and the illumination brightness value is compared with the brightness threshold, a comparison result between the illumination brightness value and the brightness threshold can be further obtained, so that the brightness threshold corresponding to the illumination brightness value can be determined according to the comparison result, then, color block information corresponding to the color block depth is searched according to the color block depth corresponding to the brightness threshold, and then, the associated power supply information can be obtained according to the color block information.

For example, the brightness threshold includes 1 Lux-10 Lux, 10 Lux-20 Lux, 20 Lux-30 Lux … …, if the illumination brightness value is 25Lux, the illumination brightness value corresponds to the brightness threshold of 20 Lux-30 Lux, and the matched color block information is searched through the color block depth corresponding to the brightness threshold.

In one embodiment, as shown in fig. 4, fig. 4 is a schematic diagram of an internal power supply and charging structure of the electronic device 100 according to another embodiment; the electronic device 100 is provided with a power supply device 101, an energy storage unit 102 for storing electric energy transmitted in the power supply device 101, and a load 103 for providing electric energy through the energy storage unit 102, the energy storage unit 102 includes at least one set of rechargeable battery 201 and at least one set of backup battery 202, and both the rechargeable battery 201 and the backup battery 202 can store electric energy transmitted by the power supply device 101 and can supply power to the load 103.

If the charging information of the rechargeable battery 201 is lower than a preset charging threshold value and there is no comparison result between the illumination brightness information and the color level map, the backup battery 202 supplies power to the load 103.

In this embodiment, the energy storage unit 102 may include not only the rechargeable battery 201, but also a backup battery 202, and the backup battery 202 may also supply power by the above-mentioned power supply method of the rechargeable battery 201.

In daily situations, the power condition of the backup battery 202 can be monitored in real time, and when the power of the backup battery 202 is reduced to a certain threshold, the above power supply mode for the rechargeable battery 201 is adopted to supply power, so that the power of the backup battery 202 is ensured to be in a state of supplying power to the load 103.

Under normal conditions, the electronic device 100 is connected with the load 103 through the rechargeable battery 201 for supplying power, and when the charging information of the rechargeable battery 201 is lower than a preset charging threshold value and no comparison result exists between the illumination brightness information and the color gradation diagram in the environment acquired through the camera, the load 103 needs to be supplied with power through the backup battery 202.

When the backup battery 202 supplies power to the load 103, the circuit connection between the rechargeable battery 201 and the load 103 needs to be disconnected, so as to avoid that the rechargeable battery 201 is in a feeding state due to continuous power supply, which affects the service life and the service performance of the rechargeable battery 201.

Further, when the illumination intensity information collected by the camera is continuously in the state of the color block in the preparation phase, the power supply circuit between the rechargeable battery 201 and the load 103 may also be disconnected, and the backup battery 202 is used to supply power to the load 103.

In an embodiment, as shown in fig. 5, fig. 5 is a schematic structural diagram of a control device for adaptive charging according to an embodiment, and in this embodiment, a control device for adaptive charging is provided, which includes: the charging monitoring module 210, the brightness contrast module 220, the information obtaining module 230, and the charging control module 240, wherein:

the charging monitoring module 210 is configured to acquire charging information of the rechargeable battery 201 in the energy storage unit 102, and if the charging information is lower than a preset charging threshold, turn on a camera associated with the energy storage unit 102.

In the module, because the electronic device 100 generally supplies power to the load 103 through the energy storage unit 102, for example, an intelligent door lock, the energy storage unit 102 is provided with the rechargeable battery 201, and the rechargeable battery 201 supplies power to the unlocking mechanism in the intelligent door lock, so that the unlocking mechanism can unlock and close the door lock according to a control instruction.

The brightness comparison module 220 is configured to obtain illumination brightness information in an environment, and compare the illumination brightness information with a color level map stored in a database.

In the module, after a camera associated with the energy storage unit 102 is turned on in the charging monitoring module 210, the illumination brightness information in the environment is collected through the camera, and it can be understood that the camera is a camera assembly which is installed on an installation panel corresponding to the intelligent door lock and can be automatically turned on according to the charging information of the rechargeable battery 201 in the energy storage unit 102 and shoot the illumination information received by the photovoltaic charging assembly, and the camera assembly has higher shooting pixels and can automatically focus and shoot; in addition, the camera can also have other functions, such as face recognition of people who go forward when the intelligent door lock is opened, a visual doorbell and the like; this photovoltaic module of charging sets up near intelligent lock.

After a plurality of groups of pictures corresponding to the illumination brightness are shot, the pictures are arranged according to the ascending order or the descending order of the illumination to manufacture a color gradation graph, and the color gradation graph is stored in a database. After the illumination brightness information in the environment is acquired through the camera, the illumination brightness information can be compared with the color gradation map stored in the database to confirm the illumination information corresponding to the color gradation map.

An information obtaining module 230, configured to determine, according to a comparison result, color block information corresponding to the illumination brightness information in the color level map, and obtain power supply information associated with the color block information; the power supply information is an information set for providing different illumination brightness for the power supply device 101 by the control light source set according to different color block information.

In this module, after the illumination brightness information in the environment is obtained by the brightness comparison module 220 and the illumination brightness information is compared with the color gradation map stored in the database, the color block information corresponding to the illumination brightness information in the color gradation map can be determined according to the comparison result, where the color block information includes illumination information, that is, an illumination interval corresponding to the illumination brightness in the illumination brightness information.

A charging control module 240, configured to control the power supply apparatus 101 to charge the rechargeable battery 201 according to the power supply information.

In this module, after the color block information corresponding to the illumination brightness information is acquired by the information acquisition module 230 and the power supply information associated with the color block information is determined, the power supply device 101 may be controlled to charge the rechargeable battery 201 according to the power supply information.

Next, for example, in the information obtaining module 230, when the illuminance in the color block information corresponding to the color level map is 10Lux to 20Lux, because the illuminance range represents weaker illuminance, the color block information may be set as a preparation stage color block, and the power supply information associated with the preparation stage color block may be set to check and detect the state of the power supply circuit between the power supply apparatus 101 and the rechargeable battery 201, so as to prepare the power supply information corresponding to the color block information of the next stage.

The self-adaptive charging control device acquires and monitors the charging information of the rechargeable battery 201 in the energy storage unit 102 in real time, if the charging information is lower than a preset charging threshold, a camera associated with the energy storage unit 102 is started, the illumination brightness information in the environment is acquired through the camera, and the illumination brightness information is compared with a color gradation map stored in a database; determining color block information corresponding to the illumination brightness information in the color level diagram according to the comparison result, and acquiring power supply information associated with the color block information; and controlling the power supply equipment 101 to charge the rechargeable battery 201 according to the power supply information.

For specific limitations of the adaptive charging control device, reference may be made to the above limitations of the adaptive charging control method, which are not described herein again. The modules in the adaptive charging control device can be wholly or partially implemented by software, hardware and a combination thereof. The modules can be embedded in a hardware form or independent of a processor in the terminal device, and can also be stored in a memory in the terminal device in a software form, so that the processor can call and execute operations corresponding to the modules.

In one embodiment, an electronic device is provided, which includes a memory and a processor, wherein the memory stores computer readable instructions, and the computer readable instructions, when executed by the processor, cause the processor to execute the steps of the control method of adaptive charging according to any one of the above embodiments.

As shown in fig. 6, fig. 6 is a schematic diagram of an internal structure of an electronic device in an embodiment. The electronic device 10 includes a processor 40 and a memory 20 connected by a bus 50 and a network port 30 connected to the processor 40. The memory 20 of the electronic device 10 stores a charging monitoring module 210, a brightness contrast module 220, an information obtaining module 230, and a charging control module 240, and when the computer readable instructions are executed by the processor, the processor 40 can implement a control method of adaptive charging. The processor 40 of the electronic device 10 is used to provide computing and control capabilities that support the operation of the entire electronic device 10. The network port 30 of the electronic device 10 is used for exchanging data between the server 120 and the processor 40 via a network.

Those skilled in the art will appreciate that the configuration shown in fig. 6 is a block diagram of only a portion of the configuration associated with the present application, and does not constitute a limitation on the electronic device to which the present application is applied, and a particular electronic device may include more or less components than those shown in the drawings, or may combine certain components, or have a different arrangement of components.

In one embodiment, a storage medium is proposed, in which computer readable instructions are stored, which, when executed by one or more processors, cause the one or more processors to perform the steps of the control method of adaptive charging of any of the above embodiments.

It should be understood that, although the steps in the flowcharts of the figures are shown in order as indicated by the arrows, the steps are not necessarily performed in order as indicated by the arrows. The steps are not performed in the exact order shown and may be performed in other orders unless explicitly stated herein. Moreover, at least a portion of the steps in the flow chart of the figure may include multiple sub-steps or multiple stages, which are not necessarily performed at the same time, but may be performed at different times, which are not necessarily performed in sequence, but may be performed alternately or alternately with other steps or at least a portion of the sub-steps or stages of other steps.

The foregoing is only a partial embodiment of the present application, and it should be noted that, for those skilled in the art, several modifications and decorations can be made without departing from the principle of the present application, and these modifications and decorations should also be regarded as the protection scope of the present application.

Claims

1. A control method of adaptive charging is characterized by comprising the following steps:

2. The method of claim 1, wherein the step of comparing the luminance information with a color level map stored in a database further comprises:

3. The adaptive charging control method according to claim 2, wherein the patch information includes at least one of a preparation phase patch, a light-on charging patch, a strong light charging patch, and a weak light charging patch.

4. The control method of adaptive charging according to claim 3, wherein the patch information is a preparation stage patch;

5. The control method of adaptive charging according to claim 3, wherein the patch information is a light-on charging patch;

6. The adaptive charging control method according to claim 3, wherein the patch information is a highlight charging patch;

7. The control method of adaptive charging according to claim 3, wherein the patch information is a low-light charging patch;

8. The method according to claim 2, wherein the step of determining the power supply information associated with each patch information is followed by further comprising:

9. The method according to claim 8, wherein after the step of determining the luminance threshold corresponding to the color block depth according to the color block depth of each color block information, the method further comprises:

10. The method according to claim 9, wherein the step of determining color block information corresponding to the illumination brightness information in the color level map according to the comparison result comprises:

11. The control method of adaptive charging according to claim 1, wherein the energy storage unit further comprises a backup battery;

12. An adaptive charging control apparatus, comprising:

13. An electronic device, characterized in that: comprising a memory and a processor, said memory having stored therein computer readable instructions which, when executed by said processor, cause said processor to carry out the steps of the method of controlling adaptive charging according to any one of claims 1 to 11.

14. A storage medium, characterized by: the storage medium has stored therein computer-readable instructions which, when executed by one or more processors, cause the one or more processors to carry out the steps of the method of controlling adaptive charging according to any one of claims 1 to 11.