CN115765119A

CN115765119A - Charging management method of energy storage power supply, energy storage power supply and storage medium

Info

Publication number: CN115765119A
Application number: CN202310034921.9A
Authority: CN
Inventors: 邱白玮; 蔡梅兰
Original assignee: Shenzhen Reflying Intelligent Technology Co ltd
Current assignee: Shenzhen Reflying Intelligent Technology Co ltd
Priority date: 2023-01-10
Filing date: 2023-01-10
Publication date: 2023-03-07
Anticipated expiration: 2043-01-10
Also published as: CN115765119B

Abstract

The application relates to a charging management method of an energy storage power supply, the energy storage power supply and a storage medium. Acquiring the attribute and the connection information of the equipment to be charged based on the connection state of the equipment to be charged; determining related information of the equipment to be charged according to the attributes; determining the priority of the equipment to be charged according to the preset equipment priority and the relevant information; and according to the connection information and the priority, determining first-stage charging equipment and adjusting the charging state of the first-stage charging equipment to charge the first-stage charging equipment. The energy storage power supply can preferentially select which equipment is charged according to the priority of the equipment, and the problem that the charging time of each equipment to be charged is increased due to the fact that a plurality of equipment to be charged are charged simultaneously after the plurality of equipment to be charged are connected can be solved. Meanwhile, by the method provided by the application, when the user wants to use the equipment with high priority, the equipment can be used in time, and the experience of the user is improved.

Description

Charging management method of energy storage power supply, energy storage power supply and storage medium

Technical Field

The present disclosure relates to the field of energy storage power supply technologies, and in particular, to a charging management method for an energy storage power supply, and a storage medium.

Background

The portable energy storage power supply is also called a portable outdoor power supply, is a standby power supply or an emergency power supply with the weight generally not exceeding 20kg, and can be generally used as a standby power supply for outdoor travel, earthquake resistance and disaster prevention. When a user plays and works outdoors, the portable energy storage power supply can be used for charging electronic equipment such as a mobile phone, a computer and an intelligent watch, and in other scenes, the portable energy storage power supply can also be used for lighting and small-power household appliances such as an electric cooker for power supply.

However, because the maximum output current of the portable energy storage power supply is usually fixed, but there may be more than one device to be charged, if there are multiple devices to be charged that are connected to the portable energy storage power supply at the same time, then the portable energy storage power supply will shunt its output current when charging these devices to be charged, thereby satisfying the requirement of charging multiple devices to be charged at the same time. In this case, the time required for the plurality of connected devices to be charged to reach the fully charged state or for the electric quantity to meet the requirement of the user is longer than the time required for charging only one connected device to be charged, which means that each device to be charged needs longer time than the predetermined time to meet the charging requirement. At this time, if the user wants to use a certain device, the user needs to wait for a longer time, which may affect the normal use requirement of the user.

Disclosure of Invention

The application provides a charging management method of an energy storage power supply, the energy storage power supply and a storage medium.

In a first aspect, the present application provides a charging management method for an energy storage power supply.

Acquiring the attribute and the connection information of the connected equipment to be charged based on the connection state of the equipment to be charged;

determining relevant information of the connected equipment to be charged according to the attribute;

determining the priority of the connected equipment to be charged according to the preset equipment priority and the related information;

and determining first-stage charging equipment and adjusting the charging state of the first-stage charging equipment to charge the first-stage charging equipment according to the connection information and the priority.

By the method, the attribute and the connection information of the connected equipment to be charged can be known according to the connection state of the equipment to be charged. Firstly, determining relevant information of the connected devices to be charged according to the attributes, and then determining the priority of the connected devices to be charged according to the preset device priority and the relevant information, thereby determining the first-stage charging device according to the connection information and the priority and charging the first-stage charging device after the charging state is adjusted. The method can lead the energy storage power supply to preferentially select which equipment is charged according to the priority of the equipment, and can avoid the problem that the charging time of each equipment is increased due to simultaneous charging after a plurality of equipment to be charged are connected. Meanwhile, by the method provided by the application, when the user wants to use the equipment with high priority, the equipment can be used in time, and the experience of the user is improved.

Optionally, the relevant information includes an applicable current of the connected device to be charged; according to the connection information and the priority, determining first-stage charging equipment and adjusting the charging state of the first-stage charging equipment to charge the first-stage charging equipment comprises the following steps:

determining the applicable current of the first-stage charging equipment according to the relevant information;

determining a current distribution scheme of the energy storage power supply according to the applicable current;

and according to the current distribution scheme, adjusting the output current of the connection port corresponding to the first-stage charging equipment to charge the first-stage charging equipment.

By the method provided by the embodiment, the current of the energy storage power supply can be distributed according to the applicable current of the first-stage charging equipment, so that the first-stage charging equipment can be charged at the fastest charging speed as much as possible. The charging time of each first-stage charging device is saved, and the charging efficiency is improved. Meanwhile, the use requirements of the user can be met in less time, and the experience of the user is improved.

Optionally, the method further includes:

acquiring the electric quantity value of the first-stage charging equipment;

comparing the electric quantity value with a first preset electric quantity threshold value, and determining whether the electric quantity value is higher than the first preset electric quantity threshold value;

if the electric quantity value is higher than the first preset electric quantity threshold, determining second-stage charging equipment according to the connection information and the priority;

and short-circuiting the connecting port corresponding to the first-stage charging equipment and adjusting the charging state of the second-stage charging equipment to charge the second-stage charging equipment.

Through the method provided by this embodiment, when the electric quantity value of the first-stage charging device reaches the first preset electric quantity threshold, it is described that the electric quantity of the first-stage charging device can meet the use requirement of the user, and at this time, the first-stage charging device may not be charged to a completely full state. And after the first preset electric quantity threshold value is reached, the corresponding connection port of the first-stage charging equipment is short-circuited, so that the charging state of the second-stage charging equipment is adjusted and the second-stage charging equipment is charged. By the method, the charging efficiency of all connected devices to be charged can be improved on the premise of meeting the use requirements of users. And can make these devices meet the use requirements of users in a shorter time.

Optionally, the method further includes:

acquiring the external environment state at the current moment;

determining key equipment needing to be charged at the current moment according to the external environment state;

acquiring the connection state of the key equipment, and determining the connected key equipment;

and setting the connected key equipment as the first-stage charging equipment at the current moment and adjusting the charging state of the first-stage charging equipment at the current moment to charge the first-stage charging equipment at the current moment.

By the method provided by the embodiment, when the mobile terminal is in different external environment states, the key devices in different external environment states can be determined, so that the connection states of the key devices are determined, the connected key devices are set as the first-stage charging devices, and meanwhile, the charging state is adjusted to be charged. The charging state of the connected equipment to be charged can be adjusted more flexibly when the equipment is in different external environment states, so that the using requirements of a user can be met as much as possible at different moments and under different conditions, and the waiting time of the user at different moments and under different conditions is reduced.

Optionally, the method further includes:

determining the unconnected key equipment at the current moment according to the connection state of the key equipment;

determining the weight of the unconnected key equipment according to the external environment state;

and determining whether to start a voice prompt to play a connection prompt of the unconnected key equipment or not according to the weight of the unconnected key equipment.

By the method provided by the embodiment, the unconnected key equipment can be determined according to the connection state of the key equipment, and the weight of the unconnected key equipment is determined according to the external environment state at the current moment, so that whether the voice prompt is started to play the corresponding connection prompt or not is determined. By the method, the user can be reminded in time, the situation that the key equipment which is not connected but has higher weight is powered off when the user uses the equipment is avoided, and the experience of the user is improved.

Optionally, the related information includes a charging mode supported by the connected device to be charged, and the energy storage power supply includes a wireless charging slot; the method further comprises the following steps:

determining connected equipment to be charged which supports wireless charging according to the charging mode supported by the connected equipment to be charged;

and when the connected equipment to be charged supporting wireless charging accesses the corresponding connection port, starting voice prompt to play a connection port adjustment prompt.

Through the mode that this embodiment provided, can carry out the pronunciation when certain equipment that supports wireless charging is connected to corresponding connection port and intends to charge, make it charge in wireless charging groove to make these connection ports idle, thereby satisfy the charging demand of other equipment that do not support wireless charging, improve energy storage power's availability factor.

Optionally, the method further includes:

acquiring the electric quantity of the energy storage power supply;

comparing the electric quantity of the energy storage power supply with a second preset electric quantity threshold value; determining whether the electric quantity of the energy storage power supply is lower than a second preset electric quantity threshold value;

if the electric quantity of the energy storage power supply is lower than the second preset electric quantity threshold value, determining whether the power consumption requirement is met by solar charging at the current moment according to the external environment state;

if the current moment does not meet the power utilization requirement through solar charging, a voice is started to remind the player of playing a low-power warning.

Through the mode that this embodiment provided, can be when energy storage power supply electric quantity is lower, confirm through the external environment state at the present moment whether solar charging can make energy storage power supply satisfy user's power consumption demand. If solar charging can not enable the energy storage power supply to meet the power consumption requirement of the user at the current moment, at the moment, voice can be started to remind the user to play a low-power warning, so that the user can timely utilize other modes to charge the energy storage power supply.

In a second aspect, the present application provides an energy storage power supply comprising:

the information acquisition module is used for acquiring the attribute and the connection information of the connected equipment to be charged based on the connection state of the equipment to be charged;

the information determining module is used for determining the relevant information of the connected equipment to be charged according to the attribute;

the priority determining module is used for determining the priority of the connected equipment to be charged according to the preset equipment priority and the relevant information;

and the state adjusting module is used for determining first-stage charging equipment and adjusting the charging state of the first-stage charging equipment to charge the first-stage charging equipment according to the connection information and the priority.

Optionally, the state adjustment module is specifically configured to:

Optionally, the energy storage power supply further includes a device adjusting module, configured to:

acquiring an electric quantity value of the first-stage charging equipment;

Optionally, the energy storage power supply further includes a key device adjusting module, configured to:

acquiring the external environment state at the current moment;

Optionally, the energy storage power supply further includes a first voice reminding module, configured to:

Optionally, the energy storage power supply further includes a second voice prompting module, configured to:

and when the connected equipment to be charged supporting wireless charging accesses the corresponding connection port, starting voice reminding to play a connection port adjustment prompt.

Optionally, the energy storage power supply further includes a charging module, configured to:

acquiring the electric quantity of the energy storage power supply;

if the power utilization requirement is not met through solar charging at the current moment, a voice prompt is started to play a low-power warning.

In a third aspect, the present application provides an energy storage power supply, comprising: a memory and a processor, the memory having stored thereon a computer program which is loadable by the processor and which is capable of performing the method of the first aspect.

In a fourth aspect, the present application provides a computer readable storage medium storing a computer program that can be loaded by a processor and execute the method of the first aspect.

Drawings

In order to more clearly illustrate the embodiments of the present application or the technical solutions in the prior art, the drawings needed to be used in the description of the embodiments or the prior art will be briefly introduced below, and it is obvious that the drawings in the following description are some embodiments of the present application, and for those skilled in the art, other drawings can be obtained according to these drawings without inventive exercise.

Fig. 1 is a schematic view of an application scenario provided in an embodiment of the present application;

fig. 2 is a flowchart of a charging management method for an energy storage power supply according to an embodiment of the present disclosure;

fig. 3 is a schematic structural diagram of an energy storage power supply according to an embodiment of the present disclosure;

fig. 4 is a schematic structural diagram of another energy storage power supply according to an embodiment of the present application.

Detailed Description

In order to make the objects, technical solutions and advantages of the embodiments of the present application clearer, the technical solutions in the embodiments of the present application will be clearly and completely described below with reference to the drawings in the embodiments of the present application. It is to be understood that the embodiments described are only a few embodiments of the present application and not all embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present application.

In addition, the term "and/or" herein is only one kind of association relationship describing the association object, and means that there may be three kinds of relationships, for example, a and/or B, and may mean: a exists alone, A and B exist simultaneously, and B exists alone. In addition, the character "/" herein generally indicates that the former and latter related objects are in an "or" relationship, unless otherwise specified.

The embodiments of the present application will be described in further detail with reference to the drawings attached hereto.

The maximum output current of a portable energy storage power supply (i.e., the above-described energy storage power supply) is usually fixed regardless of whether it is a constant current output or a constant voltage output, but there may be more than one device to be charged. If a plurality of devices to be charged are connected to the portable energy storage power supply at the same time, the output current of the portable energy storage power supply can be shunted when the devices to be charged are charged, so that the requirement of charging a plurality of devices to be charged at the same time is met. In this case, the time required for the plurality of connected devices to be charged to reach the fully charged state or for the electric quantity to meet the requirement of the user is longer than the time required for only one device to be charged to be connected and charged, which means that each device to be charged needs longer time than the original time to meet the charging requirement. At this time, if the user wants to use a certain device, the user needs to wait for a longer time, which may affect the normal use requirement of the user. In addition, other common devices of the user cannot be used by the user in time.

Based on the above, the present application provides a charging management method for an energy storage power supply, an energy storage power supply and a storage medium.

And acquiring the attribute and the connection information of the connected equipment to be charged according to the connection state of the equipment to be charged. And then determining the relevant information of the connected equipment to be charged according to the acquired attributes. And determining the priority of the connected equipment to be charged according to the preset equipment priority and the determined related information. And finally, determining the first-stage charging equipment according to the connection information and the priority of the connected equipment to be charged, and adjusting and charging the first-stage charging equipment. Therefore, the users can use the first-stage charging equipment in the first time, and the problem that all connected devices to be charged cannot meet the use requirements of the users in time due to energy storage power supply shunting is avoided.

Fig. 1 is a schematic view of an application scenario provided in the present application. The energy storage power supply is provided with the plurality of connecting ports, so that the charging requirements of a plurality of devices to be charged using different types of connecting ports can be met. When a user needs to charge a plurality of devices to be charged and the devices to be charged have different requirements, the method provided by the application can be used for solving the problem. When a plurality of devices to be charged are accessed, the attributes and the connection information of the devices to be charged are firstly obtained, then the priorities of the devices to be charged are determined after a series of operations, and the charging state of the devices to be charged is adjusted according to the priorities and the connection information, so that the purpose of charging is achieved.

Specific implementations can be found in the following examples.

Fig. 2 is a flowchart of a charging management method for an energy storage power supply according to an embodiment of the present disclosure, where the method of this embodiment may be applied to an energy storage power supply in the above scenario. As shown in fig. 2, the method includes:

s201, acquiring the attribute and the connection information of the connected equipment to be charged based on the connection state of the equipment to be charged.

All devices which are charged and can be used only after having enough electric quantity can be regarded as the devices to be charged. The connection state of the device to be charged can be understood as the state of whether the device to be charged is connected to the energy storage power supply.

The attribute of the device to be charged includes the type of the device to be charged, the model of the device to be charged, the charging mode supported by the device to be charged, and the like. The types of devices to be charged may include lighting devices, communication devices, heating devices, and the like. The model of the device to be charged may include the model of the lighting device, such as: home lighting, engineering lighting, commercial lighting, which may also include the brand and corresponding brand model of home lighting, engineering lighting, commercial lighting; the model number of the communication device may include, for example: the mobile phone, the computer, the telephone watch and the like can also comprise brands and corresponding brands and models of the mobile phone, the computer and the telephone watch; the model of the heating appliance may include a brand of the heating appliance and a corresponding brand model. The charging mode supported by the device to be charged may include: slow charge, fast charge, wireless charge, wherein slow charge means using alternating current to charge, the time that needs to be spent reaching the full charge state is longer, fast charge can be understood as that the battery can reach the full charge state in one to two hours, or the time spent comparing with fast charge is much shorter, wireless charge can be understood as the mode that realizes the battery charge under the condition of not passing through the connecting wire.

In some implementations, some devices to be charged may support fast charging, slow charging, and wireless charging simultaneously. When these devices that support fast charging, slow charging, wireless charging simultaneously charge through the connecting wire, it is generally preferred to use fast charging. The user can also perform relevant setting in the device, so that the device can select a corresponding charging mode to charge according to the setting condition of the user.

The connection information of the device to be charged may include a connection port type and a connection port number. The connection port types may include: two-port sockets, three-port sockets, USB interfaces and the like. Different connection port types can all set up a plurality ofly in the energy storage power supply that this application provided, consequently can set up corresponding connection port number for every connection port type position and distinguish.

Specifically, after determining which devices to be charged are connected to the energy storage power supply according to the connection state of the devices to be charged, the energy storage power supply may obtain the attributes and connection information of the devices to be charged in the connection state.

S202, determining relevant information of the connected equipment to be charged according to the attributes.

The related information of the device to be charged may mainly include a model of the device to be charged, for example, a model corresponding to a brand, and may further include information about a charging mode supported by the device to be charged and an applicable current corresponding to the charging mode.

Specifically, the relevant information of the devices to be charged, which are already connected with the energy storage power supply, is determined according to the attributes of the devices to be charged related to the step S201.

And S203, determining the priority of the connected equipment to be charged according to the preset equipment priority and the related information.

The preset priority of the equipment can be set when the energy storage power supply is produced, and can also be set according to the use frequency of the equipment to be charged in daily life. When the device priority is set, a layer of priority can be set according to the charging times of the device to be charged in daily life, and a plurality of layers of priorities can also be set according to time, weather or other basis. When some emergency situations or sudden changes exist, the energy storage power supply can detect the emergency situations or the sudden changes, and charging adjustment of some devices to be charged is carried out according to the set device priority, so that the devices in different scenes can meet the use requirements of the corresponding scenes through the charging adjustment.

In some implementations, a layer of priority may be set. At this time, the setting may be made according to the number of times of charging of the device to be charged in daily life. When the priorities are actually set, a large number of device usage data samples can be collected, then the devices to be charged are classified according to the classes of the devices, after the classification is completed, the devices to be charged are sorted according to the classification condition and the total charging times of all the devices in the class from a plurality of orders to determine the priority of the classes, and therefore the priorities of the classes are determined firstly according to the order. And sequencing the devices to be charged in each category from the top to the bottom according to the number of charging times, so as to determine the priority of the devices to be charged in the category. When the energy storage power supply is used for charging, the category of the equipment to be charged can be determined according to the determined related information, so that which equipment to be charged can be preferentially charged can be further determined.

In other implementation manners, multiple layers of priorities can be set according to weather conditions or use scenes, so that the priority of each device to be charged can be determined more accurately in different use scenes or different weather conditions, and then the charging state is adjusted and the charging is performed.

When the multiple layers of priorities are set according to the weather conditions or the use scenes, the priority of the first layer can be set according to the charging times of the equipment in daily life, and then the priorities of other layers can be set according to the actual weather conditions or the use scenes. For example, during play outside, this stored energy power source may need to charge a camera, a cell phone, a telephone watch, a navigator, a projector, etc. At this time, the setting of the priority may be made according to the frequency of use of these devices during the outbound. For example, a cell phone is used very frequently, a camera secondly, a telephone watch secondly, and finally a projector; or the frequency of use of the handset is high, the phone watch is followed by the camera and then finally by the projector. How often the specific use is, it can be known statistically by collecting a large amount of data of the use of the outbound devices.

In practical implementations, priorities may also be set between multiple layers of priorities. For example, the first layer of priority is a daily common situation, the second layer of priority is a priority corresponding to a plurality of weather conditions, and the third layer of priority is a priority corresponding to a plurality of usage scenarios. At this time, it may be set that the second layer priority > the third layer priority > the first layer priority, depending on the situation. With this form of arrangement, when multiple levels of priority are triggered, the priority relationship is more explicit, so that subsequent adjustments are made according to this priority relationship.

Specifically, the priorities of the devices to be charged, the connection of which has been confirmed, are determined according to the preset device priorities and the information about the devices to be charged, the connection of which has been confirmed in the above steps.

And S204, determining the first-stage charging equipment and adjusting the charging state of the first-stage charging equipment to charge the first-stage charging equipment according to the connection information and the priority.

The first-stage charging device may be understood as a device that has the highest priority and is charged preferentially when the energy storage device is accessed by multiple devices to be charged. There may be one or more.

The charging state may include a short circuit state and an on state. The short-circuit state indicates that the current of the energy storage power supply does not pass through the corresponding connection port, and although the connection port is connected, the charging is not performed. The on state indicates that the current of the energy storage power supply passes through the corresponding connection port to charge the connected device. In this embodiment, if the connection ports corresponding to some devices to be charged are in the on state, the connection ports corresponding to other devices to be charged may be set to the short-circuit state.

Specifically, according to the connection information and the priority obtained in the above steps, the first-stage charging devices that can be charged preferentially are determined, and the charging state of the first-stage charging devices is adjusted to the on state, so that the charging of the first-stage charging devices is realized.

By the method, the attribute and the connection information of the connected equipment to be charged can be known according to the connection state of the equipment to be charged. Firstly, determining relevant information of the connected devices to be charged according to the attributes, and then determining the priority of the connected devices to be charged according to the preset device priority and the relevant information, thereby determining the first-stage charging device according to the connection information and the priority and charging the first-stage charging device after the charging state is adjusted. The method enables the energy storage power supply to preferentially select which equipment is charged according to the priority of the equipment to be charged, and can avoid the problem that the charging time of each equipment is increased due to simultaneous charging after a plurality of equipment to be charged are connected. Meanwhile, by the method provided by the application, when the user wants to use the equipment with high priority, the equipment can be used in time, and the experience of the user is improved.

In some embodiments, the relevant information comprises an applicable current of the device to be charged. The current distribution condition of the energy storage power supply can be planned according to the applicable current of the first-stage charging equipment, and a current distribution scheme applicable to the first-stage charging equipment is obtained. And then, according to the current distribution scheme, adjusting the output current of the corresponding connection port of the first-stage charging equipment to achieve the purpose of charging the first-stage charging equipment. Specifically, the method may include: determining the applicable current of the first-stage charging equipment according to the relevant information; determining a current distribution scheme of the energy storage power supply according to the applicable current; and according to the current distribution scheme, adjusting the output current of the connecting port corresponding to the first-stage charging equipment to charge the first-stage charging equipment.

The applicable current can be understood as the current value which can enable each device to reach the full-charge state at the fastest charging speed when the device is charged.

Specifically, the applicable current of the first-stage charging device is determined according to the relevant information obtained in the above steps. According to the applicable current of the first-stage charging equipment, the total output current of the energy storage power supply is distributed, so that each piece of equipment related to the first-stage charging equipment can be charged at the fastest charging speed as far as possible.

In some implementations, there may be multiple first charging devices, and the total current of the energy storage power source may not be sufficient for all first stage charging devices to use the applicable current for charging. Therefore, when the situation is met, the equipment with the front priority can be determined according to the priority of the first-stage charging equipment, the equipment is charged according to the corresponding applicable current preferentially, and the equipment with the rear priority is distributed according to the residual output current of the preferentially stored energy power supply. In a specific implementation process, a current threshold may be set, where the current threshold may be set according to the available current of the device to be charged, and the generally set current threshold is a smaller current value in the available current of the device to be charged. When the current distributed to the equipment to be charged with the later priority is found to be less after distribution, the distributed output current is compared with the set current threshold value. If the distributed output current is higher than the current threshold value, the distributed output current can charge the equipment to be charged faster; if the distributed output current is lower than the current threshold value, the distributed output current is not suitable for charging the device to be charged, and the time spent for charging the device to be charged is too long. At this point, this less suitable device to be charged may be eliminated from the first stage charging device.

By the method provided by the embodiment, the current of the energy storage power supply can be distributed according to the applicable current of the first-stage charging equipment, so that the first-stage charging equipment can be charged at the fastest charging speed as much as possible. The charging time of each first-stage charging device is saved, and the charging efficiency is improved. Meanwhile, the use requirement of the user can be met in a shorter charging time, and the experience of the user is improved.

In some embodiments, whether the connection port of the first stage charging device is short-circuited is determined by the charge value of the first stage charging device, and then the charging state of the second stage charging device is adjusted to charge the second stage charging device. Specifically, the method can comprise the following steps: acquiring an electric quantity value of first-stage charging equipment; comparing the electric quantity value with a first preset electric quantity threshold value, and determining whether the electric quantity value is higher than the first preset electric quantity threshold value; if the electric quantity value is higher than a first preset electric quantity threshold value, determining second-stage charging equipment according to the connection information and the priority; and short-circuiting the corresponding connection port of the first-stage charging equipment and adjusting the charging state of the second-stage charging equipment to charge the second-stage charging equipment.

The first preset electric quantity threshold value can be understood as an electric quantity value that the first-stage charging device can meet the use requirement, and the preset electric quantity threshold value can be set according to the length that the electric quantity value of the first-stage charging device meets the use duration of a user. For example, when the electric quantity value of the mobile phone reaches 80% of the total electric quantity, the use requirement of the user for five hours can be met, and at this time, 80% of the total electric quantity can be used as a first preset electric quantity threshold value for meeting the use requirement of the user for five hours when the mobile phone is used by the user. The first preset electric quantity threshold may be fixedly set, that is, all the devices to be charged included in the first-stage charging device use the fixed first preset electric quantity threshold, or a threshold may be set for each of all the devices to be charged included in the first-stage charging device, but may be collectively referred to as the first preset electric quantity threshold.

The second-stage charging device may be understood as one or more connected devices to be charged that are second in priority to the first-stage charging device, based on the above-described preset device priority. The number of charging devices per level may be set by the manufacturer according to the specific capabilities of the energy storage power supply.

Specifically, the electric quantity value of the first-stage charging equipment is obtained, and the electric quantity value of the first-stage charging equipment is compared with a corresponding first preset electric quantity threshold value. If the electric quantity values of the devices to be charged contained in the first-stage charging device are all higher than the first preset electric quantity threshold value, it is indicated that all the devices to be charged in the first-stage charging device can meet the use requirements of users, at the moment, the second-stage charging device is determined according to the connection information and the priority, and meanwhile, the connection port corresponding to the first-stage charging device can be short-circuited, namely the first-stage charging device is connected with the energy storage power supply but the current of the energy storage power supply does not pass through the first-stage charging device. And adjusting the charging state of the second stage charging device to be in an on state to charge the second stage charging device.

Through the method provided by the embodiment, when the electric quantity value of the first-level charging device reaches the first preset electric quantity threshold value, it is described that the electric quantity of the first-level charging device can meet the use requirement of the user. At this time, the first-stage charging device may not be charged to a fully charged state, but after the first preset electric quantity threshold is reached, the connection port corresponding to the first-stage charging device is short-circuited, so as to adjust the charging state of the second-stage charging device and charge the second-stage charging device. In this way, the charging efficiency of all connected devices to be charged can be improved, and the devices can be made to meet the use requirements of users in a shorter time.

In some embodiments, the key devices that need to be charged at the current time may be determined according to the external environment state, then the connected key devices are set as the first-stage charging devices at the current time according to the connection state of the key devices, and the charging states of the devices are adjusted to charge the devices. Specifically, the method may include: acquiring the external environment state at the current moment; determining key equipment needing to be charged at the current moment according to the external environment state; acquiring the connection state of the key equipment, and determining the connected key equipment; and setting the connected key equipment as the first-stage charging equipment at the current moment, and adjusting the charging state of the first-stage charging equipment at the current moment to be the first-stage charging equipment at the current moment for charging.

The ambient condition may include a weather condition of the ambient environment. In a specific implementation mode, a camera can be arranged in the energy storage power supply, and the weather condition of the external environment at the current moment is determined by analyzing the shot image. In addition, a module capable of knowing time change can be arranged in the energy storage power supply, namely, the module can know the time of the current moment, and the time of the current moment can also reflect the external environment state of the current moment, such as day light and day black of several points.

The key equipment can be understood as equipment which needs to be charged preferentially and is determined according to the external environment state at the current moment. May be equal to the second-tier priority set according to the weather conditions among the multi-tier priorities referred to in the above-mentioned preset device priorities. For example, when it is detected that the external light has been dim or the current time is obtained at night 18. The lighting device may act as a key device. In addition, all the devices which need to be charged preferentially in the current environment state can be used as key devices whether connected with an energy storage power supply or not.

Specifically, the external environment state at the current moment is obtained, and the key equipment needing to be charged preferentially at the current moment is determined according to the external environment state at the current moment. And then acquiring the connection states of the key devices, determining the connected key devices, setting the connected key devices as first-stage charging devices at the current moment, adjusting the charging states of the key devices to be in an on state, and charging the key devices.

In some embodiments, the key device that is not connected at the current time is determined according to the connection state of the key device. And then determining the weight of the unconnected key equipment according to the external environment state, starting voice reminding according to the weight, and playing a connection prompt. Specifically, the method can comprise the following steps: determining the unconnected key equipment at the current moment according to the connection state of the key equipment; determining the weight of the unconnected key equipment according to the external environment state; and determining whether to start a voice prompt to play a connection prompt of the unconnected key equipment or not according to the weight of the unconnected key equipment.

The weight of the unconnected critical devices may be understood as the weight of the unconnected critical devices to all critical devices at the current time, i.e. the importance of these unconnected critical devices at the current time. For example, if the current time is dark and the lighting device is urgently needed, the lighting device may be regarded as important at the current time and the weight is relatively large.

This form of voice alert may be accomplished by providing an intelligent voice assistant in the energy storage power source. This intelligent voice assistant needs to be set in advance when the energy storage power supply is produced, and the set content may include a wake-up instruction, a reminder instruction, and the like. A wake-up command may be understood as a command for a user to wake up the energy storage power supply for certain operations. The reminding instruction can be understood as reminding of the user by the energy storage power supply according to the acquired related information or other contents.

Specifically, the unconnected key device may be determined according to the connection state of the key device. And then determining the weight of the unconnected key equipment in all the key equipment according to the acquired external environment state. And then determining whether to start a voice prompt to play a connection prompt of the unconnected key equipment or not according to the weight of the unconnected key equipment in all the key equipment.

In a specific implementation manner, if the weight of some key devices is higher, but the key devices are not connected to the energy storage power supply at the current moment, the voice prompt can be started to play the connection prompt of the corresponding key devices. However, the connection prompt is only used for reminding the user of charging in time, so that the purpose of reminding the user is achieved, and the prompt is not always performed before the key equipment which is higher in weight but not connected to the energy storage power supply is connected to the energy storage power supply.

In other implementation manners, a weight threshold may be set, and when the weight of the unconnected key device is greater than the weight threshold, it indicates that the unconnected key device is important in the current external environment state, and a voice prompt may be started to play a connection prompt. If the weight of the unconnected key equipment is smaller than the weight threshold value, the unconnected key equipment is not important in the current external environment state, and the voice prompt can be not started to play the connection prompt.

By the method provided by the embodiment, the unconnected key devices can be determined according to the connection state of the key devices, and the weights of the unconnected key devices are determined according to the external environment state at the current moment, so that whether the voice prompt is started to play the corresponding connection prompt is determined. By the method, the user can be reminded in time, the situation that the key equipment which is not connected but has higher weight is powered off when the user uses the equipment is avoided, and the experience of the user is improved.

In some embodiments, the relevant information includes a charging mode supported by the connected device to be charged, and the energy storage power source includes a wireless charging slot. The charging mode of each device to be charged can be acquired, and then the device to be charged supporting wireless charging is determined. When the devices to be charged supporting wireless charging are connected to the connection port, the voice prompt is started to enable the devices to be charged to be adjusted to the wireless charging slot. Specifically, the method may include: determining the equipment to be charged supporting wireless charging according to the charging mode supported by the equipment to be charged; when the device to be charged supporting wireless charging accesses the corresponding connection port, the voice reminding playing connection port is started to adjust reminding.

The wireless charging groove is arranged on the energy storage power supply provided by the application, and wireless charging can be carried out on the equipment supporting wireless charging. And saving the connecting port of the energy storage power supply. The wireless charging slot can adjust the output power according to the placed equipment, so that each equipment placed in the wireless charging slot can be charged at the fastest charging speed as possible.

Specifically, since the number of devices supporting wireless charging in the market at present is small and the number of devices not supporting wireless charging is large, it is determined which connected devices to be charged can be charged using wireless charging according to the determined charging mode supported by the connected devices to be charged. When the devices to be charged supporting wireless charging are connected to the corresponding connection ports, the intelligent voice assistant set by the embodiment is started to play the connection port adjustment prompt, so that the purpose of saving the connection ports is achieved.

In a specific implementation process, when the devices to be charged supporting wireless charging are connected to the corresponding connection ports, whether the wireless charging slot is in an idle state or not can be detected firstly. If the wireless charging slot is detected to be in an idle state, voice reminding can be carried out. If the wireless charging grooves are detected to be used, when the devices to be charged supporting wireless charging are connected to the corresponding connecting ports, voice reminding can be omitted.

Through the mode that this embodiment provided, can carry out the pronunciation when some equipment that supports wireless charging is connected to the connection port that corresponds and charges, make it charge in wireless charging groove to can make these connection ports idle, with the demand that charges that satisfies other equipment that do not support wireless charging, improve energy storage power's availability factor.

In some embodiments, the electric quantity of the energy storage power supply itself may be acquired, and when the electric quantity of the energy storage power supply itself is low, it may be determined whether the power consumption requirement is satisfied by solar charging according to the external environment state. If the power supply voltage does not meet the preset value, a voice prompt can be started to play a low-power warning, so that the user can charge the energy storage power supply in time. Specifically, the method may include: acquiring the electric quantity of an energy storage power supply; comparing the electric quantity of the energy storage power supply with a second preset electric quantity threshold value; determining whether the electric quantity of the energy storage power supply is lower than a second preset electric quantity threshold value; if the electric quantity of the energy storage power supply is lower than a second preset electric quantity threshold value, determining whether the power consumption requirement is met by solar charging at the current moment according to the external environment state; if the power utilization requirement is not met through solar charging at the current moment, a voice prompt is started to play a low-power warning.

The second preset electric quantity threshold value can be understood as the minimum electric quantity value that the energy storage power supply can meet the charging requirement, or can also be understood as the electric quantity value that the energy storage power supply is not enough to support the charging of the device to be charged. In addition, when the electric quantity of most of the devices is low, if the devices are still in the operating state, certain damage may be caused to the batteries of the devices, and therefore, the second preset electric quantity threshold value may also be understood as the minimum electric quantity value that does not cause any damage to the batteries of the energy storage power supply in the operating process. In this embodiment, the second preset electric quantity threshold may represent a minimum electric quantity value that does not cause any damage to the battery of the energy storage power supply during the operation.

The charging mode of the energy storage power supply can be divided into solar charging, commercial power charging, vehicle-mounted charging, generator charging and the like. Solar charging can be understood as setting up a solar panel on the energy storage power supply, can be through absorbing light energy to convert light energy into the electric energy and realize charging of energy storage power supply. Compared with other modes, the solar charging mode has the advantages that the cost is the least, and the mode is the most environment-friendly mode, so that the charging modes can be sorted according to the priority when the energy storage power supply is produced, for example, the solar charging mode > the commercial power charging mode > the generator charging mode > vehicle-mounted charging. Through the setting of the priority of the energy storage power supply, the energy storage power supply can finish charging in a shorter time.

Specifically, the electric quantity of the energy storage power supply is obtained and compared with a second preset electric quantity threshold value, and whether the electric quantity of the energy storage power supply is lower than the second preset electric quantity threshold value or not is determined. If the electric quantity of the energy storage power supply is higher than the second preset electric quantity threshold value, it indicates that the energy storage power supply can also continue to charge some devices to be charged at the moment, and the battery arranged in the energy storage power supply cannot be damaged. If the electric quantity of the energy storage power supply is lower than the second preset electric quantity threshold value, it indicates that the battery arranged in the energy storage power supply may be damaged if the energy storage power supply continues to charge the device to be charged. If the electric quantity of the energy storage power supply is lower than the second preset electric quantity threshold value through comparison, whether the energy storage power supply can meet the power consumption requirement of a user or not through solar charging is determined according to the external environment state at the current moment. If the energy storage power supply can meet the power demand of a user by charging in a solar energy mode, the energy storage power supply is directly charged. If the energy storage power supply cannot meet the power consumption requirement of the user through the solar charging mode, the user can be informed of using other modes to charge the energy storage power supply in time through the voice reminding playing of low-power warning.

In a specific implementation manner, after the low-power warning is performed according to the priority order corresponding to the charging manner of the energy storage power supply, the user is prompted to charge the energy storage power supply in a relatively better manner.

In other implementation manners, the solar energy can be set to supplement electric quantity for the energy storage power supply in time in a fixed time period.

Through the mode that this embodiment provided, can be when energy storage power supply electric quantity is lower, confirm whether solar charging can make energy storage power supply satisfy user's power consumption demand through the external environment state at the present moment. If solar charging can not enable the energy storage power supply to meet the power consumption requirement of the user at the current moment, at the moment, voice can be started to remind the user to play a low-power warning, so that the user can timely utilize other modes to charge the energy storage power supply.

Fig. 3 is a schematic structural diagram of an energy storage power supply according to an embodiment of the present application, and as shown in fig. 3, the energy storage power supply 300 of the embodiment includes: the system comprises an information acquisition module 301, an information determination module 302, a priority determination module 303 and a state adjustment module 304.

An information obtaining module 301, configured to obtain an attribute and connection information of a connected device to be charged based on a connection state of the device to be charged;

an information determining module 302, configured to determine, according to the attribute, relevant information of the connected device to be charged;

a priority determining module 303, configured to determine a priority of the connected device to be charged according to a preset device priority and the relevant information;

a state adjusting module 304, configured to determine a first-stage charging device according to the connection information and the priority, and adjust a charging state of the first-stage charging device to charge the first-stage charging device.

Optionally, the state adjusting module 304 is specifically configured to:

Optionally, the energy storage power supply 300 further includes a device adjusting module 305, configured to:

acquiring the electric quantity value of the first-stage charging equipment;

Optionally, the energy storage power supply 300 further includes a key device adjusting module 306, configured to:

acquiring the external environment state at the current moment;

and setting the connected key equipment as the first-stage charging equipment at the current moment and adjusting the charging state of the first-stage charging equipment at the current moment to be the first-stage charging equipment at the current moment for charging.

Optionally, the energy storage power supply 300 further includes a first voice reminding module 307, configured to:

Optionally, the energy storage power supply 300 further includes a second voice prompt module 308, configured to:

Optionally, the energy storage power supply 300 further includes a charging module 309, configured to:

acquiring the electric quantity of the energy storage power supply;

The apparatus of this embodiment may be configured to perform the method of any of the above embodiments, and the implementation principle and the technical effect are similar, which are not described herein again.

Fig. 4 is a schematic structural diagram of another energy storage power supply provided in an embodiment of the application, and as shown in fig. 4, the energy storage power supply 400 of the embodiment may include: a memory 401 and a processor 402.

The memory 401 has stored thereon a computer program that can be loaded by the processor 402 and executed to perform the method in the above-described embodiments.

The processor 402 is coupled to the memory 401, such as via a bus.

Optionally, the energy storage power supply 400 may also include a transceiver. It should be noted that, in practical applications, the transceiver is not limited to one, and the structure of the energy storage power supply 400 does not constitute a limitation to the embodiment of the present application.

The Processor 402 may be a CPU (Central Processing Unit), a general purpose Processor, a DSP (Digital Signal Processor), an ASIC (Application Specific Integrated Circuit), an FPGA (Field Programmable Gate Array), or other Programmable logic device, transistor logic, hardware components, or any combination thereof. Which may implement or execute the various illustrative logical blocks, modules, and circuits described in connection with the disclosure herein. The processor 402 may also be a combination of computing functions, e.g., comprising one or more microprocessors, a combination of a DSP and a microprocessor, or the like.

A bus may include a path that transfers information between the above components. The bus may be a PCI (Peripheral Component Interconnect) bus, an EISA (Extended Industry Standard Architecture) bus, or the like. The bus may be divided into an address bus, a data bus, a control bus, etc. For ease of illustration, only one thick line is shown, but this does not mean that there is only one bus or one type of bus.

The Memory 401 may be a ROM (Read Only Memory) or other type of static storage device that can store static information and instructions, a RAM (Random Access Memory) or other type of dynamic storage device that can store information and instructions, an EEPROM (Electrically Erasable Programmable Read Only Memory), a CD-ROM (Compact Disc Read Only Memory) or other optical Disc storage, optical Disc storage (including Compact Disc, laser Disc, optical Disc, digital versatile Disc, blu-ray Disc, etc.), a magnetic Disc storage medium or other magnetic storage device, or any other medium that can be used to carry or store desired program code in the form of instructions or data structures and that can be accessed by a computer, but is not limited to these.

The memory 401 is used for storing application program codes for executing the scheme of the application, and the processor 402 is used for controlling the execution. The processor 402 is configured to execute application program code stored in the memory 401 to implement the content shown in the foregoing method embodiments.

Among them, the energy storage power source includes but is not limited to: mobile terminals such as mobile phones, notebook computers, digital broadcast receivers, PDAs (personal digital assistants), PADs (tablet computers), PMPs (portable multimedia players), in-vehicle terminals (e.g., in-vehicle navigation terminals), and the like, and fixed terminals such as digital TVs, desktop computers, and the like. But also a server, etc. The energy storage power supply shown in fig. 4 is only an example, and should not bring any limitation to the function and the use range of the embodiment of the present application.

The energy storage power supply of this embodiment may be configured to perform the method of any of the above embodiments, and the implementation principle and the technical effect are similar, which are not described herein again.

The present application also provides a computer readable storage medium storing a computer program that can be loaded by a processor and executed to perform the method as in the above embodiments.

Those of ordinary skill in the art will understand that: all or a portion of the steps of implementing the above-described method embodiments may be performed by hardware associated with program instructions. The program may be stored in a computer-readable storage medium. When executed, the program performs steps comprising the method embodiments described above; and the aforementioned storage medium includes: various media that can store program codes, such as ROM, RAM, magnetic or optical disks.

Claims

1. A charging management method of an energy storage power supply is characterized by comprising the following steps:

determining the priority of the connected equipment to be charged according to the preset equipment priority and the relevant information;

2. The method of claim 1, wherein the related information comprises an applicable current of the connected device to be charged; according to the connection information and the priority, determining first-stage charging equipment and adjusting the charging state of the first-stage charging equipment to charge the first-stage charging equipment comprises the following steps:

3. The method of claim 2, further comprising:

acquiring the electric quantity value of the first-stage charging equipment;

4. The method of claim 1, further comprising:

acquiring the external environment state at the current moment;

5. The method of claim 4, further comprising:

6. The method of claim 1, wherein the related information comprises a charging mode supported by the connected device to be charged, and the energy storage power source comprises a wireless charging slot; the method further comprises the following steps:

7. The method of claim 1, further comprising:

acquiring the electric quantity of the energy storage power supply;

8. An energy storage power supply, comprising:

the priority determining module is used for determining the priority of the connected equipment to be charged according to the preset equipment priority and the related information;

9. An energy storage power supply, comprising: a memory and a processor;

the memory to store program instructions;

the processor is used for calling and executing the program instructions in the memory to execute the charging management method of the energy storage power supply according to any one of claims 1 to 7.

10. A computer-readable storage medium, characterized in that a computer program is stored in the computer-readable storage medium; the computer program, when executed by a processor, implements a method of managing charging of an energy storage power supply as claimed in any one of claims 1 to 7.